RU2322401C2 - Deep water desalting system on countercurrent h-oh ionite filters - Google Patents

Abstract

FIELD: water treatment.

SUBSTANCE: in deep water desalting system installed upstream of chemical desalting unit on clarified water line, H-Na cationite filter and/or Cl anionite filter, or H-Na-Cl ionite filter are additionally included. Spent regeneration solution line of H cationite filter of chemical desalting unit is linked to H-Na cationite filter or to H-Na-Cl ionite filter and spent solution line of OH anionite filter is linked to Cl anionite or H-Na-Cl ionite filter.

EFFECT: reduced specific consumption of acid on regeneration of H filters, prevented pollution of countercurrent H cationite and OH anionite filters, reduced number or eliminated chemical treatments of ion-exchange resins, and reduced consumption of water on own needs of installation.

2 cl, 4 dwg, 1 tbl

Description

The invention relates to the field of ion-exchange processes in countercurrent mode on H-OH-ionite filters and can be used to produce deeply desalted water in the energy, electronic, chemical-technological, metallurgical, oil refining and other industries.

A known system of deep desalination of water, containing sequentially included installation of clarification with a line of clarified water and a chemical desalination of clarified water with countercurrent H-cation exchange filter, OH-anion exchange filter and with lines of spent regeneration solutions [1] - prototype. The disadvantages of this system are the increased acid consumption (1.8-1.9 g-equiv / g · equiv) for the regeneration of H-cation exchange filters; contamination of ion exchange resins with suspended solids, coagulation products, aluminum and iron compounds, organic substances and the associated deterioration of filter performance; the need for periodic cleaning of ion-exchange resins in H-OH filters and the associated costs of acid and alkali; increased water consumption for own needs (~ 14%). These shortcomings are the result of a simplified pre-treatment scheme (coagulation in clarifiers and clarification on mechanical filters), which does not provide for the removal of residual contaminants from clarified water. Another disadvantage of the system [1] is the discharge of spent regeneration solutions from the H-OH-ionization unit containing high concentrations of reactive acid and alkali.

Achievable results of the invention are to reduce the specific consumption of acid for the regeneration of H-filters to 1.2-1.3 g · equiv / g · equiv; prevention of contamination of counterflow H-cation exchange and OH-anion exchange filters with suspended solids, aluminum and iron compounds, organic substances, as well as reducing the number or elimination of chemical cleaning of ion-exchange resins; Reuse of spent solutions of H- and OH-ionite filters and the acids, alkalis and sodium salts contained in them; reduction of water consumption for the plant’s own needs (up to 8-10%).

The indicated results are ensured by the fact that in a deep water desalination system comprising a clarification unit in series with a clarified water line and a chemical desalination plant for clarified water with a countercurrent H-cation exchange filter, OH-anion exchange filter and with spent regeneration solution lines, according to the invention, on a clarification line water before the installation of chemical desalination additionally included H-Na-cation exchange filter and / or Cl-anion exchange filter or H-Na-Cl-ion exchange filter, line o the spent regeneration solution of the H-cation exchange filter is connected to the H-Na-cation exchange filter or the H-Na-Cl ion exchange filter, and the line of the spent solution of the OH-anion exchange filter is connected to the Cl-anion exchange filter or the H-Na-Cl ion exchange filter. In this case, the H-Na-cation exchange filter can be loaded with strongly and / or weakly acid cation exchangers, the Cl-anion exchange filter can be loaded with a strongly basic organoabsorbing anion exchange resin, and the H-Na-Cl ion exchange filter can be loaded with a mixture of these ion exchangers.

Modern technologies of countercurrent Н-ОН ionization (Apcor, Amberpak, Schwebebede, etc.) place high demands on the quality of the incoming water (substantially more stringent than for direct-flow desalination). This is due to the fact that counter-current H-OH filters operating according to the indicated technologies are filled with ion exchangers over the entire height of the volume, almost to the upper drainage. In this regard, they are more susceptible to pollution contained in the incoming water. For this reason, before counterflow H-OH filters, the content of suspended solids is limited to less than 0.5 mg / dm ³ , iron less than 0.05 mg / dm ³ , aluminum less than 0.05 mg / dm ³ , organic compounds no more than 2 , 5 mgO / dm ³ , and for COD no more than 8.0 mgO / dm ³ .

In addition, the feature of countercurrent tinting is the possibility of obtaining higher technological parameters (working exchange capacity of ion exchangers, low specific consumption of reagents) when water comes into the filters with a predominant content of monovalent ions (for example, high sodium and low calcium, magnesium).

In accordance with the invention, an H-Na-cation exchange filter is included in the clarification unit (pre-treatment) with an increased content of iron, aluminum and the presence of hardness in clarified water.

Cl-anion exchange filter is included in the pretreatment with a high content of organic compounds and sulfates in clarified water.

The H-Na-Cl-ion exchanger filter is included in the pretreatment with an increased content of the above impurities in clarified water.

In the water entering the installation of H-OH-ionization of the system according to the invention, the suspended matter content is 0-0.1 mg / dm ³ , the content of hardness ions is 0.05 mg · equiv / l, alkalinity is 0.2 -0, 3 mEq / l, and organic substances by oxidizability - 2 mgO / l, i.e. significantly lower than in the system according to the prototype [1]. In addition, the content of aluminum and iron in this water is 5-7 times lower than in clarified water. This prevents contamination of the load of H-OH filters and reduces or completely eliminates the need for water-air leaching (which leads to mixing of the layers and the need for increased consumption of acid and alkali reagents), as well as the need for chemical cleanings, which entail additional costs of reagents. In addition, the ion composition in the additionally treated clarified water changes significantly: after the I-Na filter, the content of hardness cations and alkalinity decreases and the sodium content increases, after the Cl-anion exchange filter the content of sulfates and alkalinity decreases and the content of chlorides increases.

In the system according to the invention, the H-cation exchange filter of the chemical desalination plant will be in the Na form at the time of depletion, and therefore, displacement of monovalent sodium cations by the countercurrent regeneration scheme requires significantly lower acid consumption than displacement of divalent cations Ca and Mg.

Figure 1 as an example implementation of the invention schematically depicts a deep water desalination system with H-OH-ionite filters, the pre-treatment of which, in addition to the clarifier and the mechanical filter, provides an H-Na-cation exchange filter; figure 2 as another example with reference to the source water with a high content of organic compounds and with a low content of cationic stiffness - a system in which the Cl-anion exchange filter is included in the pretreatment; figure 3 as another example implementation of the invention in relation to water with a high content of cationic stiffness and organic compounds - a system in which the composition of the pre-treatment in series with the H-Na-cation exchange filter includes Cl-anion exchange filter to remove organic substances; figure 4 as another example implementation of the invention in relation to the source water of the same quality as in figure 3 is a system in the composition of the pre-treatment which provides a H-Na-Cl-ion exchange filter.

The deep water desalination system according to the invention comprises a series-connected clarification (pretreatment) (PO) 1 installation with clarifier (O) 1.1, a mechanical filter 1.2 and clarified water line 1.3, and a chemical desalination (CHO) 2 clarified water installation on countercurrent H-cation exchange resin filter (H) 2.1 and OH-anion exchange filter (OH) 2.2 with a decarbonizer (D) 2.3 between them, lines 2.4, 2.5 for supplying fresh regeneration solutions of acid and alkali, respectively, and lines 2.6, 2.7 for discharging the corresponding spent regeneration GOVERNMENTAL solutions. The composition of PO 1 on the clarified water line 1.3 (before HOU 2) additionally includes an H-Na-cation exchange filter (HNa) 1.4 (Figs. 1, 3), a Cl-anion exchange filter (Cl) 1.6 (Figs. 2, 3), or H-Na-Cl ion exchange filter (HNaCI) 1.5 (Fig. 4). The line 2.6 of the spent regeneration solution of the H-cation exchange filter 2.1 HOU 2 is connected to the H-Na-cation exchange filter 1.4 or the H-Na-Cl-ion exchange filter 1.5, and the line 2.7 of the spent solution of the OH-anion exchange filter 2.2 to the Cl-anion exchange filter 1.6 or H-Na-Cl-ion filter 1.5.

The system according to the invention operates as follows. The source water is preliminarily supplied to PO 1, where O1.1 clarifier passes sequentially, mechanical filter (M) 1.2, H-Na-cation exchange filter 1.4 (Figs. 1, 3) and / or Cl-anion exchange filter 1.6 (Fig. 2, 3) or H-Na-Cl-ion exchanger filter 1.5 (Fig.3). Deeply purified from suspended solids, softened water (Fig. 1), purified from organic substances (Fig. 2), softened and additionally purified from organic substances (Fig. 3, 4), is fed to HOU 2 operating on H-OH- filters 2.1, 2.2, between which it undergoes decarbonization in a decarbonizer D 2.3. For regeneration, sulfuric acid is fed into the H-cation exchange filter 2.1 through line 2.4, and sodium hydroxide is fed into the OH-anion exchange filter 2.2 through line 2.7. The spent solution from the H-cation exchange filter 2.1 is fed through line 2.6 to the regeneration of the H-Na-cation exchange filter 1.4 (Figs. 1, 3) or to the regeneration of the H-Na-Cl-ion exchange filter 1.5 (Fig. 4). The spent solution from the OH-ionite filter 2.2 is fed through line 2.7 to the regeneration of the Cl-anionite filter 1.6 (FIGS. 2, 3) or to the regeneration of the H-Na-Cl-ionite filter 1.5 (FIG. 4).

Example. The source water after treatment in clarifier O1.1 with aluminum sulfate and clarification on a mechanical filter M 1.2 (Fig. 3) is fed to H-Na cation on a filter 1.4 loaded with weakly and strongly acidic cation exchangers (MAC-3 and KU-2-8 ), and then on Cl anionization on a 1.6 filter loaded with an organoabsorbing anion exchange resin (Marathon 11). Further, deeply purified from suspended and organic substances, iron and aluminum, softened water is supplied to HOU 2 with counterflow H-OH filters 2.1, 2.2 and a decarbonizer D 2.3 between them.

The table below shows the compositions of the source, clarified and H-Na-Cl-ionized water supplied to counterflow H-OH-ionite filters 2.1, 2.2.

Table The indicators of the composition of the initial water of the VPU and the stages of its pre-treatment Composition indicators source after clarification filter after H-Na and Cl filters Suspended substances, mg / DM ³ 13-30 2.0-3.0 0,0-0,1 Oxidation, mgO / DM ³ 18-30 4.0-6.0 1.6-2.0 COD, mgO / dm ³ 40-60 15-24 6.4-8.0 Hardness, mg · equiv / dm ³ 1.8-2.8 1.8-2.8 0.02-0.05 Ca, mg · eq / dm ³ 1.1-1.6 1.1-1.6 - Mg, mg · equiv / dm ³ 0.7-1.2 0.7-1.2 - Sodium, mg / dm ³ 14-25 14-25 32-57 Alkalinity, mg · equiv / dm ³ 1.8-2.5 1.2-1.6 0.15-0.2 pH 7.6-7.9 7.4-7.6 6.4-6.6 Cl, mg / dm 14-34 14-34 322-64 SO ₄ , mg / dm ³ 11-21 40-64 16-23 SiO _2, mg / dm ³ 2.2-5.1 2.1-4.7 1.9-4.5 NO _2, mg / dm ³ 0.02-0.03 0.003-0.005 traces NO ₃ , mg / dm ³ 1.3-2.3 0.2-1.0 0.1-0.5 Fe, mg / dm ³ 0.7-1.8 0.1-0.2 0.02-0.03 Al, mg / dm ³ 0.12-0.27 0,1-0,12 0.01-0.015

As can be seen from the table, the water quality after H-Na and Cl filters (in accordance with the invention) is much better than after clarification filters (prototype) in terms of suspended solids, organics (oxidizability, COD), iron, aluminum, nitrites nitrates adversely affecting the operation of H-OH-ionite filters. This makes it possible to operate Н-ОН-ionite filters without periodic water-air washes and chemical cleanings with stable technological parameters (demineralized water quality, exchange capacity of ion exchangers, water consumption for own needs 8 - 10%). In addition, the supply of softened water for chemical desalination significantly improves the regeneration conditions of N-cation exchange filters, namely, it allows to reduce the specific acid consumption for regeneration to a minimum of 1.2-1.3 g · equiv / g · equiv.

The spent regeneration solution of the H-cation exchange filter 2.1 UXO 2 is fed through line 2.6 to the regeneration of the H-Na-cation exchange filter 1.4. As a result, weakly acid cation exchange resin transforms into the H-form, strongly basic cation exchange resin - into the Na form. The spent regeneration solution of OH-anion exchange filters 2.2 HOU 2 is fed through line 2.7 to the regeneration of Cl-filter 1.5. As a result, the organoabsorbing anion exchange resin is regenerated organically and passes predominantly into the Cl form. As a result of the regenerations, the H-Na-cation exchange filter 1.4 and Cl-anion exchange filter 1.5 provide high quality water supplied to counterflow H-OH-cation exchange filters 2.1.2.2 (see table).

The source of information

1. Introduction of counterflow technology APKORE at the water treatment plant for desalination of water at Mosenergo TPP-12 / I.I. Borovkova et al. // Electric stations. 2000, No. 5, p. 38.

Claims (2)

1. A deep water desalination system, comprising a clarification unit in series with a clarified water line and a chemical desalination system for clarified water with a countercurrent H-cation exchange filter, a OH-anion exchange filter, and lines of spent regeneration solutions, characterized in that the clarified water line is installed before installation chemical desalination additionally included H-Na-cation exchange filter and / or Cl-anion exchange filter or H-Na-Cl-ion exchange filter, spent recovery solution line N-cat the ion-exchange filter is connected to an H-Na-cation exchange filter or an H-Na-Cl-ion exchange filter, and the spent solution line of the OH-anion exchange filter is connected to a Cl-anion exchange or H-Na-Cl-ion exchange filter. 2. The system according to claim 1, characterized in that the H-Na-cation exchange filter is loaded with strongly and / or weakly acid cation exchangers, the Cl-anion exchange filter is loaded with strongly basic organoabsorbing anion exchange resin, and the H-Na-Cl ion exchange filter is loaded with a mixture of these ion exchangers.

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