RU2047569C1 - Method for clarifying and disinfecting stock farm waste water - Google Patents

Abstract

FIELD: waste water processing. SUBSTANCE: method involves delivering waste water into anode chamber 6 of electric activator 7 with aluminium anode 10. Cathode chamber 9 is filled with alkali metal chloride water solution. Aluminium hydroxide playing the role of active coagulant arises in solving aluminium anode 10 in process of water electrolysis to enable waste water to be clarified without coagulant contributing to waste water contamination. Chlorine ions form additional oxidizer on their way from cathode chamber 9 to anode chamber 10 resulting in full disinfection of waste water. Treatment is carried out under 2.0-3.0 kWh/m 2,0-3,0 kWh/m³ power consumption and 5-10% chloride solution concentration. EFFECT: full disinfection and clarification of waste water. 2 cl, 1 dwg, 1 tbl

Description

 The invention relates to water treatment, in particular to disinfection and clarification of livestock effluents, and can be used on farms and other livestock complexes where a water wash is used to remove manure, resulting in large volumes of contaminated liquid effluents that require large areas for storage .

 There is a known method of disinfecting and clarifying livestock stocks, according to which coarse particles (straw, wood chips, etc.) are removed from livestock stocks on a vibrating screen and the remaining liquid fraction is treated with an electric current in an electric activator containing two working chambers, at the bottom of which steel electrodes are installed. Disinfection of effluents from pathogenic microorganisms is achieved by oxidizing their biologically active substances with oxygen and ozone, which are formed on the anode as a result of electrolysis of water, and clarification of disinfected effluents, i.e. their purification from particles of organic nature is carried out by their flotation with hydrogen, which is released at the cathode.

 The disadvantage of this method is the low quality of clarification of effluents, since it is carried out only due to flotation, the effectiveness of which depends on the composition of the effluents entering the electroactivator. The dissolution of the steel anode does not provide effective coagulation of organic particles due to the fact that iron is a good coagulant only in an alkaline environment, and livestock runoff is either neutral or acidic. In an acidic or neutral environment, iron does not form large flakes, but only a finely divided suspension.

 In addition, due to the presence of surfactants in livestock effluents, the flotation process is accompanied by strong foaming, which requires the use of additional protective measures against splashes of foam and creates certain inconveniences for staff.

There is also a known method of disinfecting and clarifying livestock waste water, in which the mechanical treatment of waste from coarse inclusions is carried out in a separator equipped with a mesh with holes with a diameter of 0.1-0.5 mm, and for the electrochemical treatment of the obtained liquid fraction, an electroactivator having a semipermeable membrane separating the anode and cathode chambers of the electroactivator, the anode of which is made of graphite. After mechanical cleaning, the liquid fraction is fed into the cathode chamber of the electroactivator, where, in addition, a coagulant phosphoric acid is introduced at the rate of 2 l / m ^{3 of the} filtrate.

 In this method, the clarification of effluents occurs not only due to the flotation of suspended particles by hydrogen, but also due to coagulation, and therefore is more effective.

 From the cathode chamber, the clarified liquid is introduced into the anode chamber, where it is disinfected by oxidizing the biologically active substances of the microorganisms with oxygen and ozone, which are released on the anode during the decomposition of water.

The disadvantage of this method is the incomplete disinfection of effluents due to the insufficient amount of oxidizing agent released during electrolysis of water. According to the classification level of bacteriological contamination of reservoirs one measure of the degree of disinfection is the microbial count (number of colonies growing on meat-peptone agar in petri dishes after 48 hours of incubation ^at 20 ° C in 1 ml liquid). In this method, the microbial number in the treated effluent is 3000. Such liquids are considered infected and cannot be drained into nature.

 Another disadvantage of this method is the addition of phosphoric acid coagulant to the anode chamber of the electroactivator. It is practically impossible to select such a concentration of phosphoric acid so that all of it works as a coagulant, and therefore phosphoric acid is not completely consumed and some of it remains dissolved in the effluent, polluting them.

 In addition, the use of the flotation method of clarification of effluents is undesirable for the reasons described above.

 The invention is directed to the creation of a method for disinfecting and clarifying livestock effluents, which would provide the best oxidizing ability of the anolyte necessary for complete disinfection, and in which the clarification of drains would be carried out only by coagulation without introducing a coagulant into the electroactivator, which creates chemical contamination of the disinfected effluents.

 To do this, in the method of disinfecting and clarifying livestock wastes, including mechanical cleaning of coarse dispersed inclusions and subsequent electrochemical treatment in an electroactivator with a semipermeable membrane separating the anode and cathode chambers, according to the invention, an electroactivator with an aluminum anode is used, and the cathode chamber is filled with an aqueous solution of alkaline chloride metal.

 Due to the presence of an alkali metal chloride electroactivator in the cathode chamber, an additional oxidizing agent forms oxygen chlorine compounds in its anode chamber. These compounds, along with oxygen and ozone released at the anode, oxidize biologically active substances present in the effluent of microorganisms, enhancing the biocidal ability of the anolyte. As a result of this, with the appropriate concentration of alkali metal chloride, complete disinfection of livestock wastes can be achieved without increasing energy costs for electrochemical treatment.

 The use of an electroactivator with an aluminum anode makes it possible to efficiently clarify drains only through coagulation. This is due to the fact that, during electrolysis, aluminum hydroxide is formed, which is a good coagulant in media with pH 4.5–8, and livestock runoff in the anode chamber of the electroactivator has a pH of 4.6–5. The effectiveness of coagulation is also due to more intense dissolution of the aluminum anode under the action of chlorine ions. Therefore, in the proposed method, there is no need to use the flotation method of clarification, nor to introduce an “external” coagulant. Aluminum hydroxide itself does not create chemical contamination of clarified and disinfected effluents, since when reagentless coagulation, which is used in the proposed method, all coagulant precipitates.

 The drawing shows a diagram of an installation for implementing the proposed method.

 The proposed method is as follows. After water washing, livestock wastewater is fed to a wastewater storage unit 1, from where it enters the filtration device 2, equipped with a coarse-mesh steel mesh with a mesh diameter of 1 mm, a liquid tray and a stirrer. In device 2, the separation of effluents from stones, straw, sticks. Next, the effluents are fed to a centrifuge 3, where they are further separated into a solid fraction and a finely divided liquid fraction with an inclusion diameter of not more than 0.1 mm. The solid fraction is composted, and the liquid is collected in a centrifugal collector 4, from which further with the help of a metering pump 5 it is uniformly fed into the anode chamber 6 of the electroactivator 7. The presence of particles with a diameter of more than 0.1 mm in the liquid fraction is unacceptable due to possible clogging of the electroactivator and increase the electrical resistance of the processed fluid, which can lead to the failure of the electroactivator.

 The electroactivator 7 has a semi-permeable membrane 8, separating its anode 6 and cathode 9 of the chamber. The anode 10 of the electroactivator is made of aluminum, and the cathode 11, for example, of steel or any other electrically conductive material.

 At the same time, an alkali metal chloride solution, for example sodium chloride, is supplied to the cathode chamber 9 by means of a pump 12 from the reservoir 13. When the chambers 6 and 9 are filled with drains and sodium chloride solution, respectively, voltage is supplied to the electrodes 10 and 11 from the power supply 14.

As a result of water electrolysis, oxygen and ozone are released at the anode 10 of the electroactivator. Chlorine ions from the cathode chamber 9 pass through a semipermeable membrane 8 into the anode chamber 6 due to the difference in the concentration of these ions on both sides of the membrane 8. At the anode 10, chlorine gas is released, which partially dissolves in water with the formation of oxygen compounds of chlorine. These compounds are an additional oxidizing agent and, together with oxygen and ozone, are involved in the oxidation of biologically active substances of microorganisms in livestock runoff, ensuring their disinfection. The concentration of sodium chloride in the solution supplied to the cathode chamber 9 is determined experimentally from the condition of achieving complete disinfection of wastewater at given specific energy consumption for electrochemical treatment. So, for example, with a specific energy consumption of 2-3 kWh / m ^{3, the} concentration of sodium chloride in the solution is 5-10%
The introduction of an alkali metal chloride precisely into the cathode chamber 9 (and not directly into the anode chamber with filling the cathode chamber with water) reduces the electrical resistance of catholyte and, accordingly, allows the process to be carried out with lower energy consumption. As is known, the value of the electrical conductivity of aqueous solutions of alkali metal chlorides is directly proportional to their concentration in the solution. Therefore, if it is necessary to reduce the specific energy consumption for electrochemical treatment, alkali metal chloride solutions with high concentrations, up to the concentrations of saturated solutions, are used.

 An alkaline solution with a pH of more than 10, formed in the cathode chamber 9 of the electroactivator, is fed into a tank 13, into which a sodium chloride solution is periodically added, maintaining its required concentration.

 In the anode chamber 6, along with the disinfection of effluents, they are clarified. The aluminum anode 10, when dissolved, releases aluminum ions, which form aluminum hydroxide. The solubility of aluminum hydroxide depends on the pH of the medium in environments with pH in the range of 4.5-8 aluminum hydroxide is insoluble. Anolyte has a pH of 4.6-5, so that aluminum hydroxide acts as an effective coagulant, actively adsorbing organic impurities from effluents with the formation of large flakes. The solubility of the aluminum anode 10 is further enhanced by chlorine ions, which activate the aluminum anode. The activating effect of chlorine ions is associated with their small geometric dimensions and ease of penetration through the oxide film of the aluminum anode, as a result of which it is more effectively destroyed and the concentration of aluminum ions in the solution increases. The catalysis of the dissolution of the aluminum anode by chlorine ions is also explained by a strong slowdown in the formation of an oxide film as a result of adsorption displacement of oxygen.

 Disinfected and clarified effluents with large coagulant flakes located in them from the anode chamber 6 of the electroactivator enter the sump 15, where the effluents are quickly separated into a transparent supernatant and loose sediment formed from flakes. The precipitate can be fed to the fertilizer, and the supernatant can either be flushed to the farm or discharged to nature after neutralization, for example, with an alkaline solution from the cathode chamber 9 of the electroactivator or calcium carbonate.

 The technological parameters of processing the voltage on the electrodes of the electroactivator 7, the performance of the pumps 5 and 12, the concentration of sodium chloride are chosen so as to ensure complete disinfection of the effluents and their effective clarification.

 The clarification efficiency is visually controlled by the degree of transparency of the supernatant in the sump 15.

 The livestock wastewater disinfected according to the proposed method was subjected to bacteriological analysis: the microbial number, coli titer (the smallest volume of water in ml containing one cell of E. coli), and coli index (the number of bacteria of the group of Escherichia coli per 1 liter of liquid) were determined. The results of the analysis are given in the table.

As indicated above, the microbial number in disinfected effluents is 3 x 10 ³ . Data for other indicators are not available.

 According to the current classification of the degree of bacteriological pollution of water bodies, livestock effluents treated according to the known method belong to category III, which corresponds to the class of “moderately polluted”, and effluents treated by the proposed method, to category I, which corresponds to the class of “very clean” .

 Thus, the proposed method provides effective clarification of livestock stocks only due to coagulation, and without the addition of “external” chemical coagulant to the stocks, and complete disinfection of stocks.

Claims (2)

 1. METHOD FOR DISINFECTING AND LIGHTING ANIMAL WATER DRAINAGE, including its mechanical cleaning of coarse dispersed inclusions followed by electrochemical treatment in an electroactivator separated by a semipermeable membrane into an anode and cathode chambers, characterized in that the electrochemical treatment of the drain is carried out under the anode anode in an anode chamber cathode chamber of an alkali metal chloride aqueous solution. 2. The method according to claim 1, characterized in that the electrochemical treatment is carried out at an energy consumption of 2.0-3.0 kW · h / m ³ and an aqueous alkali metal chloride concentration of 5-10%

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