EA025714B1 - Method for water purification - Google Patents

Abstract

The invention relates to means and methods for water purification by a crystallisation method and can be used in everyday life, food industry and medicine. The technical result of the claimed invention is provision of such method for water purification by freezing that ensures higher quality of purified melt water and its useful properties, and also longer retention thereof in a consumer vessel. The water purification method comprises filling a vessel with water to be purified, water cooling and then freezing in said vessel to form a liquid concentrate of organic and inorganic admixtures, discharge of said liquid concentrate, ice melting at a positive temperature until it thaws, and then discharge of purified melt water. Water cooling, crystallisation and ice thawing by heating are provided outside the working vessel by means of cooling and heating elements contacting with thermally conductive walls thereof. After the discharge of the liquid concentrate of admixtures an ice layer is additionally frozen for a period of time sufficient for full freezing of a mass of ice, and melting of ice under positive temperature and discharge of melt water are provided simultaneously, while melt water is discharged continuously or periodically into a thermostatically controlled storage vessel for its subsequent storage at a positive temperature, close to the temperature of ice melting. Before melting the ice layer is frozen for 40-90 min at a temperature of -10-15°C.

Description

The invention relates to a method of water purification by crystallization, 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 improving the quality of drinking water by freezing, consisting in its freezing, crushing of ice and its melting, characterized in that freezing water is carried out up to 7090% of its volume, melting of ice is carried out by thermal insulation of its side and lower surfaces to form 30-55% of the volume of thawed snow 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 insufficient quality of purified melt water and the rapid loss of organoleptic and biologically active properties of purified melt water (for no more than 17-20 hours).

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 at about 1 / 3-2 / 3 of the height 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 of 1 - (- 1) ° С, 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 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.

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 to completely crystallize pure water with impurities of heavy water and form a liquid brine with organic and inorganic impurities; discharge of the specified brine; 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 completely thawed; re-cooling the water to the crystallization temperature of heavy water and holding it at the indicated temperature until the heavy water crystallizes completely and pouring the finished product 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 tank by at least 0.5 ° C, the temperature of the medium inside the working tank during the first crystallization of water is reduced to a value not lower than minus 4 ° C with the rate of change of the temperature of the medium in the working tank, equal to the interval of values of 0.050.1 ° 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 no higher than 10 ° C with a rate of change of the temperature of the medium in the working tank equal to the 0.16-0.18 ° C / min, and the temperature of the medium inside the working vessel 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 vessel equal to the range of 0.10 3 ° C / min.

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The disadvantages of the above methods include the insufficient quality of purified melt water and the rapid loss of organoleptic and biologically active properties of purified melt water (within no more than 17-20 hours) due to a local increase in the temperature of melt water from the heated walls of the tank during ice melting and during storage melt water at room temperature.

The technical result of the claimed invention is the creation of such a method of water purification by freezing, which provides an increase in the quality of purified melt water and its useful properties, as well as their longer storage in a consumer tank.

The specified technical result is achieved by the fact that in the method of water purification, including filling the tank with water for cleaning; 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 completely 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, water crystallization and ice melting by heating are carried out outside the working vessel by means of cooling and heating elements in accordance with the invention that are in contact with its thermally conductive walls, after the liquid concentrate is removed, the ice layer is additionally they are frozen for a time sufficient to completely freeze the mass of ice, for example, for 40-90 minutes at a temperature of - (1015) ° С, and it is melted ice under the influence of temperature of 10-15 ° C and the drain of melt water flowing over the surface of the ice layer having a temperature of 0 ° C is carried out simultaneously, preventing the temperature contact of melt water with the heated side wall of the tank for water treatment, and melt water is drained continuously or periodically in a thermostatically controlled storage tank for its subsequent storage at a temperature close to the melting point of ice in the range 0-2 ° C.

Freezing the purified ice provides compaction and ordering of its structure before melting, which improves the physicochemical properties of melt water (ORP and pH) and its beneficial properties. A longer preservation of the quality and biologically active properties of pure melt water is provided due to the fact that the process of ice melting 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 figure shows a diagram of an apparatus with an annular tank for freezing water treatment, the heating and cooling elements of which are placed around the outer cylindrical wall.

An apparatus for water purification that implements the inventive method includes (figure) a thermostatically controlled tank 1 for water purification, means 2 for freezing water with an evaporation tube 3, means 4 for melting ice with a heating element 5, and a unit 6 for draining purified and contaminated water from the tank 1 and an electronic control unit 7 connected to means 2 and 4 for freezing water and melting ice and a unit 6 for draining clean and contaminated water. The evaporation tube 3 of the means 2 for freezing water and the heating element 5 of the means 4 for melting ice are located around the outer side surface of the container 1 having thermally conductive walls and are in close contact with it.

The electronic unit 7 for controlling freezing water, melting ice and draining water is connected to the electromagnetic valves 8 and 9 of unit 6 for draining purified and contaminated water, respectively, and switches 10 and 11 of means 2 and 4, respectively, for freezing water and melting ice. The pipeline with a solenoid valve 8 is connected to a thermostatically controlled storage tank 12 for clean melt water.

An evaporation tube 3 with a freon of means 2 for freezing water is connected to a compressor 13 and a condenser 14. In addition, the electronic control unit 7 is equipped with a temperature sensor 15 mounted outside the bottom of the tank 1.

Description of the method of water purification. The method of water purification is carried out by, for example, the apparatus shown in the figure. In a thermally insulated container of 1 volume, for example, 2 liters, pour 1.5 liters of tap water. All processes: heating, cooling, water crystallization and ice melting, are carried out uniformly outside the working vessel 1 by contacting the cooling wall of the vessel 1 with cooling 3 and heating 5 elements in automatic mode by means of an electronic control unit 7 and an algorithm (program) of the sequence of cleaning operations water. When the refrigeration unit is switched on to the cooling mode of the elements 3 (evaporator tube), water is cooled through the heat-conducting wall of the tank 1. When the water is cooled, the temperature of the medium inside the working tank 1 is reduced to a value not lower than minus 3 ° С with a rate of change of the temperature of the medium in the working tank equal to the range of values of 0.1-0.3 ° C / min. Then carry out the process of crystallization of water. Using a temperature sensor 15 attached to the bottom surface of the tank 1, 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 by at least 0.5 ° C. The temperature of the water inside the tank 1 during crystallization of water 2 025714 is reduced to a value not lower than minus 4.0 ° С (the temperature is higher than the crystallization temperature of the liquid concentrate with organic and inorganic impurities) with a rate of change of the temperature of the medium in the working tank 1 equal to the interval of values 0 05-0.1 ° C / min. Over time (about 5 hours), complete crystallization of pure water is achieved in the form of an annular layer of ice near the wall of the tank 1, where the cooling elements 3 are located, and the formation of a liquid brine with organic and inorganic impurities in the axial zone of the tank 1. Within a few minutes, the liquid concentrate impurities with a volume of 300 to 550 ml are drained into the sewer when the electrovalve 9 is turned on.

After that, the ice layer is additionally frozen for 40-90 min at a temperature of - (1015) ° С, which is sufficient for the ice mass to freeze completely to the above temperature. At the same time, the ice structure becomes more ordered, the redox potential (ORP) decreases by 1.1-1.5 times and the pH increases to 9.0-9.7, and its density increases. Next, the ice frozen in the tank 1 is melted by turning off the cooling elements 3 and turning on the heating elements 5. The temperature of the wall of the tank 1 when the ice melts until it is completely melted after the impurity concentrate is drained, increases to 10-15 ° C. Ice mass is melted for about 1.5 hours until it is fully thawed. Simultaneously with the beginning of ice melting, continuous melt water is carried out continuously or batchly (every 5-10 min every) into a thermostatically controlled consumer container 12 by automatically turning on the electrovalve 8. In this case, melt water practically does not come into contact with the heated wall of container 1, which ensures conservation the temperature of the melt water both in the tank 1 and in the thermostatically controlled consumer tank 16 is about 0-2 ° C, which for a longer time preserves its biologically active properties. The full cycle of obtaining the finished product in the form of purified melt water is about 7.5 hours. The content of pure melt water is at least 65-80 vol.% Of its initial volume with a decrease in the total content of inorganic impurities by at least 1.5-2 times.

Apparatus for water purification works as follows. The working tank 1 is filled with water, pre-filtered from solids, and include a control unit 7. Automatically, the control unit 7 turns on the compressor 13. A gradual cooling of the water in the tank 1 occurs through the heat-conducting wall of the tank 1 (figure) with its subsequent freezing. The freezing process with the formation of pure ice lasts about 5 hours and is controlled by the temperature sensor 15, the data from which are sent to the electronic control unit 7. After the formation of the annular layer of pure ice is completed, the control unit 7 includes an electromagnetic valve 9 and an unfrozen liquid concentrate with impurities, i.e. water with a high salt content (brine) is discharged into the sewer. Then pure ice in the tank 1 is frozen for 40-90 minutes at a temperature of - (10-15) ° C, which is enough to lower the temperature of the mass of ice to the above temperature. At the same time, the ice structure becomes more ordered, the redox potential (ORP) decreases by 1.1-1.5 times and the pH increases to 9.0-9.7, and its density (p _l ) increases to 919.1 kg / m and the control unit 7 turns off the refrigeration unit.

Further, the control unit 7 includes a means 4 for melting ice, the thermocouple 5 of which is heated to a temperature of no higher than 20 ° C, which corresponds to natural conditions. In this case, pure ice melts. With the beginning of the melting of the ice layer, the control unit 7 includes an electromagnetic valve 8 and melt water is continuously discharged into a thermostatically controlled storage tank 12 during the entire time of melting of the ice. The electromagnetic valve 8 can be switched on periodically every 5-10 minutes and melt water is portioned into the tank 12 during the entire time of ice melting.

In this case, melt water practically does not contact the heated wall of the tank 1, which ensures that the temperature of melt water both in the tank 1 and in the thermostatically controlled consumer tank 12 is maintained at about 0-2 ° C, which preserves its biologically active properties for a longer time. Complete melting of ice is carried out in 1.5 hours. The full cycle of obtaining melt water is about 7.5 hours.

Thus, in comparison with the prototype, the inventive method of water purification provides improved quality of purified melt water and a longer preservation of its biologically active properties (pH and ORP) due to preliminary compaction and ordering of the ice structure before melting and elimination of local heating of melt water at the walls of the tank 1, as well as maintaining the temperature of melt water in the tank 12, close to the melting temperature of pure ice (about 0-2 ° C).

Claims (2)

CLAIM 1. The method of water purification, including filling the tank with water for cleaning; cooling and its subsequent freezing in the specified container at a temperature above the crystallization temperature of the liquid concentrate of organic and inorganic impurities in water for a time sufficient for complete crystallization of pure water as an ice layer and the formation of a liquid concentrate of organic and inorganic impurities; discharge of the specified liquid concentrate; melting the ice before it is completely thawed under the action of a positive temperature and draining the purified melt water, and cooling, crystallization of water and melting of ice are carried out outside the working tank by cooling and heating elements in contact with its thermally conductive walls, characterized in that after draining the liquid concentrate of impurities the ice layer additionally frozen for a time sufficient for complete freezing of ice mass, and melting of ice under the action of a temperature of 10-15 ° C and discharge of melt water s flowing over the surface of an ice layer having a temperature of 0 ° C is carried out simultaneously, preventing the temperature contact of the melt water with the heated side wall of the water purification tank, and the melt water is continuously or periodically poured into the temperature-controlled accumulative tank for its subsequent storage at a temperature close to to the melting point of ice in the range of 0-2 ° C. 2. The method of water purification according to claim 1, characterized in that the ice layer before melting is frozen for 40-90 minutes at a temperature of - (10-15) ° C.