RU2056358C1 - Water treatment and conditioning plant - Google Patents

Abstract

FIELD: treatment of water. SUBSTANCE: device comprises charges held in a container in successive layers. The charge layer for primary treatment is made of schungite with a concentration of surface acidic active groups within an interval of 1-15 /m² while the next - from a carbonate-containing rock - containing microelements of side subgroups of the periodical system in an amount of 0.001-0.1% of the mass of rock. The charge layer for primary water treatment may be made of ground schungite with a particle size of 1-5 mm. The device also may be made with a charge layer for subsequent treatment of water made from ground dolomite-containing rock with a particle size of 1-5 mm. Most effective is the charge for subsequent treatment of water consisting of(%):calcium, 20; magnesium, 11; iron, 0.002; copper, 0.01; cobalt, 0/001; nickel, 0.002; zinc, 0.01; chromium, 0.002; vanadium, 0.001. The device may be made of two removable parts for primary and subsequent treatment of water. At least a portion of the surface of each of said parts is made of a porous material. EFFECT: improved design. 6 cl, 5 dwg, 2 tbl

Description

 The invention relates to the production of drinking water and can be used for purification and conditioning, as well as the mineralization of tap, natural and waste water.

 A device is known that partially solves the problem of purifying water from organic, mineral and bacterial contaminants [1] This device includes a tank with a coral sand substance loaded from natural calcium and magnesium containing it.

 The disadvantage of this device is the low degree of water purification, which is caused only by sorption processes on an underdeveloped sand surface. Mineralization of treated water with calcium and magnesium compounds, as well as other trace elements occurs within the natural (very low) solubility of their carbonates and bicarbonates contained in coral sand.

 The closest in technical essence and general features to the proposed is a device for water purification and conditioning [2] The device consists of a unit for saturating the treated water with carbon dioxide and a tank with a load of natural calcium and magnesium dolomite placed in it.

 The disadvantage of this device is the formation of carbonic acid in water when it is saturated with carbon dioxide, the pH of which does not exceed 4 for maximum saturation. In this case, carbonate ions are formed in the water, which causes difficulties in the transition to the solution of calcium, magnesium and trace elements that make up dolomite, so as a carbonate anion is the same with respect to dolomite. In addition, the water treated according to the prototype does not contain potential complexing agents that contribute to the long-term preservation of trace elements in a dissolved state.

 The purpose of the invention is to improve purification, to increase the degree of saturation of treated water with salts of calcium, magnesium, as well as trace amounts of elements of side subgroups of the periodic system with constant contents during long-term storage of water.

The goal is achieved in that in a device for cleaning and conditioning water with a loading layer of schungite for its primary treatment in it, which reduces the pH, including a tank with a carbonated rock loading layer placed in it, these downloads are placed in a container in successive layers. The loading layer for primary processing is made of shungite with a concentration of surface acidic active groups in the range of 1-15 mgq equiv / m ² , and the next of carbonate-bearing rocks, including trace elements metals of the side subgroups of the periodic system in the amount of 0.001-0.1% by weight of the rock . The loading layer for the primary treatment of water can be made of crushed schungite with a particle size of 1-5 mm. It is possible to implement a device with a loading layer for subsequent processing of water from crushed dolomite-containing rocks with a particle size of 1-5 mm. The most effective loading for subsequent water treatment, made of dolomite-containing rocks, including calcium 20; magnesium 11; iron 0.002; copper 0.01; cobalt 0.001; nickel 0.002; zinc 0.01; chromium 0.002; vanadium 0.001. The device can be implemented in a submersible version. The capacity of such a device is made of two detachable parts for the primary and subsequent treatment of water, with at least part of the surface of each made of porous material. In this case, the detachable part of the tank for primary water treatment is made of a material with a pore size of 1-100 μm.

 The proposed device improves the purification of water from heavy metals, organic and bacterial contaminants due to the location of the layers of the downloads for the primary treatment of water that reduces the pH made of shungite, and its subsequent processing from carbonate-containing rocks. The combination of downloads and their sequential location in the tank allows you to get water with the required concentration of calcium and magnesium salts, as well as trace elements necessary for humans.

The layer for primary water treatment is made of shungite with a concentration of surface acidic active groups in the range from 1-15 μg · equiv / m ² . As a loading layer of carbonate-containing rock, including microelements of side subgroups of the periodic system in an amount of 0.001-0.1% by weight of the rock, such as dolomite, calcite-containing or coral sand can be installed. Carbonate rocks are able to interact with acidified water. The latter is transferred by cations of calcium, magnesium, trace elements, as well as carbonate anions, which react with water to form hydrocarbonate anions. As a result, drinking bicarbonate water is formed, containing 75-100 mg / l of calcium ions, 25-50 mg / l of magnesium, and also enriched with microelements of side subgroups of the periodic system.

 The implementation of the boot layer of shungite with a particle size of 1-5 mm allows to increase the degree of purification and disinfection of treated water. Loading from dolomite-containing rock with a particle size of 1-5 mm provides a high degree of saturation of water with calcium and magnesium salts, as well as trace elements. The most effective load to meet the physiological needs of a person, consisting of dolomite-containing rocks, including calcium 20; magnesium 11; iron 0.002; copper 0.01; cobalt 0.001; nickel 0.002; zinc 0.01; chrome 0,0003; vanadium 0.001 by weight of the rock.

 The device can be made in a submersible version. In this case, a container with a load of shungite is installed in a vessel with water, and then replaced with a container with carbonate-containing rock. The implementation of the container or part of it, depending on the design features, of a porous material with a pore size of 1-100 μm due to the need for easy penetration of water through the material of the structure.

 To confirm the values of the intervals conducted experiments, the results of which are shown in table. 1.

 A glass column with an inner diameter of 65 mm was loaded with crushed schungite fractions of 1-5 mm. The height of the loading layer was 30 cm.

For research, shungite was selected with the content of acid groups on the surface of the particles in the range of 1-15 μg · equiv / m ² . Subsequently, a layer of carbonate-containing rock was placed behind the schungite layer, which included in its composition trace elements metals of the transitional subgroups of the periodic system, contained in an amount of 0.001-0.1% by weight of the rock. The height of the loading layers was selected from the condition of the volume ratio between the loading layers of shungite: carbonate 0.5-1.5, and the fractions of shungite, as well as carbonate-containing rocks, were 1-5 mm.

 The limiting value of the speed of passage of water through the device, which ensures the transition to the solution of optimal amounts of calcium, magnesium and trace elements and at the same time retains the desired performance of the installation, is selected based on the degree of dispersion of the load and the diameter of the container containing the load. It was 1-2 l / h. The data are given in table. 1 and 2, obtained at a speed of 1.5 l / h. As can be seen from the data table. 2, the concentration of trace elements in the water treated by the claimed device is practically unchanged.

 In FIG. 1 shows a device for cleaning air conditioning water flow type, General view.

The device consists of a calorific tank 1 and a pipe 2 connected to it for supplying the source of purified water, a tank 3 with a tap 4 for purified water, a container 5 placed in it with a loading layer from shungite 6, with a concentration of surface acid active groups in the range of 1-15 μg · eq / m ² for the initial treatment of reducing the pH of the water and the subsequent layer on carbonate-containing rocks 7, including trace elements of the subgroups of the fourth period of the periodic system in an amount of 0.001-0.1% by weight of the rock. As a charge from a carbonate-containing rock, such as dolomitic, calcite-containing or coral sand can be installed. The most effective implementation of the boot layer for the primary treatment of water from crushed schungite with a particle size of 1-5 mm, and for the subsequent from dolomite-containing rocks with the same particle size. Download 7 can also be made from dolomite-containing rock, including calcium 20; magnesium 11; iron 0.002; copper 0.01; cobalt 0.001; nickel 0.002; zinc 0.01; chromium 0.002; vanadium 0.001. A layer of a filtering load 8, for example, of sand, is installed in a container 5 behind a loading layer of carbonate-containing rock in the course of the processed water, and porous partitions 9 are installed between the loading layers. However, the device can be implemented without them, the loading layers being located on top of each other. In the lateral surface of the container 5 there are drain holes 10 communicating its cavity with the cavity of the reservoir 3. The supply of purified water to the device can be carried out either from top to bottom or from bottom to top. The implementation of the device in the submersible version involves the execution of the tank 5 of two detachable parts installed in a vessel with water in series. First, a part of the container with shungite loading is installed in a vessel with water, and then it is replaced with a part filled with a loading from carbonate-containing rock. The implementation of the container or part of it, depending on the design features, of a porous material with a pore size of 1-100 μm, due to the need for easy penetration of water through the material of the structure.

The device operates as follows. Purified water, for example, pre-filtered from suspended impurities and treated with reagents (chlorine), is poured by the consumer into the pressure storage tank 1, then flows through the pipe 2 to the lower part of the tank 5 and passes through the loading layer from shungite 6. Shungite is a rock, containing silicates, quartz and amorphous (schungite) carbon. When shungite comes into contact with water, the concentration of hydrogen ions in it increases and, at the end of the contact time, the pH can reach less than 3. Upon contact with the surface of shungite, water is purified from both organic and inorganic contaminants, as well as bacterial contaminants. At the same time, micro amounts of organic acids are formed on the surface of shungite containing active acid groups in the range of 1-20 μg · equiv / m ² , among which there are dibasic and hydroxy acids (as well as oxalic, lactic, tartaric, etc.). Then the water passes through the porous septum into the loading layer successively located in the tank 5, made of carbonate-containing rock 7, which includes microelements, metals of side subgroups of the fourth period of the periodic system (vanadium, chromium, manganese, iron, cobalt, nickel, ground, zinc) in an amount of 0.001 -0.1% by weight of the rock.

 During the interaction of acidified water with carbonate rocks, calcium, magnesium and trace elements cations pass into the water, as well as carbonate anions, which, when reacted with water, turn into hydrocarbonate. Polyfunctional organic acids, trace amounts of which passed into water upon contact with schungite, are potential complexing agents and can form complexes with microelements (ions and metal compounds of side groups of the fourth period of the periodic system) that allow trace elements to remain in solution during storage, not while precipitating.

 The most effective load 7, made of dolomite-containing rocks, including calcium 20; magnesium 11; iron 0.002; copper 0.01; cobalt 0.001; nickel 0.002; zinc 0.01; chromium 0.002; vanadium 0.001; Manganese 0.001 by weight of the rock. The resulting water belongs to the hydrocarbonate waters and is optimal in salt composition to ensure human life. Then, after passing through the sand load 8, which serves to clean from possible ingress of suspended particles from the previous loads into the purified water, the water enters through the drain holes 10 into the tank 3 and through the tap 4 to the consumer.

 The implementation of the device in the submersible version involves the execution of the tank 5 of two detachable parts installed in a vessel with water in series. First, a part of the tank with a load of shungite is installed in a vessel with water, and then it is replaced with a part filled with a load of carbonate-containing rock. Performed containers or parts thereof, depending on the design features, of a porous material with a pore size of 1-100 μm due to the need for easy penetration of water through the material of the structure.

 In FIG. 2 and 3 depict a submersible device, appearance. The device consists of a tank made in two parts. The primary processing tank 1 is filled with shungite, the secondary processing tank 2 is filled with carbonate-containing rock. At least part of the surface of each of the parts of the container 1 and 2 is made of porous material. A pore size of 3 can be selected from an interval of 1-100 microns.

 In FIG. 4 and 5 show a submersible type device during exposure.

 Submersible device operates as follows. In a vessel 4 filled with purified water, first immerse the container 1 and keep it in water, then it is removed and immersed in the water of the vessel 2. After the container 2 is removed from the water, the water is considered purified.

 Thus, the invention allows to improve the purification, increase the degree of saturation of the treated water with calcium, magnesium salts, as well as trace amounts of elements of the side subgroups of the periodic system with their constant content during long-term storage of water.

Claims (5)

1. DEVICE FOR CLEANING AND CONDITIONING WATER with a loading layer of schungite for its primary processing in it, including a container with a loading layer of carbonate-containing rock placed in it, characterized in that the loading is placed in a container in successive layers, while the loading layer is for primary the treatment is made of shungite with a concentration of surface acidic active groups in the range from 1 to 15 μg-eq / m ² , and the subsequent one is made of carbonate-containing rock, including trace elements of secondary subgroups Periodic system in an amount of from 0.001 to 0.1% by weight of the rock.  2. The device according to claim 1, characterized in that the loading layer for the primary treatment of water is made of crushed schungite with a particle size of 1 to 5 mm.  3. The device according to claim 1, characterized in that the download for subsequent processing of water is made of crushed dolomite-containing rocks with a particle size of 1 to 5 mm 4. The device according to claim 1, characterized in that the download for subsequent water treatment is made of dolomite-containing rock, including,%:
Calcium - 20
Magnesium - 11
Iron - 0.002
Copper - 0.01
Cobalt - 0.001
Nickel - 0.002
Zinc - 0.01
Chrome - 0.002
Vanadium - 0.001
5. The device according to claim 1, characterized in that the container is made of two parts for primary and subsequent treatment of water, with at least part of the surface of each made of porous material.  6. The device according to claim 5, characterized in that the part of the tank for primary processing is made of material with a pore size of 1 - 100 microns.

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