RU194308U1 - Heat exchanger for water-ice phase transition energy - Google Patents

Abstract

The utility model relates to refrigeration technology and can be used in agriculture, namely, in enterprises of the agro-industrial complex and in heat storage systems, as well as for heating industrial and infrastructure facilities. As a result of using the utility model, it is possible to obtain energy of the water-ice phase transition and use it for heating agricultural facilities, in agricultural enterprises and in heat storage systems, as well as for heating industrial and infrastructure facilities due to the fact that the heat exchanger is equipped with an evaporator, compressor, condenser, throttle valve, solar collector, which allows to receive the energy of the water-ice phase transition. The technical result is achieved by the fact that the proposed heat exchanger is equipped with an evaporator, compressor, condenser, throttle valve, forming a closed loop, and a solar collector, while the evaporator is made in the form of a silicone tube located in the form of a coil, on the surface of which ice is formed, refrigerant circulates inside it to transfer the energy of the water-ice phase transition, and the tank is divided by a partition with insulating material, the height of which does not reach the upper edge of the tank, into two tanks, a water tank with an evaporator and a tank for collecting and melting ice, which are connected by a tube with a pump for pumping water from the tank for collecting and melting ice into a tank for water with an evaporator, and in the tank for collecting and melting ice, a heater is connected to the solar collector, and a compressor, condensers, expansion valve located on the side of the water tank to the evaporator.

Description

The utility model relates to refrigeration and can be used in agriculture, namely in agricultural enterprises and in thermal battery systems, as well as for heating industrial and infrastructure facilities.

A heating system of a residential building is known, comprising a pool located in the basement of the building, in which there is a water-ice-water system, a heat pump arranged to cool air in an air layer located above the upper water layer and to heat the air in a heated room (RF patent No. 2412401, IPC F 24 D 15/04, publ. 02.20.2011. Bull. No. 5). The system comprises a water pump installed with the possibility of pumping water from the lower layer to the upper layer, and a fan installed with the possibility of pumping air through the exhaust pipe from the specified air layer into the atmosphere outside the house, while the specified air layer is additionally connected with the atmosphere.

The disadvantages of the known system is the high cost and complexity of manufacture.

A known ice generator and a method of generating ice, comprising a heat exchanger, a source water supply system and an ice removal means, a closed loop, which is formed by a container for accommodating the source water and generated ice, by a supply pipe, a flow pump, a heat exchanger, a valve and a discharge pipe (RF patent No. 2454616, IPC F 25 C 1/12, F 25 C 5/18, published on June 27, 2012, Bull. No. 18).

The disadvantages of the known generator is that the equipment allows you to get ice without using the energy of the water-ice phase transition, low productivity, operates in periodic mode with high energy costs.

The closest in technical essence to the proposed utility model is an ice generating device that contains an elastic membrane, a pump, a nozzle, water, a housing, a refrigerant, a layer of water and ice flakes (RF patent No. 2490567, IPCF25C 1/00, F25C 1/12, publ. 08/20/2013. Bull. No. 23). In the device, water is pumped through the nozzle to the outer surface of the elastic membrane, which uniformly irrigates the outer surface of the membrane. The membrane is installed on the housing, where the refrigerant is periodically supplied and removed. As a result of heat transfer through the membrane between the water and the refrigerant, part of the water freezes, and ice flakes form on the membrane surface.

The disadvantages of the known device is that it operates in periodic mode with high energy costs, without using the energy of the water-ice phase transition.

The technical task of the proposed utility model is to use the energy of the water-ice phase transition for heating agricultural facilities, in agricultural enterprises and in thermal battery systems, as well as for heating industrial and infrastructure facilities.

As a result of using the utility model, it becomes possible to obtain the energy of the water-ice phase transition and use it for heating agricultural facilities, at enterprises of the agro-industrial complex and in heat storage systems, as well as for heating industrial and infrastructure facilities due to the fact that the heat exchanger is equipped with an evaporator, compressor, a capacitor, a throttle valve, a solar collector, allowing to receive the energy of the water-ice phase transition.

The above technical result is achieved by the fact that the proposed heat exchanger for receiving energy of the water-ice phase transition containing a tank, the pump, according to a utility model, is equipped with an evaporator, compressor, condenser, a throttle valve forming a closed loop, and a solar collector, while the evaporator is made in in the form of a silicone tube, located in the form of a coil, on the surface of which ice is formed, and refrigerant circulates inside it to transfer the energy of the water-ice phase transition, the capacity p divided by a partition with insulating material, the height of which does not reach the upper edge of the container, into two containers, a water tank with an evaporator and a tank for collecting and melting ice, which are connected by a tube to a pump for pumping water from a tank for collecting and melting ice into a tank for water with an evaporator, and in the tank for collecting and melting ice, a heater is connected to the solar collector, and the compressor, condenser, throttle valve are located on the side of the water tank with an evaporator, while springs has the ability to pump refrigerant vapors from the evaporator and pumping them into the condenser for cooling with further inflow of liquid refrigerant through an expansion valve to the evaporator.

To obtain and use the energy of the water-ice phase transition in the proposed heat exchanger, the evaporator is made in the form of a flexible silicone tube in which freon (refrigerant) circulates, on the surface of which ice is formed, which easily separates from the surface of the silicone tube. A heater associated with a solar collector is used as a heat source for melting ice.

The essence of the proposed utility model is illustrated in the drawing, which shows a general diagram of a heat exchanger for generating energy of the water-ice phase transition.

The heat exchanger for receiving energy of the water-ice phase transition consists of a tank 1 covered with insulating material to reduce heat exchange with the environment. The tank 1 is divided by a partition 2, also covered with insulating material, into two tanks. One tank for water 3 is filled with water, and the other tank 4 is a tank for collecting the formed ice and melting it. In this case, two containers are connected by a tube with a pump 5 for transferring water from the tank 4 to the tank 3, which was formed during the melting of ice, using a heater 6, which is connected to the solar collector 7. In the tank 3 there is a coil-type evaporator 8 made of a silicone tube, which refrigerant circulates (freon). The freon used may be, but is not limited to, R410a.

On the outside of the heat exchanger from the side of the water tank 3 with the evaporator 8 are located a compressor 9, a condenser 10, a throttle valve 11, forming a closed loop. In the condenser 10, heat is taken and supplied to the consumer 12 using a circulation pump 5.

The heat exchanger operates to obtain the energy of the water-ice phase transition as follows.

When Freon enters the evaporator 8, it evaporates, as a result of which heat is absorbed, and the temperature of the silicone tubes with freon decreases. The evaporator is made in the form of a silicone tube with a metal insert, which is located in the form of a coil.

The compressor 9 pumps out the freon pairs from the evaporator 8 and pumps them into the condenser 10. In the condenser 10, the freon pairs are cooled and condensed. Next, the liquid freon through the throttle valve 11 enters the evaporator 8. At the inlet of the freon to the evaporator 8, the pressure drops from the condensation pressure to the boiling pressure. When this occurs, boiling freon, entering the evaporator tube 8 boils freon, the energy necessary for boiling in the form of heat is taken from the surface of the evaporator 8, cooling the silicone tube, on the surface of which ice is formed. After passing through the evaporator 8, the liquid freon turns into steam, which is pumped out by the compressor 9. The cycle of circulation of freon closes.

Heat is taken in the condenser 10 and supplied to the consumer 12. On the evaporator 8, ice is formed as a result of lowering the temperature. In this case, heat is released due to the energy of the water-ice phase transition, which is absorbed by freon and transferred by the compressor 9 to the condenser 10, then to the consumer 12. As a consumer 12, for example, the heating system of the premises of an agricultural facility, as well as industrial and infrastructure facilities.

Ice is formed on the surface of the silicone tube 8, the thickness of which should not exceed 3.5 cm. As a result of the fact that the silicone tube 8 is elastic, the ice formed is torn off the surface. Since the density of ice is less than the density of water, ice rises up in tank 3 and falls out into tank 4.

The container 4 is installed a heating element 6 which is connected with the solar collector 7. By heating the ice melted, it passes into the liquid state (temperature about 1 ° ^C), and the pump 5 is pumped from the reservoir 4 into the container 3. The water circulation closed cycle.

Cold water from the tank 4 can be used for cooling, for example, milk, or for cooling the premises of agricultural facilities (not shown in the diagram).

Specific heat during the water-ice phase transition:

λ = 306⋅kJ / l = 0.085 kW⋅h / l.

For home heating to 100 m ² required capacity 12.76 kW. Per day: 12.76⋅24 = 306.24 kW⋅h.

For this, in one freezing cycle it is necessary: 306.24 (kW⋅h) / 0.085 (kW⋅h / l) = 3602.8 liters of ice. The volume of ice produced by the heat exchanger using the energy of the water-ice phase transition will be 150.1 liters of ice / h.

When freezing 10.75 kg of water, 1 kWh of energy is released. In one freezing cycle per day, 10.75 · 306.24 = 3292.08 kg of water is needed.

Claims (1)

A heat exchanger for receiving energy of the water-ice phase transition, comprising a tank, a pump, characterized in that it is equipped with an evaporator, compressor, condenser, a throttle valve forming a closed loop, and a solar collector, while the evaporator is made in the form of a silicone tube located in the form of a coil , on the surface of which ice is formed, and refrigerant circulates inside it to transfer the energy of the water-ice phase transition, the capacity being divided by a partition with insulating material, the height of which does not reach about the upper edge of the tank, into two tanks, a water tank with an evaporator and a tank for collecting and melting ice, which are connected by a tube to a pump for pumping water from a tank for collecting and melting ice into a water tank with an evaporator, and in a tank for collecting and to melt the ice, a heater is connected to the solar collector, and the compressor, condenser, and throttle valve are located on the side of the water tank with the evaporator, while the compressor has the ability to pump out the freon vapor from the evaporator and pump it x condenser for cooling with further inflow of liquid refrigerant through an expansion valve to the evaporator.

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