UA108003U - COMPRESSION HEAT PUMP FOR COOLING DRINKS - Google Patents

Abstract

A compression heat pump for cooling drinks contains a compressor, a condenser, an evaporator, connected by a loop filled with a refrigerant, a supply pump, a first heat exchanger. The pump further comprises a throttle and a desiccant filter, which are connected in series to the circuit of the heat pump. The elements of the heat pump are connected to each other by copper tubes by means of solder joints, forming a sealed system. Additionally, install a bath for cooling water and ice formation, with a stirrer pump to fill the bath with water. It also contains an evaporator with a first heat exchanger, which is made of thin-walled stainless steel in the form of spirals of square (rectangular) cross section, located in a bath with cooled water. a temperature regulator with a sensor located in the bath, a product line for supplying the drink through the first heat exchanger to the consumer and a fan for blowing the air condenser.

Description

The useful model belongs to heat pump technologies.

A well-known beverage cooler, type OH, model OH-30-2 (Coolers for non-alcoholic drinks / I.V. Lifshits et al. Refrigeration technology. - 1987, Mo 3, p. 42-44), which contains 2 tanks made of transparent polymer material with lids, dispensing and mixing devices, a refrigerator. The main disadvantages of the well-known device are: the slow rate of cooling of drinks, which does not ensure uninterrupted operation of the commercial enterprise, especially in the hot season; the absence of an effective system for mixing drinks during the cooling process, which does not allow to ensure a uniform temperature of the sold portions of drinks; the use of B12 freon in the refrigerating machine, which is environmentally unfavorable and currently prohibited for use.

A device for cooling drinks is also known (Pat. SHA 28486 IPC A2387/04. - Publ. 16.10.2000, Bul. Mo 5), which contains tanks with lids, dispensing devices and a refrigerator, heat removal from drinks is carried out on both sides of the coil cooling, inside which moves with the help of a circulation pump an intermediate organosilicon refrigerant, cooled in the evaporator of a refrigerating machine, which operates on the refrigerant NI1Z4a, a gear pump, with an activator placed on the shaft, pumps drinks from the internal volume, inside the cooling coil, and in in the form of a jet washes the outer surface of the coil and turbulates another volume of the drink in the tank. The disadvantage of the device is its complexity.

The well-known compression heat pump (Pat. Sha 43888. IPC g25830/02. - Publ. 15.01.2002,

Bull Mo 11, containing a supply pump, coolant circuit, evaporator, compressor and condenser, made in the form of 2n sections, where n-1, 2, 3), each of which is made of interconnected chambers of the evaporator, compressor and condenser , there are n valves in the compressor piston, and the evaporator and condenser chambers are connected through a hydraulic unit, which is located between them and has a height smaller than the distance between the bottoms of the evaporator and condenser. The disadvantage of the prototype device is its complexity and material consumption due to the presence of a multi-stage evaporator, narrow functional capabilities - only for obtaining heat.

The basis of the useful model is the technical task of reducing the material capacity due to the reduction of the elements of the heat pump (HTP), creating a compact

From an environmentally friendly device, the expansion of functionality due to the receipt of both cold and heat.

The task is solved due to the fact that the compression heat pump for cooling drinks, which contains a compressor, a condenser, an evaporator, connected to each other by a circuit filled with a refrigerant, a supply pump, a first heat exchanger, according to a useful model, additionally contains a throttle and a filter dryer, connected in series to the TN circuit, TN elements are connected to each other by copper tubes using soldered connections, forming a hermetic system, a bath for cooling water and forming an ice field, with an agitator pump for filling the bath with water, an evaporator with the first heat exchanger made of thin-walled food-grade stainless steel in the form of square (rectangular) cross-section spirals, located in a bath with cooled water, a thermostat with a sensor located in the bath, a product pipe for supplying the drink through the first heat exchanger to the consumer, a fan for blowing the air condenser. The task is also solved due to the fact that a liquid condenser placed in a tank-accumulator with water and a second heat exchanger for supplying heated water is used for washing used dishes after a drink; an environmentally safe refrigerant, such as Freon-H134 (pyrz:/gy.miKiredia.oga/miKi/Freonyi) is used in the TN circuit.

Thus, the compression heat pump for cooling drinks differs from the prototype device in its smaller material capacity due to the reduction of TN elements, the creation of a compact device, environmental safety due to the use of H134 freon as a refrigerant, and the expansion of functional capabilities due to the production of both cold and heat.

The connection in series to the TN circuit of the throttle in the form of a capillary tube ensures an increase in pressure before entering the condenser; turning on the TN circuit of the filter-drier ensures the removal of accidental moisture from the refrigerant; connecting the elements of the TN circuit to each other with copper tubes using soldering ensures the formation of a closed hermetic system; the presence of a cooling bath with water provides convection removal of cold from the evaporator through the first heat exchanger, and its accumulation in the form of an ice field; the presence of a pump-mixer ensures that the bath is filled with water and mixed to improve convection heat removal; execution of the evaporator and the first heat exchanger from thin-walled food-grade stainless steel in the form of spirals of square (rectangular) section,

provides an increase in the coefficient of useful filling of the bath and improves convection heat transfer between them; the presence of a temperature regulator with a sensitive sensor element in the form of a capillary provides regulation of the thickness of the ice field layer; the presence of a product pipe for supplying the drink through the first heat exchanger to the consumer ensures direct cooling of the drink due to convection heat transfer, the presence of a fan for blowing ensures cooling of the air condenser. The use of a liquid condenser (instead of an air condenser) placed in a water storage tank, together with a second water supply heat exchanger, provides heating of water for washing dishes after drinking. Filling the TN circuit with an environmentally safe refrigerant, Freon-H134, ensures the environmental safety of the TN.

The technical essence of the useful model is explained by graphic material: in Fig. 1 shows a technological diagram of a compression tank for cooling drinks; in Fig. 2 - version of the TN with a liquid capacitor.

The compression heat pump for cooling drinks is a box-type metal case with removable walls and a removable cover (not shown in the diagram). Inside is a compression tank, the components of which are a compressor 1, a fan 2, an air condenser 3, a filter-drier 4, a bath 5, an evaporator b, a heat exchanger 7 for direct cooling of a drink, a pump-mixer 8 for filling the bath 5 with water, a thermostat 9 with a temperature sensor 10 in the form of a capillary, a choke 11 in the form of a capillary tube, copper tubes 12 for connecting the TN elements to each other by soldering into a closed hermetic system filled with an ozone-safe refrigerant - B-134, a product line 13 for supplying the drink through the heat exchanger 7 to the consumer . As an option, a liquid condenser 15 is placed in the battery tank 14 to heat water (Fig. 2).

The compression tank for cooling drinks works according to the heat pump technology as follows. After turning on the compressor 1, it pumps refrigerant vapor from the evaporator 6 and pumps it into the condenser 3. In the condenser, the refrigerant vapor cools and condenses. Next, the liquid refrigerant passes through the filter-drier 4 and the throttle 11 in the form of a capillary tube to the evaporator b, located inside the bath 5, made of impact-resistant plastic and thermally insulated from the outside with polyurethane foam. At the entrance to the evaporator 6, the pressure drops from the value

From condensation pressure to boiling pressure. This process is called throttling. At the same time, the refrigerant boils, entering the channels of the evaporator 6, the refrigerant boils, the energy needed for boiling in the form of heat is taken from the surface of the evaporator, cooling the water in the bath 5, and the water turns into ice on the tubes of the evaporator 6. After passing through the evaporator 6, the liquid refrigerant turns into in the steam, which is pumped out by compressor 1, gives its heat to the air condenser C and the environment of the fan 2 during its condensation after compression by compressor 1, and then the process is repeated. The operation of the fan 2 contributes to intensive cooling of the heated air condenser 3. The thickness of the ice field depends on the temperature at the place of installation of the sensor (capillary) 10, and is regulated by turning the knob of the thermostat 9. When the thermostat 9 is set to the maximum, the thickness of the ice will be maximum. In the future, the thermostat 9, turning on and off the TN unit, constantly maintains the set thickness of the ice field. During the distribution of the drink, it is cooled when it passes through the first heat exchanger 7 of the product line 13.

The temperature of the outgoing beverage depends on the temperature of the incoming beverage. Until the ice field is completely exhausted, the temperature of the water that cools the first heat exchanger 7 will be close to 0 "C. As the drink is dispensed and the ice field is exhausted, the hot water unit is turned on according to the signal of the thermostat 9. When the ice field reaches a volume sufficient to maintain the temperature set by the thermostat 9 temperature values, the unit turns off.The speed of recovery of the ice field depends on the intensity of the beverage distribution.

After the ice field is completely exhausted, the temperature of the dispensed drink begins to rise. The thermostat 9 is designed to maintain the set temperature of the water in the bath 5 (due to the mass of the ice field regulated by it). Fan 2 and compressor 1 work simultaneously, automatically turning on and off at the command of the thermostat 9.

The formation of ice in bathroom 5 occurs during the operation of the DH unit using classic heat pump technology. The design of the compression TN for cooling drinks provides access to the aggregate part of the refrigerating unit through decorative removable veils (not shown) on the side walls of the case.

A useful model can be used for heating cocktails, juices, beer, when selling them.

Claims (3)

USEFUL MODEL FORMULA 1. A compression heat pump for cooling beverages, containing a compressor, a condenser, an evaporator, connected to each other by a circuit filled with a refrigerant, a supply pump, a first heat exchanger, which is characterized by the fact that the heat pump additionally contains a throttle and a filter drier, connected in series to the circuit of the heat pump, the elements of the heat pump are connected to each other by copper tubes with the help of solder joints, forming a hermetic system, a bath for cooling water and forming an ice field, with an agitator pump for filling the bath with water, an evaporator with a first heat exchanger, which made of thin-walled food-grade stainless steel in the form of square (rectangular) cross-section spirals, located in a bath with cooled water, a thermostat with a sensor located in the bath, a product pipe for supplying the drink through the first heat exchanger to the consumer and a fan for blowing the air condenser. 2. A compression heat pump for cooling drinks, which is characterized by the fact that a liquid condenser is used, placed in a water accumulator and a second heat exchanger, supplying heated water for washing used dishes after a drink. 3. Compression heat pump for cooling drinks, which differs in that an environmentally safe refrigerant is used in the circuit of the heat pump, for example Freon-A 134. t y The concept of mon FROM whose tami dn l EY still ate atzh KO and her seavoya BIO dya still yi Sha | t sho her SCHI she Y Y shey : 0 x | In KKU g i I) ke ve chn. 1 azhmnadna water rt tya nn en CHE I. lsh mohu rRashya trig