RU2518436C2 - Method of preparing water for irrigation - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: method of preparing water for irrigation, which comprises processing of the primary water in the cathode chamber of the first diaphragm electrolyser and mixing it with the product of processing the solution in the anode chamber of the second diaphragm electrolyser, at that the primary water is used as the purified fresh water, the solution of phosphoric or nitric acid or their mixture is fed for processing to the anode chamber of the second electrolyser, and the processing in the cathode chamber of the first electrolyser is carried out to a pH of 9.5-10, and the processing in the anode chamber of the second electrolyser is carried out until increase of initial redox potential of the acid solution at 200-400 mV relative the chloride silver reference electrode.

EFFECT: invention enables to simplify the process of preparation of water for irrigation.

7 cl, 1 dwg, 2 ex

Description

The invention relates to agricultural land reclamation and can be used for irrigation of vegetable and fruit crops, orchards and other agricultural crops.

In agricultural reclamation, various methods of preparing water for irrigation of agricultural plants are used. So, for example, there is a known method of preparing water for irrigation, including passing water through cation exchange resin and anion exchange resin, in ionic forms of which, as cations and anions, elements are contained that are part of water-soluble mineral fertilizers (see RF patent No. 2281255, C02F 9 / 00, 2006). However, the known method has a high cost, especially when switching to large volumes of prepared water.

Reducing the cost of water treatment is carried out, in particular, using electrochemical processing methods. A known method of processing by passing water through an electrochemical block with soluble electrodes (see RF patent No. 2071245, A01G 25/00, 1997). Soluble electrodes are made of metals or alloys whose ions saturate water for irrigation. A known method of preparing water for irrigation, including the treatment of water in the anode and cathode chambers of the diaphragm electrolyzer, moreover, the water treated in the cathode chamber is used for irrigation both independently and in the form of a mixture with anolyte or in the form of a fertilizer solution (see RF patent No. 219500, A01G 25/00, 2002).

A disadvantage of the known methods is the comparative complexity, as well as low functionality, since there is no possibility to quickly and directionally change the characteristics of either the cathodic or anodic treatment of water.

The closest in technical essence and the achieved result is a method of treating water for irrigation, including treating the source water in the cathode chamber of the first diaphragm electrolyzer and mixing it with the solution treatment product in the anode chamber of the second diaphragm electrolyzer (see RF patent No. 22179761, A01G 25/02 2003 prototype). The known method allows a relatively simple multidirectional change in the characteristics of the anolyte and catholyte. However, a disadvantage of the known solution is the difficulty of introducing nutrients into the treated water, since such introduction is carried out by introducing chemicals into the water, which requires increased labor costs for the introduction and dissolution of the reagents, as well as careful monitoring to avoid increased salinity of irrigation water.

The technical result of using the present invention is to simplify the process of preparing water for irrigation by ensuring the introduction of the main elements (nitrogen, phosphorus or a mixture thereof) into the water at the stage of electrochemical preparation without increasing the salt content of the prepared water.

The specified technical result is achieved by the fact that in the method of preparing water for irrigation, which includes treating the source water in the cathode chamber of the first diaphragm electrolyzer and mixing it with the solution treatment product in the anode chamber of the second diaphragm electrolyzer, purified fresh water is used as the source water for processing a solution of phosphoric or nitric acid or a mixture thereof is fed into the anode chamber of the second electrolyzer, and processing in the cathode chamber of the first electrolyzer is carried out until a pH of 9.5-10.0 is reached, and the processing in the anode chamber of the second electrolyzer is carried out until the initial redox potential of the acid solution is increased by 200-400 mV relative to the silver chloride reference electrode. For processing, it is advisable to use fresh water with a salinity of 0.2-2.0 g / l.

A solution of phosphoric or nitric acid or a mixture of 1-2 g / L is fed into the anode chamber of the second electrolyzer.

As diaphragm electrolyzers, it is advisable to use electrolyzers with a ceramic nanostructured ultrafiltration diaphragm.

Mixing the treated source water in the cathode chamber of the first diaphragm electrolyzer with the product of processing the acid solution in the anode chamber of the second diaphragm electrolyzer is carried out until the pH of the irrigation water reaches 5.5-7.5.

If necessary, after mixing in the water for irrigation, microelements and / or liquid fertilizers are introduced.

If it is necessary to process a relatively large amount of water with its increased mineralization, it is advisable to use the first electrolyzer and / or the second electrolyzer containing more than one cathode and more than one anode chambers, while the anode and cathode chambers are connected in series in the first electrolyzer. In the second cell, the electrode chambers can be connected in the same way or in parallel, which is advisable when processing a large volume of solution. The source water is fed to the first cathode chamber for treatment, and the source water is fed to the anode chambers for processing, and it is supplied to the last anode chamber, i.e., the solutions pass in each anode and cathode chambers in direct flow, and the chambers themselves pass countercurrently . The solution after processing in the anode chambers of the first electrolysis cell is fed to neutralization in the cathode chamber or chambers of the second electrolysis cell.

As the source water, purified fresh water is used, for example, water from open water bodies, purified from suspended impurities or tap water. For processing, it is advisable to use fresh water with a salinity of 0.2-2.0 g / l. The use of water with less mineralization leads to a product with a low content of nutrients, which does not have a positive effect on the development and growth of plants. The use of water with higher salinity can lead to the deposition of insoluble hydroxides on the cells. This will lead to increased energy consumption and labor costs for cleaning electrolyzers. When treating the source water in the cathode chamber of the electrolyzer with increasing pH to 9.5-10.0, it is possible to obtain a micro suspension of insoluble metal hydroxides, for example, magnesium and calcium, which are necessary trace elements for plant nutrition, and at the same time remove such compounds from the treated water, like chlorides, sulfates, which have a negative effect on plants. In addition, the hydroxide microparticles easily pass into the solution when mixed with the acid treatment product in the anode chamber of the second cell. At a lower pH, hydroxides do not form. And at a pH greater than pH 10, hydroxide particles coalesce to form large sediment particles that cannot be absorbed by plants.

The fact that a solution of phosphoric or nitric acid or a mixture of them is fed into the anode chamber of the second electrolyzer for processing allows us to transfer useful substances containing phosphorus and nitrogen into the treated water for irrigation, which are valuable nutrient components. Processing in the anode chamber of the second cell is carried out until the initial redox potential of the acid solution is increased by 200-400 mV relative to the silver chloride reference electrode. This mode is due to the fact that with a slight increase in potential - less than 200 mV - a small number of products of electrode reactions, for example, peracids, are formed, which are necessary for the formation of activated fertilizers, and with an increase of more than 400 mV, unproductive energy costs increase.

The concentration of the acid or mixture of acids is maintained at a level of 1-2 g / l. The use of an acid or mixture of acids with less mineralization leads to a product with a low content of nutrients, which does not have a positive effect on the growth mode of plants. The use of higher mineralization does not provide conditions for the synthesis of peracids.

As diaphragm electrolyzers, it is advisable to use electrolyzers with a ceramic nanostructured ultrafiltration diaphragm. In electrolyzers with such a diaphragm, a high degree of constancy of the process parameters is maintained and the opportunity is created to influence the electric transport of cations and anions through the diaphragm by changing easily adjustable process parameters, such as current density, chamber pressure, etc. Ceramics made of alumina or ceramics made of a mixture of alumina with oxides of other metals, such as rare earths, can be used.

Mixing the treated source water in the cathode chamber of the first diaphragm electrolyzer with the product of processing the acid solution in the anode chamber of the second diaphragm electrolyzer is carried out until the pH of the irrigation water reaches 5.5-7.5. Maintaining this pH range is due to the fact that at lower pH values, the acidity of irrigation water increases, which can lead to chemical burns of plants, and at higher values, insoluble precipitation of metal hydroxides begins to fall, which reduces the nutritional value of irrigation water.

If necessary, after mixing in the water for irrigation, microelements and / or liquid fertilizers are introduced. This is determined by the conditions of the problem being solved and the requirements for feeding certain types of plants.

If it is necessary to treat a relatively large amount of water with its increased mineralization, it is advisable to use the first and second electrolytic cells containing more than one cathode and more than one anode chambers, while the anode and cathode chambers are connected in series in the first electrolyzer. The source water is fed to the first cathode chamber for treatment, and the source water is fed to the anode chambers for treatment, and it is supplied to the last anode chamber, i.e., the solutions pass in the direct flow path to the adjacent anode and cathode chambers, and the chambers themselves (anode or cathode) sequentially pass countercurrent. The solution after processing in the anode chambers of the first electrolysis cell is fed to neutralization in the cathode chamber or chambers of the second electrolysis cell. The number and geometry of the chambers of the second cell and their hydraulic connection are determined by the required capacity and initial conditions - mineralization of the source water, its composition, acid concentration, etc. Such a process organization scheme avoids clogging of the diaphragms of electrochemical cells and transfers the pH values of the discharged water from the anode chambers of the first electrolyzer to the region of neutral values, which increases the environmental friendliness of the process.

To implement the method, a plant with a capacity of 40 l / h was used. This unit, which is part of a series of units that differ in productivity, is called "Rostock".

The installation diagram is shown in figure 1.

The installation contains the first electrolyzer, made on a modular basis and containing four electrochemical cells 1-4, each of which is divided by a ceramic diaphragm based on aluminum oxide into the anode 5 and cathode 6 of the chamber. The anode chambers 5 and the cathode chambers 6 of cells 1-4 are connected in series - the output of the anode chamber 5 of cell 1 is connected to the input of the anode chamber 5 of cell 2, etc., and the output of the cathode chamber 6 of cell 4 is connected to the input of the cathode chamber of cell 3 and t .d. The installation comprises a feed water supply line 7 connected to a water source (open water reservoir, artesian well, water supply) (not shown). Filter 8, a pressure regulator 9, and a flow sensor 10 are sequentially installed on line 7. After the flow sensor 10, a bypass line 11 with a valve 12 installed on it is connected to line 7. Line 11 is connected to the anode chamber 5 of cell 1, and line 7 to the cathode cell camera 4.

The output of the cathode chamber 6 of the cell 1 is connected to the withdrawal line 13 of the solution processed in the cathode chambers 6 cells 1-4. Line 13 is connected to the mixer 14.

The installation contains a second electrolytic cell 15 with an anode 16 and a cathode 17 chambers separated by a ceramic diaphragm based on aluminum oxide. The installation also contains a container 18 with an acid solution or an acid mixture, a line 19 for supplying an acid solution from the tank 18 to the anode chamber 16 of the electrolyzer 15. On the line 19 between the tank 18 and the inlet of the anode chamber 16, a peristaltic pump 20 and a manometer 21 are installed in series. the chamber 16 is connected by a line 22 to the mixer 14. On the line 22, before connecting to the mixer, a pressure stabilizer 23 is placed. The input of the cathode chamber 17 is connected by a line 24 to the output of the anode chamber 5 of cell 4, and the output of the cathode chamber 17 of the electrolyzer 15 is connected to the line 25 th outlet to the drain.

The drain line prepared for irrigation water 26 is connected to the mixer 14.

Installation works as follows. The source water is purified from suspended particles on the filter 8 and through line 7 through the pressure regulator 9 and the flow sensor 10 enters the cathode chamber 6 of the cell 4 for processing and, after passing through the cathode chambers of cells 3, 2 and 1, enters the mixer 14 through line 13 .

Through the bypass line 11, the source water through the valve 12 enters the anode chamber 5 of cell 1 and, successively passing the anode chambers of the cells 2, 3 and 4, is sent through line 24 to the cathode chamber 17 of the electrolysis cell 15, where it is neutralized and discharged through line 25 to the drainage. In the anode chamber 16 of the electrolysis cell 15, a solution of an acid or mixture of acids is supplied by pump 20 through line 19. The flow through the anode chamber 16 is controlled by the operating mode of the pump 20 using a pressure gauge 21 and a pressure stabilizer 23. After processing in the anode chamber 16, the solution of the acid or mixture of acids through line 22 enters the mixer 14, where it is mixed with the source water that has been treated in the cathode chambers 6 cells 1-4. The resulting water for irrigation through line 26 enters the consumer.

The invention is illustrated by the following examples, which, however, do not exhaust all the options for its implementation.

Example 1. As the source water was used tap water with a salinity of 0.3 g / l and a pH value of 7.2. The source water contained chlorides, sulfates and carbonates of sodium, potassium, calcium and magnesium. The concentration of chlorides of alkali and alkaline earth metals was 0.12 g / l, the concentration of sulfates was 0.13 g / l, the concentration of carbonates and bicarbonates was 0.04 g / l. The total concentration of chlorides and sulfates of iron, cobalt, copper, manganese was 0.01 g / l.

The source water under a pressure of 1.2 kgf / cm ² entered the cathode chamber 6 of the cell 4 and, passing the cathode chambers 6 cells 3, 2 and 1, entered the mixer 14. Due to the electrochemical treatment in the cathode chambers, the water entering the mixer 14, had the following characteristics: pH 10.3, ORP = -750 mV (h.s.).

On line 11, the source water, the flow rate of which was regulated by valve 12, entered the anode chamber 5 of cell 1 and, passing the anode chambers 5 cells 2, 3 and 4, was sent along line 24 to the cathode chamber 17 of the electrolyzer 15. As a result of processing in the anode chambers, the original the water entering the cathode chamber 17 had the following characteristics: pH 3.8; ORP = + 650 mV (HSE).

Simultaneously with the feed of treated source water into the cathode chamber 17, an orthophosphoric acid solution with a concentration of 1.1 g / L, having a pH of 2.2 and an ORP of + 490 mV (h.s.) was supplied to the anode chamber 16 of the electrolyzer 15. After processing in the anode chamber 16, the acid solution had the following characteristics: pH 1.9; ORP = + 1015 mV (h.s.), due to the formation of phosphoric acids such as peroxophosphoric (H ₃ PO ₅ ) and peroxopyrophosphoric (H ₄ P ₂ O ₈ ).

The treated solution of activated acid through line 22 entered the mixer 14, where it was mixed with the treated water in the cell cathode 6 cells 1-4. After mixing, water with a salinity of 0.29 g / l was obtained, having the following characteristics: pH 6.7; ORP = -20 mV (HSE). The specified water containing useful elements (sodium, potassium, magnesium calcium, as well as metals of the impurity group salts of phosphoric and naphosphoric acids) and having optimal characteristics for watering plants, was supplied to the consumer.

Example 2. Water for irrigation was obtained under the conditions of Example 1, but a mixture of nitric and phosphoric acids was used as an acid solution at a ratio of 1: 1, with a total mineralization of 1 g / L, pH 2.1, and ORP = + 658 mV (chemical grade) .e.).

The resulting water for irrigation had the following characteristics: pH 6.8; ORP = -43 mV (HSE). The total mineralization of water was 0.31 g / l.

As follows from the data presented, a simplification of the process of preparing water for irrigation when introducing the main nutrient elements (nitrogen, phosphorus or a mixture thereof) into the water at the stage of electrochemical preparation without increasing the salt content of the prepared water and without increasing labor costs is achieved.

Claims (7)

1. A method of preparing water for irrigation, comprising treating the source water in the cathode chamber of the first diaphragm electrolyzer and mixing it with the solution treatment product in the anode chamber of the second diaphragm electrolyzer, characterized in that purified fresh water is used as the source water for processing into the anode chamber the second electrolyzer serves a solution of phosphoric or nitric acid or a mixture thereof, and the processing in the cathode chamber of the first electrolyzer is carried out to achieve a pH of 9.5-10, and processing in the anode chamber of the second catholyzer lead to an increase in the initial redox potential of the acid solution by 200-400 mV relative to the silver chloride reference electrode. 2. The method of preparing water for irrigation according to claim 1, characterized in that they use fresh water with a salinity of 0.2-2.0 g / L. 3. The method of preparing water for irrigation according to claim 1, characterized in that a solution of phosphoric or nitric acid with a concentration of 1-2 g / l is used. 4. The method of preparing water for irrigation according to claim 1, characterized in that electrolyzers with a ceramic nanostructured ultrafiltration diaphragm are used as diaphragm electrolyzers. 5. The method of preparing water for irrigation according to claim 1, characterized in that the mixture of treated source water in the cathode chamber of the first diaphragm electrolyzer with the product of processing the acid solution in the anode chamber of the second diaphragm electrolyzer is conducted until the pH of the irrigation water reaches 5.5-7, 5. 6. The method of preparing water for irrigation according to claim 1, characterized in that after mixing in the water for irrigation microelements and / or liquid fertilizers are introduced. 7. The method of preparing water for irrigation according to claim 1, characterized in that the first and / or second electrolytic cells are used, containing more than one cathode and more than one anode chambers, while in the first electrolyzer, the anode and cathode chambers are connected in series, the source water is supplied to treatment in the first cathode chamber along the way, and feed water is fed into the anode chambers for processing, and it is fed into the last cathode chamber along the anode, and the solution after processing in the anode chambers of the first electrolyzer is fed to neutralization in the cathode chamber or amers of the second cell.