RU186269U1 - Refrigeration unit for a two-compartment refrigerator - Google Patents

Abstract

The utility model relates to the field of refrigeration and can be used in two-chamber refrigerators and freezers for domestic use. The claimed technical solution comprises a compressor connected by a discharge pipe to a condenser. After the condenser, the discharge tube is enclosed in heat insulation and forms, together with the suction pipe, a heat exchanger, the outlet of which is connected to the capillary tube through a filter dryer. The capillary tube is connected to the inlet of the steam separator, from the upper part of which (the first outlet) there is a capillary tube enclosed in heat insulation and forming a heat exchanger together with the suction pipe, the outlet of which is connected to the evaporator of the refrigerating chamber. The second outlet of the steam trap (from its lower part) is connected through the second thermally insulated capillary tube to the inlet of the freezer compartment, the outlet of which is connected in series with the evaporator of the refrigeration chamber. section of the suction tube.

Description

The refrigeration unit belongs to the field of refrigeration technology and can be used in double-chamber refrigerators and domestic freezers.

Known refrigeration unit described in RF patent No. 75232, class F25D 11/00 of 12/18/2007. Famous refrigeration unit contains a compressor, a condenser, a capillary tube, a filter drier and an evaporator.

The disadvantage of this technical solution is the high vapor content of the refrigerant at the inlet to the evaporator due to the adiabatic throttling process. This, in turn, reduces the cooling capacity of the refrigeration unit.

The problem to be solved is to increase the energy efficiency and cooling capacity of refrigeration units of two-chamber refrigerators.

The problem is solved due to the fact that the refrigeration unit contains a compressor, a condenser, capillary tubes, a filter dryer, evaporators of the refrigeration and low-temperature chambers, while the pipe after the condenser forms a first heat exchanger together with the suction pipe, the pipe outlet through the filter dryer is connected to the first capillary tube. The first capillary tube is connected to the inlet of the steam separator, from the upper part of which a second capillary tube comes out, which forms a second heat exchanger with a part of the suction pipe. The output of the second capillary tube is connected to the entrance to the evaporator of the refrigerating chamber. The second outlet from the bottom of the steam separator is connected through a third capillary tube to the inlet of the evaporator of the low-temperature chamber. The inputs of the evaporators are connected in parallel by the second and third capillary tubes, the outlet of the evaporator of the low-temperature chamber is connected in series with the evaporator of the refrigerating chamber.

The claimed technical solution is illustrated by the scheme of the refrigeration unit, shown in the figure.

The refrigeration unit (Fig.) Contains a compressor 1 connected by a discharge pipe to a condenser 2. After the condenser, a pipe 3 is included in the circuit, which forms a first heat exchanger 4 with a part of the suction pipe 13. The pipe 3 exit through a filter dryer 5 is connected to the first capillary pipe 6 The capillary tube 6 is connected to the inlet of the steam trap 7. A second capillary tube 8 emerges from the top of the steam trap 7, which forms a second heat exchanger 9 with a part of the suction pipe 13. The output of the second illyarnoy tube 8 is connected with the evaporator of the refrigerating compartment 11. A second output from the bottom of steam trap 7 is connected via a second capillary tube 10 to the input of the low-temperature evaporator chamber 12, the output of which is connected in series with the evaporator 11 of the refrigerating compartment.

The operation of the refrigeration unit is as follows. In the hermetic compressor 1, the process of compression of the refrigerant vapor occurs. Compressed refrigerant vapors are sent through a discharge line to condenser 2. In condenser 2, a condensation process occurs when heat is removed to the environment. After condensation, the liquid refrigerant in the pipe 3. The pipe 3 forms the first heat exchanger 4 with the part of the suction pipe 13. In the first heat exchanger 4, the condensed liquid refrigerant is supercooled by heat exchange with cold refrigerant vapor in the suction pipe 13. Then the supercooled liquid refrigerant passes through a filter drier 5 and throttled in the first capillary tube 6. During the throttling process in the first capillary tube 6, partial vaporization of the liquid refrigerant begins. After throttling in the first capillary tube 6, the vapor-liquid mixture of refrigerant enters the steam trap 7. From the upper part of the steam separator 7, the vapor-liquid mixture of refrigerant enters the second capillary tube 8, part of which forms the second heat exchanger 9 with the part of the suction pipe 13. Due to the heat exchange in the second heat exchanger 9, partial condensation of chaladagent vapors in the second capillary tube 8. After throttling in the second capillary tube 8, the vapor-liquid mixture enters the refrigeration evaporator chamber 11. From the second outlet of the lower part of the steam separator 7, the liquid refrigerant is throttled in the third capillary tube 10 and sent to the evaporator of the low-temperature chamber 12. The capillary tube 10 is insulated from the environment, and an adiabatic throttling process takes place in it. From the evaporator of the low-temperature chamber 12, the refrigerant enters the evaporator of the refrigerating chamber 11, then to the suction pipe 13 and to the suction side of the compressor 1.

Using the proposed technical solution increases the energy efficiency of the refrigeration unit due to the following factors:

- the use of the first heat exchanger allows for the subcooling of liquid refrigerant before the start of the throttling process, which allows to increase the cooling capacity of the refrigeration unit.

- the use of a steam separator leads to the entrance to the inlet of the third capillary tube only the liquid phase of the refrigerant, which helps to reduce the vapor content of the refrigerant at the outlet of the third capillary tube. This leads to a decrease in friction losses in the third capillary tube, to an increase in the energy efficiency and cooling capacity of the refrigeration unit.

- the use of a second heat exchanger allows you to remove heat and condense part of the vapor phase of the refrigerant in the second capillary tube, which reduces the vapor content of the refrigerant at the inlet to the evaporator of the refrigerating chamber. Such a technical solution leads to a reduction in friction losses in the second capillary tube, to an increase in the energy efficiency and cooling capacity of the refrigeration unit.

- parallel supply of refrigerant to the evaporators of the low-temperature and refrigerating chambers leads to the fact that only a part of the liquid refrigerant boils in the evaporator of the refrigerating chamber. In turn, this helps to reduce the time required to thaw the snow cover from the evaporator of the refrigeration chamber, and allows to increase the energy efficiency of the refrigerator by eliminating the electric heater from the electrical circuit to thaw the refrigeration chamber evaporator. Thawing of snow from the surface of the evaporator of the refrigerating chamber in the proposed technical solution occurs due to natural heat influx during the non-working part of the cycle.

Claims (1)

A refrigeration unit comprising a compressor, a condenser, a filter drier, capillary tubes, evaporators, characterized in that after leaving the condenser, a pipeline is included in the refrigeration unit circuit, forming a first heat exchanger with a part of the suction pipe and connected through a filter drier to the inlet of the first capillary tube , the outlet of which is connected to the inlet of the steam trap, from the top of which a second capillary tube emerges, forming a second heat exchanger with a part of the suction pipe, the output is W A swarm of the capillary tube is connected to the inlet to the evaporator of the refrigerating chamber, a second outlet from the bottom of the steam separator is connected through a third capillary to the inlet of the evaporator of the low-temperature chamber, while the inlets of the evaporators are connected in parallel with the second and third capillary tubes, and the outlet of the evaporator of the low-temperature chamber is connected in series with the evaporator of the refrigerating chamber cameras.

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