EA025716B1 - Method for water purification by crystallization method and heat exchange reservoir (embodiments) therefor - Google Patents

Abstract

The invention relates to methods and means for water purification by a crystallization method and can be used in everyday life, food industry and medicine. The technical result of the claimed invention provides the development of such method and a heat-exchange reservoir for water purification by a crystallization method, which ensure water quality improvement and shortening time for water purification. The method for water purification comprises filling the heat-exchange reservoir with water for purification, cooling and its further freezing in said reservoir at a temperature higher than a temperature of crystallization of a liquid concentrate of organic and inorganic admixtures staying in water for a period of time sufficient for crystallysing pure water as an ice layer and forming the liquid concentrate of organic and inorganic admixtures, discharging said liquid concentrate, melting ice at a positive temperature to its unfreezing with subsequent discharging purified melt water. Water before purification is shaped in the form of a flat or annular layer by filling with water the heat-exchange reservoir, the inner volume of which is implemented as a a flat or annular slit-like cavity. The heat-exchange reservoir for water purification (five embodiments) is made of a heat-conducting material and has walls forming flat vertical or horizontal or inclined slit-like cavity, or annular conical or cylindrical slit-like cavity.

Description

(57) The invention relates to methods and means for water purification by recrystallization and can be used in everyday life, food industry and medicine. The technical result of the claimed invention is the creation of such a method and a heat exchange tank for water purification by recrystallization, which provide improved quality and reduced time for water purification. The method of water purification involves filling a heat-exchange tank with water for purification, cooling, and its subsequent freezing in a tank at a temperature above the crystallization temperature of a liquid concentrate of organic and inorganic impurities in water for a time sufficient to crystallize pure water in the form of an ice layer and form a liquid concentrate organic and inorganic impurities; discharge of said liquid concentrate; melting of ice at a positive temperature until it is thawed, followed by discharge of purified melt water. Water before cleaning is formed in the form of a layer, flat or closed in a ring, by filling with water a heat exchange capacity, the internal volume of which is made in the form of a slit cavity, flat or closed in a ring. The heat exchange capacity for water purification (five options) is made of a thermally conductive material and has walls forming a flat vertical, or horizontal, or inclined slot cavity or an annular conical or cylindrical slot cavity.

025716 B1

The invention relates to methods and means for water purification by recrystallization, improving its biological properties by removing soluble organic and inorganic substances and gases, and can be used in everyday life, food industry and medicine.

A known method of water purification by recrystallization consists in freezing it at a temperature slightly below 0 ° C (for example, from -2 to -6 ° C) with the formation of ice crystals, from which at the crystallization front, most of the impurities are displaced in the form of a liquid concentrate of organic and inorganic impurities that do not freeze at these temperatures due to the high salt content. The liquid concentrate of impurities is removed, and a clean ingot of ice crystals is melted at a positive temperature to obtain purified melt water.

There is a method of improving the quality of drinking water by freezing, consisting in its freezing, crushing of ice and its melting. Freezing water is carried out up to 70-90% of its volume, melting ice is carried out by thermal insulation of its lateral and lower surfaces to form 30-55% of the volume of melt runoff with its subsequent removal (RF patent No. 2077160, IPC С02Р 1/22, publ. 04/10/1997).

There are also known methods for producing high-purity drinking water with biologically active properties, in which, in addition to a number of stages for water purification, there is a stage of freezing water (USSR patent No. 1799367, IPC С02Р 9/00, 1991, RF patent № 2010772, IPC С02Р 9 / 00, 1992, RF patent No. 2031085, IPC С02Р 9/00, 1992).

The disadvantages of the above methods include the duration of the cycle and the low degree of water purification, due to the lack of optimally selected geometry of the heat transfer tank and the modes of freezing and thawing of water.

A known water purifier for producing thawed drinking water, which includes a zone of water freezing with an annular freezer, a zone of displacing impurities from the ice front and a concentration of impurities in the form of a brine, and a zone of transition of water from solid to liquid with an annular heating element (successively located in one longitudinal vessel) RF patent No. 2312817, IPC С02Р 1/22, publ. 20.12.2007). The water purifier has separate nozzles for removing impurities in the form of brine and melt drinking water, located in the lower part of the vessel, and is additionally equipped with a drive unit for moving the frozen water rod mounted behind the freezer and an uncoupling device located in the center of the frozen water rod and made in the form of a pipe . The uncoupling device has an annular cutting part at the inlet, and an expanding profile at the outlet, forming an outlet pipe for removing impurities in the form of a brine.

However, this device provides insufficient quality of water purification, it is difficult to constructively and does not have optimally selected geometry of the heat exchange capacity.

A water purifier is known for producing melt drinking water on an industrial scale from sea water, which includes a water freezing zone with an annular freezer, a zone for displacing impurities from the ice front and a concentration of impurities in the form of brine and a zone of transition of solid state water to sequentially located in one longitudinal vessel. liquid with an annular heating element, separate nozzles for removing impurities in the form of brine and melt drinking water, located in the lower part of the vessel (French patent No. 2858607, IPC С02Р 1/22, published on 02/11/2005).

However, this device provides insufficient quality of water purification from impurities and has a long cleaning cycle. In addition, the device has large dimensions of the freezer and the total weight of the unit, designed for desalination of water on an industrial scale, which makes it difficult to use in domestic and office conditions.

A known method of purifying water in a tank (RF patent No. 2274607, IPC С02Р 1/22, publ. 04/20/2006), including heat removal using a heat exchanger located in the tank, located in the upper part of the tank, by about 1 / 3-2 / 3 the height of the liquid column from its upper layers at an equidistant distance from the center and the side surfaces of the tank, providing a temperature difference in the range from plus 1 to minus 1 ° C, which determines the process of local-volume crystallization with continuous gradual multi-stage freezing of ice crystals around the heat exchanger. For water purification, continuous gradual multi-stage freezing of ice crystals around the heat exchanger by mass of not more than 50-70% of the total mass of the source water is carried out, drainage from the reservoir of unfrozen water with impurities, complete thawing of ice and repeated partial freezing to small volumes within 3-7% from its mass and drain of melt water for its consumption with simultaneous filtration through a fine filter. The water with impurities is drained and the melt water is thawed after thawing in sections of different height and different channels, while the water with impurities is drained through a channel made at the lowest bottom of the tank bottom, and the melt water is drained through a channel located on 0.5-2 cm above the bottom of the tank.

The ice is thawed in two stages, while at the first stage up to 90-95% of the ice from its total volume, containing a small percentage of heavy hydrogen isotopes, is thawed, and at the second stage, ice remaining on the heat exchanger from the initial crystallization and containing a large percentage of heavy isotopes is thawed hydrogen, deuterium and tritium. Moreover, the ice is thawed by 1,025,716 by gradually increasing the temperature to the state of vaporization and convection movement of the vapor layers heated to a temperature of no higher than 40-80 ° С. Ice is thawed by heating a shielded cable wound around the side of the container.

A known installation for water purification (RF patent No. 2274607, IPC С02Р 1/22, publ. 04/20/2006), containing a tank for untreated water, a heat exchanger installed in the tank to remove heat and freeze ice, means for heating and thawing ice, freezer unit with its cooling system, a pipeline with a valve for draining water with impurities, a 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 approximately 1 / 3-2 / 3 of the tank height on a distance of 2-5 cm relative to the upper base of the container and symmetrically relative to its lateral surface with a gap providing 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, a pipeline for draining water with impurities installed in the cross section of the conical bottom of the tank, the pipeline for draining the melt water is installed below 0.5-2 cm above the conical bottom of the tank. The installation is equipped with a fine filter cleaning with a drain pipe with a valve and a pump for circulating and pumping melt water under pressure through a fine filter and a control unit in manual or automatic mode.

The closest analogue (prototype) of the method is a method of water purification (RF patent No. 2393996, IPC С02Р 1/22, publ. 07/10/2010), including the first cooling of water in a thermostatically controlled working tank and its subsequent gradual freezing at a temperature above the crystallization temperature of liquid brine with organic and inorganic impurities for a time sufficient for the complete crystallization of pure water with impurities of heavy water and the formation of a liquid brine with organic and inorganic impurities, discharge of the specified brine, n heating the mass of ice with a gradual increase in temperature to values exceeding the crystallization temperature of heavy water, and holding the ice at the indicated temperature until it is fully thawed, re-cooling the water to the crystallization temperature of heavy water and holding it at the indicated temperature until the heavy water crystallizes and the finished product is drained in the form of purified melt water into a consumer tank while filtering it through a fine filter. Heating, cooling, water crystallization and ice melting are carried out uniformly outside the working tank by means of thermoelectric elements in contact with its thermally conductive walls in automatic mode, the temperature of the medium inside the working tank during the first cooling of the water is reduced to a value not lower than minus 3 ° С with the rate of change of the medium temperature in working capacity equal to the interval of values of 0.1-0.3 ° C / min, the cycle time of the first crystallization of water is calculated automatically by software from the moment of its phases transition, determined by increasing the temperature of the medium at the side wall of the working vessel by at least 0.5 ° C, the temperature of the medium inside the working vessel during the first crystallization of water is reduced to a value not lower than -4 ° C with a rate of change of the temperature of the medium in the working vessel equal to the range of values 0.05-0.1 ° C / min, the temperature of the medium inside the working tank when the ice melts until it is completely melted after the brine is drained, is raised to a value not higher than 10 ° C with a rate of change of the temperature of the medium in the working tank equal to the range of 0, 16-0 , 18 ° C / min, and the temperature of the medium inside the working tank during repeated cooling of the water and crystallization of heavy water is reduced to a value not lower than 2 ° C with a rate of change of the temperature of the medium in the working tank equal to the range of 0.1-0.3 ° C / min

The closest analogue (prototype) of the device is a water purifier (RF patent No. 2393996, IPC С02Р 1/22, publ. 07/10/2010), which includes a housing in which a thermostatic working container with a lid and an inclined bottom with an opening for draining water are placed , a means for freezing water and melting ice with a control unit, a consumer container for receiving melt purified water and a container for receiving water with impurities and a high content of deuterium, pipelines with a means) for controlling the discharge of water in the latter, connected to the drain the open hole of the inclined bottom of the working tank for freezing water and melting ice, the drain pipes of which are installed respectively above the consumer tank for receiving purified melt water and a tank for receiving water with impurities and a high deuterium content. Means for freezing water and melting ice are made in the form of a thermoelectric module containing several thermoelectric elements located outside on the side wall of the working tank for freezing water and melting ice, the means for controlling the discharge of water in pipelines contains four normally closed valves installed in pairs in the last, and these pipelines for draining water are additionally interconnected by a pipeline with a fine filter of water, the connection sections of which with pipelines for I draining means disposed between the valve for controlling the discharge of water in said pipes (9 and 10). The working capacity is rectangular in shape, the ratio of its height to length and width is respectively not less than 1.0 and not more than 1.2.

However, in the above analogs and prototype (methods and devices), the process of water purification takes a long time, since the mass of freezing ice in known tank designs

- 2 025716 for water purification with non-optimal geometry (cylindrical, cubic or close to them) is formed by a thick layer (ingot) not only on the inner surface of the cooled walls of the tank, but also in the liquid volume, as a result of which the process of energy transfer from the surface of the tank to the volume the water being purified slows in proportion to the increase in the thickness of the freezing layer of ice. In addition, with an increase in the thickness of the ice layer, the intensity of the process of displacing impurities at the ice-water frontier boundary decreases.

The technical result of the claimed invention is the creation of such a method and a heat exchange tank for water purification by recrystallization, which provide improved quality and reduced time for water purification.

The specified technical result is achieved by the fact that in the method of water purification by recrystallization, which includes filling the heat exchange tank with water for purification, cooling and its subsequent freezing in the tank at a temperature above the crystallization temperature of the liquid concentrate of organic and inorganic impurities in water for a time sufficient for crystallization of pure water in the form of an ice layer and the formation of a liquid concentrate of organic and inorganic impurities, the discharge of the specified liquid concentrate, melting ice at a positive temperature before thawing it, followed by draining of purified melt water, moreover, cooling, crystallization of water and melting of ice by heating are carried out outside the heat exchange tank by means of thermocouples in contact with its heat-conducting walls to cool and heat them; according to the invention, water is formed before cleaning in the form of a layer, flat or closed in a ring, by filling with water a heat-exchange capacity, the internal volume of which is made in the form of a plane or closed in ring of the slit cavity, and the melting of ice under the influence of positive temperature and the drain of melt water are carried out simultaneously, and melt water is poured continuously or periodically into a thermostatically controlled storage tank for its subsequent storage at the melting temperature of ice.

The specified technical result is also achieved by the fact that in a heat exchange tank for water purification by recrystallization to implement the method according to p. 1 (the first option), made of a thermally conductive material and having a drain pipe in the bottom and thermocouples located on its outer surface for cooling and heating the walls containers, according to the invention it is equipped with a node for tilting the tanks for water purification at an angle to a vertical plane and includes two plane-parallel vertically oriented side walls Nk, between which there is a gap for the formation of a flat slit cavity. In addition, the heat exchange tank is equipped with a node for tilting the tank for water purification at an angle to a vertical plane.

The specified technical result is also achieved by the fact that in a heat exchange tank for water purification by recrystallization to implement the method according to p. 1 (second option), made of thermally conductive material and having a drain pipe in the bottom and thermocouples located on its outer surface for cooling and heating the walls capacity, according to the invention, it is made in the form of a cuvette with a lid, between the bottom and the lid of which is formed a flat slot cavity, and the bottom of the cuvette is located at an angle to the horizontal flatness, under which thermoelements for cooling and heating the walls of the bottom are located on a part of its surface, and a drain pipe is located at the lower edge of the bottom, free of thermocouples.

The specified technical result is also achieved by the fact that in a heat exchange tank for water purification by recrystallization method (third option), made of thermally conductive material and having a drain pipe in the bottom and thermocouples located on its outer surface for cooling and heating the walls of the tank, according to the invention it is made in in the form of a truncated hollow cone, vertically oriented with a bell up and having a lid, the container provided with an insert made in the form of a truncated cone and located inside the tank with a gap relative to its walls and bottom with the formation of an annular slotted cavity. In addition, the insert of the heat exchange capacity is attached end to the cover of the specified capacity.

Thermoelements can be made in the form of a thermoelectric battery operating in the cooling or heating mode, or in the form of an evaporating tube of a refrigeration unit (thermoelements of cooling) and a tubular electric heater (thermoelectric elements of heating).

Reducing the time of water purification is provided due to the fact that in the slotted cavity of the tank, water crystallizes in the form of an ice layer of small thickness on one of the side walls of the tank for a short time due to intensive heat exchange between the cooled surface of the tank wall through a thin layer of ice with water, and a significant the volume of this pure ice is formed due to the developed (large) area of the side surface of the container having an internal volume in the form of a flat or annular gap. It is known that for the same volume the smallest surface area will have a capacity in the form of a ball. The surface area of a cubic capacity of the same volume increases approximately 1.24 times. The surface area of the inventive heat transfer capacity of the same volume with a flat or annular slotted internal volume can be increased from 2 to 10 times. In this regard, the absorption of heat in the cooled water can be increased several times, as a result of which the time of freezing and purification of water is reduced.

- 3 025716

The specific heat flux c.] Is determined by the formula

where k is the coefficient of thermal conductivity of ice, W / (m-K);

ΔΤ - temperature difference when passing through an ice layer, K;

B is the thickness of the ice layer, m

It can be seen from the above formula that the smaller the thickness (b) of the ice layer, the greater the specific heat flux is transferred to the cooled water and the faster the water crystallizes, thereby reducing the time for water purification. Improving the quality of water treatment is achieved due to wall crystallization of the purified water. The purest ice crystallizes in a thin layer on the chilled wall of the water tank. With an increase in the thickness of the ice layer, the process of ice formation slows down, and its purity and physicochemical characteristics decrease (the pH decreases and the redox potential - ORP increases).

The quality of pure melt water is also improved due to the fact that the process of melting ice is combined with the discharge of water into a thermostatically controlled storage tank. At the same time, the melt water during ice melting is practically not affected by the increased temperature of the walls of the water treatment tank, which reduces the biological activity of melt water and destroys its structure.

The invention is illustrated by the following graphic materials.

In FIG. 1-3 shows a diagram of a heat exchange capacity (first option) with a vertical arrangement of its slot cavity, respectively, front view, side view and general view.

In FIG. 4 shows a diagram of a first embodiment of a heat exchange capacity (side view) provided with a tilt assembly thereof at an angle to a vertical plane.

In FIG. 5 is a diagram of a second embodiment of a heat exchange capacity with a horizontal arrangement of its slotted cavity.

In FIG. 6 shows a diagram of a third embodiment of a heat exchange capacity with an arrangement of its slot cavity at an angle to the horizontal plane.

In FIG. 7 is a diagram of a fourth embodiment of a heat transfer vessel with an annular slot cavity in the form of a truncated cone.

In FIG. 8 is a diagram of a fifth embodiment of a heat transfer vessel with an annular cylindrical slot cavity.

In FIG. 9 is the same, section AA.

In FIG. 10 shows a diagram of an apparatus for water purification by recrystallization, which uses the inventive heat transfer capacity (five options).

The heat exchange tank 1 for water purification by recrystallization (the first option, Fig. 1-3) includes two plane-parallel vertically oriented side walls 2 and 3, between which there is a gap for the formation of a flat slot cavity 4. The tank 1 is made of thermally conductive material and has a bottom 5 drain pipe 6 and located on the outer surface of its wall 2 or 3 thermocouples 7 for cooling and thermocouples 8 for heating the wall 3 of the tank

1. To reduce heat loss, the tank 1 can be insulated externally with a layer of thermal insulation (not shown in the drawings).

In addition, the heat transfer tank 1 (Fig. 4) can be equipped with a node 9 for tilting the tank 1 for water purification at an angle to a vertical plane with a position lock.

The heat-exchange capacity 10 (Fig. 5) for water purification by recrystallization (second option) is made in the form of a horizontally oriented cell 11 with a cover 12, between the bottom 13 and cover 12 of which a flat slot cavity 14 is formed. The tank 10 is made of thermally conductive material and has bottom 13 drain pipe 15, cooling thermocouples 16 and heating thermocouples 17 located on the cover 12 of the cuvette 11. Under the bottom 13 are placed thermocouples 18 for heating the walls of the bottom 13. To reduce heat loss, the tank 10 can be insulated from the outside loem thermal insulation (not shown).

The heat-exchange tank 19 for water purification by recrystallization (the third option) is made in the form of a cell 20 with a cover 21, between the bottom 22 and the cover 21 of which a slot cavity 23 is formed. The tank 19 is made of thermally conductive material, the bottom 22 of which is located at an angle to the horizontal plane, under which thermoelements 24 for cooling and thermoelements 25 for heating the walls of the bottom 22 are located on the upper part of its surface. A drain pipe 26 is located at the lower edge of the bottom 22, free of thermoelements 24 and 25. To reduce the heat ter tank 19 may be insulated from the outside layer of thermal insulation (not shown).

The heat exchange tank 27 (Fig. 7) for water purification by recrystallization (the fourth option) is made of a heat-conducting material in the form of a truncated hollow cone 28 vertically oriented with a bell up, has a lid 29 and is provided with an insert 30 made in the form of a truncated cone and located inside the tank 27 with a gap relative to its walls and bottom 31 with the formation of an annular slot cavity 32. The insert 30 is attached with an end (the largest base) to the cover 29 of the indicated container 27. A drain pipe 33 is installed in the bottom 31, and zhnoy 4 025716 tion conical surface of the container 27 has thermocouples 34 for cooling and thermocouples 35 for heating the walls of said container. To reduce heat loss, the container 27 may be insulated externally with a thermal insulation layer 36.

The heat-exchange tank 37 for water purification by recrystallization (the fifth option) is made of thermally conductive material in the form of a vertically oriented hollow cylinder 38 and has a lid 39. The tank 37 is equipped with an insert 40 made in the form of a cylinder and located inside the tank 37 with a gap relative to its walls and bottom 41 with the formation of an annular slot cavity 42. A drain pipe 43 is installed in the bottom 41 of the container 37. Thermocouples 44 for cooling and thermocouples 45 are located on the outer cylindrical surface of the tank 37 and the walls of the specified capacity. To reduce heat loss, the tank 37 can be insulated externally with a layer of thermal insulation (not shown in the drawings). In addition, the insert 40 is installed in the specified container 37 on a vertical rack 46.

The apparatus for water purification by recrystallization (Fig. 10) contains a heat exchange tank 47 for water purification, a means 48 for freezing water with a cooling thermocouple 49 (evaporation tube), a means 50 for melting ice with an electric heating thermocouple 51, a filtration and water supply unit 52 tank 47 through pipeline 53, unit 54 for draining purified water and contaminant from tank 47 and a microprocessor control unit (MP) 55 connected to unit 52 for filtering and supplying water to tank 47 and through the control board 56 with you 48 and 50 for freezing water and melting ice and a unit 54 for draining clean and contaminated water. Capacity 47 is one of the five claimed designs of containers 1 or 10, or 19, or 27, or 37, shown respectively in FIG. 1-9. The cooling thermocouple 49 (evaporator tube) of the water freezing means 48 and the heating thermocouple 51 of the ice melting means 50 are located on the outer side surface of the tank 47 (options 1, 4 and 5 of its implementation), or on the lid of the tank 47 (embodiment 2), or under the bottom of the tank 47 (option 3 run).

The control MP 55 is connected to the water supply pump 57 for cleaning the node 52 and the solenoid valve 58 to supply water to the tank 47, and through the control board 56, to the solenoid valves 59 and 60 of the node 53 for draining the purified water and the contaminant concentrate, respectively. The tank 47 is connected by a pipe 61 with a solenoid valve 59 with a thermostatically controlled storage tank 62 for clean melt water.

Means 48 for freezing water contains a compressor and a condenser connected to a thermocouple 49 (evaporator tube with freon). In addition, the control board 56 is connected to a temperature sensor 63 mounted outside the bottom of the tank 47.

Description of the method of water purification.

The method of water purification by recrystallization is carried out by, for example, the apparatus shown in FIG. 10. In a heat transfer tank 47 with a flat or annular slotted cavity with a volume of, for example, 8 l, pour 7 l of tap water, which takes the form of a flat or annular layer. All processes: cooling, water crystallization and ice melting by heating, are carried out outside of the working tank 47 by means of a heat-exchange tank 47 that is in contact with its heat-conducting wall (options 1, 4 and 5 of the heat-exchange tank 47), or by a heat-conducting cover (option 2 of the heat-exchange tank design 47), or thermal bottom (option 3 of the design of the tank 47) of the cooling thermoelements 49 and heating thermoelements 51 in the automatic mode by means of the MP control 55, the control board 56 and the sequence operation algorithm (program) water treatment plants. When the refrigeration unit is switched on to the cooling mode of the thermocouples 49 (evaporator tube), water is cooled through the heat-conducting wall (or its cover or bottom) of the tank 47. The temperature of the medium inside the heat-exchange tank 47 when cooling water is reduced to a value not lower - (3-4) ° With the rate of change of the temperature of the medium in the tank 47 is equal to, for example, the range of values of 0.1-0.3 ° C / min. Next, the process of near-wall crystallization of water is carried out. Using a temperature sensor 63 attached to the bottom surface of the tank 47, the cycle time of water crystallization in the automatic mode is calculated by software from the moment of its phase transition, determined by the spontaneous increase in the temperature of the water in the tank 47 by at least 0.5 ° C. The temperature of the water inside the tank 47 during crystallization of water is reduced to a value not lower than -4.0 ° C (temperature above the crystallization temperature of a liquid concentrate with organic and inorganic impurities) with a rate of change of the temperature of the medium in the working tank 47 equal, for example, to the range of 0.05 -0.1 ° C / min. Over time (about 180 min), complete crystallization of pure water is achieved in the form of a flat or annular layer of wall ice near the wall, or the lid, or the bottom of the tank 47, where cooling elements 49 are located and the formation of a liquid concentrate (brine) with organic and inorganic impurities ( depending on options 1-5 of the design of the tank 47, Fig. 1-9). Within a few minutes, a liquid impurity concentrate from 1200 to 2200 ml in volume is drained into the sewer when the electrovalve 60 is turned on. The ice remaining in the tank 47 is melted by turning off the cooling thermocouples 49 and turning on the heating thermocouples 51. The temperature of the wall of the tank 47, or its cover, or bottom when the ice melts until it is completely melted after the impurity concentrate is drained, is increased to 10-15 ° C. Melting of ice mass is carried out for about 60 minutes until it is completely thawed. Simultaneously with the beginning of ice melting, melt water is continuously or periodically (portioned every 5-7 minutes) into thermostated consumer tank 62 by automatically turning on the electrovalve 59. In this case, melt water practically does not come into contact with the heated cylinder wall 8 of tank 1, due to which the melt water temperature is maintained both in the tank 1 and in the thermostatically controlled consumer tank 16 at about 0-2 ° C, which preserves its biologically active properties for a longer time.

The full cycle of obtaining the finished product in the form of purified melt water does not exceed 240 minutes. The content of pure melt water is at least 66-80 vol.% Of its initial volume with a decrease in the total content of inorganic impurities by at least 2.5 times.

A feature of the method of water purification in the heat exchange tank 1 (option 1, Fig. 1-3) is that its walls 2 and 3 and the slot cavity 4 formed by them are oriented vertically (located in a vertical plane) or at a certain angle of inclination to the specified plane (Fig. 4), which allows you to compactly place several such containers 1 in one device and form a flat vertical (or close to it) layer of water for cleaning. In the process of cooling the wall 2 of the tank 1 to a temperature of (3-4) ° C due to contact with thermocouples 7 adjacent to the specified wall 2, the water layer is rapidly cooled (within 3-5 minutes) and a flat vertical front of water crystallization is formed. Water in a narrow slotted cavity 4 does not mix in volume due to a significant decrease in convective flows, as a result of which an ice layer forms faster on wall 2. Unit 9 (Fig. 4) allows you to tilt walls 2 and 3 of tank 1 by 6-9 ° relative to the vertical plane, which provides better contact with the inner surface of the wall 2 of a flat layer of ice during its melting during heat transfer from thermocouples 8, which reduces the time it takes to receive purified melt water.

A feature of the method of water purification in the heat exchange tank 10 (option 2, Fig. 5) is that in the indicated tank 10 a horizontal flat layer of water is formed in the slot cavity 14 between the surfaces of the lid 12 and the bottom 13, and the water is cooled and frozen from top to bottom when the lid 12 is cooled by thermoelements 16. A flat horizontal crystallization front is formed, directed from top to bottom in the same direction as the gravitational force, which contributes to the deposition of impurity particles, as a result of which the quality of water treatment is t of impurities increases compared with other variants of the proposed method. After the liquid concentrate of impurities is drained from the tank 10 through the nozzle 15, the flat ice layer is melted by heat first from the thermocouples 17 located on the cover 12, and after the ice layer settles on the bottom 13, it is melted by thermocouples 18.

A feature of the method of water purification in the heat exchange tank 19 (option 3, Fig. 6) is that in the indicated tank 19 a flat layer of water is formed in the slot cavity 23 between the surfaces of the cover 21 and the inclined bottom 22. Water is cooled and frozen under cooling the upper part of the tank 22 inclined to the horizon 22 of the tank 19 with thermocouples 24. A flat crystallization front is formed at an angle to the horizon, directed from the bottom up. During crystallization, a liquid impurity concentrate is formed at the top and in the lower part of the inclined bottom 22. After the liquid concentrate of impurities is drained from the tank 19 through the nozzle 26, a flat ice layer frozen in the upper part of the bottom 22 is melted under the action of heat from thermoelements 25 located under bottom 22.

A feature of the method of water purification in the heat exchange tank 27 (option 4, Fig. 7) is that in the indicated tank 27 an annular layer of water is formed in the slot cavity 32 formed between the walls of the hollow cone 28 and the conical insert 30 located therein. In the process cooling the wall of the hollow cone 28 of the tank 27 to a temperature of (3-4) ° C due to contact with thermocouples 34 adjacent to the outer surface of the wall of the cone 28, the water layer cools rapidly (within 3-5 minutes) and an annular crystallization front forms water directed to the side of the conical insert 30. Water in the narrow annular slit cavity 32 does not mix in volume due to a significant decrease in convective flows, as a result of which the ice layer forms on the inner surface of the wall of the hollow cone 28. After the liquid concentrate of impurities is drained through the pipe 33, the annular layer ice is melted due to the contact of the wall of the hollow cone 28 with the heating thermocouple 35. The location of the hollow cone 28 with the bell upward allows tight contact with the annular layer of ice throughout the process e of melting.

A feature of the method of water purification in the heat exchange tank 37 (option 5, Fig. 8, 9) is that in the indicated tank 37 an annular layer of water is formed in the slot cavity 42 formed between the walls of the hollow cylinder 38 and the cylindrical insert 40 located therein. In the process of cooling the wall of the hollow cylinder 38 of the tank 37 to a temperature of (3-4) ° C due to contact with thermocouples 44 adjacent to the outer surface of the wall of the cylinder 38, the water layer is rapidly cooled (within 3-5 min) and formed crystallization front s directed towards the cylindrical insert 40. The water in the narrow annular slotted cavity 42 is not mixed in the volume due to a substantial reduction in the convective flow, thereby more quickly formed layer of ice on the inner wall surface of the hollow cylinder 38. After draining the liquid concentrate

- 6 025716 impurities through the pipe 43, the annular layer of ice is melted due to the contact of the wall of the hollow cone 38 with the heating thermocouple 45.

Apparatus for water purification by recrystallization works as follows.

The microprocessor control panel 55 is turned on, from which the pump 57 is started to supply water for cleaning. Water enters the filtration unit 52 through a pipe 53, is cleaned of mechanical impurities, and when the solenoid valve 58 is turned on, it fills the heat transfer tank 47. Automatically, the control unit 55 turns on the cooling unit 48 via the board 56. The water in the tank 47 is gradually cooled through its heat-conducting wall (Fig. . 1-4, 7-9), or the cover (Fig. 5), or the bottom (Fig. 6) with its subsequent freezing. The freezing process with the formation of clean wall ice lasts about 2 hours and is controlled by the temperature sensor 63, the data from which the board 56 receives on the control MP 55. After the formation of the clean wall layer of ice, the control board 56 turns on the solenoid valve 60 and unfrozen liquid concentrate with impurities, t .e. water with a high salt content (brine) is discharged into the sewer. Next, the control board 56 turns off the cooling means 48 and turns on the heating means 50 for melting the ice, the thermocouple 51 of which is heated to a temperature of about 15 ° C, which corresponds to natural conditions. In this case, pure ice melts. When the ice layer melts, the control board 56 turns on the solenoid valve 59 and melt water is continuously discharged into the thermostatically controlled storage tank 62. The solenoid valve 59 can be switched on periodically every 5-7 minutes, and the melt water flows into the tank 62 in portions. water practically does not come into contact with the heated walls of the tank 47, due to which the temperature of the melt water is maintained both in the tank 47 and in the thermostatically controlled storage tank 62.

Claims (5)

CLAIM 1. A method of purifying water by recrystallization, comprising filling a heat exchange tank with water for purification; cooling and its subsequent freezing in the indicated container at a temperature above the crystallization temperature of the liquid concentrate of organic and inorganic impurities in water for a time sufficient to crystallize pure water in the form of an ice layer and the formation of a liquid concentrate of organic and inorganic impurities; discharge of said liquid concentrate; ice is melted at a positive temperature until it is thawed, followed by discharge of purified melt water, moreover, cooling, crystallization of water and melting of ice by heating are carried out outside the heat exchange tank by means of thermocouples in contact with its heat-conducting walls for cooling and heating, characterized in that the water is formed before cleaning in the form of a layer, flat or closed in a ring, by filling a heat-exchange capacity with water, the internal volume of which is made in the form of a slot or a plane closed in a ring th cavity, and the melting of ice under the influence of positive temperature and the drain of melt water are carried out simultaneously, and melt water is drained continuously or periodically into a thermostatically controlled storage tank for its subsequent storage at the melting temperature of ice. 2. A heat-exchange tank for water purification by recrystallization for implementing the method according to claim 1, made of a heat-conducting material and having a drain pipe in the bottom and thermocouples located on its outer surface for cooling and heating the walls of the tank, characterized in that it is equipped with a node for tilting the tank for water purification at an angle to a vertical plane and includes two plane-parallel vertically oriented side walls, between which there is a gap for the formation of a flat slotted cavity. 3. The heat exchange tank for water purification by recrystallization for implementing the method according to claim 1, made of a thermally conductive material and having a drain pipe in the bottom and thermoelements located on its outer surface for cooling and heating the tank, characterized in that it is made in the form of a cuvette with a lid , between the bottom and the lid of which a flat slot cavity is formed, the bottom of the cell being located at an angle to the horizontal plane, under which thermocouples of cooling and heating are placed on a part of its surface a roar of the bottom walls, and a drain pipe is located at the lower edge of the bottom, free of thermocouples. 4. The heat exchange tank for water purification by recrystallization for implementing the method according to claim 1, made of a thermally conductive material and having a drain pipe in the bottom and thermocouples located on its outer surface for cooling and heating the walls of the tank, characterized in that it is made in the form of a truncated hollow cone, vertically oriented with a bell up and having a lid, and the tank is equipped with an insert made in the form of a truncated cone and located inside the tank with a gap relative to its wall and the bottom to form an annular slotted cavity. 5. The heat transfer tank according to claim 4, characterized in that the insert is attached end to end to the lid of the tank.