RU2099291C1 - Method and installation for removing arsenic from acid waste waters - Google Patents

Abstract

FIELD: waste water treatment. SUBSTANCE: method may find use in chemical industry and nonferrous metallurgy for removing arsenic from waste waters, in particular, in sulfuric acid production and in heavy nonferrous metal industry. Acid waste water is treated by disintegrated iron scrap. Released gaseous arsenic hydrogen is submitted to thermal dissociation to yield elementary arsenic and hydrogen. To completely remove arsenic from partially purified waste water, the latter is treated with sodium ferrate. Process is conducted in installation containing reactor with filter reagent charge made up of disintegrated iron scrap, horizontal settler, original waste water- supply and clarified water-discharge pipelines, and sludge-withdrawal pipeline. Settler is separated into compartments by removable vertical filter elements constituting perforated steel containers filled with crushed rock mixed with fine iron scrap. EFFECT: enhanced waste water purification. 2 cl, 1 dwg

Description

 The invention relates to methods for the separation of arsenic from acidic aqueous solutions and can be used in the chemical industry and non-ferrous metallurgy for wastewater treatment from arsenic, in particular, in sulfuric acid production, metallurgy of heavy non-ferrous metals, etc.

Known sulfide purification method based on chemical precipitation of arsenic from a solution in the form of arsenic sulfide As ₂ S ₃ by treating solutions with sodium sulfide Na ₂ S or NaHS (edited by J.K. Kushney, USA, Removal of metals from wastewater. Neutralization and deposition M. Metallurgy, 1987, pp. 44, 45; auth. St. Czechoslovakia N 261397, class C 02F 1/62 of 11/01/89; RZH "Chemistry, 1990, 15I413, Method for the detoxification of arsenic-containing water, resulting from desulfurization coke oven gas).

 The disadvantage of this method is the incompleteness of deposition due to the need to use an insufficient stoichiometric amount of sodium sulfide due to the formation in the acidic environment of toxic gaseous hydrogen sulfide released into the atmosphere of industrial premises, which worsens the sanitary state of production and complicates the system of air purification from it and beyond.

 In addition, the storage of slurry sediments of arsenic sulfide is very difficult and expensive due to its high leachability by atmospheric precipitation due to the low dispersion.

There is also a method of neutralizing arsenite ions AsO $\genfrac{}{}{0ex}{}{\text{-one}}{\text{2}}$ in wastewater with pyrolusite MnO ₂ with their oxidation in an acidic environment (pH 0.5-3) to AsO ions $\genfrac{}{}{0ex}{}{\text{-3}}{\text{4}}$ followed by neutralization with milk of lime to pH 8-9 and separation of insoluble precipitates of manganese and calcium arsenates from water.

The disadvantage of this method is the appearance in the wastewater of a secondary pollutant of Mn ions, for example MnSO ₄ , in the case of sulfate effluents and pyrolusite itself due to the need for its excessive use.

 In addition, in the process of neutralization, a lot of gypsum is formed, this leads to an increase in sludge sediment, which increases its storage cost.

 A known installation for the purification of acidic wastewater from arsenic, containing a horizontal settling tank, a reaction chamber, a container for preparing a reagent, a dispenser for a reagent, pipelines for supplying purified water, for removing filtrate and sludge, a slurry pump (L.V. Milovanov. Wastewater treatment non-ferrous metallurgy enterprises. M. Metallurgy, 1971, p. 180-195).

 In such an installation, an excess amount of reagent is used to achieve complete purification from arsenic. This increases the volume of sludge and increases the cost of storage. When only lime is used as a precipitant to ensure MPC for arsenic, it is required in an amount thousands of times higher than the amount of arsenic in the treated water. In this case, complete purification from arsenic is fundamentally unattainable, since the coprecipitation of arsenic with the resulting gypsum is possible only as a result of adsorption processes, and not chemical interaction. With partial replacement of lime with pyrolusite ore, the amount of precipitation decreases proportionally, but the quality of clarified water decreases as a result of secondary pollution of it with unreacted reagent and the product of its reaction with acidic wastewater.

 The task to which the invention is directed is to eliminate secondary pollution of wastewater, reduce sludge volumes, simplify and reduce the cost of production.

 To solve the problem in a method of purifying acidic wastewater from arsenic, including treating them with a precipitating arsenic reagent and separating the precipitate by filtration, according to the invention, acidic wastewater is pretreated with crushed iron scrap to separate part of the arsenic in the form of gaseous arsenic hydrogen, from which elemental is separated by thermal dissociation arsenic and hydrogen, and the subsequent wastewater treatment is sodium ferrate-4.

 Preliminary treatment of wastewater with scrap iron allows one to isolate part of As in the form of a commercial product at the first stage of purification, which reduces the amount of reagent for oxidation of sodium ferrate-4 at the second stage of processing, where the remaining part of arsenic is neutralized by turning it into insoluble arsenic-5.

 Reducing the consumption of ferrate-4 for oxidation of the remaining part of arsenic leads in turn to a decrease in the total amount of sludge of iron hydroxide and the cost of its storage.

The use of sodium ferrate-4 due to its rapid spontaneous decomposition in the treated water to iron hydroxide and oxygen eliminates secondary contamination of wastewater by it, which makes it possible to use it in excess of arsenic in contrast to the reagents used in the analogues (Na ₂ S) and prototype ( MnO ₂ ).

 The proposed method can be carried out in an arsenic wastewater treatment plant containing a horizontal sump, pipelines for supplying purified water, for bleeding clarified water and sludge, reagent feeders, slurry pump, which according to the invention is equipped with a reactor with a filter nozzle of crushed iron scrap interconnected by means of a gas discharge pipe with an arsenic hydrogen thermal dissociation unit and connected to the purified water supply pipeline and to burn ontalnym sump, the latter is provided with a vertical filter element, a perforated, container filled with a mixture of rubble of fine iron bar separating settler into sections, each of which is equipped with a valve pulpoprinimayuschim slurry pump and is connected to a dispenser reagent supply.

 The separation of the sump into compartments by filtering elements facilitates the timely removal of sludge products from the reaction zone, which ensures a more complete oxidation reaction, i.e. the complete consumption of the sodium ferrate-4 reagent for the oxidation of arsenic, and this ultimately reduces its consumption and the amount of slurry iron hydroxide formed in this process.

 The sump combines three functions: a reactor, a filtering apparatus for preliminary cleaning of dispersed suspensions and the sump itself, in contrast to the prototype, where the reaction chamber and sump are separate and there is no pre-filtering.

 This simplifies and reduces the cost of technology to neutralize dissolved arsenic and precipitation.

 As a result of the use of filtering partitions in the sump, the quality of clarified water significantly increases, this leads to a decrease in subsequent energy costs for further cleaning from suspensions.

 By eliminating calcification, the amount of sludge is reduced and secondary pollution is eliminated, technology is simplified and production is cheaper.

 The presence of a pre-treatment unit for acidic wastewater with scrap iron also reduces the amount of reagent for the oxidation of arsenic, and helps to obtain arsenic and hydrogen in the process of purification of commercial products, which also reduces the cost of the technology.

 The method is as follows.

 For testing, acidic (pH 0.5-3) wastewater from copper smelting and sulfuric acid production was used.

Acidic wastewater is passed through a nozzle of iron shavings and small scrap iron. The evolved gaseous arsenic hydrogen is subjected to thermal dissociation at 518 ^o C to obtain elemental arsenic and hydrogen, the latter can be used in autoclave production of non-ferrous powder metals as a reducing agent after compression.

 The wastewater passing through the iron nozzle is treated with solid crushed sodium ferrate-4, which disproportionates with the formation of a highly active oxidizing agent, sodium ferrate-6 and coagulant of iron hydroxide, to complete neutralization from arsenic.

The oxidizing agent with arsenic-3 forms an insoluble iron arsenate FeAsO ₄ after the reaction, which precipitates together with a mixture of Fe (OH) ₃ hydroxide and Fe (OH) SO ₄ hydroxosulfate, which is easily separated from the solution.

 The solution is further used for secondary purposes in the water circulation, since the secondary water may have different alkalinity (pH≥7), depending on the dosage of sodium ferrate-4, for the neutralization of arsenic-3. This secondary water is used either to neutralize acidic non-arsenic solutions, or where sodium-containing raw materials are required along with neutralization, for example, in the production of polyphosphates at sulfuric acid superphosphate plants, or to neutralize and neutralize wastewater contaminated with oil.

 With an excess of sodium ferrate-4, secondary contamination of the solution to be purified does not occur due to the instability of sodium ferrate-4 in the solution, which quickly decomposes completely into coagulant hydroxide and alkali.

In addition to purification from arsenic, the proposed method also purifies from associated heavy metals, since all of them form insoluble arsenates and ferrites, for example Cu ₃ (AsO ₄ ) ₂ and CuFe ₂ O ₄ , ZnFe ₂ O ₄ , Zn ₃ (AsO ₄ ) ₂ , as well as from organic compounds, for example oil, due to their oxidation with sodium ferrate-6.

 The proposed method is carried out in an installation for the purification of acidic wastewater from arsenic.

 The drawing shows a flow chart of wastewater treatment of copper smelting-sulfuric acid production.

The installation comprises a horizontal settling tank 1 with a bottom slanted at an angle of 5-15 ^° , pipelines for supplying treated water 2, 3, for draining clarified water 4, for draining slurry 5, a reactor 6 with a filter nozzle 7 from crushed iron scrap, connected by a vent pipe 8 with thermal dissociator 9 of arsenic hydrogen.

Thermal dissociator 9 consists of nichrome wire grids heated by alternating current of 50 Hz with a voltage due to the resistance of the grids and the required dissociation temperature of arsenic hydrogen at 518 ^o C.

 The sump 1 is divided into compartments 10 by removable filter elements 11, which are perforated steel containers filled with crushed stone interspersed with scrap iron. Each compartment 10 is equipped with a slurry receiving valve 12 of the periodically switched on slurry pump 13 in case of clogging of the compartment and is connected to a reagent supply batcher 14.

 The slurry pump 13 and the sump 1 are connected to centrifuges 15 and 16, where the pulp is squeezed out from the sump compartments 10 and the clarified discharge from the last compartment in the direction of the purified water.

 Installation works as follows.

Waste water enters the reactor 6, passes through the nozzle 7 from the iron scrap, while the acids contained in it are partially neutralized and gaseous arsenic hydrogen is released, which through the pipeline 8 enters the thermal dissociator 9, where arsenic hydrogen decomposes at t 518 ^o C elemental commodity arsenic and associated hydrogen, which is sent to consumers.

Partially purified from arsenic water from the reactor 6 through the pipeline 3 enters the horizontal sump 1, the volume of which depends on the volume of purified water. Here, from the storage warehouse through the dispenser 14, solid crushed sodium ferrate-4 enters each compartment 10. The amount of sodium ferrate-4 is determined by the content of arsenic-3 in the wastewater of each compartment. In the sump, after disproportionation of sodium ferrate-4, sodium ferrate-6 interacts with arsenic-3, insoluble iron arsenate FeAsO _{4 is formed} , which co-precipitates together with Fe (OH) ₃ hydroxide - Fe (OH) SO ₄ hydroxosulphate, which, as sediment accumulates through valves 12 are aspirated to a centrifuge 15. The signal for turning on the pump 13 is an increase in the volume of pulp in the compartments in excess of the maximum controlled amount resulting from the clogging of the filter element 11. The pump is switched on automatically. The pulp from the compartments 10 of the sump is squeezed in a centrifuge 15, and the filtrate together with purified water from the centrifuge 16 is sent for re-industrial use. The precipitate after centrifuge 15, 16, containing arsenic-5, is sent for processing or disposal.

 When the wastewater moves along the sump, it is subsequently cleaned of dispersed suspensions, both newly formed and passed through the filter elements. Precipitation or suspension in each compartment 10 is formed as a result of the interaction of previously unreacted arsenic-3 with a fresh portion of sodium ferrate-4. In the last compartment, arsenic-3 is absent in the treated water. The clarified discharge from the last along the purified water compartment of the sump is subjected to separation in a centrifuge 16 with a combination of filtrates and sediments from the centrifuge 15.

 The spent iron nozzle 7 from reactor 6 is used to produce sodium ferrate-4. The containers 11 periodically as they completely stop their filtering ability (sludge) are removed and replaced with new ones with fresh filter material. The slurry contents of the spent containers are subjected to burial together with a precipitate of sulfohydroxide and iron arsenate obtained in centrifuges 15, 16.

The advantages of the proposed technical solution compared to the well-known:
reagent consumption reduction;
elimination of secondary wastewater pollution;
reduction of sludge volumes;
simplification and cheapening of technology;
improving the quality of clarified water and reducing subsequent energy costs for further treatment;
obtaining marketable products of arsenic and hydrogen;
wastewater treatment of associated heavy metals and organic compounds;
creating the possibility of using purified water for secondary purposes in the water circulation.

Claims (2)

 1. A method of purifying acidic wastewater from arsenic, including treating them with a precipitating arsenic reagent, separating the precipitate by filtration, characterized in that the wastewater is pretreated with ground iron scrap to separate part of the arsenic in the form of gaseous arsenic hydrogen, from which elemental arsenic is isolated by thermal dissociation and hydrogen, and the subsequent wastewater treatment is sodium ferrate-4.  2. Installation for cleaning acidic wastewater from arsenic, containing a horizontal settling tank, pipelines for supplying purified water, for bleeding clarified water and sludge, reagent feeders, slurry pump, characterized in that it is equipped with a reactor with a filtering nozzle of reagent from crushed iron scrap interconnected by means of a gas outlet pipe with an arsenic hydrogen thermal dissociation unit and connected to the purified water supply pipe and to a horizontal settling tank, the latter with abzhen vertical filter elements made in the form of perforated containers filled with a mixture of rubble of fine iron bar separating settler into sections, each of which is equipped with a slurry pump pulpoprinimayuschim valve and connected to the reagent feed dispensers.