RU2093764C1 - Refrigerator with semi-automatic defrosting - Google Patents

Abstract

FIELD: cooling engineering. SUBSTANCE: compression refrigerator has a closed circulation loop for coolant. The capillary tube is received in the sucking pipe line and coil-pipe evaporator connected to the sucking pipe line through its one end. The other end of the evaporator have no capillary tube and is connected with the compressor through a solenoid valve of the defrosting device to form a regenerative heat exchanger in the insulating space together with the sucking pipe line. EFFECT: improved design. 1 dwg

Description

 The invention relates to refrigeration, and in particular to compression refrigeration units of mainly domestic refrigerators and freezers.

Known refrigeration units in refrigerators having a device for reducing the rate of frost formation at the inlet of the evaporator of the refrigeration chamber by supplying refrigerant to an additional channel in the inlet of the evaporator [1] are also known refrigeration units with a defrosting system of the evaporator of the refrigerated chamber during the non-working period of the cycle, where the capillary tube located along the overflow pipe in close proximity to it with the formation of a regenerative heat exchanger, and the capillary tube is placed inside overflow pipe. The regenerative heat exchanger has the form of a siphon with a water lock and is installed above the evaporator of the cooled chamber, the upper part of the evaporator of the cooled chamber is made inclined [2]
Known compression refrigeration unit containing a series-connected compressor, condenser, capillary tube located inside the suction pipe and a coil-tube evaporator connected at one end to this pipe [3] This technical solution is the closest to this invention in technical essence and the achieved result.

 The disadvantage of the above technical solutions is the difficulty in manufacturing the evaporator thawing device, the defrosting process takes a lot of time, which leads to the loss of cold in the internal chamber of the refrigerator, assembling the refrigerator with such refrigeration units is laborious and not technologically advanced. The automation of defrosting the evaporator is difficult. Increases energy consumption. This invention solves the technical problem of accelerating the thawing of a coil-tubular evaporator with a capillary tube inside, draining the refrigerant coming into the compressor from the evaporator and preventing fogging and freezing of the suction pipe during defrosting of refrigerators and freezers.

 The invention is illustrated in the drawing, which schematically shows a compression refrigeration unit.

 The compression refrigeration unit contains a series-connected compressor 1, a condenser 2, a capillary tube 4 located inside the suction pipe 4 and a coil-tube evaporator 5 connected at one end to this pipe. Its other end is located without a capillary tube and has a section 6 connected to the compressor 1 through an electromagnetic valve 7 mounted on the discharge pipe 8. Moreover, the pipe section 6 is connected to the section of the suction pipe 4 with the formation of a regenerative heat exchanger 9 in a closed volume.

 The unit is equipped with a filter-drier 10 and a liquid dipper 11 located on the evaporator 5. The latter is placed in the working volume 12.

 A refrigeration unit with semi-automatic defrost works as follows.

 The hot refrigerant pairs compressed by compressor 1 through the heating pipe 8 from the solenoid valve 7 defrost enter the condenser 2, from where the condensate formed through the filter dryer 10 enters the capillary tube 3 located inside the suction pipe 4 and the coil-tube evaporator 5. At the end of the coil the tubular evaporator 5 freon from the capillary tube 3 enters the internal volume of the coil-tubular evaporator 5 and begins to boil intensively, taking heat from the cooled volume 12 and capillary tube 3, moving in the opposite direction. The resulting freon vapor through the suction pipe 4 enters the compressor 1, and the excess liquid freon accumulates in the boilers 11 and the cycle repeats.

 If necessary, the defrost of the coil-tubular evaporator 5, turns on the electromagnetic valve 7 defrost. Hot saturated refrigerant vapors, bypassing the condenser 2, pass through the pipe section 6 to the end of the coil-tube evaporator 5, where they condense, intensively giving off heat to the evaporator 5. The formed condensate fills the digger 11, and the excess freon together with the vapor enters the suction pipe 4. In the area of the regenerative heat exchanger 9 located in an insulated volume, the refrigerant vapor is dried, taking part of the heat of the pipe 6, and goes to the compressor 1. The cycle is repeated until complete defrost .

 The design of this refrigeration unit with semi-automatic defrost allows you to quickly defrost freezers with closed refrigerator doors. It reduces the temperature change of the internal walls of the cooling volume, eliminates the fogging of the suction pipe during defrost, protects the compressor from water hammer, increases its life, saves electricity and allows you to automate the defrost process.

 In addition, as a result of the operation of the electromagnetic valve, the defrosting process occurs without turning off the refrigerator, eliminates the loss of cold in the internal chamber of the refrigerator, reduces power consumption, improves the manufacturability of the refrigerator assembly, reduces labor intensity, improves consumer properties.

Claims (1)

 A compression refrigeration unit comprising a compressor, a condenser, a capillary tube located in series inside the suction pipe and a coil-tube evaporator connected at one end to this pipe, characterized in that the unit is equipped with a liquid booster located on the evaporator and the other end of the coil-tube the evaporator is continued without a capillary tube and connected to the compressor through an electromagnetic valve mounted on the discharge pipe, while This section of the pipeline is connected to the section of the suction pipe with the formation of a regenerative heat exchanger in a closed volume.