RU139069U1 - WATER TREATMENT DEVICE - Google Patents

Abstract

1. Apparatus for water purification, comprising a housing with a working tank with water supply and drain holes, a device for freezing water and melting ice, a receiving tank for purified melt water, characterized in that it contains an ozonizer, a receiving tank contains a mineralizer for mineralization of purified melt water, and at the bottom of the receiving tank is a perforated silver plate. 2. The apparatus according to claim 1, characterized in that a desktop version of the apparatus for supplying cold water is possible. The apparatus according to claim 1, characterized in that a desktop version of the apparatus for supplying heated water is possible. The apparatus according to claim 1, characterized in that it is possible to connect to a water supply and sewage system for the continuous production of clean water and the discharge of contaminated sewage. The apparatus according to claim 1, characterized in that the minerals in the receiving tank are in a grid of environmentally friendly material for convenient washing of minerals. The apparatus according to claim 1, characterized in that it is possible to install an additional fine filter on the pipeline for pumping melt water from working tanks after defrosting, which ensures the deposition of tiny crystals of heavy water on it. The apparatus according to claim 1, characterized in that the ozonizer is connected to a pipeline system for pumping melt water from working tanks.

Description

The utility model relates to devices for water purification and can be used in everyday life, food industry and medicine.

From the patent RU 2274607 there is known a water treatment plant comprising a tank for untreated water, a heat exchanger installed in the tank for removing heat and freezing ice, means for heating and thawing ice, a freezing unit with a cooling system, a pipeline with a valve for draining water with impurities, pipeline with a valve for draining melt water, characterized in that the heat exchanger is made in the form of a multi-stage coil located in the upper part of the tank at a height of about 1/3 ÷ 2/3 of the tank height at a distance of 2 ÷ 5 cm relative relative to the upper base of the tank and symmetrically relative to its side surface with a gap that provides the possibility of volumetric freezing of ice in water around the coil to a size that does not overlap this gap during ice crystallization, the tank is equipped with a heat-insulating cover and seal, the pipeline for draining water with impurities is installed in the section the conical bottom of the tank, the pipeline for draining the melt water is installed below the conical bottom of the tank by 0.5 ÷ 2 cm.

A disadvantage of the known installation is the use of a refrigerant, there is a danger of leakage, there is no disinfection of water, water is not mineralized and is not treated with silver, a small amount of clean water is output, for the preparation of purified water personal intervention of a person is required: filling a working tank with water, draining dirty water with impurities, according to the item: It is equipped with a device for heating and supplying warm melt water to the tank for heating and melting ice, and when heated melt water enters, it mixes with fresh water copulating with clean water, which adversely affects the final product.

A technical solution is known from patent RU 2393996 C1, which describes a METHOD FOR WATER CLEANING AND INSTALLATION FOR ITS IMPLEMENTATION. The method includes first cooling the water, in which the temperature of the medium is reduced to a value not lower than -3 ° C at a rate of 0.1-0.3 ° C / min, and subsequent freezing of water at a rate of 0.05-0.1 ° C / min to a temperature not lower than -4 ° C for the complete crystallization of pure water with impurities and the formation of a liquid brine with impurities. Next, the brine is drained, the mass of ice is heated with a gradual increase in temperature at a rate of 0.16-0.18 ° C / min to a temperature of no higher than + 10 ° C, and the ice is aged until it is fully thawed. Re-cooling of the water is carried out at a rate of 0.1-0.3 ° C / min to a temperature of at least + 2 ° C and heavy water is maintained until it crystallizes completely. The purified water is drained through a filter. The apparatus includes a case with a thermostatically controlled working tank with a lid and an inclined bottom with a drain hole, a thermoelectric module for freezing water and melting ice with a control unit, a consumer container for melt water, and a container for water with impurities. The apparatus comprises pipelines with means for controlling water discharge connected to a drain hole. Pipelines are also interconnected by a pipeline with a fine water filter. Effect: improving the quality of water treatment, process automation, reducing the time to obtain the finished product, weight, dimensions of the device. A known device is considered as the closest analogue (prototype).

The disadvantage of the closest analogue is that personal preparation is required for the preparation of purified water: filling the working tank with water, draining dirty water with impurities, two freezing stages are required (re-freezing is required), there is no water disinfection, the water is not mineralized and is not treated with silver, the output is a small amount of purified water; a capacity for contaminated water is required.

The technical result of the claimed device is that it allows you to get purified melt mineralized water through the use of multi-level cleaning from contaminants and heavy water, with the possibility of mineralization, disinfection and enrichment with silver ions.

The specified technical result is achieved by the fact that the claimed apparatus for water purification, comprising a housing with a working capacity with supply and drain holes for water, a device for freezing water and melting ice, a receiving tank for purified melt water, characterized in that it contains an ozonizer, a receiving tank contains a mineralizer for the mineralization of purified melt water, and a perforated silver plate is located at the bottom of the receiving tank.

The working capacity may be in the form of a crystal in the form of a polyhedron having six side faces, one face in the form of an upper base and six faces in the lower base, with an angle between the side faces of 120 °.

Perhaps the desktop version of the apparatus for supplying cold water.

Perhaps the desktop version of the apparatus for supplying heated water.

It is possible to connect to the water supply and sewage systems for the continuous production of clean water and the discharge of contaminated sewage.

Minerals in the receiving tank can be in a grid of environmentally friendly material for convenient washing of minerals.

It is possible to install an additional fine filter on the pipeline for pumping melt water from working tanks after defrosting, which ensures the deposition of tiny crystals of heavy water on it.

The ozonizer can be connected to a pipeline system for pumping melt water from working tanks.

An embodiment of the utility model is illustrated by the figures of Figures 1 and 2, where: 1 - housing; 2 - working capacity; 3 - inclined bottom of the working tank; 4 - cover of the working capacity, 5 - thermoelectric module; 6 - heat exchanger, 7 - radiator for cooling the heat exchanger (thermoelectric module), 8 - hole for supplying water to the working tank; 9 - pipeline for supplying water to the working tank; 10 - self-cleaning filter; 11 - electrohydrovalve for controlling water supply; 12 - ozonizer, 13 - check valve on the pipeline of the ozonizer; 14 - ozonator pipeline, 15 - hole for the output of ozone from the working tank, 16 - pipe for the output of ozone from the working tanks, 17 - check valve on the pipeline for the output of ozone from the working tanks, 18 - hole for draining contaminated water from the working tank; 19 - pipeline for pumping contaminated water from a working tank; 20 - a water pump for pumping contaminated water from working tanks, 21 - a non-return valve in the pipeline to discharge dirty water into the sewer; 22 - hole for supplying ozone and pumping out thawed melt water, located at the beginning of the narrowing of the bottom of the working tank, 23 - water pump for pumping melt purified water; 24 - pipeline for supplying ozone and for pumping melt purified water from working tanks, 25 - filter; 26 - check valve; 27 - the outlet of the pipeline with purified melt water; 28 - receiving tank for melt purified water, 29 - receiving tank cover, 30 - thermal insulation of the receiving tank, 31 - inclined bottom of the receiving tank, 32 - mineral complex, 33 - net for minerals from environmentally friendly material, 34 - silver perforated plate, 35 - control unit of thermoelectric modules (Figure 2); 36 - an electric motor with a fan for forced cooling of radiators of thermoelectric elements with a power supply (for air cooling); 37 - air cooler, for example, evaporative type (Figure 2); 38 - drain hole of the receiving tank; 39 - pipeline for pumping prepared purified water; 40 - outlet for supplying melt purified water to a consumer.

An example implementation of a utility model.

A water purification device includes a housing 1 (FIG. 1), in which a working tank (s) 2 with an inclined bottom 3, a cover of the working tank 4, a thermoelectric module 5 for freezing water and melting ice, a heat exchanger 6, a radiator 7 for cooling it are placed , the hole 8 for supplying water to the working tank through the pipeline 9 through a self-cleaning filter 10 from the water supply through the electrohydraulic valve 11 to control the water supply, ozone is supplied from the ozonizer 12 passing through the check valve 13 through the pipeline 14, connected to the pipeline 24 and gets into the slave The capacity of the container 2 through the opening 22, the ozone from the working containers 2 is discharged through the hole 15 located in the cover 4 and is discharged through pipelines 16, passes through the non-return valve 17 and is connected to the pipe 19 for discharge into the sewer, contaminated water is pumped out of the working container 2 by the pump 20 through the hole 18 for draining contaminated water through the pipe 19 and, passing through the check valve 21, is discharged into the sewer, the prepared melt water is pumped from the working tanks 2 by the water pump 23 through the hole 22 located at the beginning the narrowing of the bottom of the working tank 2 through the pipe 24 passing through the check valve 26 will fall through the outlet 27 into the receiving tank 28. The receiving tank 28 has a lid 29 and an inclined bottom 31, on the inclined bottom 31 is a mineral complex 32 in a grid of environmentally friendly material 33 and lies a perforated silver plate 34, the control unit 35 (Figure 2) of thermoelectric modules 5 located outside on the side surface of the working tanks 2 for freezing water and melting ice, an electric motor with a fan 36 for forced th cooling together with power supply unit for supplying the cooled air via conduits to FIG. not shown on the cooling radiators 7 of the heat exchanger 6 of the thermoelectric modules 5 enters the air cooler 37 (Figure 2); for example, of an evaporative type, where the cooling system is a closed-type system of a cooled stream of air or liquid (in the case of using liquid refrigerant) (not shown). The prepared purified and mineralized water is pumped through the drain hole 38 of the receiving tank 28, passing through the pipeline 39, is supplied to the consumer through the outlet 40, with the possibility of connecting to the table supply cold melt and heated purified water to the consumer.

The device operates as follows.

The device is connected to the water supply at the entrance using a pipeline, for example, as a dishwasher. The electrohydrovalve 11 opens (Fig. 1) and the incoming water from the water supply passes the primary rough water purification through the self-cleaning filter 10, and through the pipeline 9 it enters the working containers 2 and fills them to 85% of their volume and the electrohydrovalve 11 closes. Next, the ozonizer 12 produces ozone and feeds it through the pipe 14 passing through a check valve 13, which is connected to the pipe 24 and the ozone enters through the opening 22 into the working vessel 2. Ozonation time, for example, 10 l of water with a capacity of 600 mg / h of ozonizer 12 will be about 10 minutes Ozone from working tanks 2 is discharged through an opening 15 located in the lid 4 and discharged through pipelines 16, passes through a non-return valve 17 and is connected to a pipeline 19 to discharge ozone into the sewer, and in the absence of sewage, it is discharged using a separately connected pipeline. During ozonation of water, the thermoelectric module 5 begins to cool the walls of the working vessel 2 to t = 0 ° C and holding this temperature for 10 minutes to crystallize heavy water near the walls of the working vessel 2, then the temperature drops to -20 ° C until crystallization of about 75- 80% of the total volume of water and freezing stops. The unfrozen residue of contaminated water located in the center is pumped out, by pump 20 through the drainage hole 18 at the bottom 3 of the working tank 2, passing through the pipe 19 through the check valve 21, is discharged into the sewer by connecting the pipe, for example, to a sink siphon or in another way. Then, heavy water is separated from the total mass of ice by defrosting the outer layer of ice, for which the walls of the working vessel 2 are gradually heated by automatically switching the voltage polarity of thermoelectric elements, and the opposite effect occurs (the walls inside the vessel begin to heat up) is set by the program in the control unit 35 and the walls of the working tank 2 are heated to a temperature of + 20 ° C, ice is thawed at the side walls of the working tank 2 and thus thaws about 10% of the total ice volume (time I is the calculated defrosting), then thawed heavy water is pumped through the hole 18 for discharging contaminated water via conduit 19, pump 20, passes through the check valve 21 and the same is discharged into the sewers. In this case, defrosting does not stop and the remaining ice is melted by the heated walls of the working tank 2 to a water temperature in the working tank of not more than + 2 ° C. The thermoelectric module 5 is cooled by a heat exchanger 6 using cooling radiators 7 with an air stream from an electric motor with a fan and a power supply 36 (when using air cooling). After the remaining ice is completely defrosted, the prepared melt water is pumped out by the pump 23 through the hole 22, passing through the pipeline 24, it is cleaned from the suspensions by the filter 25 (the filter element has a mineral composition), passes through the check valve 26 and enters through the outlet 27 into the receiving tank 28. Moreover, the drain of melt water after thawing is carried out through the hole 22, located at the beginning of the narrowing of the bottom 3 of the working tank 2, and the drain of contaminated water is made through the hole 18, located at the very bottom of the tank, which reduces the amount of suspended sediment deposited in the bottom of the prepared water. The purified melt water enters the receiving tank 28, on the inclined bottom 31 of which there is a mineral complex 32 (for mineralization of water) in a grid of environmentally friendly material 33. The completely prepared melt processed with minerals and silver is pumped out of the receiving tank 28 through the opening 38 of the inclined bottom 31 and passing through the pipeline 39, goes through the outlet 40 and is supplied to the consumer. The mineral complex may be a mixture of minerals: shungite and various varieties of quartz: rock crystal, smoky quartz, rose quartz, amethyst, cacholong, carnelian, and may also contain other compositions for mineralizing water and giving it certain properties. Mineral complex 32 is located in a grid 33 of environmentally friendly material for convenient washing of stones during the maintenance process. For a longer preservation of the biologically active properties of the purified melt water, the receiving tank 28 has thermal insulation 30 on all sides, as well as for a longer preservation of the cool temperature of the melt water. Also in the receiving tank 28 is a perforated silver plate 34 for disinfecting water and enriching it with silver ions. In this tank, water is stored, mineralized and processed in silver and supplied to the consumer. Thus, a multilevel purification of contaminants and heavy water occurs. As a result, we get about 65% of pure (protium) water. In this apparatus, it is possible to prepare pure melt water without mineralization by removing the mineral complex from the receiving tank, as well as without silver treatment by removing the silver perforated plate from the receiving tank, thus obtaining various properties of melt water. The whole process of preparing purified melt water is carried out continuously, in which the water in the receiving tank is constantly fresh and biologically active due to periodic full renewal, i.e. as soon as thawed purified water is prepared in the working tanks, it completely replaces the previously prepared water in the receiving tank. The supply and heating can be used in a tabletop version, for example, in the device of a home water cooler. The device is designed so that the ozonizer is connected to the pipeline system for pumping melt water from the working tanks, and ozonation is performed from the hole for pumping melt water, thereby reducing the number of pipelines and due to ozone, the system is constantly disinfected, which interacts with melt water during the whole process preparation and serving to the consumer. The device can be directly connected to the water supply and sewage systems for the continuous production of clean melt water, and a pump can be provided for pumping water from any water tanks. The device can be made in such sizes and shapes that, for example, for processing 10 liters of water, the device will have approximate overall dimensions of 750 × 400 × 500 mm (length-width-height), and can be placed in a standard kitchen set to save space in the kitchen, and also can be made in floor execution. In the manufacture of the apparatus, depending on the desired amount of purified melt water and on the time spent on its production, you can change the volume and number of working tanks. The shape of the working tanks can also be of arbitrary shape and position in space. For example, the shape of the working containers may be in the form of a polyhedron crystal having six side faces, one face in the form of an upper base and six faces in the lower base, with an angle between the faces of 120 °. This recreates the natural forms of growth of the crystal of the mineral and allows you to get energy charging of water, strengthening the bonds between water molecules. It is possible to use a heat exchanger as a compressor cooling cooler, as in refrigeration units. Hot air or liquid (depending on whether air or water cooling is used) is not discharged from the apparatus, but is cooled inside the apparatus itself, which prevents the heating of air in the room, but if there is a need for heating the room, a damper for supplying hot air to the room. Gases from the ozonizer are discharged into the sewer to prevent entry into the room and at the same time disinfection of the sewage system, if not available, they are discharged into the ventilation window or outdoors. The process of preparing purified water occurs without human intervention. A counter can be installed in the apparatus to replace the filter element of the mineral composition after a certain number of cycles or the prepared volume of thawed purified water.

Claims (7)

1. Apparatus for water purification, including a housing with a working tank with water supply and drain holes, a device for freezing water and melting ice, a receiving tank for purified melt water, characterized in that it contains an ozonizer, a receiving tank contains a mineralizer for mineralization of purified melt water, and at the bottom of the receiving tank is a perforated silver plate. 2. The apparatus according to claim 1, characterized in that it is possible desktop version of the apparatus for supplying cold water. 3. The apparatus according to claim 1, characterized in that it is possible desktop version of the apparatus for supplying heated water. 4. The apparatus according to claim 1, characterized in that it is possible to connect to a water supply and sewage system for the continuous production of clean water and the discharge of contaminated sewage. 5. The apparatus according to claim 1, characterized in that the minerals in the receiving tank are in a grid of environmentally friendly material for convenient washing of minerals. 6. The apparatus according to claim 1, characterized in that it is possible to install an additional fine filter on the pipeline for pumping melt water from working tanks after defrosting, which ensures the deposition of tiny crystals of heavy water on it. 7. The apparatus according to claim 1, characterized in that the ozonizer is connected to a pipeline system for pumping melt water from working tanks.

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