RU2432320C2 - Water treatment apparatus - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to water treatment appliances and may be used in household conditions. Proposed apparatus comprises working vessel 4 with taper bottom provided with water drain hole 5, thermo electrical module 2 to freeze water and to melt ice, treated water collecting vessel 15, vessel 16 to collect water with impurities and increased content of deuterium, thermo electrical module control unit 26 and water drain system with drain branch pipes. Working vessel inner space is formed by thermo electrical module 22 tightly connected with hydraulic distribution panel 3 that doubles as working vessel bottom. Thermo electrical module comprises several thermo electrical modules arranged in evacuated tight chamber formed by ribbed outer and inner walls 6 and 8, respectively, arranged atop thermo electrical module. Filler neck 11 with blower 12 is arranged atop thermo electrical module. Hydraulic distribution system comprises valve, two flow distributors and fine filter intercommunicated via channels.

EFFECT: higher filtration efficiency and capacity.

3 cl, 2 dwg

Description

The invention relates to a device for water purification and can be used in domestic conditions. The present invention allows to effectively remove organic and inorganic substances dissolved in water, in addition, significantly reduce the content of deuterium in the water - a heavy hydrogen isotope. In this case, the principle of phase separation by the method of volume crystallization by freezing in a closed volume is used.

Water plays a significant role in various biological processes. Studies have shown that behind the unpretentious chemical formula of H ₂ O lies a substance with a unique structure and no less unique properties. It is known that natural water is a heterogeneous substance, a mixture of waters formed by various isotopes of hydrogen and oxygen. Heavy water (deuterium oxide) - has the same chemical formula as ordinary water, but instead of hydrogen atoms it contains two heavy isotopes of hydrogen - deuterium atoms. The formula for heavy water is usually written as: D ₂ O or ² H ₂ O. Externally, heavy water looks like ordinary - a colorless liquid without taste and odor, but in terms of its physicochemical properties and negative effects on the body, heavy water is very different from light water . Various researchers independently established that an increased concentration of heavy hydrogen isotopes, the so-called heavy water, negatively affects the vital functions of organisms; this happens even when using ordinary natural water with a high content of heavy water. (A. Timakov, “The main effects of light water,” 8th All-Russian Scientific Conference on the topic “Physicochemical Processes in the Selection of Atoms and Molecules”, November 6–10, 2003, Zelenogorsk). Among all stable isotopes, the isotopic effects of deuterium on living organisms are the highest. Any natural water and drinks based on it, as you know, contain up to 15 mg / l of heavy water, which in its biological properties is significantly different from ordinary water. Heavy water of high concentration is toxic to the body; chemical reactions in its environment are slower compared to ordinary water; hydrogen bonds involving deuterium are somewhat stronger than ordinary ones. At the same time, a person from time immemorial has known the amazing properties of melt water. It has long been noted that near melting springs, the vegetation of alpine meadows is always more magnificent, and life blooms violently at the edge of melting ice in the Arctic seas. Watering with melt water increases the yield of crops, accelerates the germination of seeds. With the use of melt water, weight gain in livestock is steadily increasing. The unique property of melt water contributes to its easy absorption by the body, it is biologically active. It improves metabolism and enhances blood circulation, reduces the amount of cholesterol in the blood and soothes pains in the heart, increases the adaptive capacity of the body and helps prolong life. (Belyanin BC, Romanova E. Life, water molecule and the golden ratio, Journal "Science and Life", 2004, No. 10).

The revealed multilateral negative impact of heavy water on living organisms necessitates the removal of heavy water from drinking water.

A known water purifier for producing thawed drinking water, (RF patent No. 2337883, IPC C02F 1/22, publ. 10.11.2007), comprising a zone of water freezing with an annular freezer, a zone for displacing impurities from the ice front and concentration located in series in a longitudinal vessel impurities in the form of a brine, a zone of transition of water from solid to liquid with an annular heating element, separated nozzles for removing impurities in the form of brine and melt drinking water, located in the lower part of the vessel. The water purifier is additionally equipped with a drive unit for moving the frozen water rod mounted behind the freezer, as well as a disconnecting device located in the center of the frozen water rod made in the form of a pipe, which has an annular cutting part in the form of a gear ring at the inlet and an expanding profile at the exit, which forms the outlet pipe for displacing the brine.

However, this device has large dimensions, weight and complex design. The process of obtaining melt water is long. All these disadvantages do not allow it to be used in domestic conditions for water treatment. Known thermoelectric device for the continuous production of fresh water by freezing according to the application of the Russian Federation No. 2006103183 IPC C02F 1/22, publ. 08/20/2007, containing a rotating drum and a system for measuring its temperature. The drum is made in the form of a hollow cylinder, immersed one quarter in a container into which filtered seawater is supplied, while a cooling heat exchanger is located inside the drum at the level of immersion in water, the temperature of which is set by a thermoelectric battery. Heat from the hot junctions of the battery is removed using a heat pipe, in which the coolant circulates, which removes heat from the hot junctions and condenses in the heating heat exchanger. The outer surface of the drum using ribs is divided into areas in which freezing and then thawing of water occurs. A block of ice formed is released from the region formed by the adjacent ribs of the crank mechanism, while sea water and concentrated brine are fed into the tank and removed from it respectively through a counterflow heat exchanger.

This leads to a complication of the design, an increase in metal consumption and, as a consequence, an increase in weight. This installation cannot be used in domestic conditions.

Known water purifier for producing melt drinking water on an industrial scale according to French patent No. 2858607, IPC C02F 1/22, publ. 02/11/2005, consisting of a system for lifting and holding a certain volume of sea water and a cooling system having a number of elements arranged in a circle for gradually freezing water into a ring-shaped block that pushes the brine towards the center. The device has a heating system with a ring heating element for melting the obtained ice and the transition of water from solid to liquid, a collector for collecting desalinated water from melted ice.

The device is designed for desalination of water on an industrial scale, has large dimensions and weight, which makes it impossible to use it in everyday life.

The closest in technical essence and the achieved result is a prototype, is a water purifier according to Japan patent No. 5123668, IPC C02F 1/22, B01D 9/02, F25B 21/02, including a container with a lid and a conical bottom with a hole for draining water , a thermal module for freezing and melting ice, a container for collecting melt water and water with dissolved impurities and a high deuterium content, a control unit for the thermoelectric module and the water drain system. Pipelines are connected to the drain hole in the conical bottom of the tank for freezing and melting ice and are led out to the tanks, respectively, to collect clean melt water and water with dissolved impurities and a high deuterium content. Obtaining purified water is based on the principle that impurities are not contained in ice crystals.

However, this apparatus is intended for industrial purification of sea water, therefore, has large dimensions and weight. The thermoelectric element is installed on one side of the side surface of the tank, which increases the time of freezing water, since ice formed at the beginning of the process reduces the efficiency of its further formation. This arrangement of the thermoelectric element does not allow to collect water contaminated with impurities in the center of the tank, which reduces the quality of water purification from impurities and deuterium.

The objective of the invention is to provide an apparatus for producing drinking water, purified from harmful and toxic impurities with a reduced content of heavy hydrogen isotopes in it, having high efficiency, compactness and the possibility of use in domestic conditions.

The technical result to which the invention is directed is to reduce the time of the process of ice formation and its melting, as well as to increase the efficiency of heat removal from thermoelectric elements and improve the quality of water treatment.

To achieve the specified technical result in a water purification apparatus comprising a working tank with a conical bottom with a hole for draining water, a thermoelectric module for freezing water and melting ice, a tank for collecting purified water and a tank for collecting water with impurities and a high deuterium content, a control unit thermoelectric module and a water drainage system with drain pipes, each of which is installed above the tank for collecting purified water and a tank for collecting water with impurities and high content deuterium, according to the claims, the internal space of the working capacity is limited by a thermoelectric module sealed to a hydraulic distribution panel, which is the bottom of the working capacity, while the thermoelectric module contains several thermoelectric elements installed in a vacuum sealed cavity formed by the finned outer and inner walls of the thermoelectric module, and located on its upper part, on which there is a filler neck working e capacity, with a fan installed on it, and the drainage system includes a hydraulic distribution panel, which contains a valve, at least two flow distributors and a fine filter of water, interconnected by channels.

The technical result is achieved in that the hydraulic distribution panel can be made of a material with low thermal conductivity.

The apparatus is equipped with a power supply unit, an electronic control unit, including a control unit for valves and water flow distributors and connected to them to control the drainage of water in the channels of the hydraulic distribution panel, a temperature measuring unit connected to a temperature sensor installed inside the working tank, and a program machine connected to the control unit for the thermoelectric module, the temperature measuring unit and the control unit for the valve and flow distributors and the control panel with a display.

The specified set of features is significant, not known from the prior art and has an inventive step since the use of a thermoelectric module with a bottom from a hydraulic distribution panel as a working tank and the presence of ribs on the inner and outer walls of the thermoelectric module can increase the efficiency of thermoelectric elements and significantly reduce time to receive melt water. Vacuuming the cavity between the walls of the thermoelectric module enhances thermal insulation, which in turn increases the efficiency of the apparatus. The installation of thermoelectric elements on the upper part contributes to the formation of ice both from above and from the sides of the working tank, and the principle of convection of the liquid enhances the effect of ice formation. The proposed arrangement of thermocouples allows you to freeze water evenly in volume into a ring-shaped block, push the brine towards the center of the working tank and evenly melt the ice. The concentration of brine in the center of the tank improves the quality of water treatment.

The presence of a fan installed in the upper part of the thermoelectric module on the filler neck allows cooling the outer finned wall of the thermoelectric module, which acts as a radiator, uniformly and efficiently from all sides and to avoid local overheating of the device.

The use of a hydraulic distribution panel for draining water as the bottom of the working tank increases the thermal insulation of its lower part, reduces the dimensions of the apparatus, and the absence of hoses and pipelines provides greater reliability and ease of maintenance. The proposed drainage system provides the shortest way to drain the brine without getting on the fine filter. The capture of heavy water crystals on a fine filter, followed by removal into a water tank with impurities and a high deuterium content, improves the quality of water treatment.

The above objectives and advantages of the present invention will become more apparent by way of a detailed description with reference to the accompanying drawings, in which:

Figure 1 - General diagram of an apparatus for water purification,

figure 2 is a hydraulic diagram of the distribution panel of the apparatus for water purification.

The water purification apparatus includes a housing 1, in which a thermoelectric module 2 for freezing water and melting ice is placed, which in turn is hermetically connected to the hydraulic distribution panel 3, forms a working tank 4. The hydraulic distribution panel 3, the upper surface of which is made in the form of a cone , is the bottom of the working tank 4 with an opening for draining water 5. On the outer wall 6 of the thermoelectric module 2 there are ribs 7, and on the inner wall 8 of the ribs 9, facing the inside of the working tank 4. Ter the electric module 2 contains several thermoelectric elements 10 located in a vacuum hermetically sealed cavity between the outer 6 and the inner 8 walls of the thermoelectric module and installed on the upper part of the thermoelectric module 2. On the upper part of the thermoelectric module 2 there is a filler neck 11 on which the fan 12 is mounted, rotatable by an electric motor 13. The filler neck 11 of the working container 4 is closed by a plug 14. A container 15 is installed in the lower part of the apparatus for failure a melt of purified water and the container 16 for collecting water with impurities and elevated levels of deuterium. The hydraulic distribution panel 3 includes a hole 5 for draining the water, a valve 17 blocking the hole for draining the water, flow distributors 18, 19 that change the direction of the water flow during the process of draining the water. The flow distributor 18, depending on the position of its spool, directs the water flow either to the drain in the tank 16 for collecting water with impurities and a high deuterium content or to the fine filter 20. In the initial position, the flow distributor 18 passes the water flow into the tank 16. The flow distributor 19 directs the flow of water either into the tank 16 for collecting water with impurities and a high content of deuterium, or into the tank 15 for collecting thawed purified water. In the initial position, the flow distributor 19 passes the flow of water into the tank 16.

All elements of the hydraulic distribution panel 3 are connected by channels 21 and are made inside the housing of the hydraulic distribution panel 3. Drain pipes 22 and 23 are connected to channels 21 and installed above the tank 15 for collecting melt purified water and the tank 16 for collecting water with impurities and a high deuterium content, respectively.

In addition, in the housing 1 there is a power supply 24, an electronic control unit 25, including a thermoelectric module control unit 26 connected to thermoelectric elements 10, a control unit for controlling flow distributors 18, 19, valve 17 and connected to them and a temperature measuring unit 28 connected with a temperature sensor 29 installed in the working tank 4. The program machine 30 is connected to the thermoelectric module control unit 26, the valve and flow distributors control unit 27, and the temperature measurement unit 28. To the program machine 30 is connected to the control panel with a display 31.

Apparatus for water purification works as follows.

1. The device is connected to the network, the “NETWORK” lamp lights up on display 31.

2. Open the lid 14 and pour 1.5-2 liters of water into the working tank 4. The lid 14 is closed.

3. On the control panel, press the “ENABLE” button. When this button is pressed, voltage is applied to the electronic control unit 25 of the device and testing the readiness of the device for operation. In the event of malfunctions: the presence of water in the tank 16 for collecting water with impurities and a high deuterium content and the presence of water in the tank 15 for collecting melt purified water or the absence of water in the working tank 4, the corresponding information appears on the display 31, in this case, the apparatus cannot be started.

4. If there are no deviations indicated above and the display shows “READY” on the display 31, the water purifier is ready for operation.

In the future, the order and sequence of the process for water purification is determined by the corresponding program embedded in the software 30, by issuing the appropriate commands to the electronic control unit 25. Information about the process is monitored by the control unit and displayed on the display 31 of the control panel.

5. On the control panel with the display 31, the “START PROCESS” button is pressed, the thermoelectric module control unit 26 switches the thermoelectric elements 10 into cooling mode. The temperature measurement unit 28 is switched on by the electronic unit 25 and monitors the temperature values received from the temperature sensor 29. The process of ice formation starts in the working tank 4, ice builds up from the upper and side walls of the working tank 4 to its center and the temperature is kept in the working tank 4 within minus 4-5 ° C. The duration of this part of the process is 2-2.4 hours. The heat generated during the operation of the thermoelectric elements 10 is removed using fins 7, which perform the function of a radiator, blown by a fan 12, driven by a motor 13.

In the process of ice formation, impurities dissolved in water due to the fact that their solutions have a lower freezing point, are concentrated in water and are displaced by ice growing on the inner wall 8 with ribs 9 of the working tank 4 into the volume located in its center. Thus, the formation of "brine" - a concentrated solution of salts in a liquid state in the central region of the working tank 4. The freezing temperature of the "brine" is in the range of minus 6-7 ° C, and the temperature in the working tank 4 is maintained minus 4-5 ° C .

6. At the end of the stage of ice formation and the formation of "brine" in the Central region of the working capacity 4, the program machine 30 issues a command to the water discharge control unit 27, which opens the valve 17 for 2-3 minutes. During this time, the "brine" is drained through the drain hole 5 of the working tank 4, through the channels 21 through the flow distributor 18 and the pipe 23 into the tank 16. At the end of the drain, the valve 17 closes.

7. After draining the “brine”, the program machine 30 instructs the thermoelectric module control unit 26 to turn on the thermoelectric elements 10 in the heating mode. The result is an increase in the temperature of the ice and its melting, melt water is formed. The temperature of the obtained melt water is maintained within plus 1.5-2 ° C by turning on the thermoelectric elements 10 in thermostat mode.

The heavy water D ₂ O contained in the melt water has a freezing temperature of plus 3.8 ° C and while maintaining the temperature of the melt water within plus 1.5-2 ° C, the heavy water in its composition will be in the form of small ice crystals. This is necessary to remove it later by filtering.

The process of complete melting of ice and the establishment of its temperature in the entire volume within plus 1.5-2 ° C lasts for 0.8-1.2 hours.

8. At the end of the stage of obtaining melt water with ice crystals of heavy water in the working tank 4, the inscription “PROCESS IS FINISHED” is displayed on the display 31 of the control panel and an audible signal sounds for 10 seconds.

9. Drain melt water is produced by pressing the button “MELT WATER” or automatically, after 30 minutes after the end of the process. Press the button "MELT WATER", the software 30 sends a command to the drainage control unit 27, which opens the valve 17 and the flow distributor 18 directs the melt water flow through the channels 21 to the filter element 20 and then through the flow distributor 19 to the receiving tank 16 for 10 Seconds. During this time, the filter element 20 is washed out from the residues of heavy water D ₂ O, which is in a liquid state, filtered in the previous cycle of obtaining melt water. Melt water, passing through the filter element 20, cools it, the crystals of heavy water cease to melt and are filtered by a filter 20. After 10 seconds, the program machine 30 sends a command to the drain control unit 27, the flow distributor 19 through channels 21 directs the flow of melt water into the tank 15.

10. The water discharge control unit 27 closes the valve 17, the control unit 26 of the thermoelectric module 2 turns off the thermoelectric elements 10, the electronic control unit turns off the temperature measurement unit 28 and turns off itself.

11. Automatic drainage of melt water is carried out if, within 30 minutes after notification that the process is completed, the melt water has not been drained. When activating the drain of melt water in automatic mode, the program machine 30 after 30 minutes after the end of the process issues a command to block 27 to drain the melt water. Automatic drain of melt water into the receiving tank 16 occurs after the electronic control unit 25 receives a signal from the software 30. After that, the drain control unit 27 opens the valve 17, the distributor 18 directs the flow of melt water to the filter 20, the washing mode of the filter 20 is performed, and the water is drained with increased deuterium content in the tank 16, after which melt water begins to drain and the melt water distributor 19 is sent to the tank 15. Since melt water loses its properties over time, the control panel display 31 I, at the end of the drain, information about the time of melt water drainage is reflected for the possibility of evaluating its suitability and the control system of the device is turned off.

12. Press the “NETWORK” button and turn off the device.

A new start of the process is possible only manually by pressing the “ENABLE” button

The total time course of the process of obtaining melt water is 2.8-3.6 hours.

Thus, the proposed apparatus for water purification reduces the time to obtain clean melt water in comparison with the known analogues, improves the quality of water purification from impurities and deuterium dissolved in it, has small dimensions and weight, is convenient in operation, since the entire process of water purification is automated.

The implementation of the invention allows to achieve the claimed technical result, and the proposed technical solution has wide consumer demand and industrial application.

Claims (3)

1. A water purifier, including a working tank with a conical bottom with an opening for draining water, a thermoelectric module for freezing water and melting ice, a tank for collecting purified water and a tank for collecting water with impurities and a high content of deuterium, a control unit for the thermoelectric module and a water drainage system with drain pipes, each of which is installed above a container for collecting purified water and a tank for collecting water with impurities and a high content of deuterium, characterized in that the internal space The capacity of the working vessel is limited by a thermoelectric module hermetically connected to the hydraulic distribution panel, which is the bottom of the working vessel, while the thermoelectric module contains several thermoelectric elements installed in a vacuum sealed cavity formed by the finned outer and inner walls of the thermoelectric module and located on its upper part, on which there is a filler neck of a working tank with a fan installed on it, and a drain system VK yuchaet hydraulic distribution panel which comprises a valve, at least two water flow distributor, and the water purification filter of thin, interconnected channels. 2. The apparatus according to claim 1, characterized in that the hydraulic distribution panel can be made of a material with low thermal conductivity. 3. The apparatus according to claim 1, characterized in that it is equipped with a power supply, an electronic control unit, including a control unit for valves and water flow distributors, connected to them to control the discharge of water in the channels of the hydraulic distribution panel, a temperature measuring unit connected to the sensor temperature installed inside the working tank, and a program machine connected to the control unit of the thermoelectric module, the temperature measurement unit and the control unit of the valve and flow distributors and PU control unit with display.

Images