US20160160312A1 - Hydrometallurgical System and Process Using an Ion Transport Membrane - Google Patents
Hydrometallurgical System and Process Using an Ion Transport Membrane Download PDFInfo
- Publication number
- US20160160312A1 US20160160312A1 US14/560,526 US201414560526A US2016160312A1 US 20160160312 A1 US20160160312 A1 US 20160160312A1 US 201414560526 A US201414560526 A US 201414560526A US 2016160312 A1 US2016160312 A1 US 2016160312A1
- Authority
- US
- United States
- Prior art keywords
- unit
- oxygen
- gas
- product
- metal
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Abandoned
Links
- 239000012528 membrane Substances 0.000 title claims abstract description 210
- 230000037427 ion transport Effects 0.000 title claims abstract description 165
- 238000000034 method Methods 0.000 title claims abstract description 76
- 230000008569 process Effects 0.000 title claims abstract description 70
- 239000001301 oxygen Substances 0.000 claims abstract description 323
- 229910052760 oxygen Inorganic materials 0.000 claims abstract description 323
- QVGXLLKOCUKJST-UHFFFAOYSA-N atomic oxygen Chemical compound [O] QVGXLLKOCUKJST-UHFFFAOYSA-N 0.000 claims abstract description 316
- 238000012545 processing Methods 0.000 claims abstract description 190
- 239000000047 product Substances 0.000 claims description 256
- 239000007789 gas Substances 0.000 claims description 224
- IJGRMHOSHXDMSA-UHFFFAOYSA-N Atomic nitrogen Chemical compound N#N IJGRMHOSHXDMSA-UHFFFAOYSA-N 0.000 claims description 212
- 238000002386 leaching Methods 0.000 claims description 150
- 239000000463 material Substances 0.000 claims description 147
- 229910052751 metal Inorganic materials 0.000 claims description 141
- 239000002184 metal Substances 0.000 claims description 141
- 230000001590 oxidative effect Effects 0.000 claims description 110
- 229910052757 nitrogen Inorganic materials 0.000 claims description 106
- 238000004519 manufacturing process Methods 0.000 claims description 98
- QGZKDVFQNNGYKY-UHFFFAOYSA-N Ammonia Chemical compound N QGZKDVFQNNGYKY-UHFFFAOYSA-N 0.000 claims description 92
- 238000007254 oxidation reaction Methods 0.000 claims description 92
- 239000002002 slurry Substances 0.000 claims description 83
- UFHFLCQGNIYNRP-UHFFFAOYSA-N Hydrogen Chemical compound [H][H] UFHFLCQGNIYNRP-UHFFFAOYSA-N 0.000 claims description 75
- 239000007800 oxidant agent Substances 0.000 claims description 75
- 239000001257 hydrogen Substances 0.000 claims description 74
- 229910052739 hydrogen Inorganic materials 0.000 claims description 74
- 238000000227 grinding Methods 0.000 claims description 72
- 230000003647 oxidation Effects 0.000 claims description 71
- 238000005188 flotation Methods 0.000 claims description 70
- 238000007781 pre-processing Methods 0.000 claims description 57
- 229910021529 ammonia Inorganic materials 0.000 claims description 46
- 238000011084 recovery Methods 0.000 claims description 44
- 239000002253 acid Substances 0.000 claims description 32
- 239000012466 permeate Substances 0.000 claims description 32
- 238000012805 post-processing Methods 0.000 claims description 27
- 150000002926 oxygen Chemical class 0.000 claims description 26
- 230000002950 deficient Effects 0.000 claims description 25
- 238000011144 upstream manufacturing Methods 0.000 claims description 24
- 238000009854 hydrometallurgy Methods 0.000 claims description 23
- 238000002485 combustion reaction Methods 0.000 claims description 19
- 239000012141 concentrate Substances 0.000 claims description 18
- 238000004064 recycling Methods 0.000 claims description 18
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims description 18
- 238000000746 purification Methods 0.000 claims description 17
- 238000002360 preparation method Methods 0.000 claims description 16
- 239000000446 fuel Substances 0.000 claims description 15
- 238000001035 drying Methods 0.000 claims description 14
- 238000010438 heat treatment Methods 0.000 claims description 14
- 238000005067 remediation Methods 0.000 claims description 14
- UGFAIRIUMAVXCW-UHFFFAOYSA-N Carbon monoxide Chemical compound [O+]#[C-] UGFAIRIUMAVXCW-UHFFFAOYSA-N 0.000 claims description 13
- 238000002156 mixing Methods 0.000 claims description 13
- 239000007788 liquid Substances 0.000 claims description 12
- 239000003546 flue gas Substances 0.000 claims description 7
- 238000012546 transfer Methods 0.000 claims description 6
- 238000006243 chemical reaction Methods 0.000 claims description 5
- 238000007667 floating Methods 0.000 claims description 2
- 230000010354 integration Effects 0.000 description 19
- 239000003570 air Substances 0.000 description 14
- -1 platinum group metals Chemical class 0.000 description 14
- 238000006386 neutralization reaction Methods 0.000 description 13
- 239000000203 mixture Substances 0.000 description 11
- PXHVJJICTQNCMI-UHFFFAOYSA-N Nickel Chemical compound [Ni] PXHVJJICTQNCMI-UHFFFAOYSA-N 0.000 description 10
- 230000009467 reduction Effects 0.000 description 9
- 238000006722 reduction reaction Methods 0.000 description 9
- XEEYBQQBJWHFJM-UHFFFAOYSA-N Iron Chemical compound [Fe] XEEYBQQBJWHFJM-UHFFFAOYSA-N 0.000 description 8
- 230000004913 activation Effects 0.000 description 7
- 229910052500 inorganic mineral Inorganic materials 0.000 description 7
- 150000002739 metals Chemical class 0.000 description 7
- 239000011707 mineral Substances 0.000 description 7
- RYGMFSIKBFXOCR-UHFFFAOYSA-N Copper Chemical compound [Cu] RYGMFSIKBFXOCR-UHFFFAOYSA-N 0.000 description 6
- ZOKXTWBITQBERF-UHFFFAOYSA-N Molybdenum Chemical compound [Mo] ZOKXTWBITQBERF-UHFFFAOYSA-N 0.000 description 6
- CBENFWSGALASAD-UHFFFAOYSA-N Ozone Chemical compound [O-][O+]=O CBENFWSGALASAD-UHFFFAOYSA-N 0.000 description 6
- QAOWNCQODCNURD-UHFFFAOYSA-N Sulfuric acid Chemical compound OS(O)(=O)=O QAOWNCQODCNURD-UHFFFAOYSA-N 0.000 description 6
- 238000001816 cooling Methods 0.000 description 6
- 239000010949 copper Substances 0.000 description 6
- 229910052802 copper Inorganic materials 0.000 description 6
- 239000011733 molybdenum Substances 0.000 description 6
- 229910052750 molybdenum Inorganic materials 0.000 description 6
- 239000010970 precious metal Substances 0.000 description 6
- XFXPMWWXUTWYJX-UHFFFAOYSA-N Cyanide Chemical compound N#[C-] XFXPMWWXUTWYJX-UHFFFAOYSA-N 0.000 description 5
- 230000000712 assembly Effects 0.000 description 5
- 238000000429 assembly Methods 0.000 description 5
- 238000011161 development Methods 0.000 description 5
- 230000018109 developmental process Effects 0.000 description 5
- 229910052759 nickel Inorganic materials 0.000 description 5
- 239000000126 substance Substances 0.000 description 5
- 239000012080 ambient air Substances 0.000 description 4
- 229910017052 cobalt Inorganic materials 0.000 description 4
- 239000010941 cobalt Substances 0.000 description 4
- GUTLYIVDDKVIGB-UHFFFAOYSA-N cobalt atom Chemical compound [Co] GUTLYIVDDKVIGB-UHFFFAOYSA-N 0.000 description 4
- 238000010586 diagram Methods 0.000 description 4
- 229910001882 dioxygen Inorganic materials 0.000 description 4
- 229910052742 iron Inorganic materials 0.000 description 4
- 239000002893 slag Substances 0.000 description 4
- ZAMOUSCENKQFHK-UHFFFAOYSA-N Chlorine atom Chemical compound [Cl] ZAMOUSCENKQFHK-UHFFFAOYSA-N 0.000 description 3
- MYMOFIZGZYHOMD-UHFFFAOYSA-N Dioxygen Chemical compound O=O MYMOFIZGZYHOMD-UHFFFAOYSA-N 0.000 description 3
- 238000010531 catalytic reduction reaction Methods 0.000 description 3
- 239000000460 chlorine Substances 0.000 description 3
- 229910052801 chlorine Inorganic materials 0.000 description 3
- 230000006835 compression Effects 0.000 description 3
- 238000007906 compression Methods 0.000 description 3
- 230000003750 conditioning effect Effects 0.000 description 3
- 239000002274 desiccant Substances 0.000 description 3
- 238000000605 extraction Methods 0.000 description 3
- 230000014509 gene expression Effects 0.000 description 3
- 239000011533 mixed conductor Substances 0.000 description 3
- CURLTUGMZLYLDI-UHFFFAOYSA-N Carbon dioxide Chemical compound O=C=O CURLTUGMZLYLDI-UHFFFAOYSA-N 0.000 description 2
- UCKMPCXJQFINFW-UHFFFAOYSA-N Sulphide Chemical compound [S-2] UCKMPCXJQFINFW-UHFFFAOYSA-N 0.000 description 2
- RAHZWNYVWXNFOC-UHFFFAOYSA-N Sulphur dioxide Chemical compound O=S=O RAHZWNYVWXNFOC-UHFFFAOYSA-N 0.000 description 2
- 229910052770 Uranium Inorganic materials 0.000 description 2
- HCHKCACWOHOZIP-UHFFFAOYSA-N Zinc Chemical compound [Zn] HCHKCACWOHOZIP-UHFFFAOYSA-N 0.000 description 2
- 230000002378 acidificating effect Effects 0.000 description 2
- 230000003213 activating effect Effects 0.000 description 2
- 230000008901 benefit Effects 0.000 description 2
- 230000000295 complement effect Effects 0.000 description 2
- 230000001143 conditioned effect Effects 0.000 description 2
- 230000008878 coupling Effects 0.000 description 2
- 238000010168 coupling process Methods 0.000 description 2
- 238000005859 coupling reaction Methods 0.000 description 2
- 125000004122 cyclic group Chemical group 0.000 description 2
- PCHJSUWPFVWCPO-UHFFFAOYSA-N gold Chemical compound [Au] PCHJSUWPFVWCPO-UHFFFAOYSA-N 0.000 description 2
- 229910052737 gold Inorganic materials 0.000 description 2
- 239000010931 gold Substances 0.000 description 2
- 239000011133 lead Substances 0.000 description 2
- WPBNNNQJVZRUHP-UHFFFAOYSA-L manganese(2+);methyl n-[[2-(methoxycarbonylcarbamothioylamino)phenyl]carbamothioyl]carbamate;n-[2-(sulfidocarbothioylamino)ethyl]carbamodithioate Chemical compound [Mn+2].[S-]C(=S)NCCNC([S-])=S.COC(=O)NC(=S)NC1=CC=CC=C1NC(=S)NC(=O)OC WPBNNNQJVZRUHP-UHFFFAOYSA-L 0.000 description 2
- VNWKTOKETHGBQD-UHFFFAOYSA-N methane Chemical compound C VNWKTOKETHGBQD-UHFFFAOYSA-N 0.000 description 2
- 229910003455 mixed metal oxide Inorganic materials 0.000 description 2
- YFLLTMUVNFGTIW-UHFFFAOYSA-N nickel;sulfanylidenecopper Chemical compound [Ni].[Cu]=S YFLLTMUVNFGTIW-UHFFFAOYSA-N 0.000 description 2
- 229910052761 rare earth metal Inorganic materials 0.000 description 2
- 150000002910 rare earth metals Chemical class 0.000 description 2
- 239000011819 refractory material Substances 0.000 description 2
- 229910052702 rhenium Inorganic materials 0.000 description 2
- WUAPFZMCVAUBPE-UHFFFAOYSA-N rhenium atom Chemical compound [Re] WUAPFZMCVAUBPE-UHFFFAOYSA-N 0.000 description 2
- 238000000926 separation method Methods 0.000 description 2
- 229910052709 silver Inorganic materials 0.000 description 2
- 239000004332 silver Substances 0.000 description 2
- 238000000638 solvent extraction Methods 0.000 description 2
- UMGDCJDMYOKAJW-UHFFFAOYSA-N thiourea Chemical compound NC(N)=S UMGDCJDMYOKAJW-UHFFFAOYSA-N 0.000 description 2
- JFALSRSLKYAFGM-UHFFFAOYSA-N uranium(0) Chemical compound [U] JFALSRSLKYAFGM-UHFFFAOYSA-N 0.000 description 2
- 229910052725 zinc Inorganic materials 0.000 description 2
- 239000011701 zinc Substances 0.000 description 2
- QGZKDVFQNNGYKY-UHFFFAOYSA-O Ammonium Chemical compound [NH4+] QGZKDVFQNNGYKY-UHFFFAOYSA-O 0.000 description 1
- CPELXLSAUQHCOX-UHFFFAOYSA-M Bromide Chemical compound [Br-] CPELXLSAUQHCOX-UHFFFAOYSA-M 0.000 description 1
- 239000004215 Carbon black (E152) Substances 0.000 description 1
- VEXZGXHMUGYJMC-UHFFFAOYSA-M Chloride anion Chemical compound [Cl-] VEXZGXHMUGYJMC-UHFFFAOYSA-M 0.000 description 1
- DGAQECJNVWCQMB-PUAWFVPOSA-M Ilexoside XXIX Chemical compound C[C@@H]1CC[C@@]2(CC[C@@]3(C(=CC[C@H]4[C@]3(CC[C@@H]5[C@@]4(CC[C@@H](C5(C)C)OS(=O)(=O)[O-])C)C)[C@@H]2[C@]1(C)O)C)C(=O)O[C@H]6[C@@H]([C@H]([C@@H]([C@H](O6)CO)O)O)O.[Na+] DGAQECJNVWCQMB-PUAWFVPOSA-M 0.000 description 1
- BQCADISMDOOEFD-UHFFFAOYSA-N Silver Chemical compound [Ag] BQCADISMDOOEFD-UHFFFAOYSA-N 0.000 description 1
- 238000003723 Smelting Methods 0.000 description 1
- ZMZDMBWJUHKJPS-UHFFFAOYSA-M Thiocyanate anion Chemical compound [S-]C#N ZMZDMBWJUHKJPS-UHFFFAOYSA-M 0.000 description 1
- XSQUKJJJFZCRTK-UHFFFAOYSA-N Urea Natural products NC(N)=O XSQUKJJJFZCRTK-UHFFFAOYSA-N 0.000 description 1
- OLBVUFHMDRJKTK-UHFFFAOYSA-N [N].[O] Chemical compound [N].[O] OLBVUFHMDRJKTK-UHFFFAOYSA-N 0.000 description 1
- 239000003463 adsorbent Substances 0.000 description 1
- 238000005273 aeration Methods 0.000 description 1
- 230000015572 biosynthetic process Effects 0.000 description 1
- FAYYUXPSKDFLEC-UHFFFAOYSA-L calcium;dioxido-oxo-sulfanylidene-$l^{6}-sulfane Chemical compound [Ca+2].[O-]S([O-])(=O)=S FAYYUXPSKDFLEC-UHFFFAOYSA-L 0.000 description 1
- 229910002092 carbon dioxide Inorganic materials 0.000 description 1
- 239000001569 carbon dioxide Substances 0.000 description 1
- 239000000919 ceramic Substances 0.000 description 1
- 229910010293 ceramic material Inorganic materials 0.000 description 1
- 239000003795 chemical substances by application Substances 0.000 description 1
- 239000000567 combustion gas Substances 0.000 description 1
- 239000002131 composite material Substances 0.000 description 1
- XLJMAIOERFSOGZ-UHFFFAOYSA-M cyanate Chemical compound [O-]C#N XLJMAIOERFSOGZ-UHFFFAOYSA-M 0.000 description 1
- 230000006378 damage Effects 0.000 description 1
- 238000001784 detoxification Methods 0.000 description 1
- 238000011143 downstream manufacturing Methods 0.000 description 1
- 238000005363 electrowinning Methods 0.000 description 1
- 238000005516 engineering process Methods 0.000 description 1
- 230000002255 enzymatic effect Effects 0.000 description 1
- 239000000284 extract Substances 0.000 description 1
- 239000002737 fuel gas Substances 0.000 description 1
- 150000004820 halides Chemical class 0.000 description 1
- 229930195733 hydrocarbon Natural products 0.000 description 1
- 150000002430 hydrocarbons Chemical class 0.000 description 1
- XMBWDFGMSWQBCA-UHFFFAOYSA-N hydrogen iodide Chemical compound I XMBWDFGMSWQBCA-UHFFFAOYSA-N 0.000 description 1
- ZMZDMBWJUHKJPS-UHFFFAOYSA-N hydrogen thiocyanate Natural products SC#N ZMZDMBWJUHKJPS-UHFFFAOYSA-N 0.000 description 1
- 238000009413 insulation Methods 0.000 description 1
- 150000002500 ions Chemical class 0.000 description 1
- 229910044991 metal oxide Inorganic materials 0.000 description 1
- 150000004706 metal oxides Chemical class 0.000 description 1
- 229910052752 metalloid Inorganic materials 0.000 description 1
- 150000002738 metalloids Chemical class 0.000 description 1
- 230000000116 mitigating effect Effects 0.000 description 1
- 239000003345 natural gas Substances 0.000 description 1
- 230000007935 neutral effect Effects 0.000 description 1
- 230000003472 neutralizing effect Effects 0.000 description 1
- 239000011224 oxide ceramic Substances 0.000 description 1
- 230000036284 oxygen consumption Effects 0.000 description 1
- 238000010979 pH adjustment Methods 0.000 description 1
- 239000002245 particle Substances 0.000 description 1
- 238000010248 power generation Methods 0.000 description 1
- 239000002244 precipitate Substances 0.000 description 1
- 238000009853 pyrometallurgy Methods 0.000 description 1
- 238000011946 reduction process Methods 0.000 description 1
- 238000007670 refining Methods 0.000 description 1
- 238000009877 rendering Methods 0.000 description 1
- 238000011160 research Methods 0.000 description 1
- 229910052710 silicon Inorganic materials 0.000 description 1
- 239000010703 silicon Substances 0.000 description 1
- 238000005245 sintering Methods 0.000 description 1
- 239000011734 sodium Substances 0.000 description 1
- 229910052708 sodium Inorganic materials 0.000 description 1
- 239000007787 solid Substances 0.000 description 1
- 238000001179 sorption measurement Methods 0.000 description 1
- 229910052569 sulfide mineral Inorganic materials 0.000 description 1
- 150000003464 sulfur compounds Chemical class 0.000 description 1
- 231100000331 toxic Toxicity 0.000 description 1
- 230000002588 toxic effect Effects 0.000 description 1
- 230000032258 transport Effects 0.000 description 1
Images
Classifications
-
- C22B3/0098—
-
- C—CHEMISTRY; METALLURGY
- C22—METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
- C22B—PRODUCTION AND REFINING OF METALS; PRETREATMENT OF RAW MATERIALS
- C22B3/00—Extraction of metal compounds from ores or concentrates by wet processes
- C22B3/02—Apparatus therefor
-
- C—CHEMISTRY; METALLURGY
- C22—METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
- C22B—PRODUCTION AND REFINING OF METALS; PRETREATMENT OF RAW MATERIALS
- C22B3/00—Extraction of metal compounds from ores or concentrates by wet processes
- C22B3/04—Extraction of metal compounds from ores or concentrates by wet processes by leaching
-
- C—CHEMISTRY; METALLURGY
- C22—METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
- C22B—PRODUCTION AND REFINING OF METALS; PRETREATMENT OF RAW MATERIALS
- C22B3/00—Extraction of metal compounds from ores or concentrates by wet processes
- C22B3/20—Treatment or purification of solutions, e.g. obtained by leaching
- C22B3/42—Treatment or purification of solutions, e.g. obtained by leaching by ion-exchange extraction
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P10/00—Technologies related to metal processing
- Y02P10/20—Recycling
Definitions
- the present invention relates to the production and utilization of oxygen in hydrometallurgical processes for obtaining one or more metal values from a metal-bearing material like mineral ore and/or concentrate.
- Hydrometallurgical processes are wet processes to extract and recover metals. They rely on leaching one or more valuable metals, so-called metal values, like gold, silver, platinum group metals, copper, nickel, cobalt, lead, zinc, manganese, molybdenum, rhenium, rare earth metals, and uranium from metal-bearing materials such as ore, concentrate, tailings, matte, slag, and calcine.
- the one or more metal values of interest are dissolved from the metal-bearing material into an appropriate solution. The solution is then separated from insoluble residue.
- the leaching process may employ one or more of a variety of chemicals such as dilute sulfuric acid and/or dilute aqueous cyanide.
- the lixiviant in solution may be acidic or basic or neutral in nature.
- Methods for contacting the metal-bearing material and the lixiviant can include agitating comminuted solids and solution (slurry) in open tanks, agitating slurry at a high temperature in a pressure vessel, and percolating lixiviant through crushed ore that has been piled in a heap or vat and collecting the solution that issues from the bottom.
- Enhanced- or high-temperature and pressure leach processes are performed in autoclaves. Autoclaves may be operated under oxidizing, acidic, or alkaline conditions. Oxidizing or reducing gases, such as air, oxygen, and sulfur dioxide, may be used, taking into account the gas-liquid contact requirements.
- the metal-bearing material may be pre-processed, as is the case e.g. with refractory materials like refractory ores, concentrates and tailings, to liberate the metal values and make them accessible to leaching.
- refractory materials like refractory ores, concentrates and tailings
- Common pre-processing options include roasting, pressure oxidation, bio-oxidation, and ultra-fine grinding.
- roasting, pressure oxidation, and bio-oxidation the metal-bearing material is oxidized.
- ultra-fine grinding the material is ground to small particle sizes such that the significant surfaces of the metal values are exposed, enabling high contact of the metal values with the lixiviant solution.
- Oxygen may also be required for atmospheric leaching, for activation of the metal-bearing material e.g. in a grinding process, for on-site production of acid, and/or for the remediation of lixiviant.
- Bio-oxidation and bio-leaching may also require oxygen.
- U.S. Pat. No. 3,741,752 discloses a process for the recovery of nickel and copper from copper-nickel-sulfide matte by means of a three-stage leaching process. Air is introduced into each of the leaching stages and furthermore into a copper purification stage following the second leaching stage.
- nickel-copper-sulfur concentrates are leached in a combination of a first stage atmospheric leaching unit and two subsequent pressure leaching stages. In each of these leaching stages or units, air or oxygen is used to create oxidizing conditions.
- U.S. Pat. No. 5,645,708 (Jones) utilizes a pressure oxidation pre-processing unit and an atmospheric leaching unit for the extraction of copper from sulfide copper ore or concentrate.
- U.S. Pat. No. 6,569,224 (Kerfoot et al.) teaches a hydrometallurgical process for the recovery of nickel and cobalt values from a sulfidic flotation concentrate with atmospheric chlorine leaching as pre-processing followed by downstream oxidative pressure leaching.
- Oxygen is introduced in the oxidative pressure leaching unit, and may also be used in the atmospheric leach pre-processing unit to maximize the reaction of sulfuric acid with sulfide minerals.
- U.S. Pat. No. 8,623,115 discloses hydrometallurgical processing of precious metal-bearing materials in which the precious metal-bearing material, in this case a refractory material, is comminuted and conditioned to form a slurry of a desired density which is subsequently subjected to pressure oxidation in an autoclave.
- the autoclave discharge slurry is flash cooled, neutralized and the neutralized discharge slurry is subjected to leaching with a suitable lixiviant.
- Cyanide, ammonium, sodium, and calcium thiosulfate and also halides (iodide, bromide, chloride), and thiourea are mentioned as typical leaching agents.
- the sorbed precious metal is recovered from the pregnant leach solution e.g. by electrowinning or cementation to form the precious metal product. Considerable amounts of oxygen are consumed in the pressure oxidation pre-processing circuit.
- U.S. Pat. No. 8,025,859 discloses a combination of pressure oxidation and downstream pressure cyanidation with optional intermediate atmospheric leaching and flotation.
- An initial metal-bearing material in the form of a concentrate slurry is subjected to pressure oxidation at elevated temperature and pressure, using high purity oxygen as oxidant.
- Pressure cyanidation is carried out under an elevated oxygen pressure to reduce the duration of the cyanidation and minimize thiocyanide formation.
- U.S. Pat. No. 8,268,037 discloses a method of recovering molybdenum from a molybdenum bearing sulfide material by bioleaching mentioning that adequate aeration is required as oxygen is the preferred terminal electron acceptor for enzymatic bio-oxidation of iron and sulfur compounds in the bioleaching process.
- the prior art processes exemplify the variety of applications of oxygen in hydrometallurgical processing facilities.
- air may be enriched by the addition of oxygen or substituted by a higher oxygen content gas or high purity oxygen to intensify the respective one or more oxidative reactions.
- PSANSA pressure or vacuum swing adsorption
- the present invention accomplishes economic supply of oxygen by integration of a hydrometallurgical processing circuit and an ion transport membrane assembly for the production of an oxygen product from an oxygen- and nitrogen-containing feed gas.
- the hydrometallurgical processing circuit is operatively disposed to receive an oxidant gas containing at least a portion of the oxygen product from the ion transport membrane assembly and/or activated oxygen generated from at least a portion of the oxygen product from the ion transport membrane assembly.
- the oxygen-containing feed gas to the ion transport membrane assembly may in particular be pressurized and heated air or a pressurized and heated gas mixture formed from air and one or more other sources.
- Gaseous effluent from the hydrometallurgical processing circuit e. g. vent gas and/or bleed gas from pressure oxidation and/or oxidative pressure leaching, may in particular be such a source.
- Oxygen can be separated from oxygen-containing gases, e.g. from air, at high temperatures by mixed metal oxide ceramic materials utilized in the form of nonporous ion transport membranes (ITM).
- ITM nonporous ion transport membranes
- An oxygen partial pressure differential or a voltage differential across the membrane causes oxygen ions to migrate through the membrane from the feed side to the permeate side.
- Ion transport membrane assemblies comprising one or more ion transport membranes each with one or more membrane layers and their utility in recovering oxygen from air or other oxygen-containing gases are known in the art (e.g. U.S. Pat. Nos. 5,681,373, 7,179,323, and 7,955,423).
- Particularly suited for the present invention are ion transport membrane assemblies with one or more membranes of the mixed conductor type, i.e. membranes in which an oxygen partial pressure differential across the respective membrane causes oxygen ions to migrate through the membrane from the feed side to the permeate side where the ions recombine to form electrons and oxygen product
- U.S. Pat. No. 5,643,354 discloses a high-temperature ion transport membrane assembly to recover oxygen for use in a direct iron making smelting process. Heat for the integrated oxygen recovery is obtained from the combustion of fuel gas and/or indirect heat exchange with a hot gas from the iron making process.
- a combined cycle power generation system is included so that the product portfolio of the ion transport membrane assembly includes oxygen product gas, electric power and steam. The steam is exported or expanded in a steam turbine to make additional electric power. The electric power is exported or used internally.
- U.S. Pat. No. 5,855,648 discloses the integration of an ion transport membrane assembly in a pyrometallurgical process.
- the oxygen product of the membrane assembly is added to the feed gas stream of a blast furnace for the production of iron from ore.
- the prior art has not yet considered utility of the ion transport membrane technology for the production of oxygen needed in the hydrometallurgical processing of metal-bearing materials to recover one or more of its metal values.
- the present invention proposes advantageous integrations of an ion transport membrane assembly with a hydrometallurgical processing circuit in a hydrometallurgical processing system and in a hydrometallurgical process.
- the hydrometallurgical processing circuit comprises a leaching unit and one or more pre-processing units. It may furthermore comprise one or more post-processing units and/or an acid production unit.
- the pre-processing unit is operatively disposed to receive a metal-bearing material and adapted to process the metal-bearing material, for example, by grinding or oxidation.
- the pre-processing unit is disposed upstream of the leaching unit.
- the leaching unit disposed downstream of the pre-processing unit may therefore be termed ‘downstream leaching unit’, not the least because an upstream leaching unit may constitute the pre-processing unit.
- the pre-processing unit may be any one of a grinding unit, in particular a ball mill, for grinding the metal-bearing material, a roasting unit for roasting the material, a pressure oxidation unit, a bio-oxidation unit, an atmospheric leaching unit, a bio-leaching unit, a pressure leaching unit, and a solution or slurry preparation unit, e.g. a solution or slurry neutralization unit.
- a solution or slurry preparation unit for example a solution or slurry neutralization unit, or a lixiviant remediation unit or a further leaching unit may constitute the optional post-processing unit.
- the pre-processing and post-processing units mentioned are potential oxygen consumers, the downstream leaching unit and the optional acid production unit as well.
- the hydrometallurgical processing circuit may comprise one or more pre-processing and/or post-processing units not requiring oxygen to perform their specific processing function. Identifying certain pre-processing and/or post-processing units as potential oxygen consumers does not mean necessarily that the respective unit, should the hydrometallurgical processing circuit comprise that unit, does need oxygen to accomplish its specific processing function, or is supplied by the ITM assembly.
- the hydrometallurgical processing circuit may comprise a grinding unit and/or a bio-oxidation unit and/or a bio-leaching unit and/or a remediation unit with no oxygen supply at all, and/or a pressure oxidation unit and/or an oxidative leaching unit not supplied with oxygen product from the ITM assembly.
- the hydrometallurgical processing circuit may comprise an acid production unit.
- the downstream leaching unit may in those embodiments operatively be disposed to receive acid from the acid production unit.
- the one or more pre-processing units comprise a pressure oxidation unit and/or an upstream leaching unit, at least one of these units may operatively be disposed to receive acid from the acid production unit. This includes embodiments in which only one of these units, i.e. only the downstream leaching unit, or only a pressure-oxidation unit, or only an upstream leaching unit, is operatively disposed to receive acid from the acid production unit, and also embodiments in which any two or all three of these units are present and operatively disposed to receive acid from the acid production unit.
- the hydrometallurgical processing circuit may comprise a post-processing unit as mentioned above.
- the post-processing unit is in those embodiments operatively disposed to receive at least a portion of the discharge material from the downstream leaching unit e.g. for subsequent solution or slurry neutralization, subsequent further leaching, or remediation of lixiviant.
- the optional subsequent further leaching unit may operatively be disposed to receive acid from the acid production unit, if present.
- the integrated processing system comprises one or more pre-processing units and one or more post-processing units, and optionally an acid production unit for producing acid which could be utilized in a leaching or pressure oxidation unit of the system, in particular, in one or more of the leaching units mentioned above.
- the hydrometallurgical processing circuit comprises a grinding unit and the downstream leaching unit
- the downstream leaching unit is operatively disposed to receive at least a portion of the material ground by the grinding unit.
- the ground material may be subjected to intermediate pre-processing, e.g. pressure oxidation, upstream leaching, and/or flotation on its way from the grinding unit to the downstream leaching unit.
- a roasting unit, a pressure oxidation unit, and a bio-oxidation unit are alternatives one to the other.
- the hydrometallurgical processing circuit may comprise any two or all three of these types of pre-processing units, such as, a roasting unit and a pressure oxidation unit in parallel, or a bio-oxidation unit and a pressure oxidation unit in series, only to mention examples of suitable combinations.
- One or more upstream leaching units may be adapted to separate different metals from one another by dissolving metals selectively.
- the downstream leaching unit may, for example, operatively be disposed to receive either the fraction with the one or more dissolved metals or the fraction with one or more other metals not dissolved in upstream leaching.
- At least one of the pre-processing unit, the downstream leaching unit, the acid production unit, if present, and the post-processing unit, if present, is an oxygen consuming unit and operatively disposed to receive an oxidant gas containing at least a portion of the oxygen product from the ion transport membrane assembly or activated oxygen, typically ozone, generated from at least a portion of the oxygen product from the ion transport membrane assembly.
- any two or any three or all four of the units mentioned may be oxygen consuming units, but not each of the oxygen consuming units must be provided with oxidant gas from the ion transport membrane assembly. Rather, oxidant gas containing oxygen product from the ion transport membrane assembly or activated oxygen generated therefrom may be provided to only a subgroup of oxygen consuming units of the hydrometallurgical processing system.
- the ion transport membrane assembly is adapted to provide at least part of the oxygen consumed by the hydrometallurgical processing circuit during operation in at least one oxidative process performed by the at least one oxygen consuming unit.
- the oxygen product may be used as such as oxidant in one or more oxygen consuming units of the hydrometallurgical process circuit. It may however be advantageous to use instead or in combination with the oxygen product an activated oxygen, preferably ozone, as oxidant in one or more oxygen consuming units of the hydrometallurgical process circuit.
- Activated oxygen may be used as oxidant, for example, in the downstream leaching unit and/or an upstream leaching unit and/or a further leaching unit downstream of the downstream leaching unit and/or in a pressure oxidation unit and/or in a lixiviant remediation unit.
- Use of activated oxygen, in particular ozone, is known for example for cyanide remediation.
- the oxygen product from the ion transport membrane assembly and/or activated oxygen generated therefrom may constitute the oxidant gas and may constitute, in particular, all of the oxidant used for oxidation in one or more oxygen-consuming units of the hydrometallurgical process circuit.
- Oxygen product from the ion transport membrane assembly and/or activated oxygen generated therefrom may constitute all of the oxidant used in oxidation in the hydrometallurgical process circuit.
- the oxidant gas may contain diatomic oxygen and/or activated oxygen from one or more oxygen sources other than the ion transport membrane assembly.
- the oxidant gas may comprise, as oxidant, not only oxygen but also one or more other oxidants, such as, chlorine.
- the invention has recognized that the product portfolio of an ion transport membrane assembly, namely, the permeate oxygen product, the non-permeate nitrogen-enriched product, power, and steam which can be generated by each of the two products, in particular the non-permeate product, matches ideally with the needs of hydrometallurgical processing. Furthermore, instead of or in addition to steam generation, the thermal energy of one or both of the two products can be heat exchanged with one or more process streams of the hydrometallurgical processing circuit. Ion transport membrane assemblies typically produce a permeate oxygen product comprised of at least 95 vol. %, or at least 97 vol. %, or at least 99 vol. % oxygen. High purity oxygen is required in many applications of hydrometallurgical processing. The high oxygen purity of the oxygen product is a further advantage of integrating an ion transport membrane assembly.
- only the oxygen product gas from the ion transport membrane assembly and/or activated oxygen generated therefrom is/are utilized in the hydrometallurgical processing circuit, e.g. for activating the metal-bearing material during grinding in the grinding unit and/or for oxidation purposes in a roasting unit and/or in a pressure oxidation unit and/or in a bio-oxidation unit and/or in an upstream leaching unit and/or in a solution neutralization unit.
- oxygen product gas from the ion transport membrane assembly and/or activated oxygen generated therefrom may be employed in an optional oxygen consuming post-processing unit, e.g. for remediation (detoxification) of lixiviant, and/or in the acid production unit, if present, for the production of acid which can be provided into a slurry or solution fed to or contained in an oxygen consuming unit, e.g. an optional pressure oxidation unit, and/or an optional upstream leaching unit, and/or the downstream leaching unit.
- Integration of the ion transport membrane and the hydrometallurgical processing circuit can be improved by recycling a gaseous oxygen-containing effluent from the hydrometallurgical processing circuit. At least a portion of that recycle effluent may be mixed with fresh oxygen-containing feed gas and the mixture fed to the feed side of the ion transport membrane assembly, and/or at least a portion of the recycle effluent may be mixed with at least a portion of the oxygen product from the ion transport membrane assembly.
- Such recycling enables oxygen recovery and recovery of the internal energy (heat and/or pressure) of the recycle effluent to the greatest possible extent.
- vent gas and/or bleed gas withdrawn from a pressure oxidation unit and/or an oxidative pressure leaching unit to maintain a certain minimum oxygen purity in the respective unit may have an oxygen purity higher than that of ambient air, rendering it a prime candidate for recycling as at least a portion of the recycle effluent.
- one or more of the other products of the ion transport membrane assembly can be utilized in the hydrometallurgical processing circuit.
- an oxygen-containing feed gas is fed to the ITM assembly at a high temperature, typically in the range of 700° C. to 1000° C., and a high pressure, typically in the range of 1000 to 4000 kPa (absolute) resulting in the co-production of high-temperature permeate oxygen product gas and high-temperature high-pressure non-permeate nitrogen-enriched product gas.
- At least a portion of the nitrogen-enriched product may be used as flotation gas to float one or more metal values, e.g. molybdenum, in a flotation unit to deliver flotation concentrate and flotation tail.
- the at least a portion of the nitrogen-enriched product may be provided to the flotation unit at or near the pressure at the outlet of the non-permeate side of the ion transport membrane assembly, or may be reduced in pressure before use for flotation.
- the at least a portion of the nitrogen-enriched product may be reduced in temperature by indirect heat exchange with feed gas to the ion transport membrane assembly and/or a process stream of the hydrometallurgical process circuit.
- Flotation with an oxygen-deficient flotation gas i.e. a flotation gas having a lower oxygen concentration than air
- a flotation gas having a lower oxygen concentration than air is advantageous in flotation processing where oxidation of metal values soluble in the flotation liquid should be impeded in order to have the one or more metal values dissolved in the flotation liquid precipitate from the solution in a metallic form that can more readily be floated than the respective metal oxide.
- the oxygen-depleted, nitrogen-enriched product gas from the ion transport membrane assembly is oxygen-deficient as compared with ambient air and may therefor serve as a relatively inert flotation gas.
- the nitrogen-enriched product gas from the ion transport membrane assembly may also comprise considerable amounts of carbon dioxide which, however, can also be regarded as inert with respect to flotation processing.
- the nitrogen-enriched product gas from the ion transport membrane assembly may be purified in a nitrogen purification unit providing a purified nitrogen product. At least a portion of the purified nitrogen product may be used as flotation gas or blended with unpurified nitrogen-enriched product from the ion transport membrane assembly to form the flotation gas for oxygen-deficient flotation.
- At least a portion of the nitrogen-enriched product may be used for drying at least a portion of the metal-bearing material.
- at least a portion of the hot nitrogen-enriched product may be used to dry the wet material or only a portion thereof by indirect heat exchange and/or by direct contact. This includes embodiments in which a first portion of the nitrogen-enriched product is used as drying agent and heat is recovered from a second portion by indirect heat exchange, and also embodiments in which heat is recovered from at least a portion of the hot nitrogen-enriched product first by indirect heat exchange and subsequently by using the already temperature reduced gas as drying agent and/or drying by indirect heat exchange.
- Ion transport membrane assemblies of the pressure-driven type advantageously integrate with turbo-machinery-based power cycles (e.g. Brayton cycles).
- the nitrogen-enriched product can be expanded in a hot gas expander or combustion turbine to recover useful work.
- Further downstream processing in a heat recovery steam generator (HRSG) can result in an overall product mix of oxygen product gas, mechanical and/or electric power, and/or steam.
- the mechanical and/or electric power can be used to drive one or more agitators in one or more autoclaves for agitating the slurry in a pressure oxidation unit and/or a bio-oxidation unit and/or any of the leaching units mentioned.
- all or part of the mechanical and/or electric power can be used to drive one or more pumps and/or compressors for feeding one or more process streams of the hydrometallurgical processing circuit and/or support the drive of the optional grinding unit and/or drive one or more fuel pumps and/or one or more compressors for compressing one or more oxygen-containing feed gas streams for the ITM assembly.
- Autoclaves of pressure oxidation units and pressure leaching units are operated at a temperature typically in the range between 80° C. to 300° C. and at a pressure typically in the range between 300 kPa and 5000 kPa (absolute) making the oxygen product a perfect match also in this respect.
- the ion transport membrane assembly can be operated to provide the oxygen product at a pressure close to the lower limit of this pressure range and does therefore not require extensive compression if injected into a slurry or solution processed, for example, in a pressure oxidation unit or oxidative pressure leaching unit.
- Oxygen product from the ion transport membrane assembly or activated oxygen generated therefrom may be cooled before providing it to the at least one oxygen consuming unit or process by indirect heat exchange with a process stream to or from the hydrometallurgical processing circuit and/or a process stream between units of the hydrometallurgical processing circuit and/or with a slurry or solution contained in a vessel of the hydrometallurgical processing circuit and/or with feed gas to the ion transport membrane assembly to recover heat from the oxygen product.
- At least a portion of the non-permeate nitrogen-enriched product from the ion transport membrane assembly can be used for the production of ammonia in an ammonia production unit.
- the hydrometallurgical processing system comprises the ammonia production unit.
- the nitrogen-enriched product can be purified in a nitrogen purification unit.
- the nitrogen purification unit is operatively disposed to receive the nitrogen-enriched product from the ion transport membrane assembly, and the ammonia production unit is operatively disposed to receive the purified nitrogen product from the nitrogen purification unit.
- the hydrometallurgical processing system can comprise a hydrogen production unit, e.g. a steam-methane reformer (SMR), to provide a hydrogen-containing product.
- the hydrometallurgical processing circuit can operatively be disposed to receive the hydrogen-containing product from the hydrogen production unit.
- the hydrogen-containing product can for example be used for neutralization purposes in the hydrometallurgical processing of the metal-bearing material.
- Hydrogen may be used in a reduction process, e.g. in nickel and/or cobalt reduction units, and/or for the generation of heat and/or introduced into the reducing atmosphere in a sintering unit.
- the ammonia production unit may be operatively disposed to receive at least a portion of the hydrogen-containing product from the hydrogen production unit and at least a portion of the nitrogen-enriched product from the ion transport membrane assembly to produce ammonia. At least one of the hydrogen-containing product from the hydrogen production unit and the nitrogen-enriched product from the ion transport membrane assembly can have undergone purification on its way the ammonia production unit to deliver a purified hydrogen product and/or a purified nitrogen product to the ammonia production unit.
- Aspect 2 The system of aspect 1 wherein the ion transport membrane assembly ( 10 ) is operatively disposed to receive at least a portion ( 25 . 1 , 25 . 2 , 25 . 3 , 25 . 4 ) of an oxygen-containing effluent gas ( 25 ) from the hydrometallurgical processing circuit ( 20 ).
- Aspect 3 The system of any one of the preceding aspects wherein the hydrometallurgical processing circuit ( 20 ) comprises at least one outlet for an oxygen-containing effluent gas ( 25 ), this outlet operatively connected with one or both of
- Aspect 4 The system of any one of the preceding aspects wherein the pre-processing unit ( 230 ) and/or the downstream leaching unit ( 260 ) and/or the post-processing unit, the latter if present, comprises or comprises each a pressure vessel, preferably an autoclave, adapted to be operated at or above 80° C. and at or above 300 kPa (absolute), preferably at or above 100° C. and/or at or above 600 kPa (absolute), the pressure vessel operatively connected with one or both of
- Aspect 5 The system of any one of the preceding aspects wherein the pre-processing unit ( 230 ) and/or the downstream leaching unit ( 260 ) and/or the post-processing unit, the latter if present, comprises or comprises each a pressure vessel, preferably an autoclave, and is adapted to control the oxygen concentration of an atmosphere within the pressure vessel to be greater than 20 vol. % oxygen, preferably greater than 30 vol. % oxygen, the pressure vessel operatively connected with one or both of
- Aspect 6 The system of any one of the preceding aspects wherein the pre-processing unit is a pressure oxidation unit ( 230 ) operatively disposed to receive at least a portion ( 151 ) of the oxidant gas.
- the pre-processing unit is a pressure oxidation unit ( 230 ) operatively disposed to receive at least a portion ( 151 ) of the oxidant gas.
- Aspect 7 The system of any one of the preceding aspects wherein the downstream leaching unit ( 260 ) is an oxidative leaching unit operatively disposed to receive at least a portion ( 152 ) of the oxidant gas.
- Aspect 8 The system of any one of the preceding aspects wherein the pre-processing unit is a grinding unit ( 210 ) operatively disposed to receive at least a portion ( 150 ) of the oxidant gas for grinding the metal-bearing material ( 21 ) in an oxygen containing gas or liquid.
- the pre-processing unit is a grinding unit ( 210 ) operatively disposed to receive at least a portion ( 150 ) of the oxidant gas for grinding the metal-bearing material ( 21 ) in an oxygen containing gas or liquid.
- Aspect 9 The system of any one of aspects 1 to 7 wherein the pre-processing unit is a grinding unit ( 210 ) operatively disposed to receive an oxygen-deficient grinding gas containing at least a portion of the nitrogen-enriched product ( 13 ) from the ion transport membrane assembly ( 10 ) and adapted to grind the metal-bearing material in an oxygen-deficient environment.
- the pre-processing unit is a grinding unit ( 210 ) operatively disposed to receive an oxygen-deficient grinding gas containing at least a portion of the nitrogen-enriched product ( 13 ) from the ion transport membrane assembly ( 10 ) and adapted to grind the metal-bearing material in an oxygen-deficient environment.
- Aspect 10 The system of any one of the preceding aspects wherein the pre-processing unit is an oxidative solution neutralization unit ( 240 ) operatively disposed to receive at least a portion ( 153 ) of the oxidant gas.
- the pre-processing unit is an oxidative solution neutralization unit ( 240 ) operatively disposed to receive at least a portion ( 153 ) of the oxidant gas.
- Aspect 11 The system of any one of the preceding aspects, wherein
- Aspect 13 The system of any one of the preceding aspects wherein the pre-processing unit ( 230 ) and/or the downstream leaching unit ( 260 ) and/or the post-processing unit, if present, comprises or comprises each an autoclave operatively disposed to receive at least a portion ( 151 , 152 ) of the oxidant gas.
- Aspect 14 The system of the preceding aspect wherein the autoclave is operatively disposed to receive an autoclave slurry or solution ( 22 , 24 ) containing one or more metal values of the metal-bearing material, and comprises a gassing system for introducing, preferably in the autoclave, at least a portion ( 151 , 152 ) of the oxidant gas into the autoclave slurry or solution ( 22 , 24 ).
- Aspect 15 The system of any one of the preceding aspects wherein the hydrometallurgical processing circuit ( 20 ) comprises:
- Aspect 16 The system of any one of the preceding aspects further comprising a turbine ( 30 ) operatively disposed to receive at least a portion of the nitrogen-enriched product ( 13 ) from the ion transport membrane assembly ( 10 ), wherein the turbine ( 30 ) is a gas turbine, a combustion turbine, or a pressure letdown turbine.
- Aspect 17 The system of the preceding aspect wherein the turbine ( 30 ) is operatively disposed to provide at least a portion of the first feed gas ( 11 ) to the ion transport membrane assembly ( 10 ).
- Aspect 18 The system of aspect 16 or aspect 17 further comprising a compressor operatively connected to a turbine wheel of the turbine ( 30 ) to be driven by the turbine wheel and operatively disposed to provide at least a portion of the first feed gas ( 11 ) to the ion transport membrane assembly ( 10 ).
- Aspect 19 The system of any one of aspects 16 to 18 further comprising a generator ( 50 ) for producing electric power ( 57 ), the generator ( 50 ) operatively connected to the turbine ( 30 ) to receive shaft work from the turbine ( 30 ).
- Aspect 20 The system of the preceding aspect wherein the hydrometallurgical processing circuit ( 20 ) is operatively disposed to receive at least a portion of the electric power ( 57 ) produced by the generator ( 50 ).
- Aspect 21 The system of any one of the preceding aspects further comprising a heat recovery steam generator ( 40 ) operatively disposed to receive a steam generator feed stream ( 31 ), wherein the steam generator feed stream ( 31 ) is an effluent stream ( 31 ) from the turbine ( 30 ), the heat recovery steam generator ( 40 ) adapted to recover heat from the steam generator feed stream ( 31 ).
- Aspect 22 The system of any one of the preceding aspects further comprising a heat recovery steam generator ( 40 ) operatively disposed to receive one or more steam generator feed streams ( 26 , 31 ) and feed water ( 41 ), the heat recovery steam generator ( 40 ) adapted to produce steam ( 43 ) from the feed water ( 41 ), preferably by recovering heat from the one or more steam generator feed streams ( 26 , 31 ), wherein the one or more steam generator feed streams ( 26 , 31 ) comprise at least a portion ( 31 ) of the nitrogen-enriched product ( 13 ) from the ion transport membrane assembly ( 10 ) and/or a hot off-gas ( 26 ) from the hydrometallurgical processing circuit ( 20 ).
- a heat recovery steam generator ( 40 ) operatively disposed to receive one or more steam generator feed streams ( 26 , 31 ) and feed water ( 41 ), the heat recovery steam generator ( 40 ) adapted to produce steam ( 43 ) from the feed water ( 41 ), preferably by recovering heat from the one or more steam generator feed
- Aspect 23 The system of the preceding aspect wherein the hydrometallurgical processing circuit ( 20 ) is operatively disposed to receive at least a portion of the steam ( 43 ) from the heat recovery steam generator ( 40 ).
- Aspect 24 The system of aspect 22 or aspect 23 wherein the heat recovery steam generator ( 40 ) is operatively disposed to receive the at least a portion ( 31 ) of the nitrogen-enriched product ( 13 ) from the ion transport membrane assembly ( 10 ) as the steam generator feed stream ( 31 ) and the hot off-gas ( 26 ) from the hydrometallurgical processing circuit ( 20 ) as a further steam generator feed stream ( 26 ).
- Aspect 25 The system of any one of aspects 22 to 24 wherein the at least a portion ( 31 ) of the nitrogen-enriched product ( 13 ) is an effluent stream ( 31 ) from the turbine ( 30 ) of claim 16 .
- Aspect 26 The system of any one of aspects 21 to 25 wherein the steam generator feed stream ( 31 ) is combusted with fuel ( 47 ), the heat recovery steam generator ( 40 ) adapted to recover heat from the combustion of the steam generator feed stream ( 31 ) with the fuel ( 47 ) and/or from at least a portion of a hot combustion product of that combustion.
- Aspect 27 The system of any one of aspects 21 to 26 wherein the heat recovery steam generator ( 40 ) is operatively disposed to receive feed water ( 41 ), the heat recovery steam generator ( 40 ) adapted to recover heat from one or more of the following heat sources:
- Aspect 28 The system of any one of aspects 21 to 27 further comprising a steam turbine ( 60 ) operatively disposed to receive at least a portion of the steam ( 43 ) from the heat recovery steam generator ( 40 ) to generate power and/or low pressure steam for the hydrometallurgical processing circuit ( 20 ) and/or for export.
- a steam turbine ( 60 ) operatively disposed to receive at least a portion of the steam ( 43 ) from the heat recovery steam generator ( 40 ) to generate power and/or low pressure steam for the hydrometallurgical processing circuit ( 20 ) and/or for export.
- Aspect 29 The system of any one of the preceding aspects further comprising a hydrogen production unit ( 70 ) operatively disposed to receive a hydrogen production feed stream ( 71 ) and to provide a hydrogen-containing product ( 73 );
- Aspect 30 The system of the preceding aspect further comprising a heat exchanger ( 19 ) adapted to heat the hydrogen production feed stream ( 71 ) by indirect heat transfer with a heat exchanger feed stream comprising at least a portion of the oxygen product ( 15 ) and/or at least a portion of the nitrogen-enriched product ( 13 ) from the ion transport membrane assembly ( 10 ).
- Aspect 31 The system of aspect 29 or aspect 30 further comprising a heat exchanger ( 18 ) adapted to heat at least a portion of the first feed stream ( 11 ) by indirect heat transfer with a heat exchanger feed stream comprising at least a portion of the hydrogen-containing product ( 73 ) and/or a hydrogen production unit flue gas ( 74 ).
- Aspect 32 The system of any one of the preceding aspects further comprising:
- Aspect 33 The system of the preceding aspect wherein the hydrometallurgical processing circuit ( 20 ) is operatively disposed to receive at least a portion ( 94 ) of the ammonia product ( 93 ) from the ammonia production unit ( 90 ).
- Aspect 34 The system of aspect 32 or aspect 33 wherein the hydrometallurgical processing circuit ( 20 ) comprises a solvent extraction unit ( 97 ) and/or a hydrogen reduction unit ( 98 , 280 ) and/or a selective catalytic reduction unit ( 99 ) operatively disposed to receive at least a portion ( 94 ) of the ammonia product ( 93 ) from the ammonia production unit ( 90 ).
- the hydrometallurgical processing circuit ( 20 ) comprises a flotation unit ( 215 ) operatively disposed to receive a flotation slurry containing at least a portion of the metal-bearing material ( 1 , 21 ) and operatively disposed to receive an oxygen-deficient flotation gas containing at least a portion ( 32 ) of the nitrogen-enriched product ( 13 ) from the ion transport membrane assembly ( 10 ), the flotation unit ( 215 ) adapted to pass the flotation gas through the flotation slurry to float one or more metal values of the flotation slurry with the floatation gas and provide a flotation concentrate and a flotation tail.
- Aspect 36 The system of the preceding aspect wherein the downstream leaching unit ( 260 ) is operatively disposed to receive at least a portion ( 24 ) of the flotation concentrate or of the flotation tailing for leaching.
- Aspect 37 The system of aspect 35 wherein the downstream leaching unit ( 260 ) is operatively disposed to provide at least a portion of the metal bearing material to the flotation slurry.
- Aspect 38 The system of any one of aspects 35 to 37 wherein the hydrometallurgical processing circuit ( 20 ) comprises a grinding unit ( 210 ) operatively disposed to receive at least a portion ( 21 ) of the metal bearing material and operatively disposed to provide at least a portion of the ground material to the flotation slurry.
- the hydrometallurgical processing circuit ( 20 ) comprises a drying unit ( 208 ) operatively disposed to receive at least a portion of the metal bearing material ( 1 ) and operatively disposed to receive at least a portion ( 34 ) of the nitrogen-enriched product ( 13 ) from the ion transport membrane assembly ( 10 ), the drying unit ( 208 ) adapted to reduce a liquid content of the at least a portion of the metal bearing material ( 1 ) by direct contact and/or indirect heat exchange of the at least a portion of the metal bearing material ( 1 ) with the at least a portion ( 34 ) of the nitrogen-enriched product ( 13 ) and to provide a dried metal bearing material ( 21 ).
- Aspect 40 The system of the preceding aspect wherein the downstream leaching unit ( 260 ) is operatively disposed to receive at least a portion ( 24 ) of the dried metal bearing material ( 21 ) for leaching.
- Aspect 41 The system of aspect 39 or aspect 40 wherein the hydrometallurgical processing circuit ( 20 ) comprises a grinding unit ( 210 ) operatively disposed to receive at least a portion ( 21 ) of the metal bearing material dried in the dryer ( 208 ).
- the hydrometallurgical processing circuit ( 20 ) comprises an oxygen activation unit ( 160 ) operatively disposed to receive at least a portion of the oxygen product ( 15 ) from the ion transport membrane assembly ( 10 ) and adapted to generate activated oxygen, preferably ozone, from the at least a portion of the oxygen product ( 15 ), and operatively disposed to provide at least a portion of the activated oxygen to one or more of the pre-processing unit ( 210 , 230 , 240 ) and/or the downstream leaching unit ( 260 ) and/or the post-processing unit, the latter if present, for at least partial consumption in oxidation.
- a hydrometallurgical process for processing a metal-bearing material such as mineral ore, concentrate, tailings, matte, slag, and calcine, containing one or more metal values, the process comprising the steps of:
- Aspect 44 The process of the preceding aspect further comprising:
- Aspect 45 The process of aspect 43 or aspect 44 further comprising:
- Aspect 46 The process of any one of aspects 43 to 45 wherein at least one of the one or more units ( 230 , 260 ) of the hydrometallurgical processing circuit ( 20 ) comprises a pressure vessel, preferably an autoclave, the process furthermore comprising the steps of
- Aspect 47 The process of any one of aspects 43 to 46 wherein at least one of the one or more units ( 230 , 260 ) of the hydrometallurgical processing circuit ( 20 ) comprises a pressure vessel, preferably an autoclave, the process furthermore comprising the steps of
- Aspect 48 The process of aspect 46 or aspect 47 wherein the pressure vessel is operatively disposed to receive at least a portion ( 22 , 24 ) of the metal-bearing material, the process furthermore comprising the steps of
- Aspect 49 The process of any one of aspects 43 to 48 wherein
- Aspect 50 The process of the preceding aspect wherein at least a first portion of the oxidant gas ( 150 , 151 , 153 ) is introduced into the pre-processing unit ( 210 , 230 , 240 ) and/or at least a second portion ( 152 ) of the oxidant gas is introduced into the downstream leaching unit ( 260 ) for oxidation.
- Aspect 51 The process of any one of aspects 43 to 50 comprising
- Aspect 52 The process of the preceding aspect, furthermore comprising the step of recovering heat from the at least a portion ( 151 , 152 ) of the oxidant gas before introducing the at least a portion ( 151 , 152 ) of the oxidant gas into the at least one oxygen consuming unit ( 230 , 260 ) in step (g).
- Aspect 53 The process of any one of aspects 43 to 52 wherein the pre-processed portion ( 24 ) of the metal-bearing material is leached in step (f) in the downstream leaching unit ( 260 ), and at least a portion ( 152 ) of the oxidant gas is introduced in step (g) into the downstream leaching unit ( 260 ) to provide oxidant for oxidative leaching.
- Aspect 54 The process of any one of aspects 43 to 53 wherein at least a portion ( 150 ) of the oxidant gas is introduced into a grinding unit ( 210 ) of the hydrometallurgical processing circuit ( 20 ) for grinding the at least a portion of the metal-bearing material ( 21 ) in an oxygen-containing gas or liquid, and wherein at least a portion of the ground material is leached in step (f).
- Aspect 55 The process of any one of aspects 43 to 53 wherein at least a portion ( 150 ) of the nitrogen-enriched product ( 13 ) from the ion transport membrane assembly ( 10 ) is introduced into a grinding unit ( 210 ) of the hydrometallurgical processing circuit ( 20 ) for grinding at least a portion of the metal-bearing material ( 21 ) in an oxygen-deficient environment, and wherein at least a portion of the ground material is leached in step (f).
- Aspect 56 The process of any one of aspects 43 to 55 wherein at least a portion ( 151 ) of the oxidant gas is introduced into a pressure oxidation unit ( 230 ) for oxidizing at least a portion ( 22 ) of the metal-bearing material, and wherein at least a portion ( 24 ) of the metal-bearing material from the pressure oxidation unit ( 230 ) is leached in step (f).
- Aspect 57 The process of any one of aspects 43 to 56 wherein at least a portion ( 151 , 153 ) of the oxidant gas is introduced into a pre-processing unit ( 230 , 240 ) for oxidizing or leaching at least a portion ( 22 ) of the metal-bearing material or neutralizing a solution ( 23 ) containing at least one metal value of the metal-bearing material in solution, and wherein at least a portion ( 24 ) of the pre-processed material from the pre-processing unit ( 230 , 240 ) is leached in step (f).
- Aspect 58 The process of any one of aspects 43 to 57 wherein at least a portion ( 150 ) of the oxidant gas is introduced into a grinding unit ( 210 ) for grinding at least a portion ( 21 ) of the metal-bearing material in an oxygen containing gas or liquid and/or into a roasting unit for roasting at least a portion of the metal-bearing material, and wherein at least a portion ( 24 ) of the ground and/or roasted material is leached in step (f).
- Aspect 59 The process of any one of aspects 43 to 58 furthermore comprising one or more of the following steps:
- Aspect 60 The process of any one of aspects 43 to 59 wherein the hydrometallurgical processing circuit ( 20 ) comprises a flotation unit ( 215 ), the process furthermore comprising the steps of:
- Aspect 61 The process of any one of aspects 43 to 60 furthermore comprising the steps of:
- Aspect 62 The process of any one of the aspects 43 to 61 wherein the hydrometallurgical processing circuit ( 20 ) comprises an oxygen activation unit ( 160 ), the process furthermore comprising the steps of:
- FIG. 1 is a flow diagram of a hydrometallurgical process and processing system integrating an ion transport membrane assembly and a hydrometallurgical processing circuit according to a first embodiment of the invention
- FIG. 2 is a flow diagram of a hydrometallurgical process and processing system integrating an ion transport membrane assembly and a hydrometallurgical processing circuit according to a second embodiment of the invention
- FIG. 3 is a flow diagram illustrating integration of ammonia production and options of utilization of ammonia
- FIG. 4 is a flow diagram of a hydrometallurgical processing circuit illustrating options for utilization of oxygen product from the ion transport membrane assembly
- FIG. 5 shows options for heat integration of the ion transport membrane assembly and the hydrometallurgical processing circuit
- FIG. 6 shows options for heat integration of the ion transport membrane assembly and a hydrogen production unit.
- the term “and/or” placed between a first entity and a second entity includes any of the meanings of (1) only the first entity, (2) only the second entity, and (3) the first entity and the second entity.
- the term “and/or” placed between the last two entities of a list of 3 or more entities means at least one of the entities in the list including any specific combination of entities in this list.
- “A, B and/or C” has the same meaning as “A and/or B and/or C” and comprises the following combinations of A, B and C: (1) only A, (2) only B, (3) only C, (4) A and B and not C, (5) A and C and not B, (6) B and C and not A, and (7) A and B and C.
- phrases “at least one of” preceding a list of features or entities means one or more of the features or entities.
- “at least one of A, B, or C” has the same meaning as “A and/or B and/or C” and comprises the following combinations of A, B and C: (1) only A, (2) only B, (3) only C, (4) A and B and not C, (5) A and C and not B, (6) B and C and not A, and (7) A and B and C.
- the phrase “at least a portion” means “a portion or all.”
- the at least a portion of a stream or material may have the same composition as the stream or material from which it is derived.
- the at least a portion of a stream or material may include all or only specific components of the stream or material from which it is derived.
- a stream or material may be subjected to one or more material processing steps, for example chemical treatment and/or physical treatment, to form the at least a portion of that stream or material.
- first”, “second”, “third”, etc. are used to distinguish from among a plurality of steps and/or features, and is not indicative of the relative position in time and/or space.
- An ion transport membrane layer is an active layer of ceramic membrane material comprising mixed metal oxides capable of transporting or permeating oxygen ions at elevated temperatures.
- the ion transport membrane layer also may transport electrons as well as oxygen ions, and this type of ion transport membrane layer typically is described as a mixed conductor membrane layer.
- the ion transport membrane layer also may include one or more elemental metals thereby forming a composite membrane.
- the membrane layer being very thin, is typically supported by a porous layer support structure and/or a ribbed support structure.
- the support structure is generally made of the same material (i.e. it has the same chemical composition), so as to avoid thermal expansion mismatch.
- the support structure might comprise a different chemical composition than the membrane layer.
- a membrane unit also called a membrane structure, comprises a feed zone, an oxygen product zone, and a membrane layer disposed between the feed zone and the oxygen product zone.
- An oxygen-containing gas is passed to the feed zone and contacts one side of the membrane layer, oxygen is transported through the membrane layer, and an oxygen-depleted gas is withdrawn from the feed zone.
- An oxygen gas product which may contain at least 95 vol. % or at least 97 vol. % or preferably at least 99 vol. % oxygen, is withdrawn from the oxygen product zone of the membrane unit.
- the membrane unit may have any configuration known in the art. When the membrane unit has a planar configuration, it is typically called a “wafer.”
- a membrane module sometimes called a “membrane stack,” comprises a plurality of membrane units.
- Membrane modules in the present ion transport membrane assembly 70 may have any configuration known in the art.
- An “ion transport membrane assembly” comprises one or more membrane modules, a pressure vessel containing the one or more membrane modules, and any additional components necessary to introduce one or more feed streams and to withdraw two or more effluent streams formed from the one or more feed streams.
- the additional components may comprise flow containment duct(s), insulation, manifolds, etc. as is known in the art.
- the two or more membrane modules in an ion transport membrane assembly may be arranged in parallel and/or in series with respect to the predominate direction of flow of either the feed or permeate streams.
- ion transport membrane layers, membrane units, membrane modules, and ion transport membrane assemblies are described in U.S. Pat. Nos. 5,681,373, 7,179,323, and 7,955,423.
- FIG. 1 illustrates a first example embodiment of a hydrometallurgical processing system comprising an ion transport membrane assembly 10 and a hydrometallurgical processing circuit 20 for the hydrometallurgical recovery of one or more metal values from an initial metal-bearing material 1 which may in particular be provided as an initial slurry.
- the metal-bearing material 1 may be any one of mineral ore, mineral concentrate, tailing material, matte, slag, and calcine or a combination of two or more of these materials. It contains one or more metal values, such as, gold, silver, one or more platinum group metals, copper, nickel, cobalt, lead, zinc, manganese, molybdenum, rhenium, rare earth metals, uranium, and metalloids, e.g. silicon, recovered by hydrometallurgical processing in the hydrometallurgical processing circuit 20 .
- the hydrometallurgical process accomplished in circuit 20 produces at least one refined metal product 27 or refined intermediate metal-bearing product 27 and residue 28 .
- the ion transport membrane assembly 10 comprises one or more membranes each with one or more membrane layers.
- the one or more membranes are of the mixed conductor type, wherein oxygen ions migrate through the membrane driven by an oxygen partial pressure differential.
- the hydrometallurgical processing circuit 20 comprises a pre-processing unit for pre-processing at least a portion of the metal-bearing material 1 for a downstream leaching process in a downstream leaching unit also comprised by the hydrometallurgical processing circuit 20 .
- the pre-processing unit if present, may be one of a grinding unit, a roasting unit, a pressure oxidation unit, a bio-oxidation unit, an upstream leaching unit, and a solution neutralization unit.
- the hydrometallurgical processing circuit 20 may comprise at least one post-processing unit operatively disposed to receive at least a portion of a discharge material from the downstream leaching unit for post-processing.
- the at least one post-processing unit if present, may be one of a further leaching unit, a solution neutralization unit, and a remediation unit for the remediation of toxic lixiviant.
- the hydrometallurgical processing circuit 20 may comprise an acid production unit for the production of acid. In operation each of the units specifically mentioned may consume oxygen.
- the hydrometallurgical processing circuit 20 comprises at least one such oxygen consuming unit and may comprise two or more of these oxygen consuming units.
- an oxygen-containing first feed gas 11 is introduced through an inlet on a feed side of the ion transport membrane assembly 10 at a feed temperature of typically 700° C. to 1000° C. and a feed pressure of typically 1000 kPa to 4000 kPa.
- a stream of gaseous oxygen-depleted nitrogen-enriched product 13 is withdrawn through a first outlet on the feed or non-permeate side of the membrane assembly 10 at near feed temperature and near feed pressure.
- a stream of gaseous oxygen product 15 is withdrawn on the permeate side through a second outlet of the membrane assembly 10 at near feed temperature and a second outlet pressure.
- the permeate or second outlet pressure may be selected to fall into the range of, for example, approximately 20 to 300 kPa (absolute); and more preferred into the range of, for example, approximately 40 to 150 kPa; and may most preferred be in the order of around 50 kPa.
- At least a portion of the oxygen product 15 is fed to the hydrometallurgical processing circuit 20 to provide at least a portion of the oxygen consumed in the one or more oxygen consuming units of the processing circuit 20 .
- All or only part of the oxygen product 13 fed to the hydrometallurgical processing circuit 20 can provide heat to one or more oxygen consuming units by contact and/or reaction with the material processed in the respective unit and/or by indirect heat exchange during the process and/or before introduction into the process.
- the at least a portion of the oxygen product 13 can be cooled by indirect heat exchange with one or more effluent streams and/or internal material streams of the hydrometallurgical processing circuit 20 before introducing the at least a portion of the oxygen product 15 into the one or more oxygen consuming units.
- Dashed lines illustrate units and connections which are only optional although advantageous to the process and processing system of the invention. One or more or all of the units and connections illustrated in dashed lines may be present in advantageous developments of the basic process and processing system of the invention. Whereas units and connections optional to the invention are characterized this way in FIGS. 1 and 2 , the distinction is not made in FIGS. 3 to 6 .
- Integration of the ion transport membrane 10 and the hydrometallurgical processing circuit 20 can be improved by recycling gaseous oxygen-containing effluent 25 from the hydrometallurgical processing circuit 20 to the ion transport membrane assembly 10 and/or to at least a portion of the oxygen product 15 from the ion transport membrane assembly 10 .
- Oxygen-containing recycle effluent 25 may accordingly be mixed with the oxygen-containing feed gas 7 to form the first feed gas 11 which is separated by the ion transport membrane assembly 10 into the non-permeate and permeate products 13 and 15 .
- the oxygen-containing recycle effluent 25 may be mixed with at least a portion of the oxygen product 15 .
- the oxygen-containing recycle effluent 25 may be split into at least two portions (streams), a first of these portions mixed with the oxygen-containing feed gas 7 to form the first feed gas 11 or at least a portion thereof, and a second of the portions of recycle effluent 25 mixed with the oxygen product 15 , as illustrated in FIG. 1 , or with only a portion of the oxygen product 15 .
- Recycle effluent 25 may originate from the downstream leaching unit and/or from one or more pre-processing units such as a grinding unit, a roasting unit, a pressure oxidation unit, and an upstream leaching unit, in particular an oxidative pressure leaching unit, and/or from one or more post-processing units such as a further leaching unit.
- one or more hydrometallurgical processing units comprise one or more autoclaves
- the oxygen-containing recycle effluent 25 may advantageously originate from at least one of these autoclaves.
- One or more autoclaves may each comprise an effluent outlet through which oxygen-containing recycle effluent can be withdrawn from the pressurized gas built-up above the slurry or solution treated in the respective autoclave.
- Effluent 25 may originate from a single unit of the hydrometallurgical processing circuit 20 .
- oxygen-containing effluent from two or more units of the hydrometallurgical processing circuit 20 may be mixed to form recycle effluent 25 , e.g. oxygen-containing effluent from two or more autoclaves and/or one or more of the other units mentioned may be combined to form recycle effluent 25 as a combined recycle effluent 25 .
- Effluent 25 may be fed back and mixed with oxygen-containing feed gas 7 expediently at a location where the temperatures and/or pressures and/or oxygen concentrations of the two streams 7 and/or 15 on the one and 25 on the other hand are matching closest.
- Various alternative and complementary options for recycling effluent 25 taking its temperature and/or pressure and/or oxygen concentration into account are available. Specific options 25 . 1 to 25 . 5 are denoted in FIG. 1 , namely:
- any of streams 25 . 1 to 25 . 4 is mixed with oxygen-containing feed gas 7 upstream of membrane assembly 10 .
- Valuable is in particular oxygen-containing recycle effluent 25 of high temperature and/or high pressure and/or high oxygen concentration which can be mixed with at least a portion of the oxygen product 15 and/or oxygen-containing feed gas 7 after compression of feed gas 7 , e.g. by a compressor driven by turbine 30 , and/or after heating of feed gas 7 , e.g. by indirect heat exchange in heat exchanger 16 .
- Particularly valuable is effluent gas from an autoclave operated with an oxidant gas having a high oxygen purity as is often the case in pressure oxidation and oxidative pressure leaching.
- a pressure oxidation unit and/or an oxidative pressure leaching unit of circuit 20 may be operated to keep the oxygen concentration of the atmosphere within a pressure vessel of the respective unit at an operational level above that of ambient air, e.g. at or above 50 mol. %, or 70 mol. %, or 80 mol. %.
- bleed gas containing oxygen at the operational level may be withdrawn and oxidant gas of higher oxygen purity introduced.
- Such a bleed gas may in particular be recycled as or in the recycle effluent 25 or any of the recycle effluent streams 25 . 1 to 25 . 5 .
- Oxygen-containing recycle effluents from two or more units of the hydrometallurgical processing circuit 20 may be kept separate from one another and fed back as separate streams, in particular, if recycle effluents of different sources (units) differ widely with respect to temperature and/or pressure and/or oxygen concentration. If, for example, gaseous effluent of a first unit has a higher oxygen concentration than gaseous effluent of a second unit, the effluent of the first unit may be recycled as recycle effluent 25 . 5 mixed with at least a portion of the oxygen product 15 sent to circuit 20 , and gaseous effluent of the second unit may be recycled in or as any one of recycle effluents 25 . 1 to 25 .
- gaseous effluent of a first unit has a higher temperature than gaseous effluent of a second unit
- the effluent of the first unit may be recycled in or as recycle effluent 25 . 3 or 25 . 4
- gaseous effluent of the second unit may be recycled in or as any one of recycle effluents 25 . 1 to 25 . 3
- Reference sign 25 may accordingly denote either a combined recycle effluent stream or a plurality of separate recycle effluent streams complying with any two or more of streams 25 . 1 to 25 . 5 .
- the internal energy (heat and work) of the nitrogen-enriched product 13 can be recovered at least partially to generate electric and/or mechanical power and/or steam and/or by indirect heat exchange with one or more other process streams and/or by combustion with fuel 17 .
- a turbine 30 may operatively be disposed to receive at least a portion of the nitrogen-enriched product 13 from the ion transport membrane assembly 10 at a turbine high-pressure side to drive the turbine 30 by expansion.
- An oxygen-containing feed gas 7 for example air, may be compressed by a compressor coupled with the turbine 30 to be driven either directly by means of a mechanical coupling or indirectly by means of an electric coupling.
- the compressed oxygen-containing gas 7 may be fed to the ion transport membrane assembly 10 as the first feed gas 11 directly or after further compression and/or heating by indirect heat exchange in a heat exchanger 23 and/or combustion with fuel 5 . All or only a portion of the oxygen-containing gas 7 compressed by mechanical and/or electric power generated by the turbine 30 may constitute all or only a portion of the first feed gas 11 .
- Turbine 30 driven by expansion of the nitrogen-enriched gas 13 may be coupled with a generator 50 to produce electric energy 57 which may be utilized to drive one or more agitators in one or more units of the hydrometallurgical processing circuit 20 .
- the generator 50 alone or in combination with some other source of electrical energy may drive one or more agitators in an autoclave of a pressure oxidation unit and/or a pressure leaching unit and/or an atmospheric leaching unit and/or a bio-oxidation unit.
- the integrated hydrometallurgical processing system may comprise a heat recovery steam generator (HRSG) 40 operatively disposed to receive a steam generator feed stream 31 comprising at least a portion of the nitrogen-enriched product 13 from the ion transport membrane assembly 10 .
- the HRSG 40 may receive all or only part of the nitrogen-enriched product 13 directly from the ion transport membrane assembly 10 , i.e. without intermediate energy recovery from product 13 .
- the at least a portion of the nitrogen-enriched product 13 is fed to the HRSG 40 after having recovered work by means of a turbine such as turbine 30 .
- a turbine may be arranged downstream of the HRSG 40 to recover work after having extracted at least part of the thermal energy of the at least a portion of the nitrogen-enriched product 13 .
- HRSG 40 extracts thermal energy from steam generator feed gas 31 by indirect heat exchange with feed water 41 to make steam 43 .
- the steam 43 generated by HRSG 40 can be fed to the hydrometallurgical processing circuit 20 for heating and/or conditioning purposes, for example, in an autoclave of a pressure oxidation unit or leaching unit, and/or for heating a feed slurry 21 of metal-bearing material, only to name examples for utilization.
- the processing system may comprise a steam turbine 60 operatively disposed to receive at least a portion of steam 43 generated by HRSG 40 to recover work. Steam expanded in steam turbine 60 can be fed to the hydrometallurgical processing circuit 20 and utilized there for at least one of the purposes mentioned in connection with steam 43 .
- Steam turbine 60 may be coupled with a generator, mechanically or electrically, for the production of electrical energy which may be used in the hydrometallurgical processing circuit 20 .
- HRSG off-gas 45 may be purified in a purification unit to produce a nitrogen product for ammonia production.
- Steam generator feed gas 31 may be heat exchanged with feed water 41 in HRSG to recover only sensible heat from steam generator feed gas 31 . At least a portion of steam generator feed gas 31 , however, may be combusted with fuel 47 to produce additional thermal energy, and the combustion gas heat exchanged with feed water 41 .
- the hydrometallurgical processing system may comprise a heat exchanger 100 for heating initial material 1 and/or one or more slurries or solutions of metal-bearing material which may be formed at different stages of a multi-stage processing circuit 20 , such as slurries 21 to 24 , as will be explained later.
- Slurry 22 and slurry 24 may for example be fed to autoclaves of the hydrometallurgical processing circuit 20 .
- At least part of the heat for heating initial material 1 and/or one or more of slurries 21 to 24 can be provided by nitrogen-enriched product 13 from the ion transport membrane assembly 10 .
- Heat exchanger 100 may therefore be operatively disposed to receive at least a portion of the nitrogen-enriched product 13 directly or, more preferred, at least a portion 33 of the nitrogen-enriched product 13 after expansion by optional turbine 30 .
- One or more of initial material 1 and slurries 21 to 24 is/are preferably heated in heat exchanger 100 by indirect heat exchange with this at least a portion 33 of product 13 .
- the at least a portion 33 is a portion of steam generator feed gas 31 .
- At least a portion 32 of the nitrogen-enriched product 13 may be used in the hydrometallurgical process performed in hydrometallurgical processing circuit 20 as flotation gas in an optional flotation unit to float a portion of a flotation slurry containing one or more metal values, for example, to float molybdenum.
- at least a portion 34 of the nitrogen-enriched product 13 may be used to dry the initial metal-bearing material 1 before slurry 21 has been formed and/or to dry ground material, only to mention examples for drying.
- the at least a portion 34 may be used as drying agent to dry by contact and/or to dry by indirect heat exchange.
- the nitrogen-enriched product 13 may be used for grinding in an oxygen-deficient gas.
- oxygen-deficient it is meant that the respective gas or environment is either substantially free of oxygen or, if the respective gas or environment does contain some oxygen, the molar fraction of oxygen is smaller than the molar fraction of oxygen contained in ambient air.
- An oxygen-deficient gas or environment does preferably contain less than 15 mol. %, or less than 10 mol. % of oxygen. Oxygen concentrations of less than 5 mol. % are even more preferred.
- the hydrometallurgical processing system may comprise a hydrogen production unit 70 operatively disposed to receive a hydrogen production feed stream 71 and adapted to provide a hydrogen-containing product 73 .
- the hydrogen production feed stream 71 may comprise natural gas or any hydrocarbon-containing feedstock known for hydrogen production. All or only a portion of the hydrogen-containing product 73 can be exported at 74 . More preferred, at least a portion 75 of the hydrogen-containing product 73 is fed to the hydrometallurgical processing circuit 20 and used for metal reduction and/or pH adjustment and/or other conditioning purposes within circuit 20 . In addition or instead of utilizing the hydrogen-containing product 73 or at least a portion 75 thereof directly, i.e.
- H 2 molecular hydrogen
- all or only part of the hydrogen-containing product 73 can be used to produce ammonia in an optional ammonia production unit of the hydrometallurgical processing system.
- a material processing system comprising an ammonia production unit 90 is shown in FIG. 2 .
- FIG. 2 shows a second integration example in which an ion transport membrane 10 and a hydrometallurgical processing circuit 20 are integrated with a hydrogen production unit 70 and an ammonia production unit 90 .
- a first oxygen-containing feed gas 11 is introduced into the ion transport membrane assembly 10 at a suitable pressure and temperature for the pressure driven recovery of a nitrogen-enriched product 13 and an oxygen product 15 .
- At least a portion of the oxygen product 15 is fed to the hydrometallurgical processing circuit 20 for utilization as an oxidant in one or more processing units of circuit 20 , as described earlier, in particular with respect to the first example embodiment.
- a first portion 75 of hydrogen-containing product 73 is fed to the hydrometallurgical processing circuit 20 to be used directly for one or more of the purposes already mentioned with respect to the first example embodiment.
- Ammonia production unit 90 is operatively disposed to receive a second portion 77 of hydrogen-containing product 73 either directly or after one or more purification steps.
- Ammonia production unit 90 is furthermore operatively disposed to receive at least a portion of the nitrogen-enriched product 13 from the ion transport membrane assembly 10 .
- Nitrogen-enriched product 13 is expediently purified in an optional nitrogen purification unit 80 operatively disposed to receive product 13 from the ion transport membrane assembly 10 and deliver a purified nitrogen product 87 to the ammonia production unit 90 .
- Hydrogen-containing product portion 77 is expediently purified in a hydrogen purification unit operatively disposed to receive hydrogen product portion 77 and deliver a purified hydrogen product to the ammonia production unit 90 .
- At least a portion of the ammonia product 93 of ammonia production unit 90 can be utilized in one or more units of the hydrometallurgical processing circuit 20 .
- Hydrometallurgical processing circuit 20 may therefore be operatively disposed to receive at least a portion 94 of the ammonia product 93 . All or preferably only a portion of the ammonia product 93 may be exported as export ammonia 95 .
- All of the ammonia product 93 that is produced by ammonia production unit 90 , or only product portion 94 may be incorporated in various integrations with the material processing in hydrometallurgical processing circuit 20 .
- Utilization examples that are shown in FIG. 3 include use in solvent extraction unit 97 , and/or in one or more hydrogen reduction autoclaves 98 , and/or in NOx mitigation via selective catalytic reduction (SCR) in a catalytic reduction unit 99 .
- Export ammonia 95 is shown as a further option.
- An optional hydrogen purification unit 85 operatively disposed to receive hydrogen-containing product portion 77 and producing a purified hydrogen product 78 sent to ammonia production unit 90 is also shown.
- any of the options of integration explained with reference to FIGS. 1 to 3 can advantageously be combined, e.g. integrated ammonia production and integrated recovery of heat and/or work from nitrogen-enriched product 13 and/or oxygen product 15 can be implemented in the same processing system.
- FIG. 4 is a flow chart of a hydrometallurgical processing system in conformity with the invention. Various options of integration of oxygen product 15 of the ion transport membrane assembly 10 of the previous example embodiments are illustrated.
- the hydrometallurgical processing circuit 20 is shown in more detail to illustrate some of these options.
- the hydrometallurgical processing circuit 20 shown in FIG. 4 is however only an example circuit not intended to limit the invention to this specific circuit 20 .
- a metal-bearing material 1 for example, crushed mineral ore, is ground in grinding unit 210 .
- Grinding unit 210 can in particular be a ball mill. If the initial material 1 contains excessive water material 1 may be dried in a drying unit 208 to reduce its water content before grinding to form a dried material to be ground as such or in a slurry 21 .
- Nitrogen-enriched product portion 34 may be used for drying at least a portion of the initial material 1 by indirect heat exchange and/or direct contact, i.e. by passing the at least a portion of nitrogen-enriched product 13 through material 1 .
- At least a portion of the ground material may be subjected to flotation in a flotation unit 215 to produce a flotation concentrate and a flotation tail.
- Nitrogen-enriched product portion 32 of adequate pressure and temperature may serve as an oxygen-deficient flotation gas or a portion of an oxygen-deficient flotation gas.
- the ground material or one of the flotation concentrate or flotation tail of flotation unit 215 if present, is transported to slurry preparation unit 220 , either as dry ground material or already as slurry, and conditioned there for pressure oxidation.
- Pressure oxidation unit 230 comprises at least one autoclave, preferably a multi-compartment autoclave, operatively disposed to receive autoclave slurry 22 from slurry preparation unit 220 .
- Autoclave slurry 22 from slurry preparation unit 220 may be heated by indirect heat exchange in optional heat exchanger 100 , as explained above with respect to FIG. 1 , and heated slurry 22 fed to pressure oxidation unit 230 .
- Pressure oxidation is in many cases an exothermic process and may require not for heating but for cooling. If this is the case, at least a part of the cooling required may be provided by cooling at least a portion of slurry 22 within or before introducing it into a pressure vessel, typically an autoclave, of the pressure oxidation unit 230 .
- Cooling of at least a portion of slurry 22 may be provided by heat exchange with at least a portion of the oxygen-containing feed gas 7 instead of or, preferably, in addition to heating feed gas 7 by heat exchange with at least a portion of the nitrogen-enriched product 13 from the ion transport membrane assembly 10 .
- Pressure oxidized discharge slurry 23 from the pressure oxidation unit 230 is neutralized in a solution neutralization unit 240 to separate the pressure oxidized discharge in different portions (fractions) in a subsequent separation unit 250 .
- a slurry 24 of a resultant fraction containing one or more metal values to be recovered, e.g. one or more precious metals, is sent to downstream pressure leaching unit 260 for leaching, preferably oxidative pressure leaching.
- the discharge of separation unit 250 may have to be subjected to intermediate conditioning and/or one of cooling and heating to produce slurry 24 for downstream leaching. If heating is required slurry 24 may be heated by indirect heat exchange in optional heat exchanger 100 , as explained above with respect to FIG. 1 , and heated slurry 24 fed to downstream leaching unit 260 .
- Downstream leaching unit 260 may in particular be an oxidative leaching unit, preferably an oxidative pressure leaching unit. It may comprise at least one autoclave, preferably a multi-compartment autoclave, operatively disposed to receive slurry 24 for leaching.
- a metal value containing solution from downstream leaching unit 260 is sent to a post-processing circuit for extraction/purification in an extraction/purification unit 270 and/or subjected to hydrogen reduction in a hydrogen reduction unit 280 .
- a metal value containing portion (fraction) discharged from the post-processing circuit is further refined in a refining unit 290 downstream of hydrogen reduction unit 280 to produce refined metal product 27 .
- FIG. 4 shows, as already mentioned, options for integrating the oxygen product 15 from the ion transport membrane assembly 10 .
- At least a portion 151 of the oxygen product 15 may be introduced into the at least one autoclave of the pressure oxidation unit 230 .
- the downstream leaching unit 260 is an oxidative leaching unit 260 , preferably an oxidative pressure leaching unit
- at least a portion 152 of the oxygen product 15 may be introduced into at least one container, preferably an autoclave, of the downstream leaching unit 260 , as another prime option of utilization of oxygen product 15 from the ion transport membrane assembly 10 .
- a first portion 151 of the oxygen product 15 can be introduced into the one or more autoclaves of the pressure oxidation unit 230
- a second portion 152 can be introduced into the one or more autoclaves of the downstream oxidative pressure leaching unit 260 .
- at least a portion 153 of the oxygen product 15 may be sent to the solution neutralization unit 240 and/or at least a portion of the oxygen product 15 may be sent to a lixiviant remediation unit, e.g. for cyanide destruction.
- the integrated hydrometallurgical processing system of the invention comprises an on-site acid production unit 300 for the production of acid 302 , for example, sulfuric acid, and/or an on-site hydrogen production unit 70 such units 70 and/or 300 may also need oxygen. At least a portion 154 of the oxygen product 15 may therefore be sent to optional on-site acid production unit 300 , and/or at least a portion 155 may be sent to optional on-site hydrogen production unit 70 . At least a portion of a hot flue gas 74 of hydrogen production unit 70 , if present, may be heat exchanged with water in an optional heat recovery steam generator 315 to generate steam 79 for use in the hydrometallurgical processing, e.g. in hydrogen reduction unit 280 .
- a comparable set-up is shown for the optional acid production unit 300 .
- At least a portion of a hot flue gas from acid production unit 300 may be cooled by indirect heat exchange with water in a heat recovery steam generator 305 to generate steam 309 for use in the hydrometallurgical processing, e.g. in pressure oxidation unit 230 .
- Heat recovery steam generator 305 and/or heat recovery steam generator 315 may be combined with HRSG 40 or may be combined one with the other to generate steam for one or more of the units of the hydrometallurgical processing circuit 20 , for example, to generate steam for the pressure oxidation unit 230 and/or hydrogen reduction unit 280 , as illustrated, or a leaching unit of circuit 20 , for example, the downstream leaching unit 260 .
- Grinding unit 210 may grind metal-bearing material 1 or slurry 21 containing at least a portion of material 1 in an oxygen-containing gas or liquid, in particular in example embodiments in which grinding unit 210 is a fine or ultra-fine grinder. Grinding in oxygen can provide for metal activation already during grinding. At least a portion 150 of the oxygen product 15 may therefore be sent to grinding unit 210 for grinding in oxygen or in an oxygen gas mixture, e.g. in oxygen air. In alternative embodiments it might be desirable to impede oxidation during grinding. In those embodiments grinding unit 210 may operatively be disposed to receive an oxygen-deficient gas containing at least a portion of the nitrogen-enriched product 13 from the ion transport membrane assembly 10 for grinding in an oxygen-deficient environment.
- Any autoclave receiving at least a portion 151 or 152 of the oxygen product 15 may comprise a gassing system for the introduction of the assigned portion 151 or 152 to inject the same into the slurry or solution within the respective autoclave.
- the gassing system is preferably adapted to sparge the received at least a portion 152 or 152 through the slurry or solution in the respective autoclave.
- One or more mechanical agitators typically arranged in an autoclave, may agitate the slurry or solution to intensify contact with the metal-bearing material in the slurry or solution.
- the oxygen product 15 from ion transport membrane assembly 10 may provide for all of the oxidant or at least all of the oxygen consumed in the hydrometallurgical process, as preferred. In alternative embodiments, however, ion transport membrane assembly 10 may supply only part of the oxidant consumed in circuit 20 .
- Oxidant gas provided to one or more oxygen consuming units of circuit 20 contains at least a portion of oxygen product gas 15 and may contain one or more other oxidants, such as, chlorine, and/or oxygen from some other oxygen sources.
- oxygen product 15 from ion transport membrane assembly 10 may be provided as such, i. e. as diatomic oxygen, to one or more oxygen consuming units of circuit 20 .
- at least a portion of the oxygen product 15 from ion transport membrane assembly 10 may be activated in an oxygen activation unit and provided as activated oxygen, in particular, as ozone, to one or more oxygen consuming units of circuit 20 to increase the rate of oxidation in the respective unit.
- Oxidant gas introduced into one or more oxygen consuming units of circuit 20 may accordingly consist of or comprise activated oxygen generated from at least a portion of the oxygen product 15 from ion transport membrane assembly 10 .
- FIG. 4 illustrates, as an option, utilization of activated oxygen in the downstream leaching unit 260 .
- the at least a portion 152 of oxygen product 15 is fed through an oxygen activation unit 160 to activate at least part of oxygen product portion 152 and provide at least partly activated portion 152 as oxidant gas to the downstream leaching unit 260 .
- FIG. 5 shows an example for further heat integration of ion transport membrane assembly 10 and hydrometallurgical processing circuit 20 by heat exchanging additional streams in heat recovery steam generator 40 .
- Heat recovery from steam generator feed stream 31 to produce steam 43 from water feed 41 has been explained with respect to the first example embodiment ( FIG. 1 ).
- the option of combusting at least a portion of steam generator feed stream 31 with fuel provided by fuel feed 47 has also been mentioned.
- at least a portion of oxygen-containing feed gas 7 can be preheated by indirect heat exchange in HRSG 40 .
- Another option, which might be implemented in addition or alternatively, is to recover heat from another steam generator feed stream 26 , which is a hot off-gas from hydrometallurgical processing circuit 20 .
- heat may be recovered from steam generator feed gas 31 , i.e. from at least a portion of the nitrogen-enriched product 13 received from ion transport membrane assembly 10 directly or after intermediate expansion and/or intermediate cooling, and/or from combusting at least a portion of steam generator feed gas 31 with feed fuel 47 , and/or from steam generator feed gas 26 (hot off-gas) from circuit 20 .
- At least a portion of oxygen-containing feed gas 7 may be heated in HRSG 40 in addition to the generation of steam 43 .
- FIG. 6 shows an example for heat integration of ion transport membrane assembly 10 and optional hydrogen production unit 70 .
- the hydrogen production feed stream 71 can be heated in an optional heat exchanger 19 by indirect heat exchange with at least a portion of the oxygen product 15 from ion transport membrane assembly 10 .
- Heated feed stream 71 is introduced into hydrogen production unit 70 , and cooled oxygen product 15 is fed to the hydrometallurgical processing circuit 20 .
- At least a portion of first feed gas 11 may be heated by indirect heat exchange in heat exchanger 18 against at least a portion of the hydrogen-containing product 73 from hydrogen production unit 70 and/or against hydrogen production flue gas 74 from hydrogen production unit 70 .
- First feed gas 11 heated in heat exchanger 18 may be combusted with fuel 5 before being introduced into the ion transport membrane assembly 10 .
- Hydrogen-containing product 73 having been cooled in heat exchanger 18 may then be split into product portion 75 which is sent to hydrometallurgical processing circuit 20 and product portion 77 sent to ammonia production unit 90 ( FIG. 2 ), if present.
- the heat exchangers 18 and 19 are illustrated to be distinct heat exchangers. In developments the heat exchangers 18 and 19 may be combined to form a single integrated heat exchanger to recover heat from at least a portion of the oxygen product 15 and at least one of the hydrogen product 73 and flue gas 74 for heating feed gas 11 and/or feed stream 71 .
- At least one of the heat exchangers 18 and 19 may be used to produce steam, i.e. operated as a heat recovery steam generator. This option has already been mentioned with respect to FIG. 4 where hot flue gas 74 is illustrated to be used in heat recovery steam generator 315 for the production of steam 79 .
Landscapes
- Engineering & Computer Science (AREA)
- Chemical & Material Sciences (AREA)
- Manufacturing & Machinery (AREA)
- Geochemistry & Mineralogy (AREA)
- Geology (AREA)
- General Life Sciences & Earth Sciences (AREA)
- Life Sciences & Earth Sciences (AREA)
- Environmental & Geological Engineering (AREA)
- Materials Engineering (AREA)
- Mechanical Engineering (AREA)
- Metallurgy (AREA)
- Organic Chemistry (AREA)
- Manufacture And Refinement Of Metals (AREA)
Abstract
A hydrometallurgical system and process with a hydrometallurgical processing circuit integrated with an ion transport membrane assembly. The ion transport membrane assembly provide oxygen to the hydrometallurgical processing circuit.
Description
- This invention was made with government support under Cooperative Agreement No. DE-FC26-98FT40343 between Air Products and Chemicals, Inc. and the U.S. Department of Energy. The United States Government has certain rights in this invention.
- The present invention relates to the production and utilization of oxygen in hydrometallurgical processes for obtaining one or more metal values from a metal-bearing material like mineral ore and/or concentrate.
- Hydrometallurgical processes are wet processes to extract and recover metals. They rely on leaching one or more valuable metals, so-called metal values, like gold, silver, platinum group metals, copper, nickel, cobalt, lead, zinc, manganese, molybdenum, rhenium, rare earth metals, and uranium from metal-bearing materials such as ore, concentrate, tailings, matte, slag, and calcine. The one or more metal values of interest are dissolved from the metal-bearing material into an appropriate solution. The solution is then separated from insoluble residue. The leaching process may employ one or more of a variety of chemicals such as dilute sulfuric acid and/or dilute aqueous cyanide. The lixiviant in solution may be acidic or basic or neutral in nature. Methods for contacting the metal-bearing material and the lixiviant can include agitating comminuted solids and solution (slurry) in open tanks, agitating slurry at a high temperature in a pressure vessel, and percolating lixiviant through crushed ore that has been piled in a heap or vat and collecting the solution that issues from the bottom. Enhanced- or high-temperature and pressure leach processes are performed in autoclaves. Autoclaves may be operated under oxidizing, acidic, or alkaline conditions. Oxidizing or reducing gases, such as air, oxygen, and sulfur dioxide, may be used, taking into account the gas-liquid contact requirements.
- The metal-bearing material may be pre-processed, as is the case e.g. with refractory materials like refractory ores, concentrates and tailings, to liberate the metal values and make them accessible to leaching. Common pre-processing options include roasting, pressure oxidation, bio-oxidation, and ultra-fine grinding. In roasting, pressure oxidation, and bio-oxidation, the metal-bearing material is oxidized. In ultra-fine grinding, the material is ground to small particle sizes such that the significant surfaces of the metal values are exposed, enabling high contact of the metal values with the lixiviant solution.
- Hydrometallurgical processing facilities have large oxygen requirements, in particular, in pressure oxidation, roasting, and oxidative pressure leaching. Oxygen may also be required for atmospheric leaching, for activation of the metal-bearing material e.g. in a grinding process, for on-site production of acid, and/or for the remediation of lixiviant. Bio-oxidation and bio-leaching may also require oxygen.
- U.S. Pat. No. 3,741,752 (Evans et al.), for example, discloses a process for the recovery of nickel and copper from copper-nickel-sulfide matte by means of a three-stage leaching process. Air is introduced into each of the leaching stages and furthermore into a copper purification stage following the second leaching stage.
- According to U.S. Pat. No. 4,093,526 (Blanco et al.) nickel-copper-sulfur concentrates are leached in a combination of a first stage atmospheric leaching unit and two subsequent pressure leaching stages. In each of these leaching stages or units, air or oxygen is used to create oxidizing conditions.
- U.S. Pat. No. 5,645,708 (Jones) utilizes a pressure oxidation pre-processing unit and an atmospheric leaching unit for the extraction of copper from sulfide copper ore or concentrate.
- U.S. Pat. No. 6,569,224 (Kerfoot et al.) teaches a hydrometallurgical process for the recovery of nickel and cobalt values from a sulfidic flotation concentrate with atmospheric chlorine leaching as pre-processing followed by downstream oxidative pressure leaching. Oxygen is introduced in the oxidative pressure leaching unit, and may also be used in the atmospheric leach pre-processing unit to maximize the reaction of sulfuric acid with sulfide minerals.
- U.S. Pat. No. 8,623,115 (Langhans et al.) discloses hydrometallurgical processing of precious metal-bearing materials in which the precious metal-bearing material, in this case a refractory material, is comminuted and conditioned to form a slurry of a desired density which is subsequently subjected to pressure oxidation in an autoclave. The autoclave discharge slurry is flash cooled, neutralized and the neutralized discharge slurry is subjected to leaching with a suitable lixiviant. Cyanide, ammonium, sodium, and calcium thiosulfate and also halides (iodide, bromide, chloride), and thiourea are mentioned as typical leaching agents. The sorbed precious metal is recovered from the pregnant leach solution e.g. by electrowinning or cementation to form the precious metal product. Considerable amounts of oxygen are consumed in the pressure oxidation pre-processing circuit.
- U.S. Pat. No. 8,025,859 (Jones), as a further example for precious metals recovery, discloses a combination of pressure oxidation and downstream pressure cyanidation with optional intermediate atmospheric leaching and flotation. An initial metal-bearing material in the form of a concentrate slurry is subjected to pressure oxidation at elevated temperature and pressure, using high purity oxygen as oxidant. Pressure cyanidation is carried out under an elevated oxygen pressure to reduce the duration of the cyanidation and minimize thiocyanide formation.
- U.S. Pat. No. 8,268,037 (Kummer et al.) discloses a method of recovering molybdenum from a molybdenum bearing sulfide material by bioleaching mentioning that adequate aeration is required as oxygen is the preferred terminal electron acceptor for enzymatic bio-oxidation of iron and sulfur compounds in the bioleaching process.
- The prior art processes exemplify the variety of applications of oxygen in hydrometallurgical processing facilities. As far as air is employed in the various processes the air may be enriched by the addition of oxygen or substituted by a higher oxygen content gas or high purity oxygen to intensify the respective one or more oxidative reactions.
- For remote facilities, an oxygen production unit is required. This would typically be a pressure or vacuum swing adsorption (PSANSA) unit. The compressors and vacuum blowers of PSA or VSA units, however, consume considerable amounts of electric power for cyclic pressurization and depressurization of adsorbent beds, power that has to be produced on-site if the facility is remotely located. The cyclic nature of PSA and VSA impedes integration with hydrometallurgical processing. The adsorbed gas fraction is desorbed by depressurization. Work can hardly be recovered from this fraction.
- Industry desires to improve the economics for providing oxygen to hydrometallurgical processes.
- It is object of the present invention to improve the economics, including energy efficiency, operating costs, and/or capital costs, of hydrometallurgical processing by the use of an ion transport membrane device and/or process for the production of oxygen used therein.
- It is another object of the present invention to improve the overall economics of hydrometallurgical processing and oxygen production by integration of said hydrometallurgical processing process and said ion transport membrane device and/or process.
- There is a need for improved integration of oxygen supply and hydrometallurgical processing enabling on-site production of at least a portion of the oxygen needed by one or more material processing units of a hydrometallurgical processing facility.
- The present invention accomplishes economic supply of oxygen by integration of a hydrometallurgical processing circuit and an ion transport membrane assembly for the production of an oxygen product from an oxygen- and nitrogen-containing feed gas. The hydrometallurgical processing circuit is operatively disposed to receive an oxidant gas containing at least a portion of the oxygen product from the ion transport membrane assembly and/or activated oxygen generated from at least a portion of the oxygen product from the ion transport membrane assembly. The oxygen-containing feed gas to the ion transport membrane assembly may in particular be pressurized and heated air or a pressurized and heated gas mixture formed from air and one or more other sources. Gaseous effluent from the hydrometallurgical processing circuit, e. g. vent gas and/or bleed gas from pressure oxidation and/or oxidative pressure leaching, may in particular be such a source.
- Oxygen can be separated from oxygen-containing gases, e.g. from air, at high temperatures by mixed metal oxide ceramic materials utilized in the form of nonporous ion transport membranes (ITM). An oxygen partial pressure differential or a voltage differential across the membrane causes oxygen ions to migrate through the membrane from the feed side to the permeate side. Ion transport membrane assemblies comprising one or more ion transport membranes each with one or more membrane layers and their utility in recovering oxygen from air or other oxygen-containing gases are known in the art (e.g. U.S. Pat. Nos. 5,681,373, 7,179,323, and 7,955,423). Particularly suited for the present invention are ion transport membrane assemblies with one or more membranes of the mixed conductor type, i.e. membranes in which an oxygen partial pressure differential across the respective membrane causes oxygen ions to migrate through the membrane from the feed side to the permeate side where the ions recombine to form electrons and oxygen product gas.
- U.S. Pat. No. 5,643,354 (Agrawal et al.) discloses a high-temperature ion transport membrane assembly to recover oxygen for use in a direct iron making smelting process. Heat for the integrated oxygen recovery is obtained from the combustion of fuel gas and/or indirect heat exchange with a hot gas from the iron making process. A combined cycle power generation system is included so that the product portfolio of the ion transport membrane assembly includes oxygen product gas, electric power and steam. The steam is exported or expanded in a steam turbine to make additional electric power. The electric power is exported or used internally.
- U.S. Pat. No. 5,855,648 (Prasad et al.) discloses the integration of an ion transport membrane assembly in a pyrometallurgical process. The oxygen product of the membrane assembly is added to the feed gas stream of a blast furnace for the production of iron from ore.
- The prior art has not yet considered utility of the ion transport membrane technology for the production of oxygen needed in the hydrometallurgical processing of metal-bearing materials to recover one or more of its metal values.
- The present invention proposes advantageous integrations of an ion transport membrane assembly with a hydrometallurgical processing circuit in a hydrometallurgical processing system and in a hydrometallurgical process.
- The hydrometallurgical processing circuit comprises a leaching unit and one or more pre-processing units. It may furthermore comprise one or more post-processing units and/or an acid production unit. The pre-processing unit is operatively disposed to receive a metal-bearing material and adapted to process the metal-bearing material, for example, by grinding or oxidation. The pre-processing unit is disposed upstream of the leaching unit. The leaching unit disposed downstream of the pre-processing unit may therefore be termed ‘downstream leaching unit’, not the least because an upstream leaching unit may constitute the pre-processing unit. The pre-processing unit may be any one of a grinding unit, in particular a ball mill, for grinding the metal-bearing material, a roasting unit for roasting the material, a pressure oxidation unit, a bio-oxidation unit, an atmospheric leaching unit, a bio-leaching unit, a pressure leaching unit, and a solution or slurry preparation unit, e.g. a solution or slurry neutralization unit. A solution or slurry preparation unit, for example a solution or slurry neutralization unit, or a lixiviant remediation unit or a further leaching unit may constitute the optional post-processing unit. The pre-processing and post-processing units mentioned are potential oxygen consumers, the downstream leaching unit and the optional acid production unit as well. The hydrometallurgical processing circuit may comprise one or more pre-processing and/or post-processing units not requiring oxygen to perform their specific processing function. Identifying certain pre-processing and/or post-processing units as potential oxygen consumers does not mean necessarily that the respective unit, should the hydrometallurgical processing circuit comprise that unit, does need oxygen to accomplish its specific processing function, or is supplied by the ITM assembly. For example, the hydrometallurgical processing circuit may comprise a grinding unit and/or a bio-oxidation unit and/or a bio-leaching unit and/or a remediation unit with no oxygen supply at all, and/or a pressure oxidation unit and/or an oxidative leaching unit not supplied with oxygen product from the ITM assembly.
- The hydrometallurgical processing circuit may comprise an acid production unit. The downstream leaching unit may in those embodiments operatively be disposed to receive acid from the acid production unit. If the one or more pre-processing units comprise a pressure oxidation unit and/or an upstream leaching unit, at least one of these units may operatively be disposed to receive acid from the acid production unit. This includes embodiments in which only one of these units, i.e. only the downstream leaching unit, or only a pressure-oxidation unit, or only an upstream leaching unit, is operatively disposed to receive acid from the acid production unit, and also embodiments in which any two or all three of these units are present and operatively disposed to receive acid from the acid production unit.
- The hydrometallurgical processing circuit may comprise a post-processing unit as mentioned above. The post-processing unit is in those embodiments operatively disposed to receive at least a portion of the discharge material from the downstream leaching unit e.g. for subsequent solution or slurry neutralization, subsequent further leaching, or remediation of lixiviant. The optional subsequent further leaching unit may operatively be disposed to receive acid from the acid production unit, if present.
- In embodiments, the integrated processing system comprises one or more pre-processing units and one or more post-processing units, and optionally an acid production unit for producing acid which could be utilized in a leaching or pressure oxidation unit of the system, in particular, in one or more of the leaching units mentioned above.
- If, for example, the hydrometallurgical processing circuit comprises a grinding unit and the downstream leaching unit, the downstream leaching unit is operatively disposed to receive at least a portion of the material ground by the grinding unit. The ground material may be subjected to intermediate pre-processing, e.g. pressure oxidation, upstream leaching, and/or flotation on its way from the grinding unit to the downstream leaching unit.
- Typically, a roasting unit, a pressure oxidation unit, and a bio-oxidation unit are alternatives one to the other. On the other hand, the hydrometallurgical processing circuit may comprise any two or all three of these types of pre-processing units, such as, a roasting unit and a pressure oxidation unit in parallel, or a bio-oxidation unit and a pressure oxidation unit in series, only to mention examples of suitable combinations.
- One or more upstream leaching units, if present, may be adapted to separate different metals from one another by dissolving metals selectively. The downstream leaching unit may, for example, operatively be disposed to receive either the fraction with the one or more dissolved metals or the fraction with one or more other metals not dissolved in upstream leaching.
- These are only examples of a recovery process that might be implemented in the hydrometallurgical processing circuit. The hydrometallurgical process and the hydrometallurgical processing circuit as such can be designed as known in the art. The background art acknowledged above discloses examples of hydrometallurgical processes suited for integration taught by the invention.
- According to the invention, at least one of the pre-processing unit, the downstream leaching unit, the acid production unit, if present, and the post-processing unit, if present, is an oxygen consuming unit and operatively disposed to receive an oxidant gas containing at least a portion of the oxygen product from the ion transport membrane assembly or activated oxygen, typically ozone, generated from at least a portion of the oxygen product from the ion transport membrane assembly. This includes embodiments in which only one of the four units mentioned is an oxygen consuming unit and operatively disposed to receive the oxidant gas and also embodiments in which any two or any three or all four of the units mentioned are oxygen consuming units and operatively disposed to receive the oxidant gas. Furthermore, any two or any three or all four of the units mentioned may be oxygen consuming units, but not each of the oxygen consuming units must be provided with oxidant gas from the ion transport membrane assembly. Rather, oxidant gas containing oxygen product from the ion transport membrane assembly or activated oxygen generated therefrom may be provided to only a subgroup of oxygen consuming units of the hydrometallurgical processing system.
- The ion transport membrane assembly is adapted to provide at least part of the oxygen consumed by the hydrometallurgical processing circuit during operation in at least one oxidative process performed by the at least one oxygen consuming unit. The oxygen product may be used as such as oxidant in one or more oxygen consuming units of the hydrometallurgical process circuit. It may however be advantageous to use instead or in combination with the oxygen product an activated oxygen, preferably ozone, as oxidant in one or more oxygen consuming units of the hydrometallurgical process circuit.
- Activated oxygen may be used as oxidant, for example, in the downstream leaching unit and/or an upstream leaching unit and/or a further leaching unit downstream of the downstream leaching unit and/or in a pressure oxidation unit and/or in a lixiviant remediation unit. Use of activated oxygen, in particular ozone, is known for example for cyanide remediation.
- The oxygen product from the ion transport membrane assembly and/or activated oxygen generated therefrom may constitute the oxidant gas and may constitute, in particular, all of the oxidant used for oxidation in one or more oxygen-consuming units of the hydrometallurgical process circuit. Oxygen product from the ion transport membrane assembly and/or activated oxygen generated therefrom may constitute all of the oxidant used in oxidation in the hydrometallurgical process circuit. In principle, however, the oxidant gas may contain diatomic oxygen and/or activated oxygen from one or more oxygen sources other than the ion transport membrane assembly. The oxidant gas may comprise, as oxidant, not only oxygen but also one or more other oxidants, such as, chlorine.
- The invention has recognized that the product portfolio of an ion transport membrane assembly, namely, the permeate oxygen product, the non-permeate nitrogen-enriched product, power, and steam which can be generated by each of the two products, in particular the non-permeate product, matches ideally with the needs of hydrometallurgical processing. Furthermore, instead of or in addition to steam generation, the thermal energy of one or both of the two products can be heat exchanged with one or more process streams of the hydrometallurgical processing circuit. Ion transport membrane assemblies typically produce a permeate oxygen product comprised of at least 95 vol. %, or at least 97 vol. %, or at least 99 vol. % oxygen. High purity oxygen is required in many applications of hydrometallurgical processing. The high oxygen purity of the oxygen product is a further advantage of integrating an ion transport membrane assembly.
- In basic embodiments of integration, only the oxygen product gas from the ion transport membrane assembly and/or activated oxygen generated therefrom is/are utilized in the hydrometallurgical processing circuit, e.g. for activating the metal-bearing material during grinding in the grinding unit and/or for oxidation purposes in a roasting unit and/or in a pressure oxidation unit and/or in a bio-oxidation unit and/or in an upstream leaching unit and/or in a solution neutralization unit. Instead or in addition to employing all or part of the oxygen product and/or activated oxygen generated therefrom in one or more oxygen consuming pre-processing units, oxygen product gas from the ion transport membrane assembly and/or activated oxygen generated therefrom may be employed in an optional oxygen consuming post-processing unit, e.g. for remediation (detoxification) of lixiviant, and/or in the acid production unit, if present, for the production of acid which can be provided into a slurry or solution fed to or contained in an oxygen consuming unit, e.g. an optional pressure oxidation unit, and/or an optional upstream leaching unit, and/or the downstream leaching unit.
- Integration of the ion transport membrane and the hydrometallurgical processing circuit can be improved by recycling a gaseous oxygen-containing effluent from the hydrometallurgical processing circuit. At least a portion of that recycle effluent may be mixed with fresh oxygen-containing feed gas and the mixture fed to the feed side of the ion transport membrane assembly, and/or at least a portion of the recycle effluent may be mixed with at least a portion of the oxygen product from the ion transport membrane assembly. Such recycling enables oxygen recovery and recovery of the internal energy (heat and/or pressure) of the recycle effluent to the greatest possible extent. For example, vent gas and/or bleed gas withdrawn from a pressure oxidation unit and/or an oxidative pressure leaching unit to maintain a certain minimum oxygen purity in the respective unit may have an oxygen purity higher than that of ambient air, rendering it a prime candidate for recycling as at least a portion of the recycle effluent.
- In embodiments, one or more of the other products of the ion transport membrane assembly can be utilized in the hydrometallurgical processing circuit. If the ion transport membrane assembly is of the pressure-driven type, as preferred, an oxygen-containing feed gas is fed to the ITM assembly at a high temperature, typically in the range of 700° C. to 1000° C., and a high pressure, typically in the range of 1000 to 4000 kPa (absolute) resulting in the co-production of high-temperature permeate oxygen product gas and high-temperature high-pressure non-permeate nitrogen-enriched product gas.
- At least a portion of the nitrogen-enriched product may be used as flotation gas to float one or more metal values, e.g. molybdenum, in a flotation unit to deliver flotation concentrate and flotation tail. The at least a portion of the nitrogen-enriched product may be provided to the flotation unit at or near the pressure at the outlet of the non-permeate side of the ion transport membrane assembly, or may be reduced in pressure before use for flotation. Before used for flotation, the at least a portion of the nitrogen-enriched product may be reduced in temperature by indirect heat exchange with feed gas to the ion transport membrane assembly and/or a process stream of the hydrometallurgical process circuit.
- Flotation with an oxygen-deficient flotation gas, i.e. a flotation gas having a lower oxygen concentration than air, is advantageous in flotation processing where oxidation of metal values soluble in the flotation liquid should be impeded in order to have the one or more metal values dissolved in the flotation liquid precipitate from the solution in a metallic form that can more readily be floated than the respective metal oxide. The oxygen-depleted, nitrogen-enriched product gas from the ion transport membrane assembly is oxygen-deficient as compared with ambient air and may therefor serve as a relatively inert flotation gas.
- In embodiments incorporating recycling of recycle effluent from the hydrometallurgical process to the feed side of the ion transport membrane assembly the nitrogen-enriched product gas from the ion transport membrane assembly may also comprise considerable amounts of carbon dioxide which, however, can also be regarded as inert with respect to flotation processing. The nitrogen-enriched product gas from the ion transport membrane assembly may be purified in a nitrogen purification unit providing a purified nitrogen product. At least a portion of the purified nitrogen product may be used as flotation gas or blended with unpurified nitrogen-enriched product from the ion transport membrane assembly to form the flotation gas for oxygen-deficient flotation.
- At least a portion of the nitrogen-enriched product may be used for drying at least a portion of the metal-bearing material. In applications where excess water makes it difficult to process initial metal-bearing material, as for example, mineral ore, at least a portion of the hot nitrogen-enriched product may be used to dry the wet material or only a portion thereof by indirect heat exchange and/or by direct contact. This includes embodiments in which a first portion of the nitrogen-enriched product is used as drying agent and heat is recovered from a second portion by indirect heat exchange, and also embodiments in which heat is recovered from at least a portion of the hot nitrogen-enriched product first by indirect heat exchange and subsequently by using the already temperature reduced gas as drying agent and/or drying by indirect heat exchange.
- Grinding in oxygen was mentioned before with respect to the oxidant gas. Depending on the metal-bearing material to be ground and/or the hydrometallurgical process performed, it might in alternative embodiments be advantageous to provide an oxygen-deficient gas to the optional grinding unit in order to prevent or at least impede oxidation of one or more metal values during grinding. At least a portion of the nitrogen-enriched product from the ion transport membrane assembly may in those embodiments be provided to the optional grinding unit for grinding under inert conditions or at least under conditions more inert than grinding in air.
- Ion transport membrane assemblies of the pressure-driven type advantageously integrate with turbo-machinery-based power cycles (e.g. Brayton cycles). The nitrogen-enriched product can be expanded in a hot gas expander or combustion turbine to recover useful work. Further downstream processing in a heat recovery steam generator (HRSG) can result in an overall product mix of oxygen product gas, mechanical and/or electric power, and/or steam. The mechanical and/or electric power can be used to drive one or more agitators in one or more autoclaves for agitating the slurry in a pressure oxidation unit and/or a bio-oxidation unit and/or any of the leaching units mentioned. Instead of, or in addition thereto, all or part of the mechanical and/or electric power can be used to drive one or more pumps and/or compressors for feeding one or more process streams of the hydrometallurgical processing circuit and/or support the drive of the optional grinding unit and/or drive one or more fuel pumps and/or one or more compressors for compressing one or more oxygen-containing feed gas streams for the ITM assembly.
- Autoclaves of pressure oxidation units and pressure leaching units are operated at a temperature typically in the range between 80° C. to 300° C. and at a pressure typically in the range between 300 kPa and 5000 kPa (absolute) making the oxygen product a perfect match also in this respect. The ion transport membrane assembly can be operated to provide the oxygen product at a pressure close to the lower limit of this pressure range and does therefore not require extensive compression if injected into a slurry or solution processed, for example, in a pressure oxidation unit or oxidative pressure leaching unit. Oxygen product from the ion transport membrane assembly or activated oxygen generated therefrom may be cooled before providing it to the at least one oxygen consuming unit or process by indirect heat exchange with a process stream to or from the hydrometallurgical processing circuit and/or a process stream between units of the hydrometallurgical processing circuit and/or with a slurry or solution contained in a vessel of the hydrometallurgical processing circuit and/or with feed gas to the ion transport membrane assembly to recover heat from the oxygen product.
- At least a portion of the non-permeate nitrogen-enriched product from the ion transport membrane assembly can be used for the production of ammonia in an ammonia production unit. In those embodiments the hydrometallurgical processing system comprises the ammonia production unit. The nitrogen-enriched product can be purified in a nitrogen purification unit. In those embodiments the nitrogen purification unit is operatively disposed to receive the nitrogen-enriched product from the ion transport membrane assembly, and the ammonia production unit is operatively disposed to receive the purified nitrogen product from the nitrogen purification unit.
- The hydrometallurgical processing system can comprise a hydrogen production unit, e.g. a steam-methane reformer (SMR), to provide a hydrogen-containing product. The hydrometallurgical processing circuit can operatively be disposed to receive the hydrogen-containing product from the hydrogen production unit. The hydrogen-containing product can for example be used for neutralization purposes in the hydrometallurgical processing of the metal-bearing material. Hydrogen may be used in a reduction process, e.g. in nickel and/or cobalt reduction units, and/or for the generation of heat and/or introduced into the reducing atmosphere in a sintering unit.
- The ammonia production unit, if present, may be operatively disposed to receive at least a portion of the hydrogen-containing product from the hydrogen production unit and at least a portion of the nitrogen-enriched product from the ion transport membrane assembly to produce ammonia. At least one of the hydrogen-containing product from the hydrogen production unit and the nitrogen-enriched product from the ion transport membrane assembly can have undergone purification on its way the ammonia production unit to deliver a purified hydrogen product and/or a purified nitrogen product to the ammonia production unit.
- Advantageous features are also described in the sub-claims and the combinations of the same.
- In the following, specific aspects of the method and system will be outlined. The reference signs and expressions set in parentheses are referring to example embodiments explained further below with reference to figures. The reference signs and expressions are, however, only illustrative and do not limit the respective aspect to any specific component or feature of the example embodiments. The aspects can be formulated as claims in which the reference signs and expressions set in parentheses are omitted or replaced by appropriate others.
-
Aspect 1. A hydrometallurgical processing system for processing a metal-bearing material, such as mineral ore, concentrate, tailings, matte, slag, and calcine, the system comprising: -
- an ion transport membrane assembly (10) comprising an ion transport membrane layer and having a feed side and a permeate side where the feed side has an inlet for introducing a first feed gas (11) comprising oxygen and nitrogen into the ion transport membrane assembly (10) and a first outlet for withdrawing a nitrogen-enriched product (13) from the feed side of the ion transport membrane assembly (10), and where the permeate side has a second outlet for withdrawing an oxygen product (15) from the ion transport membrane assembly (10); and
- a hydrometallurgical processing circuit (20) comprising
- a pre-processing unit (210, 230, 240) operatively disposed to receive a metal-bearing material and being selected from a group of units consisting of a grinding unit (210), a roasting unit, a pressure oxidation unit (230), a bio-oxidation unit, an upstream leaching unit, and a solution or slurry preparation unit, e.g. a solution neutralization unit (240);
- a downstream leaching unit (260) operatively disposed to receive at least a pre-processed portion (24) of the metal-bearing material from the pre-processing unit (210, 230, 240); and
- one or both of an acid production unit (300) and a post-processing unit, the post-processing unit, if present, operatively disposed to receive and adapted to post-process material from the downstream leaching unit (260) and preferably being selected from a group of units consisting of a further leaching unit, a lixiviant remediation unit, and a solution or slurry preparation unit e.g. a solution or slurry neutralization unit;
- wherein the pre-processing unit (210, 230, 240) and/or the downstream leaching unit (260) and/or the acid production unit (300), if present, and/or the post-processing unit, if present, is/are operatively disposed to receive an oxidant gas (150, 151, 152, 153, 154) containing at least a portion of the oxygen product (15) and/or activated oxygen generated from at least a portion of the oxygen product (15) from the ion transport membrane assembly (10).
- Aspect 2. The system of
aspect 1 wherein the ion transport membrane assembly (10) is operatively disposed to receive at least a portion (25.1, 25.2, 25.3, 25.4) of an oxygen-containing effluent gas (25) from the hydrometallurgical processing circuit (20). - Aspect 3. The system of any one of the preceding aspects wherein the hydrometallurgical processing circuit (20) comprises at least one outlet for an oxygen-containing effluent gas (25), this outlet operatively connected with one or both of
-
- the feed side of the ion transport membrane assembly (10) for feeding at least a portion (25.1, 25.2, 25.3, 25.4) of an oxygen-containing effluent gas (25) from the hydrometallurgical processing circuit (20) to the feed side of the ion transport membrane assembly (10); and/or
- a mixing junction for mixing at least a portion (25.5) of an oxygen-containing effluent gas (25) from the hydrometallurgical processing circuit (20) with the at least a portion of the oxygen product (15).
- Aspect 4. The system of any one of the preceding aspects wherein the pre-processing unit (230) and/or the downstream leaching unit (260) and/or the post-processing unit, the latter if present, comprises or comprises each a pressure vessel, preferably an autoclave, adapted to be operated at or above 80° C. and at or above 300 kPa (absolute), preferably at or above 100° C. and/or at or above 600 kPa (absolute), the pressure vessel operatively connected with one or both of
-
- the feed side of the ion transport membrane assembly (10) for feeding at least a portion (25.1, 25.2, 25.3, 25.4) of an oxygen-containing effluent gas (25) from the pressure vessel to the feed side of the ion transport membrane assembly (10); and/or
- a mixing junction for mixing at least a portion (25.5) of an oxygen-containing effluent gas (25) from the pressure vessel with the at least a portion of the oxygen-enriched product (15).
-
Aspect 5. The system of any one of the preceding aspects wherein the pre-processing unit (230) and/or the downstream leaching unit (260) and/or the post-processing unit, the latter if present, comprises or comprises each a pressure vessel, preferably an autoclave, and is adapted to control the oxygen concentration of an atmosphere within the pressure vessel to be greater than 20 vol. % oxygen, preferably greater than 30 vol. % oxygen, the pressure vessel operatively connected with one or both of -
- the feed side of the ion transport membrane assembly (10) for feeding at least a portion (25.1, 25.2, 25.3, 25.4) of an oxygen-containing effluent gas (25) from the pressure vessel to the feed side of the ion transport membrane assembly (10); and/or
- a mixing junction for mixing at least a portion (25.5) of an oxygen-containing effluent gas (25) from the pressure vessel with the at least a portion of the oxygen-enriched product (15).
- Aspect 6. The system of any one of the preceding aspects wherein the pre-processing unit is a pressure oxidation unit (230) operatively disposed to receive at least a portion (151) of the oxidant gas.
-
Aspect 7. The system of any one of the preceding aspects wherein the downstream leaching unit (260) is an oxidative leaching unit operatively disposed to receive at least a portion (152) of the oxidant gas. - Aspect 8. The system of any one of the preceding aspects wherein the pre-processing unit is a grinding unit (210) operatively disposed to receive at least a portion (150) of the oxidant gas for grinding the metal-bearing material (21) in an oxygen containing gas or liquid.
- Aspect 9. The system of any one of
aspects 1 to 7 wherein the pre-processing unit is a grinding unit (210) operatively disposed to receive an oxygen-deficient grinding gas containing at least a portion of the nitrogen-enriched product (13) from the ion transport membrane assembly (10) and adapted to grind the metal-bearing material in an oxygen-deficient environment. -
Aspect 10. The system of any one of the preceding aspects wherein the pre-processing unit is an oxidative solution neutralization unit (240) operatively disposed to receive at least a portion (153) of the oxidant gas. -
Aspect 11. The system of any one of the preceding aspects, wherein -
- the pre-processing unit is a grinding unit (210) operatively disposed to receive the metal-bearing material (21); and
- the hydrometallurgical processing circuit (20) comprises at least one further pre-processing unit (230, 240) operatively disposed to receive at least a portion (22, 23) of the ground metal-bearing material from the grinding unit (210) and selected from the group consisting of a pressure oxidation unit (230), a roasting unit, a bio-oxidation unit, an upstream oxidative leaching unit, and an oxidative solution or slurry preparation unit, e.g. an oxidative solution or slurry neutralization unit (240).
- Aspect 12. The system of the preceding aspect wherein
-
- (a) the grinding unit (210) is operatively disposed either to receive at least a portion (150) of the oxidant gas for grinding in an oxygen containing gas or liquid or to receive an oxygen-deficient grinding gas containing at least a portion of the nitrogen-enriched product (13) from the ion transport membrane assembly (10) and adapted to grind the metal-bearing material in an oxygen-deficient environment; and/or
- (b) the at least one further pre-processing unit (230, 240) is operatively disposed to receive at least a portion (151, 153) of the oxidant gas for at least partial consumption in oxidation; and/or
- (c) the downstream leaching unit (260) is an oxidative leaching unit operatively disposed to receive at least a portion (152) of the oxidant gas.
-
Aspect 13. The system of any one of the preceding aspects wherein the pre-processing unit (230) and/or the downstream leaching unit (260) and/or the post-processing unit, if present, comprises or comprises each an autoclave operatively disposed to receive at least a portion (151, 152) of the oxidant gas. - Aspect 14. The system of the preceding aspect wherein the autoclave is operatively disposed to receive an autoclave slurry or solution (22, 24) containing one or more metal values of the metal-bearing material, and comprises a gassing system for introducing, preferably in the autoclave, at least a portion (151, 152) of the oxidant gas into the autoclave slurry or solution (22, 24).
-
Aspect 15. The system of any one of the preceding aspects wherein the hydrometallurgical processing circuit (20) comprises: -
- an autoclave operatively disposed to receive an autoclave slurry or solution (22, 24) containing one or more metal values of the metal-bearing material; and
- a heat exchanger (100) to heat the autoclave slurry or solution (22, 24) by indirect heat transfer with a heat exchanger feed stream (33) comprising at least a portion of the nitrogen-enriched product (13) and/or at least a portion of the oxidant gas.
-
Aspect 16. The system of any one of the preceding aspects further comprising a turbine (30) operatively disposed to receive at least a portion of the nitrogen-enriched product (13) from the ion transport membrane assembly (10), wherein the turbine (30) is a gas turbine, a combustion turbine, or a pressure letdown turbine. -
Aspect 17. The system of the preceding aspect wherein the turbine (30) is operatively disposed to provide at least a portion of the first feed gas (11) to the ion transport membrane assembly (10). -
Aspect 18. The system ofaspect 16 oraspect 17 further comprising a compressor operatively connected to a turbine wheel of the turbine (30) to be driven by the turbine wheel and operatively disposed to provide at least a portion of the first feed gas (11) to the ion transport membrane assembly (10). -
Aspect 19. The system of any one ofaspects 16 to 18 further comprising a generator (50) for producing electric power (57), the generator (50) operatively connected to the turbine (30) to receive shaft work from the turbine (30). -
Aspect 20. The system of the preceding aspect wherein the hydrometallurgical processing circuit (20) is operatively disposed to receive at least a portion of the electric power (57) produced by the generator (50). -
Aspect 21. The system of any one of the preceding aspects further comprising a heat recovery steam generator (40) operatively disposed to receive a steam generator feed stream (31), wherein the steam generator feed stream (31) is an effluent stream (31) from the turbine (30), the heat recovery steam generator (40) adapted to recover heat from the steam generator feed stream (31). -
Aspect 22. The system of any one of the preceding aspects further comprising a heat recovery steam generator (40) operatively disposed to receive one or more steam generator feed streams (26, 31) and feed water (41), the heat recovery steam generator (40) adapted to produce steam (43) from the feed water (41), preferably by recovering heat from the one or more steam generator feed streams (26,31), wherein the one or more steam generator feed streams (26, 31) comprise at least a portion (31) of the nitrogen-enriched product (13) from the ion transport membrane assembly (10) and/or a hot off-gas (26) from the hydrometallurgical processing circuit (20). -
Aspect 23. The system of the preceding aspect wherein the hydrometallurgical processing circuit (20) is operatively disposed to receive at least a portion of the steam (43) from the heat recovery steam generator (40). -
Aspect 24. The system ofaspect 22 oraspect 23 wherein the heat recovery steam generator (40) is operatively disposed to receive the at least a portion (31) of the nitrogen-enriched product (13) from the ion transport membrane assembly (10) as the steam generator feed stream (31) and the hot off-gas (26) from the hydrometallurgical processing circuit (20) as a further steam generator feed stream (26). -
Aspect 25. The system of any one ofaspects 22 to 24 wherein the at least a portion (31) of the nitrogen-enriched product (13) is an effluent stream (31) from the turbine (30) ofclaim 16. -
Aspect 26. The system of any one ofaspects 21 to 25 wherein the steam generator feed stream (31) is combusted with fuel (47), the heat recovery steam generator (40) adapted to recover heat from the combustion of the steam generator feed stream (31) with the fuel (47) and/or from at least a portion of a hot combustion product of that combustion. -
Aspect 27. The system of any one ofaspects 21 to 26 wherein the heat recovery steam generator (40) is operatively disposed to receive feed water (41), the heat recovery steam generator (40) adapted to recover heat from one or more of the following heat sources: -
- (i) at least a portion (31) of the nitrogen-enriched product received as the steam generator feed stream (31), and/or
- (ii) a hot off-gas of the hydrometallurgical processing circuit (20) received as the steam generator feed stream (26) or a further steam generator feed stream (26), and/or
- (iii) the combustion of the preceding aspect, and/or
- (iv) the at least a portion of the hot combustion product of the preceding aspect to produce steam (43) from the feed water (41);
- wherein the hydrometallurgical processing circuit (20) is operatively disposed to receive at least a portion of the steam (43) from the heat recovery steam generator (40); and/or
- wherein the heat recovery steam generator (40) is operatively disposed to receive an oxygen-containing feed gas (7) and adapted to heat the oxygen-containing feed gas (7) by the recovery of heat from one or more of the heat sources (i) to (iv), the ion transport membrane assembly (10) operatively disposed to receive at least a portion of the heated oxygen-containing feed gas (7) from the heat recovery steam generator (40), the at least a portion of the heated oxygen-containing feed gas (7) from the heat recovery steam generator (40) forming at least a portion of the first feed gas (11).
-
Aspect 28. The system of any one ofaspects 21 to 27 further comprising a steam turbine (60) operatively disposed to receive at least a portion of the steam (43) from the heat recovery steam generator (40) to generate power and/or low pressure steam for the hydrometallurgical processing circuit (20) and/or for export. - Aspect 29. The system of any one of the preceding aspects further comprising a hydrogen production unit (70) operatively disposed to receive a hydrogen production feed stream (71) and to provide a hydrogen-containing product (73);
- wherein the hydrometallurgical processing circuit (20) is operatively disposed to receive at least a portion (75) of the hydrogen-containing product (73).
-
Aspect 30. The system of the preceding aspect further comprising a heat exchanger (19) adapted to heat the hydrogen production feed stream (71) by indirect heat transfer with a heat exchanger feed stream comprising at least a portion of the oxygen product (15) and/or at least a portion of the nitrogen-enriched product (13) from the ion transport membrane assembly (10). -
Aspect 31. The system of aspect 29 oraspect 30 further comprising a heat exchanger (18) adapted to heat at least a portion of the first feed stream (11) by indirect heat transfer with a heat exchanger feed stream comprising at least a portion of the hydrogen-containing product (73) and/or a hydrogen production unit flue gas (74). -
Aspect 32. The system of any one of the preceding aspects further comprising: -
- a hydrogen production unit (70) operatively disposed to receive a hydrogen production feed stream (71) and to provide a hydrogen-containing product (73);
- a nitrogen purification unit (80) operatively disposed to receive at least a portion of the nitrogen-enriched product (13) from the ion transport membrane assembly (10); and
- an ammonia production unit (90) operatively disposed to receive a nitrogen product (87) from the nitrogen purification unit (80) and operatively disposed to receive at least a portion (77) of the hydrogen-containing product (73) from the hydrogen production unit (70) to produce an ammonia product (93).
-
Aspect 33. The system of the preceding aspect wherein the hydrometallurgical processing circuit (20) is operatively disposed to receive at least a portion (94) of the ammonia product (93) from the ammonia production unit (90). -
Aspect 34. The system ofaspect 32 oraspect 33 wherein the hydrometallurgical processing circuit (20) comprises a solvent extraction unit (97) and/or a hydrogen reduction unit (98, 280) and/or a selective catalytic reduction unit (99) operatively disposed to receive at least a portion (94) of the ammonia product (93) from the ammonia production unit (90). -
Aspect 35. The system of any one of the preceding aspects wherein the hydrometallurgical processing circuit (20) comprises a flotation unit (215) operatively disposed to receive a flotation slurry containing at least a portion of the metal-bearing material (1, 21) and operatively disposed to receive an oxygen-deficient flotation gas containing at least a portion (32) of the nitrogen-enriched product (13) from the ion transport membrane assembly (10), the flotation unit (215) adapted to pass the flotation gas through the flotation slurry to float one or more metal values of the flotation slurry with the floatation gas and provide a flotation concentrate and a flotation tail. - Aspect 36. The system of the preceding aspect wherein the downstream leaching unit (260) is operatively disposed to receive at least a portion (24) of the flotation concentrate or of the flotation tailing for leaching.
- Aspect 37. The system of
aspect 35 wherein the downstream leaching unit (260) is operatively disposed to provide at least a portion of the metal bearing material to the flotation slurry. - Aspect 38. The system of any one of
aspects 35 to 37 wherein the hydrometallurgical processing circuit (20) comprises a grinding unit (210) operatively disposed to receive at least a portion (21) of the metal bearing material and operatively disposed to provide at least a portion of the ground material to the flotation slurry. - Aspect 39. The system of any one of the preceding aspects wherein the hydrometallurgical processing circuit (20) comprises a drying unit (208) operatively disposed to receive at least a portion of the metal bearing material (1) and operatively disposed to receive at least a portion (34) of the nitrogen-enriched product (13) from the ion transport membrane assembly (10), the drying unit (208) adapted to reduce a liquid content of the at least a portion of the metal bearing material (1) by direct contact and/or indirect heat exchange of the at least a portion of the metal bearing material (1) with the at least a portion (34) of the nitrogen-enriched product (13) and to provide a dried metal bearing material (21).
-
Aspect 40. The system of the preceding aspect wherein the downstream leaching unit (260) is operatively disposed to receive at least a portion (24) of the dried metal bearing material (21) for leaching. -
Aspect 41. The system of aspect 39 oraspect 40 wherein the hydrometallurgical processing circuit (20) comprises a grinding unit (210) operatively disposed to receive at least a portion (21) of the metal bearing material dried in the dryer (208). - Aspect 42. The system of any one of the preceding aspects wherein the hydrometallurgical processing circuit (20) comprises an oxygen activation unit (160) operatively disposed to receive at least a portion of the oxygen product (15) from the ion transport membrane assembly (10) and adapted to generate activated oxygen, preferably ozone, from the at least a portion of the oxygen product (15), and operatively disposed to provide at least a portion of the activated oxygen to one or more of the pre-processing unit (210, 230, 240) and/or the downstream leaching unit (260) and/or the post-processing unit, the latter if present, for at least partial consumption in oxidation.
-
Aspect 43. A hydrometallurgical process for processing a metal-bearing material, such as mineral ore, concentrate, tailings, matte, slag, and calcine, containing one or more metal values, the process comprising the steps of: - (a) providing an ion transport membrane assembly (10) comprising an ion transport membrane layer and having a feed side and a permeate side;
- (b) introducing a first feed gas (11) comprising oxygen and nitrogen into an inlet to the feed side of the ion transport membrane assembly (10);
- (c) withdrawing a non-permeate nitrogen-enriched product (13) from an outlet from the feed side and a permeate oxygen product (15) from an outlet from the permeate side of the ion transport membrane assembly (10);
- (d) providing a hydrometallurgical processing circuit (20) comprising one or more units (210, 230, 240, 260, 300) for carrying out the hydrometallurgical process, a process carried out in at least one of the one or more units consuming oxygen by chemical reaction, the one or more units selected from the group consisting of a grinding unit (210), a roasting unit, a pressure oxidation unit (230), a bio-oxidation unit, an upstream leaching unit, an upstream solution or slurry preparation unit (240), a downstream leaching unit (260), a further downstream leaching unit, a further downstream solution or slurry preparation unit, a lixiviant remediation unit, and an acid production unit (300);
- (e) pre-processing the metal-bearing material in the hydrometallurgical processing circuit (20);
- (f) leaching at least a pre-processed portion (24) of the metal-bearing material in the hydrometallurgical processing circuit (20) to recover at least one metal value from the metal-bearing material; and
- (g) introducing an oxidant gas (150, 151, 152, 153, 154) containing at least a portion of the oxygen product (15) and/or activated oxygen generated from at least a portion of the oxygen product (15) of the ion transport membrane assembly (10) into at least one oxygen consuming unit of the one or more units (210, 230, 240, 260, 300) of the hydrometallurgical processing circuit (20) for oxidation.
- Aspect 44. The process of the preceding aspect further comprising:
-
- recycling at least a portion (25.1, 25.2, 25.3, 25.4) of an oxygen-containing effluent gas (25) of the hydrometallurgical processing circuit (20) in a first recycle effluent stream; and
- recycling the first recycle effluent stream to the feed side of the ion transport membrane assembly (10) to form a portion of the first feed gas (11).
-
Aspect 45. The process ofaspect 43 or aspect 44 further comprising: -
- recycling at least a portion (25.5) of an oxygen-containing effluent gas (25) of the hydrometallurgical processing circuit (20) in a second recycle effluent stream; and
- mixing the second recycle effluent stream with at least a portion of the oxygen product (15) of the ion transport membrane assembly (10) to form a mixed stream containing the at least a portion of the oxygen product (15) and the oxygen containing effluent gas of the second recycle effluent stream, and introducing the mixed stream into the at least one oxygen consuming unit (210, 230, 240, 260, 300) of the hydrometallurgical processing circuit (20) to provide oxidant.
- Aspect 46. The process of any one of
aspects 43 to 45 wherein at least one of the one or more units (230, 260) of the hydrometallurgical processing circuit (20) comprises a pressure vessel, preferably an autoclave, the process furthermore comprising the steps of -
- operating the pressure vessel at a temperature at or above 80° C. and/or a pressure at or above 300 kPa (absolute), preferably at or above 100° C. and/or at or above 600 kPa (absolute);
- feeding at least a portion (25.1, 25.2, 25.3, 25.4) of an oxygen-containing effluent gas (25) from a pressure vessel atmosphere to the feed side of the ion transport membrane assembly (10); and/or
- mixing at least a portion (25.5) of an oxygen-containing effluent gas (25) from a pressure vessel atmosphere with at least a portion of the oxygen-enriched product (15) from the ion transport membrane assembly (10) to form a gas mixture and feeding at least a portion of the gas mixture to the hydrometallurgical processing circuit (20) in or as said oxidant gas.
-
Aspect 47. The process of any one ofaspects 43 to 46 wherein at least one of the one or more units (230, 260) of the hydrometallurgical processing circuit (20) comprises a pressure vessel, preferably an autoclave, the process furthermore comprising the steps of -
- operating the pressure vessel with a pressure vessel atmosphere having an oxygen concentration of greater than 20 vol. % oxygen, preferably greater than 30 vol. % oxygen;
- feeding at least a portion (25.1, 25.2, 25.3, 25.4) of an oxygen-containing effluent gas (25) from the pressure vessel atmosphere to the feed side of the ion transport membrane assembly (10); and/or
- mixing at least a portion (25.5) of an oxygen-containing effluent gas (25) from the pressure vessel atmosphere with at least a portion of the oxygen-enriched product (15) from the ion transport membrane assembly (10) to form a gas mixture and feeding at least a portion of the gas mixture to the hydrometallurgical processing circuit (20) in or as said oxidant gas.
- Aspect 48. The process of aspect 46 or
aspect 47 wherein the pressure vessel is operatively disposed to receive at least a portion (22, 24) of the metal-bearing material, the process furthermore comprising the steps of -
- feeding at least a portion (151, 152) of the oxidant gas to the pressure vessel; and
- oxidizing one or more metal values contained in the at least a portion (22, 24) of the metal-bearing material in the pressure vessel.
- Aspect 49. The process of any one of
aspects 43 to 48 wherein -
- the hydrometallurgical processing circuit (20) comprises a pre-processing unit (210, 230, 240) and a downstream leaching unit (260);
- the metal-bearing material is pre-processed in the pre-processing unit (210, 230, 240) by one or more of grinding, roasting, pressure oxidation, bio-oxidation, upstream leaching, and solution or slurry preparation to produce a pre-processed material containing the at least one metal value; and
- at least a portion (24) of the pre-processed material is leached in step (f) in the downstream leaching unit (260) as the at least a portion (24) of the metal-bearing material.
-
Aspect 50. The process of the preceding aspect wherein at least a first portion of the oxidant gas (150, 151, 153) is introduced into the pre-processing unit (210, 230, 240) and/or at least a second portion (152) of the oxidant gas is introduced into the downstream leaching unit (260) for oxidation. - Aspect 51. The process of any one of
aspects 43 to 50 comprising -
- operating the ion transport membrane assembly (10) at a temperature within a membrane temperature range of 700° C. to 1100° C.;
- withdrawing the non-permeate nitrogen-enriched product (13) in step (c) at a temperature within the membrane temperature range;
- withdrawing the permeate oxygen product (15) in step (c) at a temperature within the membrane temperature range;
- operating the at least one oxygen consuming unit (230, 260) at a temperature within a unit temperature range of 80° C. to 300° C.;
- and providing oxidant to a process performed in this oxygen consuming unit (230, 260) by introducing at least a portion (151, 152) of the oxidant gas into the at least one oxygen consuming unit (230, 260) in step (g).
- Aspect 52. The process of the preceding aspect, furthermore comprising the step of recovering heat from the at least a portion (151, 152) of the oxidant gas before introducing the at least a portion (151, 152) of the oxidant gas into the at least one oxygen consuming unit (230, 260) in step (g).
- Aspect 53. The process of any one of
aspects 43 to 52 wherein the pre-processed portion (24) of the metal-bearing material is leached in step (f) in the downstream leaching unit (260), and at least a portion (152) of the oxidant gas is introduced in step (g) into the downstream leaching unit (260) to provide oxidant for oxidative leaching. - Aspect 54. The process of any one of
aspects 43 to 53 wherein at least a portion (150) of the oxidant gas is introduced into a grinding unit (210) of the hydrometallurgical processing circuit (20) for grinding the at least a portion of the metal-bearing material (21) in an oxygen-containing gas or liquid, and wherein at least a portion of the ground material is leached in step (f). - Aspect 55. The process of any one of
aspects 43 to 53 wherein at least a portion (150) of the nitrogen-enriched product (13) from the ion transport membrane assembly (10) is introduced into a grinding unit (210) of the hydrometallurgical processing circuit (20) for grinding at least a portion of the metal-bearing material (21) in an oxygen-deficient environment, and wherein at least a portion of the ground material is leached in step (f). - Aspect 56. The process of any one of
aspects 43 to 55 wherein at least a portion (151) of the oxidant gas is introduced into a pressure oxidation unit (230) for oxidizing at least a portion (22) of the metal-bearing material, and wherein at least a portion (24) of the metal-bearing material from the pressure oxidation unit (230) is leached in step (f). -
Aspect 57. The process of any one ofaspects 43 to 56 wherein at least a portion (151, 153) of the oxidant gas is introduced into a pre-processing unit (230, 240) for oxidizing or leaching at least a portion (22) of the metal-bearing material or neutralizing a solution (23) containing at least one metal value of the metal-bearing material in solution, and wherein at least a portion (24) of the pre-processed material from the pre-processing unit (230, 240) is leached in step (f). - Aspect 58. The process of any one of
aspects 43 to 57 wherein at least a portion (150) of the oxidant gas is introduced into a grinding unit (210) for grinding at least a portion (21) of the metal-bearing material in an oxygen containing gas or liquid and/or into a roasting unit for roasting at least a portion of the metal-bearing material, and wherein at least a portion (24) of the ground and/or roasted material is leached in step (f). - Aspect 59. The process of any one of
aspects 43 to 58 furthermore comprising one or more of the following steps: - (i) generating steam (43) from feed water (41) by heat exchange with at least a portion of the nitrogen-enriched product (13) and introducing at least a portion of the generated steam (43) into the hydrometallurgical processing circuit (20); and/or
- (ii) heating an autoclave slurry or solution (22, 24) by heat exchange with at least a portion of the nitrogen-enriched product (13) and introducing the heated autoclave slurry or solution (22, 24) into an autoclave of the hydrometallurgical processing circuit (20) for leaching or pressure oxidation; and/or
- (iii) introducing at least a portion of the nitrogen-enriched product (13) into an ammonia production unit (90) to produce an ammonia product (93), and introducing at least a portion of the ammonia product (93) into the hydrometallurgical processing circuit (20).
-
Aspect 60. The process of any one ofaspects 43 to 59 wherein the hydrometallurgical processing circuit (20) comprises a flotation unit (215), the process furthermore comprising the steps of: -
- introducing a flotation slurry containing at least a portion of the metal bearing material into the flotation unit (215);
- floating one or more metal values of the flotation slurry in the flotation unit (215) with an oxygen-deficient flotation gas containing at least a portion (32) of the nitrogen-enriched product (13) from the ion transport membrane assembly (10) thereby providing a flotation concentrate and a flotation tail; and
- leaching at least a portion (24) of the flotation concentrate or of the flotation tail in step (f); and/or
- providing at least a portion of a metal bearing material produced in step (f) to the flotation slurry.
- Aspect 61. The process of any one of
aspects 43 to 60 furthermore comprising the steps of: -
- drying at least a portion of the metal bearing material (1) by contact and/or indirect heat exchange with at least a portion (34) of the nitrogen-enriched product (13) from the ion transport membrane assembly (10) to provide a dried metal-bearing material;
- subjecting at least a portion (21) of the dried metal-bearing material to a further pre-processing step to provide a pre-processed material; and
- leaching at least a portion (24) of the pre-processed material in step (f).
- Aspect 62. The process of any one of the
aspects 43 to 61 wherein the hydrometallurgical processing circuit (20) comprises an oxygen activation unit (160), the process furthermore comprising the steps of: -
- activating at least a portion of the oxygen product (15) from the ion transport membrane assembly (10) in the oxygen activation unit (16) to generate activated oxygen, preferably ozone; and
- introducing at least a portion of the activated oxygen in or as the oxidant gas to the at least one oxygen consuming unit (210, 230, 240, 260, 300) of the hydrometallurgical processing circuit (20) in step (g).
- The invention is explained below by way of examples with reference to figures. Features disclosed there, each individually and in any combination of features, advantageously develop the subjects of the claims and also the embodiments and aspects described above.
-
FIG. 1 is a flow diagram of a hydrometallurgical process and processing system integrating an ion transport membrane assembly and a hydrometallurgical processing circuit according to a first embodiment of the invention; -
FIG. 2 is a flow diagram of a hydrometallurgical process and processing system integrating an ion transport membrane assembly and a hydrometallurgical processing circuit according to a second embodiment of the invention; -
FIG. 3 is a flow diagram illustrating integration of ammonia production and options of utilization of ammonia; -
FIG. 4 is a flow diagram of a hydrometallurgical processing circuit illustrating options for utilization of oxygen product from the ion transport membrane assembly; -
FIG. 5 shows options for heat integration of the ion transport membrane assembly and the hydrometallurgical processing circuit; and -
FIG. 6 shows options for heat integration of the ion transport membrane assembly and a hydrogen production unit. - The ensuing detailed description provides preferred exemplary embodiments only, and is not intended to limit the scope, applicability, or configuration of the invention. Rather, the ensuing detailed description of the preferred exemplary embodiments will provide those skilled in the art with an enabling description for implementing preferred exemplary embodiments of the invention, it being understood that various changes may be made in the function and arrangement of elements without departing from scope of the invention as defined by the claims.
- The articles “a” and “an” as used herein mean one or more when applied to any feature in embodiments of the present invention described in the specification and claims. The use of “a” and “an” does not limit the meaning to a single feature unless such a limit is specifically stated. The article “the” preceding singular or plural nouns or noun phrases denotes a particular specified feature or particular specified features and may have a singular or plural connotation depending upon the context in which it is used. The adjective “any” means one, some, or all indiscriminately of whatever quantity.
- The term “and/or” placed between a first entity and a second entity includes any of the meanings of (1) only the first entity, (2) only the second entity, and (3) the first entity and the second entity. The term “and/or” placed between the last two entities of a list of 3 or more entities means at least one of the entities in the list including any specific combination of entities in this list. For example, “A, B and/or C” has the same meaning as “A and/or B and/or C” and comprises the following combinations of A, B and C: (1) only A, (2) only B, (3) only C, (4) A and B and not C, (5) A and C and not B, (6) B and C and not A, and (7) A and B and C.
- The phrase “at least one of” preceding a list of features or entities means one or more of the features or entities. For example, “at least one of A, B, or C” has the same meaning as “A and/or B and/or C” and comprises the following combinations of A, B and C: (1) only A, (2) only B, (3) only C, (4) A and B and not C, (5) A and C and not B, (6) B and C and not A, and (7) A and B and C.
- The phrase “at least a portion” means “a portion or all.” The at least a portion of a stream or material may have the same composition as the stream or material from which it is derived. The at least a portion of a stream or material may include all or only specific components of the stream or material from which it is derived. A stream or material may be subjected to one or more material processing steps, for example chemical treatment and/or physical treatment, to form the at least a portion of that stream or material.
- As used herein, “first”, “second”, “third”, etc. are used to distinguish from among a plurality of steps and/or features, and is not indicative of the relative position in time and/or space.
- In the claims, letters may be used to identify claimed steps (e.g. (a), (b), and (c)). These letters are used to aid in referring to the method steps and are not intended to indicate the order in which claimed steps are performed, unless and only to the extent that such order is specifically recited in the claims.
- An ion transport membrane layer is an active layer of ceramic membrane material comprising mixed metal oxides capable of transporting or permeating oxygen ions at elevated temperatures. The ion transport membrane layer also may transport electrons as well as oxygen ions, and this type of ion transport membrane layer typically is described as a mixed conductor membrane layer. The ion transport membrane layer also may include one or more elemental metals thereby forming a composite membrane.
- The membrane layer, being very thin, is typically supported by a porous layer support structure and/or a ribbed support structure. The support structure is generally made of the same material (i.e. it has the same chemical composition), so as to avoid thermal expansion mismatch. However, the support structure might comprise a different chemical composition than the membrane layer.
- A membrane unit, also called a membrane structure, comprises a feed zone, an oxygen product zone, and a membrane layer disposed between the feed zone and the oxygen product zone. An oxygen-containing gas is passed to the feed zone and contacts one side of the membrane layer, oxygen is transported through the membrane layer, and an oxygen-depleted gas is withdrawn from the feed zone. An oxygen gas product, which may contain at least 95 vol. % or at least 97 vol. % or preferably at least 99 vol. % oxygen, is withdrawn from the oxygen product zone of the membrane unit. The membrane unit may have any configuration known in the art. When the membrane unit has a planar configuration, it is typically called a “wafer.”
- A membrane module, sometimes called a “membrane stack,” comprises a plurality of membrane units. Membrane modules in the present ion
transport membrane assembly 70 may have any configuration known in the art. - An “ion transport membrane assembly” comprises one or more membrane modules, a pressure vessel containing the one or more membrane modules, and any additional components necessary to introduce one or more feed streams and to withdraw two or more effluent streams formed from the one or more feed streams. The additional components may comprise flow containment duct(s), insulation, manifolds, etc. as is known in the art. When two or more membrane modules are used, the two or more membrane modules in an ion transport membrane assembly may be arranged in parallel and/or in series with respect to the predominate direction of flow of either the feed or permeate streams.
- Exemplary ion transport membrane layers, membrane units, membrane modules, and ion transport membrane assemblies are described in U.S. Pat. Nos. 5,681,373, 7,179,323, and 7,955,423.
-
FIG. 1 illustrates a first example embodiment of a hydrometallurgical processing system comprising an iontransport membrane assembly 10 and ahydrometallurgical processing circuit 20 for the hydrometallurgical recovery of one or more metal values from an initial metal-bearingmaterial 1 which may in particular be provided as an initial slurry. The metal-bearingmaterial 1 may be any one of mineral ore, mineral concentrate, tailing material, matte, slag, and calcine or a combination of two or more of these materials. It contains one or more metal values, such as, gold, silver, one or more platinum group metals, copper, nickel, cobalt, lead, zinc, manganese, molybdenum, rhenium, rare earth metals, uranium, and metalloids, e.g. silicon, recovered by hydrometallurgical processing in thehydrometallurgical processing circuit 20. The hydrometallurgical process accomplished incircuit 20 produces at least onerefined metal product 27 or refined intermediate metal-bearingproduct 27 andresidue 28. - The ion
transport membrane assembly 10 comprises one or more membranes each with one or more membrane layers. The one or more membranes are of the mixed conductor type, wherein oxygen ions migrate through the membrane driven by an oxygen partial pressure differential. Thehydrometallurgical processing circuit 20 comprises a pre-processing unit for pre-processing at least a portion of the metal-bearingmaterial 1 for a downstream leaching process in a downstream leaching unit also comprised by thehydrometallurgical processing circuit 20. The pre-processing unit, if present, may be one of a grinding unit, a roasting unit, a pressure oxidation unit, a bio-oxidation unit, an upstream leaching unit, and a solution neutralization unit. Thehydrometallurgical processing circuit 20 may comprise at least one post-processing unit operatively disposed to receive at least a portion of a discharge material from the downstream leaching unit for post-processing. The at least one post-processing unit, if present, may be one of a further leaching unit, a solution neutralization unit, and a remediation unit for the remediation of toxic lixiviant. Should hydrometallurgical processing in thehydrometallurgical processing circuit 20 include, for example, cyanidation as the downstream leaching process cyanide may be oxidized to cyanate in the optional remediation unit. Thehydrometallurgical processing circuit 20 may comprise an acid production unit for the production of acid. In operation each of the units specifically mentioned may consume oxygen. Thehydrometallurgical processing circuit 20 comprises at least one such oxygen consuming unit and may comprise two or more of these oxygen consuming units. - In operation, an oxygen-containing
first feed gas 11 is introduced through an inlet on a feed side of the iontransport membrane assembly 10 at a feed temperature of typically 700° C. to 1000° C. and a feed pressure of typically 1000 kPa to 4000 kPa. A stream of gaseous oxygen-depleted nitrogen-enrichedproduct 13 is withdrawn through a first outlet on the feed or non-permeate side of themembrane assembly 10 at near feed temperature and near feed pressure. A stream ofgaseous oxygen product 15 is withdrawn on the permeate side through a second outlet of themembrane assembly 10 at near feed temperature and a second outlet pressure. In pressure driven embodiments the permeate or second outlet pressure may be selected to fall into the range of, for example, approximately 20 to 300 kPa (absolute); and more preferred into the range of, for example, approximately 40 to 150 kPa; and may most preferred be in the order of around 50 kPa. - At least a portion of the
oxygen product 15 is fed to thehydrometallurgical processing circuit 20 to provide at least a portion of the oxygen consumed in the one or more oxygen consuming units of theprocessing circuit 20. All or only part of theoxygen product 13 fed to thehydrometallurgical processing circuit 20 can provide heat to one or more oxygen consuming units by contact and/or reaction with the material processed in the respective unit and/or by indirect heat exchange during the process and/or before introduction into the process. The at least a portion of theoxygen product 13 can be cooled by indirect heat exchange with one or more effluent streams and/or internal material streams of thehydrometallurgical processing circuit 20 before introducing the at least a portion of theoxygen product 15 into the one or more oxygen consuming units. - Dashed lines illustrate units and connections which are only optional although advantageous to the process and processing system of the invention. One or more or all of the units and connections illustrated in dashed lines may be present in advantageous developments of the basic process and processing system of the invention. Whereas units and connections optional to the invention are characterized this way in
FIGS. 1 and 2 , the distinction is not made inFIGS. 3 to 6 . - Integration of the
ion transport membrane 10 and thehydrometallurgical processing circuit 20 can be improved by recycling gaseous oxygen-containingeffluent 25 from thehydrometallurgical processing circuit 20 to the iontransport membrane assembly 10 and/or to at least a portion of theoxygen product 15 from the iontransport membrane assembly 10. Oxygen-containingrecycle effluent 25 may accordingly be mixed with the oxygen-containingfeed gas 7 to form thefirst feed gas 11 which is separated by the iontransport membrane assembly 10 into the non-permeate and permeateproducts transport membrane assembly 10 the oxygen-containingrecycle effluent 25 may be mixed with at least a portion of theoxygen product 15. In yet a further alternative, the oxygen-containingrecycle effluent 25 may be split into at least two portions (streams), a first of these portions mixed with the oxygen-containingfeed gas 7 to form thefirst feed gas 11 or at least a portion thereof, and a second of the portions ofrecycle effluent 25 mixed with theoxygen product 15, as illustrated inFIG. 1 , or with only a portion of theoxygen product 15. - Recycle
effluent 25 may originate from the downstream leaching unit and/or from one or more pre-processing units such as a grinding unit, a roasting unit, a pressure oxidation unit, and an upstream leaching unit, in particular an oxidative pressure leaching unit, and/or from one or more post-processing units such as a further leaching unit. In embodiments, in which one or more hydrometallurgical processing units comprise one or more autoclaves, for example, one or more autoclaves for pressure oxidation and/or one or more autoclaves for oxidative pressure leaching, the oxygen-containingrecycle effluent 25 may advantageously originate from at least one of these autoclaves. One or more autoclaves may each comprise an effluent outlet through which oxygen-containing recycle effluent can be withdrawn from the pressurized gas built-up above the slurry or solution treated in the respective autoclave. -
Effluent 25 may originate from a single unit of thehydrometallurgical processing circuit 20. In alternative embodiments, oxygen-containing effluent from two or more units of thehydrometallurgical processing circuit 20 may be mixed to form recycleeffluent 25, e.g. oxygen-containing effluent from two or more autoclaves and/or one or more of the other units mentioned may be combined to form recycleeffluent 25 as a combinedrecycle effluent 25.Effluent 25 may be fed back and mixed with oxygen-containingfeed gas 7 expediently at a location where the temperatures and/or pressures and/or oxygen concentrations of the twostreams 7 and/or 15 on the one and 25 on the other hand are matching closest. Various alternative and complementary options for recyclingeffluent 25 taking its temperature and/or pressure and/or oxygen concentration into account are available. Specific options 25.1 to 25.5 are denoted inFIG. 1 , namely: -
- recycling a low temperature low pressure recycle effluent stream 25.1 to be compressed, e.g. by a compressor driven, by
optional turbine 30, and heated, e.g. inoptional heat exchanger 16 and/or optional combustion withfuel 5; and/or - recycling a low temperature high pressure recycle effluent stream 25.2 to be heated by indirect heat exchange e.g. in
optional heat exchanger 16 and/or by optional combustion withfuel 5; and/or - recycling a medium temperature high pressure recycle effluent stream 25.3 to be heated by optional combustion with
fuel 5; and/or - recycling a high temperature high pressure recycle effluent stream 25.4 directly to the feed side of
assembly 10; and/or - recycling a high temperature recycle effluent stream 25.5 to be mixed with the at least a portion of the
oxygen product 15 sent tocircuit 20.
- recycling a low temperature low pressure recycle effluent stream 25.1 to be compressed, e.g. by a compressor driven, by
- Numerous other arrangements are possible, and will readily be configured by one skilled in the art.
- Any of streams 25.1 to 25.4 is mixed with oxygen-containing
feed gas 7 upstream ofmembrane assembly 10. Valuable is in particular oxygen-containingrecycle effluent 25 of high temperature and/or high pressure and/or high oxygen concentration which can be mixed with at least a portion of theoxygen product 15 and/or oxygen-containingfeed gas 7 after compression offeed gas 7, e.g. by a compressor driven byturbine 30, and/or after heating offeed gas 7, e.g. by indirect heat exchange inheat exchanger 16. Particularly valuable is effluent gas from an autoclave operated with an oxidant gas having a high oxygen purity as is often the case in pressure oxidation and oxidative pressure leaching. A pressure oxidation unit and/or an oxidative pressure leaching unit ofcircuit 20, for example, the downstream leaching unit, may be operated to keep the oxygen concentration of the atmosphere within a pressure vessel of the respective unit at an operational level above that of ambient air, e.g. at or above 50 mol. %, or 70 mol. %, or 80 mol. %. To maintain the oxygen concentration at the high operational level despite oxygen consumption, bleed gas containing oxygen at the operational level may be withdrawn and oxidant gas of higher oxygen purity introduced. Such a bleed gas may in particular be recycled as or in therecycle effluent 25 or any of the recycle effluent streams 25.1 to 25.5. - Oxygen-containing recycle effluents from two or more units of the
hydrometallurgical processing circuit 20 may be kept separate from one another and fed back as separate streams, in particular, if recycle effluents of different sources (units) differ widely with respect to temperature and/or pressure and/or oxygen concentration. If, for example, gaseous effluent of a first unit has a higher oxygen concentration than gaseous effluent of a second unit, the effluent of the first unit may be recycled as recycle effluent 25.5 mixed with at least a portion of theoxygen product 15 sent tocircuit 20, and gaseous effluent of the second unit may be recycled in or as any one of recycle effluents 25.1 to 25.4 mixed with oxygen-containingfeed gas 7 upstream ofmembrane assembly 10. If, as a further example, gaseous effluent of a first unit has a higher temperature than gaseous effluent of a second unit, the effluent of the first unit may be recycled in or as recycle effluent 25.3 or 25.4, and gaseous effluent of the second unit may be recycled in or as any one of recycle effluents 25.1 to 25.3.Reference sign 25 may accordingly denote either a combined recycle effluent stream or a plurality of separate recycle effluent streams complying with any two or more of streams 25.1 to 25.5. - The internal energy (heat and work) of the nitrogen-enriched
product 13 can be recovered at least partially to generate electric and/or mechanical power and/or steam and/or by indirect heat exchange with one or more other process streams and/or by combustion withfuel 17. Aturbine 30 may operatively be disposed to receive at least a portion of the nitrogen-enrichedproduct 13 from the iontransport membrane assembly 10 at a turbine high-pressure side to drive theturbine 30 by expansion. An oxygen-containingfeed gas 7, for example air, may be compressed by a compressor coupled with theturbine 30 to be driven either directly by means of a mechanical coupling or indirectly by means of an electric coupling. The compressed oxygen-containinggas 7 may be fed to the iontransport membrane assembly 10 as thefirst feed gas 11 directly or after further compression and/or heating by indirect heat exchange in aheat exchanger 23 and/or combustion withfuel 5. All or only a portion of the oxygen-containinggas 7 compressed by mechanical and/or electric power generated by theturbine 30 may constitute all or only a portion of thefirst feed gas 11. -
Turbine 30 driven by expansion of the nitrogen-enrichedgas 13 may be coupled with agenerator 50 to produceelectric energy 57 which may be utilized to drive one or more agitators in one or more units of thehydrometallurgical processing circuit 20. For example, thegenerator 50 alone or in combination with some other source of electrical energy may drive one or more agitators in an autoclave of a pressure oxidation unit and/or a pressure leaching unit and/or an atmospheric leaching unit and/or a bio-oxidation unit. - The integrated hydrometallurgical processing system may comprise a heat recovery steam generator (HRSG) 40 operatively disposed to receive a steam
generator feed stream 31 comprising at least a portion of the nitrogen-enrichedproduct 13 from the iontransport membrane assembly 10. TheHRSG 40 may receive all or only part of the nitrogen-enrichedproduct 13 directly from the iontransport membrane assembly 10, i.e. without intermediate energy recovery fromproduct 13. In expedient embodiments however the at least a portion of the nitrogen-enrichedproduct 13 is fed to theHRSG 40 after having recovered work by means of a turbine such asturbine 30. In alternative embodiments of a combined recovery of work and heat a turbine may be arranged downstream of theHRSG 40 to recover work after having extracted at least part of the thermal energy of the at least a portion of the nitrogen-enrichedproduct 13. -
HRSG 40 extracts thermal energy from steamgenerator feed gas 31 by indirect heat exchange withfeed water 41 to makesteam 43. Thesteam 43 generated byHRSG 40 can be fed to thehydrometallurgical processing circuit 20 for heating and/or conditioning purposes, for example, in an autoclave of a pressure oxidation unit or leaching unit, and/or for heating afeed slurry 21 of metal-bearing material, only to name examples for utilization. The processing system may comprise asteam turbine 60 operatively disposed to receive at least a portion ofsteam 43 generated byHRSG 40 to recover work. Steam expanded insteam turbine 60 can be fed to thehydrometallurgical processing circuit 20 and utilized there for at least one of the purposes mentioned in connection withsteam 43.Steam turbine 60 may be coupled with a generator, mechanically or electrically, for the production of electrical energy which may be used in thehydrometallurgical processing circuit 20. HRSG off-gas 45 may be purified in a purification unit to produce a nitrogen product for ammonia production. Steam generator feedgas 31 may be heat exchanged withfeed water 41 in HRSG to recover only sensible heat from steamgenerator feed gas 31. At least a portion of steamgenerator feed gas 31, however, may be combusted withfuel 47 to produce additional thermal energy, and the combustion gas heat exchanged withfeed water 41. - The hydrometallurgical processing system may comprise a
heat exchanger 100 for heatinginitial material 1 and/or one or more slurries or solutions of metal-bearing material which may be formed at different stages of amulti-stage processing circuit 20, such asslurries 21 to 24, as will be explained later.Slurry 22 andslurry 24 may for example be fed to autoclaves of thehydrometallurgical processing circuit 20. At least part of the heat for heatinginitial material 1 and/or one or more ofslurries 21 to 24 can be provided by nitrogen-enrichedproduct 13 from the iontransport membrane assembly 10.Heat exchanger 100 may therefore be operatively disposed to receive at least a portion of the nitrogen-enrichedproduct 13 directly or, more preferred, at least aportion 33 of the nitrogen-enrichedproduct 13 after expansion byoptional turbine 30. One or more ofinitial material 1 andslurries 21 to 24 is/are preferably heated inheat exchanger 100 by indirect heat exchange with this at least aportion 33 ofproduct 13. In the example embodiment the at least aportion 33 is a portion of steamgenerator feed gas 31. - At least a
portion 32 of the nitrogen-enrichedproduct 13 may be used in the hydrometallurgical process performed inhydrometallurgical processing circuit 20 as flotation gas in an optional flotation unit to float a portion of a flotation slurry containing one or more metal values, for example, to float molybdenum. Alternatively or in addition to a use as flotation gas, at least aportion 34 of the nitrogen-enrichedproduct 13 may be used to dry the initial metal-bearingmaterial 1 beforeslurry 21 has been formed and/or to dry ground material, only to mention examples for drying. The at least aportion 34 may be used as drying agent to dry by contact and/or to dry by indirect heat exchange. Furthermore, at least a portion of the nitrogen-enrichedproduct 13 may be used for grinding in an oxygen-deficient gas. By “oxygen-deficient” it is meant that the respective gas or environment is either substantially free of oxygen or, if the respective gas or environment does contain some oxygen, the molar fraction of oxygen is smaller than the molar fraction of oxygen contained in ambient air. An oxygen-deficient gas or environment does preferably contain less than 15 mol. %, or less than 10 mol. % of oxygen. Oxygen concentrations of less than 5 mol. % are even more preferred. - The hydrometallurgical processing system may comprise a
hydrogen production unit 70 operatively disposed to receive a hydrogenproduction feed stream 71 and adapted to provide a hydrogen-containingproduct 73. The hydrogenproduction feed stream 71 may comprise natural gas or any hydrocarbon-containing feedstock known for hydrogen production. All or only a portion of the hydrogen-containingproduct 73 can be exported at 74. More preferred, at least aportion 75 of the hydrogen-containingproduct 73 is fed to thehydrometallurgical processing circuit 20 and used for metal reduction and/or pH adjustment and/or other conditioning purposes withincircuit 20. In addition or instead of utilizing the hydrogen-containingproduct 73 or at least aportion 75 thereof directly, i.e. as molecular hydrogen (H2), all or only part of the hydrogen-containingproduct 73 can be used to produce ammonia in an optional ammonia production unit of the hydrometallurgical processing system. A material processing system comprising anammonia production unit 90 is shown inFIG. 2 . -
FIG. 2 shows a second integration example in which anion transport membrane 10 and ahydrometallurgical processing circuit 20 are integrated with ahydrogen production unit 70 and anammonia production unit 90. As in the first example embodiment, a first oxygen-containingfeed gas 11 is introduced into the iontransport membrane assembly 10 at a suitable pressure and temperature for the pressure driven recovery of a nitrogen-enrichedproduct 13 and anoxygen product 15. At least a portion of theoxygen product 15 is fed to thehydrometallurgical processing circuit 20 for utilization as an oxidant in one or more processing units ofcircuit 20, as described earlier, in particular with respect to the first example embodiment. For the advantages nevertheless only optional recycling of oxygen-containingeffluent 25 from thehydrometallurgical processing circuit 20 only with the option of mixing this gas stream with the oxygen-containingfeed gas 7 to form at least a portion of thefirst feed gas 11 is illustrated. Various options of recycling oxygen-containingeffluent 25 ofcircuit 20 are available, in particular those described with respect to the first example embodiment. As far as the reference signs of the first example embodiment are used, reference is made to the explanations made with respect thereto. - A
first portion 75 of hydrogen-containingproduct 73 is fed to thehydrometallurgical processing circuit 20 to be used directly for one or more of the purposes already mentioned with respect to the first example embodiment.Ammonia production unit 90 is operatively disposed to receive asecond portion 77 of hydrogen-containingproduct 73 either directly or after one or more purification steps.Ammonia production unit 90 is furthermore operatively disposed to receive at least a portion of the nitrogen-enrichedproduct 13 from the iontransport membrane assembly 10. Nitrogen-enrichedproduct 13 is expediently purified in an optionalnitrogen purification unit 80 operatively disposed to receiveproduct 13 from the iontransport membrane assembly 10 and deliver a purifiednitrogen product 87 to theammonia production unit 90. Hydrogen-containingproduct portion 77 is expediently purified in a hydrogen purification unit operatively disposed to receivehydrogen product portion 77 and deliver a purified hydrogen product to theammonia production unit 90. At least a portion of theammonia product 93 ofammonia production unit 90 can be utilized in one or more units of thehydrometallurgical processing circuit 20.Hydrometallurgical processing circuit 20 may therefore be operatively disposed to receive at least aportion 94 of theammonia product 93. All or preferably only a portion of theammonia product 93 may be exported asexport ammonia 95. - All of the
ammonia product 93 that is produced byammonia production unit 90, or onlyproduct portion 94 may be incorporated in various integrations with the material processing inhydrometallurgical processing circuit 20. Utilization examples that are shown inFIG. 3 include use insolvent extraction unit 97, and/or in one or more hydrogen reduction autoclaves 98, and/or in NOx mitigation via selective catalytic reduction (SCR) in acatalytic reduction unit 99.Export ammonia 95 is shown as a further option. An optionalhydrogen purification unit 85 operatively disposed to receive hydrogen-containingproduct portion 77 and producing a purified hydrogen product 78 sent toammonia production unit 90 is also shown. - Any of the options of integration explained with reference to
FIGS. 1 to 3 can advantageously be combined, e.g. integrated ammonia production and integrated recovery of heat and/or work from nitrogen-enrichedproduct 13 and/oroxygen product 15 can be implemented in the same processing system. -
FIG. 4 is a flow chart of a hydrometallurgical processing system in conformity with the invention. Various options of integration ofoxygen product 15 of the iontransport membrane assembly 10 of the previous example embodiments are illustrated. Thehydrometallurgical processing circuit 20 is shown in more detail to illustrate some of these options. Thehydrometallurgical processing circuit 20 shown inFIG. 4 is however only an example circuit not intended to limit the invention to thisspecific circuit 20. - In operation, a metal-bearing
material 1, for example, crushed mineral ore, is ground in grindingunit 210. Grindingunit 210 can in particular be a ball mill. If theinitial material 1 containsexcessive water material 1 may be dried in adrying unit 208 to reduce its water content before grinding to form a dried material to be ground as such or in aslurry 21. Nitrogen-enrichedproduct portion 34 may be used for drying at least a portion of theinitial material 1 by indirect heat exchange and/or direct contact, i.e. by passing the at least a portion of nitrogen-enrichedproduct 13 throughmaterial 1. - At least a portion of the ground material may be subjected to flotation in a
flotation unit 215 to produce a flotation concentrate and a flotation tail. Nitrogen-enrichedproduct portion 32 of adequate pressure and temperature, as indicated e.g. inFIG. 1 , may serve as an oxygen-deficient flotation gas or a portion of an oxygen-deficient flotation gas. The ground material or one of the flotation concentrate or flotation tail offlotation unit 215, if present, is transported toslurry preparation unit 220, either as dry ground material or already as slurry, and conditioned there for pressure oxidation. -
Pressure oxidation unit 230 comprises at least one autoclave, preferably a multi-compartment autoclave, operatively disposed to receiveautoclave slurry 22 fromslurry preparation unit 220. Autoclaveslurry 22 fromslurry preparation unit 220 may be heated by indirect heat exchange inoptional heat exchanger 100, as explained above with respect toFIG. 1 , andheated slurry 22 fed to pressureoxidation unit 230. Pressure oxidation is in many cases an exothermic process and may require not for heating but for cooling. If this is the case, at least a part of the cooling required may be provided by cooling at least a portion ofslurry 22 within or before introducing it into a pressure vessel, typically an autoclave, of thepressure oxidation unit 230. Cooling of at least a portion ofslurry 22 may be provided by heat exchange with at least a portion of the oxygen-containingfeed gas 7 instead of or, preferably, in addition toheating feed gas 7 by heat exchange with at least a portion of the nitrogen-enrichedproduct 13 from the iontransport membrane assembly 10. - Pressure oxidized
discharge slurry 23 from thepressure oxidation unit 230 is neutralized in asolution neutralization unit 240 to separate the pressure oxidized discharge in different portions (fractions) in asubsequent separation unit 250. Aslurry 24 of a resultant fraction containing one or more metal values to be recovered, e.g. one or more precious metals, is sent to downstreampressure leaching unit 260 for leaching, preferably oxidative pressure leaching. The discharge ofseparation unit 250 may have to be subjected to intermediate conditioning and/or one of cooling and heating to produceslurry 24 for downstream leaching. If heating is requiredslurry 24 may be heated by indirect heat exchange inoptional heat exchanger 100, as explained above with respect toFIG. 1 , andheated slurry 24 fed todownstream leaching unit 260. -
Downstream leaching unit 260 may in particular be an oxidative leaching unit, preferably an oxidative pressure leaching unit. It may comprise at least one autoclave, preferably a multi-compartment autoclave, operatively disposed to receiveslurry 24 for leaching. A metal value containing solution fromdownstream leaching unit 260 is sent to a post-processing circuit for extraction/purification in an extraction/purification unit 270 and/or subjected to hydrogen reduction in ahydrogen reduction unit 280. A metal value containing portion (fraction) discharged from the post-processing circuit is further refined in arefining unit 290 downstream ofhydrogen reduction unit 280 to producerefined metal product 27. -
FIG. 4 shows, as already mentioned, options for integrating theoxygen product 15 from the iontransport membrane assembly 10. At least aportion 151 of theoxygen product 15 may be introduced into the at least one autoclave of thepressure oxidation unit 230. In embodiments, in which thedownstream leaching unit 260 is anoxidative leaching unit 260, preferably an oxidative pressure leaching unit, at least aportion 152 of theoxygen product 15 may be introduced into at least one container, preferably an autoclave, of thedownstream leaching unit 260, as another prime option of utilization ofoxygen product 15 from the iontransport membrane assembly 10. In embodiments, in which thehydrometallurgical processing circuit 20 comprisespressure oxidation unit 230 and downstream oxidativepressure leaching unit 260, afirst portion 151 of theoxygen product 15 can be introduced into the one or more autoclaves of thepressure oxidation unit 230, and asecond portion 152 can be introduced into the one or more autoclaves of the downstream oxidativepressure leaching unit 260. As a complementary or alternative option, at least aportion 153 of theoxygen product 15 may be sent to thesolution neutralization unit 240 and/or at least a portion of theoxygen product 15 may be sent to a lixiviant remediation unit, e.g. for cyanide destruction. - In embodiments in which the integrated hydrometallurgical processing system of the invention comprises an on-site
acid production unit 300 for the production ofacid 302, for example, sulfuric acid, and/or an on-sitehydrogen production unit 70such units 70 and/or 300 may also need oxygen. At least aportion 154 of theoxygen product 15 may therefore be sent to optional on-siteacid production unit 300, and/or at least aportion 155 may be sent to optional on-sitehydrogen production unit 70. At least a portion of ahot flue gas 74 ofhydrogen production unit 70, if present, may be heat exchanged with water in an optional heatrecovery steam generator 315 to generatesteam 79 for use in the hydrometallurgical processing, e.g. inhydrogen reduction unit 280. A comparable set-up is shown for the optionalacid production unit 300. At least a portion of a hot flue gas fromacid production unit 300 may be cooled by indirect heat exchange with water in a heatrecovery steam generator 305 to generatesteam 309 for use in the hydrometallurgical processing, e.g. inpressure oxidation unit 230. Heatrecovery steam generator 305 and/or heatrecovery steam generator 315 may be combined withHRSG 40 or may be combined one with the other to generate steam for one or more of the units of thehydrometallurgical processing circuit 20, for example, to generate steam for thepressure oxidation unit 230 and/orhydrogen reduction unit 280, as illustrated, or a leaching unit ofcircuit 20, for example, thedownstream leaching unit 260. - Grinding
unit 210 may grind metal-bearingmaterial 1 orslurry 21 containing at least a portion ofmaterial 1 in an oxygen-containing gas or liquid, in particular in example embodiments in which grindingunit 210 is a fine or ultra-fine grinder. Grinding in oxygen can provide for metal activation already during grinding. At least aportion 150 of theoxygen product 15 may therefore be sent to grindingunit 210 for grinding in oxygen or in an oxygen gas mixture, e.g. in oxygen air. In alternative embodiments it might be desirable to impede oxidation during grinding. In thoseembodiments grinding unit 210 may operatively be disposed to receive an oxygen-deficient gas containing at least a portion of the nitrogen-enrichedproduct 13 from the iontransport membrane assembly 10 for grinding in an oxygen-deficient environment. - Any autoclave receiving at least a
portion oxygen product 15 may comprise a gassing system for the introduction of the assignedportion portion - The
oxygen product 15 from iontransport membrane assembly 10 may provide for all of the oxidant or at least all of the oxygen consumed in the hydrometallurgical process, as preferred. In alternative embodiments, however, iontransport membrane assembly 10 may supply only part of the oxidant consumed incircuit 20. Oxidant gas provided to one or more oxygen consuming units ofcircuit 20 contains at least a portion ofoxygen product gas 15 and may contain one or more other oxidants, such as, chlorine, and/or oxygen from some other oxygen sources. - Furthermore,
oxygen product 15 from iontransport membrane assembly 10 may be provided as such, i. e. as diatomic oxygen, to one or more oxygen consuming units ofcircuit 20. In developments, at least a portion of theoxygen product 15 from iontransport membrane assembly 10 may be activated in an oxygen activation unit and provided as activated oxygen, in particular, as ozone, to one or more oxygen consuming units ofcircuit 20 to increase the rate of oxidation in the respective unit. Oxidant gas introduced into one or more oxygen consuming units ofcircuit 20 may accordingly consist of or comprise activated oxygen generated from at least a portion of theoxygen product 15 from iontransport membrane assembly 10. -
FIG. 4 illustrates, as an option, utilization of activated oxygen in thedownstream leaching unit 260. The at least aportion 152 ofoxygen product 15 is fed through anoxygen activation unit 160 to activate at least part ofoxygen product portion 152 and provide at least partly activatedportion 152 as oxidant gas to thedownstream leaching unit 260. -
FIG. 5 shows an example for further heat integration of iontransport membrane assembly 10 andhydrometallurgical processing circuit 20 by heat exchanging additional streams in heatrecovery steam generator 40. Heat recovery from steamgenerator feed stream 31 to producesteam 43 fromwater feed 41 has been explained with respect to the first example embodiment (FIG. 1 ). The option of combusting at least a portion of steamgenerator feed stream 31 with fuel provided byfuel feed 47 has also been mentioned. As a further option, at least a portion of oxygen-containingfeed gas 7 can be preheated by indirect heat exchange inHRSG 40. Another option, which might be implemented in addition or alternatively, is to recover heat from another steamgenerator feed stream 26, which is a hot off-gas fromhydrometallurgical processing circuit 20. To summarize, heat may be recovered from steamgenerator feed gas 31, i.e. from at least a portion of the nitrogen-enrichedproduct 13 received from iontransport membrane assembly 10 directly or after intermediate expansion and/or intermediate cooling, and/or from combusting at least a portion of steamgenerator feed gas 31 withfeed fuel 47, and/or from steam generator feed gas 26 (hot off-gas) fromcircuit 20. At least a portion of oxygen-containingfeed gas 7 may be heated inHRSG 40 in addition to the generation ofsteam 43. -
FIG. 6 shows an example for heat integration of iontransport membrane assembly 10 and optionalhydrogen production unit 70. As shown, at least a portion of the hydrogenproduction feed stream 71 can be heated in anoptional heat exchanger 19 by indirect heat exchange with at least a portion of theoxygen product 15 from iontransport membrane assembly 10.Heated feed stream 71 is introduced intohydrogen production unit 70, and cooledoxygen product 15 is fed to thehydrometallurgical processing circuit 20. At least a portion offirst feed gas 11 may be heated by indirect heat exchange inheat exchanger 18 against at least a portion of the hydrogen-containingproduct 73 fromhydrogen production unit 70 and/or against hydrogenproduction flue gas 74 fromhydrogen production unit 70. First feedgas 11 heated inheat exchanger 18 may be combusted withfuel 5 before being introduced into the iontransport membrane assembly 10. Hydrogen-containingproduct 73 having been cooled inheat exchanger 18 may then be split intoproduct portion 75 which is sent tohydrometallurgical processing circuit 20 andproduct portion 77 sent to ammonia production unit 90 (FIG. 2 ), if present. Theheat exchangers heat exchangers oxygen product 15 and at least one of thehydrogen product 73 andflue gas 74 forheating feed gas 11 and/or feedstream 71. In further developments at least one of theheat exchangers FIG. 4 wherehot flue gas 74 is illustrated to be used in heatrecovery steam generator 315 for the production ofsteam 79.
Claims (20)
1. A hydrometallurgical processing system for processing a metal-bearing material, the system comprising:
an ion transport membrane assembly comprising an ion transport membrane layer and having a feed side and a permeate side where the feed side has an inlet for introducing a first feed gas comprising oxygen and nitrogen into the ion transport membrane assembly and a first outlet for withdrawing a nitrogen-enriched product from the feed side of the ion transport membrane assembly, and where the permeate side has a second outlet for withdrawing an oxygen product from the ion transport membrane assembly; and
a hydrometallurgical processing circuit comprising
a pre-processing unit operatively disposed to receive a metal-bearing material and selected from a group of units consisting of a grinding unit, a roasting unit, a pressure oxidation unit, a bio-oxidation unit, an upstream leaching unit, and a solution or slurry preparation unit;
a downstream leaching unit operatively disposed to receive at least a pre-processed portion of the metal-bearing material from the pre-processing unit; and
one or both of an acid production unit and a post-processing unit, the post-processing unit, if present, operatively disposed to receive and adapted to post-process material from the downstream leaching unit;
wherein at least one of the pre-processing unit, the downstream leaching unit, the acid production unit, if present, or the post-processing unit, if present, are operatively disposed to receive an oxidant gas containing at least a portion of the oxygen product and/or activated oxygen generated from at least a portion of the oxygen product from the ion transport membrane assembly.
2. The system of claim 1 wherein the hydrometallurgical processing circuit comprises at least one outlet for an oxygen-containing effluent gas, this outlet operatively connected with one or both of
the feed side of the ion transport membrane assembly for feeding at least a portion of an oxygen-containing effluent gas from the hydrometallurgical processing circuit to the feed side of the ion transport membrane assembly; and
a mixing junction for mixing at least a portion of an oxygen-containing effluent gas from the hydrometallurgical processing circuit with the at least a portion of the oxygen product.
3. The system of claim 1 wherein the pre-processing unit is a pressure oxidation unit operatively disposed to receive at least a portion of the oxidant gas, and/or the downstream leaching unit is an oxidative leaching unit operatively disposed to receive at least a portion of the oxidant gas.
4. The system of claim 1 , wherein
the pre-processing unit is a grinding unit operatively disposed to receive the metal-bearing material; and
the hydrometallurgical processing circuit comprises at least one further pre-processing unit operatively disposed to receive at least a portion of the ground metal-bearing material from the grinding unit and selected from the group consisting of a pressure oxidation unit, a roasting unit, a bio-oxidation unit, an upstream oxidative leaching unit, and an oxidative solution or slurry preparation unit;
wherein at least one of
(a) the grinding unit is operatively disposed either to receive at least a portion of the oxidant gas for grinding in an oxygen containing gas or liquid or to receive an oxygen-deficient grinding gas containing at least a portion of the nitrogen-enriched product for grinding in an oxygen-deficient environment;
(b) the at least one further pre-processing unit is operatively disposed to receive at least a portion of the oxidant gas for at least partial consumption in oxidation; or
(c) the downstream leaching unit is operatively disposed to receive at least a portion of the oxidant gas for oxidative leaching.
5. The system of claim 1 wherein at least one of the pre-processing unit, the downstream leaching unit, or the post-processing unit, the latter if present, comprises an autoclave operatively disposed to receive an autoclave slurry or solution containing one or more metal values of the metal-bearing material and operatively disposed to receive at least a portion of the oxidant gas, the autoclave comprising a gassing system for introducing the at least a portion of the oxidant gas into the autoclave slurry or solution.
6. The system of claim 1 wherein the hydrometallurgical processing circuit comprises:
an autoclave operatively disposed to receive an autoclave slurry or solution containing one or more metal values of the metal-bearing material; and
a heat exchanger to heat the autoclave slurry or solution by indirect heat transfer with a heat exchanger feed stream comprising at least a portion of the nitrogen-enriched product and/or at least a portion of the oxidant gas.
7. The system of claim 1 further comprising a turbine operatively disposed to receive at least a portion of the nitrogen-enriched product from the ion transport membrane assembly, the turbine being a gas turbine, a combustion turbine, or a pressure letdown turbine,
wherein the turbine is operatively disposed to provide at least a portion of the first feed gas to the ion transport membrane assembly, and/or
wherein the system further comprises a generator for producing electric power, the generator operatively connected to the turbine to receive shaft work from the turbine and the hydrometallurgical processing circuit operatively disposed to receive at least a portion of the electric power produced by the generator.
8. The system of claim 1 further comprising a heat recovery steam generator operatively disposed to receive one or more steam generator feed streams and feed water, the heat recovery steam generator adapted to extract heat from the one or more steam generator feed streams and to produce steam from the feed water, wherein the one or more steam generator feed streams comprise at least a portion of the nitrogen-enriched product from the ion transport membrane assembly and/or a hot off-gas from the hydrometallurgical processing circuit.
9. The system of claim 8 wherein a steam generator feed stream is combusted with fuel, the heat recovery steam generator adapted to recover heat from the combustion of the steam generator feed stream with the fuel and/or from at least a portion of a hot combustion product of that combustion.
10. The system of claim 8 wherein the heat recovery steam generator is adapted to recover heat from one or more of the following heat sources (i) to (iv):
(i) at least a portion of the nitrogen-enriched product received as the steam generator feed stream,
(ii) a hot off-gas of the hydrometallurgical processing circuit received as the steam generator feed stream or as a further steam generator feed stream,
(iii) the combustion of the preceding claim, or
(iv) the at least a portion of the hot combustion product of the preceding claim to produce steam from the feed water;
wherein the hydrometallurgical processing circuit is operatively disposed to receive at least a portion of the steam from the heat recovery steam generator; and/or
wherein the heat recovery steam generator is operatively disposed to receive an oxygen-containing feed gas and adapted to heat the oxygen-containing feed gas by recovering heat from one or more of the heat sources (i) to (iv), the heat recovery steam generator operatively disposed to provide at least a portion of the heated oxygen-containing feed gas to the ion transport membrane assembly.
11. The system of claim 1 further comprising:
a hydrogen production unit operatively disposed to receive a hydrogen production feed stream and to provide a hydrogen-containing product wherein the hydrometallurgical processing circuit is operatively disposed to receive at least a portion of the hydrogen-containing product;
and at least one of
a heat exchanger adapted to heat the hydrogen production feed stream by indirect heat transfer with a heat exchanger feed stream comprising at least a portion of the oxygen product and/or at least a portion of the nitrogen-enriched product from the ion transport membrane assembly; or
a heat exchanger adapted to heat at least a portion of the first feed gas by indirect heat transfer with a heat exchanger feed stream comprising at least a portion of the hydrogen-containing product and/or a hydrogen production unit flue gas.
12. The system of claim 1 further comprising:
a hydrogen production unit operatively disposed to receive a hydrogen production feed stream and to provide a hydrogen-containing product;
a nitrogen purification unit operatively disposed to receive at least a portion of the nitrogen-enriched product from the ion transport membrane assembly; and
an ammonia production unit operatively disposed to receive a nitrogen product from the nitrogen purification unit and operatively disposed to receive at least a portion of the hydrogen containing product from the hydrogen production unit to produce an ammonia product;
wherein the hydrometallurgical processing circuit is operatively disposed to receive at least a portion of the ammonia product from the ammonia production unit.
13. The system of claim 1 wherein the hydrometallurgical processing circuit comprises one or more of the following units:
a drying unit operatively disposed to receive at least a portion of the metal bearing material and a drying gas containing at least a portion of the nitrogen-enriched product from the ion transport membrane assembly, the drying unit adapted to reduce a liquid content of the at least a portion of the metal bearing material by at least one of direct contact and indirect heat exchange with the drying gas to provide a dried metal bearing material for further processing in the hydrometallurgical processing circuit; and/or
a grinding unit operatively disposed to receive at least a portion of metal-bearing material and an oxygen-deficient grinding gas containing at least a portion of the nitrogen-enriched product from the ion transport membrane assembly, the grinding unit adapted to grind the at least a portion of the metal-bearing material in an oxygen-deficient environment by contacting the at least a portion of the metal-bearing material with the grinding gas; and/or
a flotation unit operatively disposed to receive a flotation slurry containing at least a portion of the metal-bearing material and an oxygen-deficient flotation gas containing at least a portion of the nitrogen-enriched product from the ion transport membrane assembly, the flotation unit adapted to pass the flotation gas through the flotation slurry to float one or more metal values of the flotation slurry with the flotation gas to provide a flotation concentrate and a flotation tail.
14. A hydrometallurgical process for processing a metal-bearing material containing one or more metal values, the process comprising the steps of:
(a) providing an ion transport membrane assembly comprising an ion transport membrane layer and having a feed side and a permeate side;
(b) introducing a first feed gas comprising oxygen and nitrogen into an inlet to the feed side of the ion transport membrane assembly;
(c) withdrawing a non-permeate nitrogen-enriched product from an outlet from the feed side and a permeate oxygen product from an outlet from the permeate side of the ion transport membrane assembly;
(d) providing a hydrometallurgical processing circuit comprising one or more units for carrying out the hydrometallurgical process, a process carried out in at least one of the one or more units consuming oxygen by chemical reaction, the one or more units selected from the group consisting of a grinding unit, a roasting unit, a pressure oxidation unit, a bio-oxidation unit, an upstream leaching unit, an upstream solution or slurry preparation unit, a downstream leaching unit, a further downstream leaching unit, a further downstream solution or slurry preparation unit, a lixiviant remediation unit, and an acid production unit;
(e) pre-processing the metal-bearing material in the hydrometallurgical processing circuit;
(f) leaching at least a pre-processed portion of the metal-bearing material in the hydrometallurgical processing circuit to recover at least one metal value from the metal-bearing material; and
(g) introducing an oxidant gas containing at least a portion of the oxygen product and/or activated oxygen generated from at least a portion of the oxygen product from the ion transport membrane assembly into at least one oxygen consuming unit of the one or more units of the hydrometallurgical processing circuit for oxidation.
15. The process of claim 14 further comprising:
recycling at least a portion of an oxygen-containing effluent gas of the hydrometallurgical processing circuit in a first recycle effluent stream and/or a second recycle effluent stream;
and at least one of
recycling the first recycle effluent stream to the feed side of the ion transport membrane assembly to form a portion of the first feed gas; or
mixing the second recycle effluent stream with at least a portion of the oxygen product of the ion transport membrane assembly to form a mixed stream containing the at least a portion of the oxygen product and the oxygen containing effluent gas of the second recycle effluent stream, and introducing the mixed stream into the at least one oxygen consuming unit of the hydrometallurgical processing circuit to provide oxidant.
16. The process of claim 14 wherein
the hydrometallurgical processing circuit comprises a pre-processing unit and a downstream leaching unit;
at least a portion of the metal-bearing material is pre-processed in the pre-processing unit by one or more of grinding, roasting, pressure oxidation, bio-oxidation, upstream leaching, and/or solution or slurry preparation to produce a pre-processed material containing the at least one metal value; and
at least a portion of the pre-processed material is leached in step (f) in the downstream leaching unit as the at least a pre-processed portion of the metal-bearing material;
wherein at least a first portion of the oxidant gas is introduced into the pre-processing unit and/or at least a second portion of the oxidant gas is introduced into the downstream leaching unit for oxidation.
17. The process of claim 14 comprising
operating the ion transport membrane assembly at a temperature within a membrane temperature range of 700° C. to 1000° C.;
withdrawing the non-permeate nitrogen-enriched product in step (c) at a temperature within the membrane temperature range;
withdrawing the permeate oxygen product in step (c) at a temperature within the membrane temperature range;
operating the at least one oxygen consuming unit at a temperature within a unit temperature range of 80° C. to 300° C.;
and providing oxidant to a process performed in this oxygen consuming unit by introducing at least a portion of the oxidant gas into the at least one oxygen consuming unit in step (g).
18. The process of claim 17 , furthermore comprising the step of recovering heat from at least a portion of the oxidant gas by heating a process stream of the hydrometallurgical processing circuit before introducing the at least a portion of the oxidant gas into the at least one oxygen consuming unit in step (g).
19. The process of claim 14 wherein at least a portion of the oxidant gas is introduced into a grinding unit for grinding at least a portion of the metal-bearing material in an oxygen containing gas or liquid; and/or wherein at least a portion of the oxidant gas is introduced into a roasting unit for roasting at least a portion of the metal-bearing material; and wherein at least a portion of the ground and/or roasted material is leached in step (f).
20. The process of claim 14 furthermore comprising at least one of the following steps:
(i) generating steam from feed water by heat exchange with at least a portion of the nitrogen-enriched product and introducing at least a portion of the generated steam into the hydrometallurgical processing circuit;
(ii) heating an autoclave slurry or solution by heat exchange with at least a portion of the nitrogen-enriched product and introducing the heated autoclave slurry or solution into an autoclave of the hydrometallurgical processing circuit for leaching or pressure oxidation;
(iii) introducing at least a portion of the nitrogen-enriched product into an ammonia production unit to produce an ammonia product, and introducing at least a portion of the ammonia product into the hydrometallurgical processing circuit;
(iv) floating one or more metal values of the metal-bearing material with an oxygen-deficient flotation gas containing at least a portion of the nitrogen-enriched product in a flotation unit;
(v) grinding at least a portion of the metal-bearing material in a grinding unit while contacting the at least a portion of the metal-bearing material with an oxygen-deficient grinding gas containing at least a portion of the nitrogen-enriched product; or
(vi) drying at least a portion of the metal-bearing material by passing a drying gas containing at least a portion of the nitrogen-enriched product through the at least a portion of the metal-bearing material.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| US14/560,526 US20160160312A1 (en) | 2014-12-04 | 2014-12-04 | Hydrometallurgical System and Process Using an Ion Transport Membrane |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| US14/560,526 US20160160312A1 (en) | 2014-12-04 | 2014-12-04 | Hydrometallurgical System and Process Using an Ion Transport Membrane |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| US20160160312A1 true US20160160312A1 (en) | 2016-06-09 |
Family
ID=56093772
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| US14/560,526 Abandoned US20160160312A1 (en) | 2014-12-04 | 2014-12-04 | Hydrometallurgical System and Process Using an Ion Transport Membrane |
Country Status (1)
| Country | Link |
|---|---|
| US (1) | US20160160312A1 (en) |
Citations (6)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US4869883A (en) * | 1988-06-24 | 1989-09-26 | Air Products And Chemicals, Inc. | Inert gas purifier for bulk nitrogen without the use of hydrogen or other reducing gases |
| CA2016640A1 (en) * | 1989-05-17 | 1990-11-17 | Kevin S. Fraser | Process for recovery of gold from refractory ores |
| US6733567B1 (en) * | 1999-09-07 | 2004-05-11 | Billiton Intellectual Property, B.V. | Recovery of nickel from nickel bearing sulphide minerals by bioleaching |
| US7179323B2 (en) * | 2003-08-06 | 2007-02-20 | Air Products And Chemicals, Inc. | Ion transport membrane module and vessel system |
| US20130112568A1 (en) * | 2010-07-21 | 2013-05-09 | Hitachi Zosen Corporation | Method for synthesizing ammonia |
| US20130153436A1 (en) * | 2011-12-20 | 2013-06-20 | Freeport-Mcmoran Corporation | Systems and methods for metal recovery |
-
2014
- 2014-12-04 US US14/560,526 patent/US20160160312A1/en not_active Abandoned
Patent Citations (6)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US4869883A (en) * | 1988-06-24 | 1989-09-26 | Air Products And Chemicals, Inc. | Inert gas purifier for bulk nitrogen without the use of hydrogen or other reducing gases |
| CA2016640A1 (en) * | 1989-05-17 | 1990-11-17 | Kevin S. Fraser | Process for recovery of gold from refractory ores |
| US6733567B1 (en) * | 1999-09-07 | 2004-05-11 | Billiton Intellectual Property, B.V. | Recovery of nickel from nickel bearing sulphide minerals by bioleaching |
| US7179323B2 (en) * | 2003-08-06 | 2007-02-20 | Air Products And Chemicals, Inc. | Ion transport membrane module and vessel system |
| US20130112568A1 (en) * | 2010-07-21 | 2013-05-09 | Hitachi Zosen Corporation | Method for synthesizing ammonia |
| US20130153436A1 (en) * | 2011-12-20 | 2013-06-20 | Freeport-Mcmoran Corporation | Systems and methods for metal recovery |
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| US10480046B2 (en) | Process for copper and/or precious metal recovery | |
| EP3290534A1 (en) | Alkaline and acid pressure oxidation of precious metal-containing materials | |
| Singer et al. | Learning from nature: recovery of rare earth elements by the extremophilic bacterium Methylacidiphilum fumariolicum | |
| WO2013096070A1 (en) | Systems and methods for metal recovery | |
| CN102712965A (en) | Process of recovery of base metals from oxide ores | |
| US20120034154A1 (en) | Production of hydrogen through oxidation of metal sulfides | |
| FI20215804A1 (en) | System and method for enhanced metal recovery during atmospheric leaching of metal sulfides | |
| US9371228B2 (en) | Integrated process for production of ozone and oxygen | |
| CN111433377A (en) | Method for recovering and extracting gold from electronic waste or gold-containing minerals, ores and sands | |
| US20090032403A1 (en) | Uranium recovery using electrolysis | |
| US20170240434A1 (en) | Enhanced metal recovery through oxidation in liquid and/or supercritical carbon dioxide | |
| CA1110076A (en) | Metal leaching from concentrates using nitrogen dioxide in acids | |
| US20160160312A1 (en) | Hydrometallurgical System and Process Using an Ion Transport Membrane | |
| CN114854982A (en) | Gas-based low-temperature reduction roasting-leaching method for recovering copper and cobalt in sulfuric acid slag | |
| Liao et al. | Synergistic roasting of spent lithium-ion batteries and nickel matte for preferential lithium extraction and efficient leaching of transition metals | |
| WO1996007762A1 (en) | Mineral processing | |
| EA008574B1 (en) | Recovery of platinum group metals | |
| CN100355917C (en) | Recovery of platinum group metals | |
| US3915689A (en) | Pollution-free process for treating copper sulfide flotation concentrates and recovering copper | |
| CA2472495A1 (en) | Process to recover base metals | |
| RU2749310C2 (en) | Method for pocessing sulphide gold and copper float concentrate | |
| CN116287756A (en) | Method and system for extracting copper and cobalt from copper-cobalt slag | |
| RU2255127C2 (en) | Method of extraction of copper and gold from oxidized ores and technogenious wastes | |
| US20230147263A1 (en) | Sulphide oxidation in leaching of minerals | |
| WO1989012699A1 (en) | Hydrometallurgical recovery of gold |
Legal Events
| Date | Code | Title | Description |
|---|---|---|---|
| AS | Assignment |
Owner name: AIR PRODUCTS AND CHEMICALS, INC., PENNSYLVANIA Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:THAYER, MATTHEW J.;REPASKY, JOHN MICHAEL;ARMSTRONG, PHILLIP ANDREW;AND OTHERS;REEL/FRAME:034378/0873 Effective date: 20141203 |
|
| STCB | Information on status: application discontinuation |
Free format text: ABANDONED -- FAILURE TO RESPOND TO AN OFFICE ACTION |