RU2090517C1 - Method of cleaning natural water - Google Patents

Abstract

FIELD: water treatment. SUBSTANCE: invention relates to treating natural water for household-drinking purposes and can be used in water-supply systems of towns, inhabited localities, and various industrial enterprises. Method includes oxidative-disinfecting treatment, coagulation, clarification, and filtration. Oxidative-disinfecting treatment is carried out using anolyte produced in anode chamber of vertical electrolyzer with coaxial cylindrical insoluble electrodes and ceramic diaphragm when treating sodium chloride aqueous solution in concentration 1-3 g/l to achieve pH 5-7 and redox potential from +10 to +800 mV against Ag/AgCl reference electrode, volume of introduced solution constituting 0.01- 1.0% of volume of water being treated. Coagulation process may be performed using flocculants. If necessary (when treating strongly polluted water), after filtration, treated solution with the same characteristics and in the same amount is added. Initial sodium chloride solution is prepared using cleaned water, which is also introduced into cathode chamber of diaphragm electrolyzer and catholyte is used in coagulation stage. EFFECT: enhanced efficiency of process. 4 cl, 2 dwg

Description

 The invention relates to the field of natural water treatment for domestic and drinking purposes and can be used in water supply systems of cities, towns and enterprises of various industries.

 There is a known scheme for the preparation of drinking water taken from open water bodies, which provides for its bleaching, clarification and disinfection. Moreover, the technological scheme contains sequentially installed pumping station of the first lift, mixers, reagent workshop, flocculation chambers, sedimentation tank, quick filters, chlorine filter, clean water tanks.

 To eliminate persistent unpleasant tastes and odors, to destroy plankton and other impurities, double water chlorination is introduced into the treatment scheme: primary chlorination at the pumping station of the first rise and secondary chlorination behind the sump or filters. The method provides a good disinfection of water, reduces the content of ammonia and organic substances due to the oxidation of chlorine.

 The disadvantage of this method is the use of reagents, which complicates the technological scheme, requires strict adherence to safety rules when working with toxic chlorine.

 It is known that these disadvantages can be solved by using solutions containing active chlorine for disinfection and obtained directly on the spot by electrolysis of a chloride solution to obtain a disinfectant hypochlorite solution.

 However, the use of chlorine and hypochlorite solutions leads to the formation of trihalomethanes in water as a result of oxidation by active chlorine of humic and fulvic acids with carcinogenic properties. In addition, to achieve the required degree of purification, an excess of chlorine-containing reagents is used, which leads to a deterioration in the consumer properties of the obtained drinking water and requires additional operations for its dechlorination.

 It is known to use various oxidizing agents for water purification, such as, for example, chloramine, 1,3-dichloro-5,5-dimethylhydantoin, in order to increase the degree of disinfection and stabilize the residual chlorine in water. However, the above method is characterized by all the disadvantages of reagent cleaning methods, and in addition, the use of specific reagents leads to an increase in the cost of the cleaning process.

 Of non-chlorine-containing reagents, ozone is widely used as an oxidizing disinfecting agent. At the same time, organochlorine substances are not formed during the cleaning process, however, the desired prolonged bactericidal effect is not provided.

 The closest in technical essence and the achieved result is a method that includes oxidation-disinfection treatment, coagulation, clarification, filtering and disinfection. Oxidative-disinfecting treatment is carried out by natural biocenosis, microfiltration with a speed of 0.2-0.6 m / s and ozonation.

 The known method allows to achieve a high degree of purification and is selected as a prototype.

 The disadvantage of this method is its complexity, multi-stage, as well as the fact that the treated water requires the final stage of disinfection, i.e., treatment with chlorine, which affects the characteristics of the treated water. In addition, the known method requires a large consumption of coagulant.

 The aim of the invention is to simplify the method, reducing the consumption of coagulant and improving the quality of the treated water.

 This goal is achieved by the fact that in the method of purification of natural waters, including oxidation-disinfection treatment, coagulation, clarification and filtering, oxidation-disinfection treatment is carried out using a solution of sodium chloride with a concentration of 1-3 g / l, pre-treated in the anode chamber of a vertical electrolyzer with coaxial cylindrical insoluble electrodes and ceramic diaphragm until a pH of 5-7 is reached and the value of the redox potential is plus 600-800 mV relative to chl rserebryanogo reference electrode, and the volume of the solution administered is from 1/1000 to 1/100 of the volume of treated water (about 0.01-1.0%).

 If necessary (when treating heavily polluted or waste water), after filtration, a treated solution with the same characteristics and in the same amount is additionally introduced.

 The initial solution of sodium chloride is prepared on purified water, it is fed into the cathode and anode chambers of the diaphragm electrolyzer, and the catholyte is used at the coagulation stage to adjust the pH.

 During the electrochemical treatment of low-mineralized (up to 5 g / L) solutions in the electrode chambers of the diaphragm electrolyzer, the formation of chlorine dioxide and unstable superactive compounds are observed, which provide high efficiency of such solutions with a seemingly low content of detected active components, for example, active chlorine. So, solutions with a salinity of up to 5 g / l, processed at an electricity consumption of 300 to 1500 C / l and a current density of 30 to 1000 A / m (2) or more, are used as detergents and sterilizing solutions in medicine, although the content active chlorine in them is very low 250-350 mg / l.

 The authors found that the introduction of a low-saline solution of sodium chloride processed in the anode chamber into the treated water during the water treatment process allows to achieve the required degree of disinfection with significantly lower amounts of active chlorine in the solutions, and in addition, the introduction of such solutions changes the flocculation conditions in the treated water when the coagulant is introduced, which reduces the consumption of coagulant by approximately 40% compared with the calculated.

 As noted above, it is known to use sodium chloride solutions for preparing an active chlorine solution by electrochemical treatment. However, in the known solutions, more saturated chloride solutions (up to 50 g / l) are used and the process is conducted in diaphragmless electrolyzers, because To obtain hypochlorite, it is essential to ensure mixing in the interelectrode space of the products of electrode reactions. It also indicates the possibility of using sea water for wastewater treatment plants. The process is fully automated, monitoring the operation of the installation is carried out using electronic equipment. Wastewater treatment plants with electrolysis plants are very compact.

 When using electrolyzers in sea water for sanitary and hygienic reasons, it is necessary to use hypochlorite solutions with a higher content of active chlorine (up to 3-3.5 g / l). In addition, in order to prevent the formation of cathodic deposits of hardness salts, electrolyte is supplied with increased speeds. In these cases, technological schemes with recirculation of the solution are used. Sea or underground mineralized water is sequentially fed into the electrolyzer of a recirculation tank and a storage tank of sodium hypochlorite. Only a part of the finished product flows by gravity into the storage tank, while the bulk of the solution is fed back to the beginning of the process using a recirculation pump. The mutual ratio of flows is determined depending on the required concentration of active chlorine, and the speed of movement of the electrolyte through the installation is selected for structural reasons.

At the installation, in one pass through the electrolyzer, depending on the voltage and current load, a solution of sodium hypochlorite with a concentration of active chlorine of 0.2-0.6 g / l is obtained. During recirculation, the concentration of active chlorine in the solution can be brought up to 5 g / l. The recirculation flow rate is 2-2.3 m ³ .

 It is obvious that the use of plants for the production of sodium hypochlorite from seawater is limited to areas located in the coastal strip. Mineralized underground water can be used as a source electrolyte only in those cases when there are multi-purpose drilled wells near the treatment plant (for example, for use in balneological purposes, the chemical industry, etc.). In addition, the solutions obtained during the electrolysis of sea water are more saturated with active chlorine than the solutions used in the present invention.

 In the proposed solution, the solution is subjected to a solution with a chloride concentration of 1-3 g / l, and the treatment is carried out in the anode chamber of the diaphragm electrolyzer using insoluble electrodes and a ceramic diaphragm. When processing less concentrated solutions (less than 1 g / l), the required degree of change in the properties of the solution is not provided and the energy costs significantly increase, at concentrations above 3 g / l the content of active chlorine in the form of hypochlorite ion increases, which requires the dechlorination stage to be introduced into the water treatment process and initiates the formation of trihalogenomethanes.

 Processing is carried out until a pH of 5-7 is reached and the values of the redox potential are plus 600 plus 800 mV relative to the silver chloride reference electrode. With a further decrease in pH and an increase in the redox potential, the energy consumption increases and the disinfecting ability of solutions decreases, while decreasing the potential value, the disinfecting ability of the solution also sharply decreases.

 In the practice of water purification, the influence of pre-treatment of a coagulant solution by electro-hydraulic action with an energy consumption of 0.6-0.8 kJ per gram of coagulant is known, which reduces the coagulant consumption by 40%. However, the known method requires the use of complex equipment, as well as a significant energy consumption .

 The amount of injected solution is determined by the degree of contamination of the water, the requirements for its purification and are in the range of 0.01-1.0% vol. from the amount of water treated.

In applied electrochemistry, various designs of diaphragm electrolyzers are used to process solutions of both periodic and continuous action with different shapes of electrodes. For the proposed solution, it is advisable to use vertical flow electrolyzers with coaxial cylindrical insoluble electrodes and a ceramic diaphragm, which ensures efficient processing with sufficient productivity. In addition, coaxial electrodes provide a non-uniform field of water treatment, which increases the efficiency of the resulting solutions. For electrodes and diaphragms, it is preferable to use the following materials:
Titanium anode coated with ruthenium oxide, iridium, platinum;
Titanium cathode (polished or coated with pyrocarbon);
Diaphragm ultrafiltration electrocatalytic ceramics based on zirconium, yttrium, aluminum oxides;
Schematic diagram of the process of preparing drinking water is presented in figure 1.

 The main part of the scheme is the installation for obtaining anolyte solution. Salted water is supplied to the unit module from the mixer, into which water passes through all stages of purification, and a solution of sodium chloride from the block for the preparation of saline solution with a concentration of 100,300 g / l. The mixer provides salting of pure water in the concentration range of 1.0 to 3.0 g / l.

 From the installation, the anolyte is sent to the tank, from where it is fed into the purified water in front of the mixer of the main water treatment plants, before the coagulant is introduced, and by another dosing pump into the purified drinking water before it is introduced into the clean water tank, i.e. after water purification in illuminators and filters. As dispensing pumps, dispenser pumps of the ND series, or water-jet pumps fed from a clean water pressure line can be used.

 Catholyte with pH 12 can be used for preliminary alkalization of water (before the introduction of the coagulant), for the preparation of milk of lime, as well as solutions of coagulants.

 Given that the active chlorine of the anolyte has a biocidal activity that significantly exceeds the similar parameters of traditional chemical biocidal agents, including molecular chlorine dissolved in water, the dose of active chlorine under the conditions of using a neutral anolyte should be set within 2.0 2.5 mg / l, however, it is possible to reduce this dose for different regions.

If drinking water is in the tank and water conduits for a considerable time (> 1.5 h), then, in order to ensure a longer action of chlorine in the water, ammonia is also introduced. With the introduction of ammonia, the consumption of chlorine is reduced and in some cases the taste of water improves. As a result of the reaction of hypochlorous acid (formed under the influence of chlorination of water) with ammonia, monochloramines are obtained, which, when hydrolyzed, form a strong oxidizing agent - hypochlorite ion. The hydrolysis of chloramines proceeds rather slowly, in connection with which the oxidative effect of chloramines is lower at first than chlorine, however, the duration of the bactericidal action of chloramines is much longer. The ratio of doses of chlorine and ammonia depends on the quality of the source water. Usually the optimal dose of ammonia, providing the formation of monochloramides, is 5-6 times less than the dose of chloride
The same ratio of active chlorine and ammonia is maintained in the case of anolyte.

 The complexity of the composition of water pollution and its variability over a wide range in different water sources makes it difficult to theoretically justify the selection of coagulants for water treatment, so today's coagulation practice is based mainly on empirical research. The most widely used salts are Al and Fe.

 By calculation it is not possible to determine how many aluminum or iron salts must be introduced into the treated water to ensure the optimal regime of the coagulation process, given the variety of various factors that have an effect on this process to one degree or another. In addition, the main of these factors does not maintain the quality of the treated water, especially in surface waters, which are characterized by sharp changes in composition during periods of heavy rains or spring floods. In addition, the values of the total salinity, characteristics of the composition of water, temperature, etc., influence this process.

 For most natural surface waters in Russia, the dose of aluminum sulfate ranges from 0.5 to 1.2 mg equiv / L, and iron sulfate 0.1 to 0.5 mg equiv / L.

 Under the conditions of application of anolyte, these doses can be approximately reduced to 0.25 0.8 mEq / L and 0.05 0.2 mEq / L, respectively, as follows from the data shown in figure 2.

 The formation of large flakes is markedly accelerated by the use of high molecular weight substances called flocculants.

 When treating natural waters, high molecular weight flocculants are usually used in conjunction with coagulants. More often, polyacrylamide (PAA) is used as a flocculant. PAA is used in the form of a dilute solution of 0.1 - 0.2% concentration. The dosage of the flocculant is usually in the range of 0.5-1.5 mg per 100 mg of suspended solids in the water. The use of anolyte as a primary chlorination agent, according to experimental studies, can reduce the dosage of PAA by 30–50% of the traditionally accepted values.

 It is considered that when PAA is added to the water to be purified, complex aggregates are formed, for example, of the type “particle - macroion-multiply charged macroion-particle ion”.

 A weighty argument in favor of the “bridge” flocculation mechanism is the observation that the maximum flocculation of an AgI sol with polyvinyl alcohol additives and Au and AgI sols with polyethylene oxide additives occurs if the calloid solution with polymer-coated particles is equal in volume to the initial sol. In other words, stability is minimal for an equal number of polymer-containing and "bare" particles.

 When using a neutral anolyte, another mechanism of stability violation is possible, a decrease in the particle potential (similar to neutralization coagulation by multiply charged counterions).

 The invention is illustrated by the following examples, which do not exhaust all possible embodiments of the invention. In the examples, the cell according to PCT WO 93/20014 was used as an electrochemical cell.

 Example 1

 A solution of chloride with a concentration of 2 g / l was prepared on purified water and fed with a volumetric flow rate of 25 l / h into the anode chamber of a diaphragm electrochemical cell with a diaphragm based on aluminum, yttrium, zirconium oxides. The anode material is titanium coated with ruthenium oxide, the cathode is polished titanium. Purified water was supplied to the cathode chamber. The ratio of volumes supplied to the anode and cathode chambers was 50: 1.

The obtained anolyte having a pH of 6.1 and a redox potential of + 730 mV is mixed with river water containing suspended solids, dissolved contaminants, organic contaminants, phyto and zooplankton contamination of the source water:
color, hail. 60
turbidity, mg / l 130
total organic carbon, mg / l 9.84
iron, total, mg / l 0.61
ammonia, mg / l 1.54
SAS, mg / l 0.18
microbial number pcs / ml 1160000
The amount of anolyte introduced was 1.0 vol. from the amount of water treated.

 Next, the water is treated with alumina with a dose of 2 3 mg and after stirring it is left to stand for 60 minutes.

The settled water is filtered through quartz sand at a speed of 5 6 m / h. At the outlet of the installation, water has the following indicators:
color, gr 4
turbidity, mg / l 0.8
total organic carbon, mg / l 0.35
iron, total, mg / l 0.09
ammonia, mg / l absent
SPAV traces
microbial number, pcs / l 3
Example 2

 Processing is carried out under conditions similar to example 1, but the amount of anolyte introduced is 0.5% vol. from the amount of water treated.

 After filtration through quartz sand, the resulting water is analyzed. Treated water has indicators higher than permissible in accordance with GOST according to the microbial number.

 An additional portion of anolyte is introduced into water in an amount of 0.1% vol. from the total amount and after 30 minutes of contact, the analysis is repeated. Treated water meets the requirements of GOST for drinking water.

 Using the data of the method allows to obtain potable water with minimal costs, and also allows to reduce the consumption of coagulant (aluminum sulfate) by 30 to 50% and flocculant consumption (PAA) by 20 35%.

 The use of anolyte as an oxidizing-disinfecting agent will eliminate the formation of toxic trihalomethanes that occur while improving organoleptic characteristics.

 In addition, this method will allow you to abandon the application and, accordingly, from storing significant reserves of liquid chlorine in the territory of a water treatment plant, which will increase the level of safety for people and nature.

Claims (4)

 1. The method of purification of natural waters, including the oxidation-disinfection treatment, coagulation, clarification and filtering, characterized in that the oxidation-disinfection treatment is carried out using anolyte obtained by electrolysis of a solution of sodium chloride with a concentration of 1-3 g / l in the anode chamber of a vertical electrolyzer with coaxial cylindrical insoluble electrodes and a ceramic diaphragm, the anolyte having a pH of 5 7 and a redox potential of 600,800 mV relative to chlorine erebryanogo reference electrode and the anolyte volume injected is 0.01 to 1.0% by volume of water to be purified.  2. The method according to claim 1, characterized in that after filtering the water is additionally treated with anolyte.  3. The method according to PP. 1 and 2, characterized in that during the coagulation process, flocculants are additionally introduced into the water.  4. The method according to claims 1 to 3, characterized in that the sodium chloride solution is prepared on purified water, the prepared sodium chloride solution is also fed into the cathode chamber of the diaphragm electrolyzer during electrolysis and the catholyte is used in the coagulation stage.

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