UA47470C2 - Method of purification and softening of water - Google Patents

Abstract

Invention relates to the water used in cogeneration plants, in food industry, alcoholic beverage industry, brewing trade, pharmaceutical and other industrial branches for concentrating of elements, isolation of radionuclids from water, etc. The method of purification and softening of water from Ca, Mg, Fe, Cu, Si and other non-organic admixtures (Sr, Ba, Cr, Ni, Co, Mn, Zn, Cd, etc.) is carried out by reaction of water with gels of hydroxides of multivalent metals and regeneration of precipitators, Precipitators used in the form of gels quantitatively precipitate above mentioned admixtures low-soluble in the water are environmentally appropriate and in inoffensive for people.

Description

Description of the invention

The invention relates to water used in steam generators, in food, liquor, 2 brewing, pharmaceutical and other industries; for concentrating elements, purifying water from radionuclides, etc. In these industries, high requirements are placed on water to contain inorganic impurities (Ca, Ma, Re, Si, z, A, Ca, St, 7p, C, etc.).

Most of the years in Ukraine; as well as the rivers of the European part of Russia (including the Volga, Dnipro, Dniester), according to the nature of the salts dissolved in them, they belong to hydrocarbonate, with a total salt content of 300 - 7OOmg/l.

Therefore, the treatment of mineralized waters becomes a problem of global importance.

One of the main factors determining the suitability of water for various purposes is its chemical composition.

Chemical composition of waters of some years of the CIS (mg/l) | see Kulsky L.A., Goronovsky I.T., Koganovsky A.M,.,

M.A. Shevchenko Handbook on the properties, methods of analysis and purification of water. Kyiv, Scientific Thought. 1980. 1206 p. with 0 you screen the nose of the ox (the power of the fence 011 2

In Dniester water, which is used for the needs of the population and industry of the Odesa region, the content of impurities varies widely depending on the time of year: water hardness (Ca 2 Ma?) - 4.3 - Umg-eq/l, including Ca ? - 21 - 114mg/l, Ma?" - 5 - 5Omg/l; bicarbonates - 159 - Zobmg/l; iron - 0.1 - about 4.Bmg/l; copper - "0.2Zmg/l; zinc - " 0.007mg/l; Z" - 1.8 - Bmg/l; molybdenum - 0.03 - 0.04bmg/l; (Kya - Ma") - 12 - 112mg/l; arsenic "x 0.008 mg/l; dry residue - 257 - 865mg/l; the sum of nitrates and nitrites - 0.5 4mg/l; chlorine - 27 - 129mg/l; sulfates - 52 - 196 mg/l; fluorine - "x 0.0 Zbmg/l; alkalinity - 2 - 5 mg-eq./l. The concentration of hydrogen ions Ha") (pH) in water usually ranges from 7 to 8.5.

According to literary data | see Kulsky L.A. Basic chemistry and technology of drivers Kyiv: Naukova Dumka. 1991, volume 568 p.; Chemistry of the environment". Edited by J.O.M. Bokris. M.. Chemistry. 1982. 671 p.), alkaline earth "I elements (Ca, Ma, as well as 5g, Ba) and iron are present in water in the form of bicarbonate acid complexes of the exemplary composition of Me (HSO)", where Me is a metal. in

The closest and known to the applicants is the method of water purification, which is applied at the thermal power plant and is a generally accepted technology in this "I industry, see Feiziev G.K. A highly effective method of water softening, desalination and desalination. M.: Znergoatomichdat 1988, 193 p.|.

The technology of water purification at the Odesa CHP-1 from hardness and other impurities (Ca, Ma, Re, Sy, 81, etc.) "is in the following stages: 1. Calcification of CaS water to pH x" 10 - 10.5 for precipitation of Ca in the form of CaSoO with and Ma - in the form of Ma (OH)" (The total retention of Ca and Ma in water for 8 s is 2 - 2.5 mg-eq/l after this stage). and 2. Purification of water from silicon compounds with magnesium hydroxide. "» Z. Deep purification of water from impurities - cations is achieved by their sorption on activated carbon sulfonate and the main cationite KU - 2 - 8.

Purification of water from inorganic impurities to the following limits is achieved by this technology: hardness « и O,OZmg-eq./l, Re « 0. mg/l, Sy « 0.005mg/l, 5iO» « 0.26m g/l. -1 This tool is selected as a prototype. What the prototype and the invention have in common is the preliminary treatment of water with alkalizing reagents. However, the method according to the prototype has the following shortcomings: i- high consumption of calcium and magnesium oxides: at the first stage of the process 50 - bOg/l of calcium oxide, at stage -I 20 of water purification from silicon - 12 - 20g/m3 - magnesium oxide: application expensive and scarce ion exchangers that contaminate water with organic substances; me, large production areas necessary for the implementation of this technology, etc.

The purpose of the proposed invention is to replace the cation exchange technology of water purification from hardness and other inorganic impurities with a simpler and cheaper technology. This goal is achieved by using gels of 22 hydroxides of multivalent metals: Be(I), (HO, Zp(M), T(IM), Mpy(IM), rare earth elements - a, U,

F! Se(M) and others.

It is known from the literature that aluminum and iron hydroxides are widely used in water technology as coagulants to purify it from dispersed impurities | see L.A. Kulsky The basis! chemicals and technologies of drivers. Kyiv: Scientific opinion. 1991 568 p.; Shutko A.P., Sorochenko V.F., Kozlykovsky Ya.B., Grechko V.Y. Purification of 60 water with basic aluminum chlorides. K.: Technique. 1984 137 p.; Yu.V. Kuznetsov, V.N. Shchebegkovsky, A.G. Trusov,

The basis for cleaning radioactive contaminated waters. M.: Atomizdat. 1974. 360 p.). The use of these substances for its quantitative purification from calcium and magnesium has not been identified by us in the patent and scientific literature, see L.A. Kulsky, I.T. Goronovsky, A.M. Koianovsky, M.A. Shevchenko. Handbook on the properties, methods of analysis and purification of water. K: Scientific opinion. 1980. 1206 p.; L.A. Kulsky Basic chemistry and water technology, Kyiv: bo Naukova dumka. 1991. 568 p.; Honcharuk V.V., Yakimovat.I. Use of unconditioned groundwater in drinking water supply. Water chemistry and technology. 7.18. B.5. 1996. 495 - 532 pp.|.

Our studies on the extraction of germanium from aqueous solutions and over-resin waters of coke chemistry with hydroxides of iron (II), zirconium, aluminum, REE, etc. it was established that the degree of its precipitation depends mainly on the pH of the solutions. This is explained by the fact that in weakly acidic and neutral environments (pH C - 7), the above metal hydroxides are positively charged and act as cation exchangers. As the pH of the medium at the isoelectric point increases, metal hydroxides change their charge sign to negative and become anion exchangers. | see Magunov R.L., Stasenko I.V., Voevudskaya S.V. et al., A method of extracting germanium from over-resin waters. A, c,

USSR. Mo731823. 1976; Zagorodnyuk A.V., Magunov R.L., Bondar N.M., Stasenko I.V. Investigation of iron germanates obtained from aqueous solutions. Journal of inorganic chemistry. 1.21. V.1, 1976. 24 - 28 pp.)

On the basis of research on the precipitation of calcium and magnesium from pure water, we have established that metal hydroxides in anionic form, obtained by precipitation with alkalis (mainly caustic sodium), and which are charged with OH 7 ions at рНаВ.5 - 10.5, quantitatively precipitate these elements, apparently , with the formation of chemical hydroxo compounds of calcium and magnesium. Quantitative precipitation of calcium and magnesium from water by metal hydroxides is mixed with bi- and carbonate ions. For their decomposition, we used the well-known method of liming water with calcium oxide (soda, caustic soda).

The method is implemented as follows.

A suspension of calcium oxide (in the case of Dniester water, 0.06 - 0.1 g/l) is added to a polyethylene 5-liter container with tap water with constant stirring to remove temporary hardness. After 2 hours of mixing and 1-3 hours of settling, the water is separated from the sediment and transferred to quantitative purification from impurities.

In O, Bl glasses, dissolve in demineralized water a suspension of hydrogen chloride salt of a multi-charged metal or pour the necessary amount of hydrochloric acid solution of the above metals, dilute with water to 100 - 200 ml with stirring. Then they are precipitated and charged with hydroxyl anions, using strong caustic soda solutions (01H and Mahon's IN solutions), gels of multivalent metals at pHV.5 - 10.5. Planter gels are transferred to a 2-liter container, where water is poured after liming. The process is carried out with constant i) stirring during 1 - Zg. Next, the solution is settled or filtered from sediment and suspension. The water obtained after that is the target product.

Merits and novelty claimed in the invention: o z o 1 Preliminary water alkalinization is done in a slightly alkaline environment (pNa.5 - 10.5), which leads to a significant reduction in the consumption of lime (alkaline reagent), and the refusal to use magnesium oxide for cleaning - from silicon "Mr

Retention of impurities in water purified from hardness and other impurities by hydrogels of multivalent metals « example) Cation gelate « cho - - y» 5lasyuzooz obov oo oo 1» 75 2. Instead of cation exchangers, environmentally friendly compounds are used - iron, zirconium, tin and others that are practically insoluble in the pH ranges specified in the method, they are not toxic substances. -and 3. The losses of the depositors after 5-10 times of use are 5 1095, most of which can be returned to production. 4. This method together makes it possible to make almost any natural water potable. -| 50 Example Мо1 o Dniester water with a hardness of 5.1mg-eq/l and pH7.9 at room temperature was processed at the rate of 0.07g/l of calcium oxide. After settling and filtering for 2 hours, water with a hardness of 2.4 mg-eq/l and a pH of 10.3 was obtained. 4.5 g of BeSiz 0 NoO was dissolved in 120 ml of demineralized water and a 59 gel of iron oxide hydrate was precipitated with a caustic solution of nasra (0.1N and 1N) at a pH of 10.4. The precipitate was filtered and added to 1 liter of water. After 2 hours

HF) stirring sediment was filtered and regenerated with a solution of HC (0.1N) at pH 3.5, and the water was analyzed for impurity 7 (see table).

Examples MomMoe2 - 5 in Illustrate the purification of water by various planters. The cleaning results are shown in the table.

Claims (2)

The formula of the invention 1. A method of cleaning and softening water from hardness salts (Ca, Ma, 5g) and impurities (Re, A1, Si, 2p, Ca, Mi, bo So, Mp, RB, Na and other metals and silicon), which includes pre-treatment of water with alkalizing reagents, which differs in that the process is carried out in three stages, in the first of which the water is alkalinized with calcium oxide or soda ash or caustic soda to pH 8.5-10.5, after separation from the sediment, the water treated in this way is quantitatively purified in the second stage from hardness salts and inorganic impurities by treating it with hydroxides of polyvalent metals (Re), 27, TIM), Zp(M), REE, AI, etc.) or their mixtures, saturated with hydroxyl ions OH", and after separating the sediment from purified water in the third stage, the regeneration of hydroxides of multivalent metals or their mixtures is carried out by treating sediments with hydrochloric acid solutions at pH 2.0-5.0, separating sediments from the liquid phase, washing them, and then treating hydroxides of multivalent metals or their mixtures with solutions of caustic soda or soda ash 70 at pH 8.5-10.5. 2. The method according to claim 1, which differs in that water purification and softening from hardness salts and impurities is carried out by hydroxides of multivalent metals or their mixtures, which are pretreated with solutions of caustic soda or soda ash at pH 8.5-10.5. Official bulletin "Industrial Property". Book 1 "Inventions, useful models, topographies of integrated microcircuits", 2002, M 7, 15.07.2002. State Department of Intellectual Property of the Ministry of Education and Science of Ukraine. c schi 6) «c) cha « cha « - with . and? sh» -I sh» - 50 (42) ime) 60 b5