RU2482074C1 - Method of treating waste water from arsenic - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention can be used in industry when treating waste or natural water from arsenic. The method involves use of a composite sorbent which contains as the sorbing component iron hydroxide particles which are immobilised on organic fibres, bringing the sorbent into contact with water to form insoluble arsenic compounds and separating the treated water from solid treatment products. In the sorbent, iron hydroxide particles are immobilised by cellulose fibres during chemical deposition thereof in an aqueous dispersion of said fibres. Waste water is brought into contact with the sorbent by mixing to form a suspension of solid treatment products containing arsenic. The cellulose fibres contain, wt %: at least 94% fibres with length of not more than 1.23 mm and at least 54% fibres with length of not more than 0.63 mm. The sorbent has the following composition, pts.wt: cellulose fibres -100, iron hydroxide - 20-500. Water treatment is carried out at sorbent concentration of 40-300 mg/dm³. Separation of the treated water from solid treatment products is carried out by pressure flotation, wherein the flotation sludge or a portion thereof is fed into the water treatment process.

EFFECT: method increases efficiency of the water treatment process, simplifies the treatment technology, increases the degree of purification of water with different contamination levels at high volume rate of treatment.

5 cl, 3 ex

Description

The invention relates to technologies for the treatment of wastewater or natural water from arsenic compounds and can be used in various industries.

A known method of purification of solutions from arsenic by precipitation with a sulfide-containing reagent, for example sodium hydrosulfide (RU, No. 2312820, C02F 1/62, C01G 22/00, C02F 103/16, publ. 20.12.2007). The deposition of arsenic is carried out to its residual concentration in the solution of 0.03 g / DM ³ .

The disadvantages of the method are the high residual concentration of arsenic in purified water, as well as the complexity of the processing of precipitation.

There is also a method of treating wastewater from arsenic, including sorption on the wood-inorganic sorbent DNS-1 (Wood-inorganic sorbent DNS-1. Directory-reference book "Inorganic sorbents", Perm, 1988, S. 49-50). The sorbent is obtained by precipitation of iron hydroxide in the pores of the wood carrier with an alkaline reagent.

The disadvantage of this method is the single use of the sorbent and the low efficiency of water purification due to the low content of the active component (iron hydroxide) in the sorbent matrix.

Closest to the technical nature of the present invention is a method for wastewater treatment from arsenic, including the use of a composite sorbent containing, as the sorbing (active) component, iron hydroxide particles mechanically immobilized with chlorine fibers (RU, application No. 94028249, C02F 1/28, 1 / 62, published on 05/20/1996). Mechanical immobilization is carried out by injection into water of an organomineral suspension consisting of iron hydroxide powder (solid phase) and dimethylformamide (liquid phase) with perchlorovinyl dissolved in it. The sorbent consists of 75-83% of particles of iron hydroxide and 17-25% of the fibers. The granules formed from the dried sorbent are poured into a column filter. Water is purified by contacting it with a sorbent by filtration through this filter to obtain purified water that does not contain sorbent particles at the outlet. When cleaning water with an arsenic content of 0.3-2.5 mg / dm ^{3, the} capacity of the sorbent was 15.6 mg per 1 g of iron hydroxide, or 1.95% based on the weight of the sorbent. The authors suggest that arsenic is adsorbed on iron hydroxide particles due to the chemical affinity of these substances.

The disadvantage of this method is the low productivity of the filtration technology for water purification due to the low efficiency of the sorbent used in it.

The new positive results from the use of the proposed method are to increase the efficiency of the water purification process due to the use of a sorbent with a high capacity in it, simplifying the purification technology, increasing the degree of purification at different levels of water pollution, increasing the volumetric purification rate.

These goals are achieved by the fact that in the method of purifying water from arsenic, including the use of a composite sorbent containing iron hydroxide particles immobilized with organic fibers as a sorbing component, contacting the wastewater with the sorbent to form insoluble arsenic compounds, separating the purified water from solid refined products, according to the invention, the particles of iron hydroxide are immobilized by cellulose fibers during their chemical deposition in an aqueous dispersion of these fibers, and aktirovanie effluent sorbent is carried out by mixing them to form a slurry containing arsenic solid cleaning products. Cellulose fibers contain, in wt.%: Not less than 94% of fibers with a length of not more than 1.23 mm and not less than 54% of fibers with a length of not more than 0.63 mm. The method uses a sorbent of the composition, in parts by weight, cellulose fibers - 100, iron hydroxide - 20-500, the water is purified at a concentration of sorbent in it of 40-300 mg / dm ³ , and the separation of purified water from solid cleaning products is carried out by the method pressure flotation with the formation of flotation sludge. Fleet sludge taken from the flotator can be sent to the water treatment process. The sludge removed from the process is disposed of.

A variant is possible in which the sludge is concentrated on a filter press or centrifuged to a sorbent concentration of 4-6% and sent to containers for production in need thereof. But, since the technology for producing a sorbent is simple, and its productivity is determined by the rate of runoff formation and the flotator productivity corresponding to this speed, it is advisable to have a plant for producing a sorbent as part of a water treatment plant. In this case, the method is implemented as follows. A dispersion of cellulose fibers is prepared with a concentration of, for example, 1% based on the weight of dry fibers. The fibers contain, in parts by weight, at least 94% of the fibers with a length of not more than 1.23 mm and at least 54% of the fibers with a length of not more than 0.63 mm. On the installation, consisting of a mixer, reactor, saturator and flotator, using these fibers and methods of reagent chemical deposition and pressure flotation, a dispersion of a composite sorbent with specified characteristics is obtained in the form of a slurry. The sorbent consists of fibers with tightly immobilized by the forces of tension on them nanoscale particles of iron hydroxide. The set characteristic of the sorbent - the mass ratio between cellulose fibers and iron hydroxide - is determined by the content of arsenic in the water to be purified. The optimal value of this ratio for each particular case is advisable to determine in laboratory tests when treating water with different arsenic contents.

The flotation sludge is sent to the sorbent storage tank or directly in the process of water purification.

Water purification is carried out using an installation consisting of a mixer, a saturator, a flotator and a filter press (or centrifuge). Arsenic-containing wastewater and a predetermined amount of sorbent dispersion are supplied to the mixer at any given volumetric rate (for example, with a rate of runoff formation). Water purification from arsenic compounds proceeds according to the mechanism of transformation of one iron compound - hydroxide, into another compound - into iron arsenate (or arsenite), which has less solubility. For example, the solubility product of iron and hydroxyl ions is several orders of magnitude greater than the solubility product of iron and arsenic anhydride ions. Therefore, in an aqueous medium, iron hydroxide is converted to iron arsenate (or arsenite).

Sorbent is a material with a very high dispersion of particles. Iron hydroxide nanoparticles adsorbed on cellulose fibers have a huge specific surface and have high chemical activity. Therefore, the conversion rate of iron hydroxide to iron arsenate is very high.

In the cleaning process, another property of the composite fibrous sorbent is manifested for flotation technology. In water without mixing, the fibers form well-floated flocculi and flakes in 10-15 seconds. When mixed, they are easily destroyed with the formation of a uniform suspension, but without mixing, the fibers again quickly form floccules and flakes.

The suspension from the mixer is sent to the saturator, it is saturated with air and fed into the water distributor in the flotator chamber. Pressure is released to normal, and air bubbles are released from the water. Individual fibers, and especially flocculi and flakes, hold them well, and all suspended solids are completely floated to the surface of the water in the flotator chamber and form a layer of sludge. The clarified water that does not contain arsenic and sorbent particles is removed from the flotator and discharged into the sewer. The flotation sludge is fed to a filter press or centrifuged, dehydrated and sent for disposal.

The following examples illustrate the possibility of the proposed method.

Example 1. Water with arsenic content in the form of arsenate 3 mg / dm ³ and a suspension of the sorbent with a ratio of iron (III) hydroxide: cellulose fiber (GF: CV) in it, equal, in parts by weight, 20: 100 and flow rate 40 mg per 1 dm ^{3 of} water is fed to a flow mixer, then to a saturator, then to a flotator and using the known method of pressure flotation, solid water purification products are separated in the form of sludge from purified water. The cleaning product is cellulose fibers with particles of FeAsO ₄ firmly bound to them. 1 parts by weight iron in hydroxide binds 1.34 wt.h. arsenic. Accordingly, the theoretical capacity of 40 mg of the sorbent used in the example containing 6.66 mg of iron is 8.93 mg of arsenic. In the example, 3 mg of arsenic are adsorbed in the path of the sorbent from the point of supply to wastewater to the output from the flotator in the form of a flotation sludge. The utilization rate of iron hydroxide is 33.59%.

It is obvious that the efficiency of using iron hydroxide in wastewater treatment with a low arsenic content can be improved by using a well-known technique - returning part of the sludge to the process (into the mixer) with an equal decrease in the supply of fresh sorbent. In the steady state, when 30 mg of sludge is supplied (by r.v.) and 10 mg of fresh sorbent per 1 dm ^{3 of} water with an arsenic content of 3 mg / dm ^{3, the} coefficient of utilization of iron hydroxide increases to 62%.

According to reference data, FeAsO _{4 is} insoluble. Accordingly, the degree of water purification should be considered high.

Example 2. Purify water with an arsenic content of 100 mg / DM ³ . For cleaning use a sorbent with a ratio of GF: CV = 200: 100 at a flow rate of 150 mg / DM ³ water. The theoretical capacity of such an amount of sorbent is 134 mg of arsenic. Accordingly, with full purification, the utilization rate of iron hydroxide is 74.6%. The sludge is completely removed from the treatment system and sent for disposal.

Example 3. Purification is subject to water with an arsenic content of 600 mg / dm ³ . This water is diluted to an arsenic content of 230 mg / dm ³ . For the purification of diluted water, a sorbent is used with a ratio of GF: CV = 500: 100 at a flow rate of 300 mg / dm ^{3 of} water and a theoretical capacity of 335 mg of arsenic. When fully cleaned, the utilization ratio of iron hydroxide is 68.65%. Flotoshlamy sent for recycling. Purified water is used to dilute the original waste water.

Claims (5)

1. The method of purification of water from arsenic, including the use of a composite sorbent containing iron hydroxide particles immobilized by organic fibers as the sorbing component, contacting water with a sorbent to form insoluble arsenic compounds, separating purified water from solid cleaning products, characterized in that in the sorbent particles of iron hydroxide are immobilized by cellulose fibers during their chemical deposition in an aqueous dispersion of these fibers, and the contact of waste water with sorben the volume is carried out by mixing them with the formation of a suspension of arsenic-containing solid cleaning products, while cellulose fibers contain, in wt.%, at least 94% of the fibers with a length of not more than 1.23 mm and not less than 54% of the fibers with a length of not more than 0.63 mm 2. The method according to claim 1, characterized in that they use a sorbent composition, in parts by weight, cellulose fibers - 100, iron hydroxide - 20-500. 3. The method according to claim 1, characterized in that the water purification is carried out at a concentration of sorbent in it of 40-300 mg / DM ³ . 4. The method according to claim 1, characterized in that the separation of purified water from solid cleaning products is carried out by pressure flotation. 5. The method according to claim 4, characterized in that the sludge or part thereof is sent to the water treatment process.