WO2011134036A1 - System for the dry concentration of metallic and nonmetallic materials and for the processing of technological waste - Google Patents

Abstract

The claimed system relates to mining concentration equipment and can be used in branches of the national economy including construction, mining, the chemical industry, etc. for the dry concentration of metallic and nonmetallic materials and technological waste comprising components having particles of differing shape or density, for example vermiculite, mica, metal ores, metallurgical slag, etc. The system for the dry concentration of metallic and nonmetallic materials and for the processing of technological waste comprises the following, which are interconnected: a preliminary material preparation section or a material storage site, or a technological process section, at least one sifter and at least two separating apparatuses which are connected separately from each other to different outputs of the products of the sifting operation. The separating apparatuses are in the form of pneumatic classifiers. The technical result is an increase in the quality of separating a wide class of materials.

Description

 COMPLEX FOR DRY TREATMENT OF ORE AND NON-METAL MATERIALS AND PROCESSING OF TECHNOGENIC WASTE.

The utility model relates to mining and processing equipment and can be used in the construction, mining, chemical and other sectors of the economy for the dry beneficiation of ore, non-metallic materials and industrial waste containing components with different shapes or densities of particles, for example, vermiculite, mica, ore metals, metallurgical slag, etc.

 A known complex for dry dressing of ore and non-metallic materials and processing of industrial waste, including interconnected section of preliminary preparation of material or a place of accumulation of material, or a section of a technological process, a screen, to the outputs of which, separately from each other, two screens are connected, the outputs of which are equipped vibrating screens [1].

 The disadvantages of this complex include the low separation efficiency.

 The task to which the utility model is directed is to create a complex of processing equipment that ensures high quality separation of a wide class of materials.

The problem is solved in that in the complex for dry dressing of ore and non-metallic materials and the processing of industrial waste, including interconnected section of the preliminary preparation of the material or the place of accumulation of material, or the section of the technological process, at least one screen and at least two separating devices connected separately from each other with different outputs of the screening products, separating devices are made in the form of pneumatic classifiers. The problem can also be solved by the fact that at least one pneumatic classifier can be equipped with a dust separator; at least one dust collector may be provided with at least one vibrating screen; at least one pneumatic classifier may be provided with at least one vibrating screen; the complex can be equipped with at least one grinder; at least one pneumatic classifier can be connected to at least one chopper connected to at least one screen; at least one vibrating screen connected to a pneumatic classifier can be connected to at least one shredder connected to at least one screen; the complex can be equipped with an additional pneumatic classifier for processing crushed material connected to a grinder and equipped with a dust collector connected to a vibrating screen and at least one vibrating screen; the preliminary preparation section may include sequentially arranged and interconnected primary screen, a drying drum, a secondary screen, and / or a magnetic separator.

 Figure 1 presents a complex for dry concentration of ore and non-metallic materials and the processing of industrial waste.

The complex for dry dressing of ore and non-metallic materials and processing of industrial waste includes interconnected section of preliminary preparation of material 1 or a place of accumulation of material, or a section of a technological process (not shown in FIG. 1), at least one screen 2, having at least, the output of a large screening product 3 and the output of a small screening product 4, and at least a pneumatic classifier 5 and a pneumatic classifier 6. A pneumatic classifier 5 is connected to the output of a large the screening product 3, and the pneumatic classifier 6 is connected to the output of the small screening product 4. Any pneumatic classifier 5 and 6 can be equipped with a dust collector 7 and 8, with each dust collector 7 and 8 can be equipped with a vibrating screen 9 and 10. Any pneumatic classifier 5 and 6 may be provided with at least one vibrating screen 11 and 12. The proposed the complex can be equipped with at least one grinder 13, the input of which can be connected with at least one pneumatic classifier 5 and 6, and the output with at least one screen 2. In addition, the input of the grinder 13 can be connected to at least one vibrating screen 11 and 12. The proposed complex can also be equipped with an additional pneumatic classifier for processing the crushed material 14, connected to the grinder 13 and equipped with a dust collector 15, equipped with a vibrating screen 16, and at least one him vibrosieve 17. The preliminary preparation section 1 may include sequentially located and interconnected primary screen, drying drum, secondary screen, and / or magnetic separator (not shown in FIG. 1).

 We will consider the operation of the complex for dry concentration of ore and non-metallic materials and the processing of industrial waste using the example of processing electronic scrap.

In this example of work of the proposed complex, scrap is divided into metal components (MK) with a particle density of p _μ > 7 g / cm and non-metallic components (NMC) with a particle density of p _{мк μ} <2 g / cm ³ . Particles are separated in pneumatic classifiers in air flows, where their aerodynamic drag for this example is determined by Newton’s resistance law, which operates at Ke> 1000 (where Res is the Reynolds criterion for a particle, determined by the formula Res = 5xv / v, where δ is the size particles, ν is the relative velocity of air flow around it, V is the kinematic viscosity coefficient of air). In the range of the Newton’s law of resistance, the value of the boundary particle size of particle separation is 5 _rp ~ f (l / p), where p is the particle density. In this case, the ratio of the particle sizes of the boundary size separation of the NMC and MK will be determined by the ratio 5 _grNM / §grmk ⁼ Rmk / Rnmk> 7/2 = 3.5. The value of the dynamic coefficient of the shape of the particles, affecting the aerodynamic resistance of the particles, for most NMC particles, is significantly larger than for MK particles. Therefore, we assume that the ratio of the particle sizes of the boundary fineness of the separation of NMC and MK is determined by the value of 5 _g nmk / $ _g mk The complex works as follows. After the preliminary preparation section 1, electronic scrap with a particle size of up to 10 mm is fed to a screen 2, where it is divided into at least two products: a large screening product (CNG) of a size of 2.5-10 mm and a small screening product (MPG) of a size of 0- 2.5 mm.

 CNG, through the exit of a large screening product 3, screen 2 is fed into a pneumatic classifier 5, where a heavy separation product (TPR5) and a light separation product (LPR5) are separated into two products according to the boundary separation size relative to metal components of MK, for example, about 2.5 mm. TPR5 is a polymetallic concentrate with a MK content of 2.5-10 mm. LPR5 contains NMC with a particle size of 2.5-10 mm.

 The PGM through the output of the small screening product 4 of the screen 2 is fed into the pneumatic classifier 6, where it is separated into two products TPR6 and LPR6 according to the boundary separation size relative to MK 0.63 mm. TPR6 is a polymetallic concentrate with an MK content of 0.63-2.5 mm. LPR6 is an industrial product and contains NMC with a particle size of 0-2.5 mm and MK with a particle size of less than 0.63 mm.

The content of MK in the polymetallic concentrate is regulated by the value of the boundary coarse grain size of the MK separation - δ _ΓρΜ κ and can reach a mass content of more than 95%. TPR5 with the required content of MK goes to metallurgical processing. LPR5 contains NMC with a particle size of 2.5-10 mm and is a waste product or is supplied for further processing in order to produce building aggregates.

If the design of pneumatic classifiers does not provide for internal circulation of air flow and dust deposition, pneumatic classifiers 5 and 6 can be connected to dust precipitators 7 and 8 to isolate the DM from the aerodisperse stream. For further processing, LDP4 after dust collector 8 can be fed to a vibrating screen 10. On the vibrating screen 10, LDP4 is fractionated by size, for example, 0.63 mm. Moreover, a large fractionation product (KPF10) contains NMC with a particle size of 0.63-2.5 mm and does not contain MK, i.e. is a waste product, and a small fractionation product (MPF10) contains MK and NMK with a particle size of less than 0.63 mm and, being an industrial product, it can be sent for storage or further processing.

When the intergrowths of MK and NMK are contained in electronic scrap, additional processing of the separation products is necessary to reveal the intergrowths and the separation of their components. In this case, TPR5 is a polymetallic concentrate or intermediate product containing MK with a particle size of 2.5-10 mm and intergrowths with a particle size of 2.5 <5 _cpT np5min <10 mm, where 5 _cp tpR5tt is the minimum size of the intergrowth, and LPR5 is a dump or intermediate product with the content of NMC with a particle size of 2.5-10 mm and splices with a particle size of 2.5 <5 _srL pR5tah ^< 10 ^mm _> where 5 _cp lpR5takh is the maximum size of the sprout. TPR5 for further processing can be fed to a grinder 13 for opening splices or to a vibrating screen 1 1, where it is fractionated according to the technologically selected size SrpBci ^P R ^{I et m} 5 _gr bc11> 5 _cpTrT p ₅ min, to obtain two products - MPF1 1 and KPF11. MPF1 1 is a polymetallic concentrate with a size of 2.5 mm- $ _g rvsp- KPF11 is an intermediate product, contains MK and splices with a size of A-rvsp-10 ^{mm and} can be sent to warehousing or further processing, including to a shredder 13 for opening splices.

LPR5 can be fed to a dust separator 7 and then to a vibrating screen 9, where it is fractionated by a technologically selected size of 5 _gV s9 with 5 _{g of} sun 9 ^ 5 _srL pr5tah. As a result, KFR9 can be obtained with a predominantly NMC content of 5 _{gVS of} size 9-U mm dump product and MPF9, containing HMW and splices with a size of 2.5 mm-5 _gV s9 _> which can be sent for storage or further processing, including a shredder 13 for opening splices.

TPR6 is a polymetallic concentrate or intermediate product and contains MK with a grain size of 0.63-2.5 mm and intergrowths with a grain size of 0.63 <5 _srTP p _4tt <2.5 mm, where 5 _cpT np6min is the minimum size of the intergrowth. LPR6 is a dump or intermediate product and contains NMC with a particle size of 0-2.5 mm and intergrowths with a particle size of 0 <b _sr lprbtah ^< 2.5 mm, where 5 _srL srbtah is the maximum size of the splicing. For further processing, TPR6 can be fed to a grinder 13 for opening splices or to a vibrating screen 12, where it is fractionated by a technologically selected size of 6 _rpB ci 2 _? at the same time 5 _grVS12 > 5 _cpT np6min- V MPF12, which is a polymetallic concentrate with a size of 0.63 mm-5 _grVS12 and KPF12, which is an intermediate product and contains MK and intergrowths with a particle size of 5 _rpB ci2-2.5 mm and can be sent for storage or further processing, including chopper 13 for disclosing splices.

LPR8 can be fed to a vibrating screen 10, where it is fractionated into two fractions, KFR10 and MPF10, according to the technologically selected size of 5 _rpBC io, with δ _{Γρ α ο} > 5 _srL pRbtah-, with this, KFR10 is a waste product and contains mainly NMK fineness $ _{gr is} all-2.5 mm, and MPF10 is an intermediate product and contains MK, NMK and intergrowths with a particle size of 0-6 _grV sy and can be sent further. for storage or further processing.

The grinder 13 is configured for selective grinding - first of all, for the opening or destruction of splices, as well as for grinding the NMC. After the grinder 13, the material can be fed to the screen 2 or to an additional pneumatic classifier for processing the crushed material 14, the optimal value of the boundary separation size of which is determined by the fractional and component composition of the material after the grinder 13, namely: the minimum size of MK particles and aggregates entering the grinder 13 with TPR6 is ~ 0.63 mm, if we assume that the grinder 13 does not significantly reduce the particle size of MK, then the value of the boundary particle size of separation by MK δ _ΓρΜ κ additional pneumatic classifier for processing crushed material 14 may be ~ 0.63 mm Material can be fed into the pneumatic classifier 14 after the grinder 13. In it, the material is separated on TPR14, which is a polymetallic concentrate with a grain size of MK> 0.63 mm and on LPR14, which enters the dust collector 15 and is a waste product with a grain size of NMC <2.5 mm

If necessary, TPR14 can be fed to a vibrating screen 17, where it is fractionated by the required size, determined by the fractional and component composition of TPR14, to KPF17 and MPF17, which are polymetallic concentrates of the second and first grade. KPF17 may come for additional processing to the grinder 13. LPR15 can be fed to a vibrating screen 16, where it is fractionated according to the required size, determined by the fractional and component composition of LPR14, to KPF16 and MPF16, which in this case are a waste product and industrial product.

 The result is a marketable product in the form of a polymetallic concentrate with an adjustable MK content of more than 90-95%.

 Thus, the proposed complex provides with high quality separation the dry enrichment of ore, nonmetallic materials and industrial waste containing components with different shapes or densities of particles, for example, vermiculite, mica, metal ores, metallurgical slag, etc.

Information sources:

 1. WO 2005014188 A1, 2005.

Claims

USEFUL MODEL FORMULA 1. A complex for dry concentration of ore and non-metallic materials and processing of industrial waste, including a pre-prepared material preparation area or a material storage site, or a process section, at least one screen and at least two separation devices connected separately from each other with different yields of screening products, characterized in that the separating devices are made in the form of pneumatic classifiers.  2. The complex according to claim 1, characterized in that at least one pneumatic classifier is equipped with a dust separator.  3. The complex according to claim 2, characterized in that at least one dust collector is equipped with at least one vibrating screen.  4. The complex according to claim 1, characterized in that at least one pneumatic classifier is equipped with at least one vibrating screen.  5. The complex according to claim 1, characterized in that it is equipped with at least one grinder.  6. The complex according to claim 5, characterized in that at least one pneumatic classifier is connected to at least one chopper connected to at least one screen.  7. The complex according to claim 5, characterized in that at least one vibrating screen connected to a pneumatic classifier is connected to at least one grinder connected to at least one screen. 8. The complex according to claim 5, characterized in that it is equipped with an additional pneumatic classifier for processing crushed material connected to a grinder and equipped with a dust collector connected to a vibrating screen, and at least one vibrating screen. 9. The complex according to any one of paragraphs. 1-8, characterized in that the pre-treatment section includes sequentially located and interconnected primary screen, dryer drum, secondary screen, and / or magnetic separator