RU2342609C1 - Domestic refrigerator - Google Patents

Abstract

FIELD: heating systems.

SUBSTANCE: domestic refrigerator consists of a heat-insulated cabinet, compressor, condenser, temperature control, dehydrator filter, and heat exchanger. Compressor, condenser, dehydrator filter, leakproof radiator with liquid heat carrier, temperature sensor, electromagnetic valves, electric pump, and heat exchanger channel of cabinet freezing compartment are included into a separate block which is located out-of-doors on the building outer side and is connected with heat-insulated tubes to heat exchanger which is located in a refrigerating cabinet.

EFFECT: ensuring the operation during winter period owing to ambient cold.

1 dwg

Description

The invention relates to refrigeration, in particular to small refrigeration machines.

Known refrigerator containing a cabinet, condenser, evaporator, filter drier, hermetic compressor, temperature controller and start-up relay (Weinberg BS, Vayn LN Household compression refrigerators. M .: Food industry, 1974, p.25- thirty).

When a sealed compressor is operating, noise is generated, the heat generated in the sealed compressor and condenser is diverted to the room, which creates some discomfort, especially in the summer.

Existing household refrigerators, regardless of their type, operate in apartments year-round, for many years. When the refrigerator is operating, the condenser and electric motor heat up, and this heat spreads into the room, most often in the kitchen, creating an already elevated temperature.

In addition, the operation of the refrigerator is accompanied by noise caused by the motor and compressor.

In winter, household refrigerators operate in the same mode as in summer, since the room where it is located is heated.

In areas with cold and long winters, the operation of such a refrigerator in the winter is simply irrational, since you can use the natural cold of the environment and significantly reduce energy consumption.

A built-in refrigerator is known, comprising a cabinet with a front door, a filter, an evaporator, an electric motor with a compressor, a temperature controller and a backlight, and the working chambers are divided and have openings communicating with the atmosphere in the rear walls, which can be closed (published application RU No. 94005794, class F25D 11/00, 10.20.1995).

A built-in refrigerator is known, comprising a cabinet with a front door, a filter, an evaporator, an electric motor with a compressor, a temperature regulator and a backlight, and the working chambers are divided and have openings communicating with the atmosphere in the rear walls, which can be closed (published application RU No. 2002135534, Cl F25D 11/00, A47B 75/00, 11/26/2002).

The disadvantage of the device according to the application No. 2002135534 is that during its installation it is necessary to make an opening in the outer wall of the room.

The aim of the invention is to remedy these disadvantages, namely: improving the operational capabilities of the refrigerator by increasing the size and configuration of the vegetable chamber (because the compressor is removed from the cabinet), improving comfort, especially in the summer, as the heat from the electric motor and condenser is not will be distributed throughout the room, the noise emitted by the compressor and the motor during its start-up, shutdown and operation, and a significant reduction in energy consumption will be significantly reduced.

The technical result, which consists in eliminating these shortcomings in a domestic refrigerator containing a thermally insulated cabinet, a compressor, a condenser, a temperature controller, a filter dryer, a heat exchanger, is achieved due to the fact that the compressor, the condenser filter dryer, a sealed radiator with a coolant, a temperature sensor , electromagnetic valves, electric pump, channel of the heat exchanger of the freezer compartment of the cabinet are allocated in a separate block, placed outside the premises and located on the external Ron buildings connected by insulated pipes to a heat exchanger located in the refrigerator.

The proposed design of a domestic refrigerator is designed to work in areas with cold, long winters and allows you to use the negative outside temperature to cool the internal cavity of the refrigerator.

The invention is illustrated in the drawing, which shows a refrigerator.

The refrigerator contains a cabinet 3 with a front door, a two-channel heat exchanger 5, a filter drier 6, a compressor 7, a temperature regulator 8, pipelines 11, 12, 13, 14, two electric valves 17 and 18, a pump 19, a radiator 20, a bellows expander 21 .

The unit is divided into two blocks: block 1 and block 2. Block 1 is located in the room, and block 2 is moved outside the room (to the street).

The blocks are connected to each other by heat-insulated tubes 11, 12, 13 and 14, which are passed through holes in the outer wall of the building 15.

Block 1 of the refrigerator contains a two-channel heat exchanger 5, in which two parallel, independent from each other channels 9 and 10 are made.

One of the channels 9 of the heat exchanger 5 works with a compressor 7, a condenser 4, a filter drier 6, a capillary tube 16, that is, according to the existing analogue circuit. This is a summer mode of operation. In this case, the compressor 7 pumps the refrigerant vapor into the condenser 4, through the filter dryer 6, the capillary tube 16 through the pipe 11 to the channel 9 of the heat exchanger 5, where the refrigerant boils at a negative temperature, receives heat and returns through the pipe 14 to the compressor crankcase.

Another channel 10 of the heat exchanger 5 operates from an environmentally cooled liquid heat carrier located in the radiator 20, which is located on the (street) in block 2. The radiator 20 is sealed and equipped with a bellows expander 21, which compensates for the thermal expansion of the liquid coolant.

When the automatics switches to winter mode, the electric power of the compressor 7 is automatically turned off and the power of the pump 19 and valves 17 and 18 is turned on. The environmentally cooled coolant from the radiator 20 is pumped through a pipe 23 through an open solenoid valve 17, pipe 13, through the second, through the second channel 10 of the heat exchanger 5, while cooling the freezer of the refrigerator.

An example of the inventive refrigerator is shown in the drawing, where the design of the refrigerator is schematically shown.

A refrigerator comprising a cabinet 3 with a front door, separated by thermally insulated chambers, a condenser 4, a capillary tube 16, a two-channel heat exchanger 5, a filter dryer 6, a compressor 7, a temperature regulator 8, electromagnetic valves 17 and 18, a radiator 20, a pump 19, a temperature sensor 22, bellows expander 21, start-up relay, is divided into two blocks: block 1 and block 2.

Block 1 contains a thermally insulated cabinet 3 with an opening door and a backlight, a temperature controller 8, a heat exchanger 5 with two separated channels 9 and 10. This block is located in the room.

Block 2 contains a compressor 7, a condenser 4, a filter drier 6, a capillary tube 16, two electromagnetic valves 17 and 18, a pump 19, a radiator 20, the cavity of which is filled with liquid coolant and is cooled from the environment, a bellows 21 compensating for the thermal expansion of the coolant, coolant temperature sensor 22 and pipelines. This block is located on the street (i.e. fixed on the outside of the building).

The blocks are connected together by pipelines 11, 12, 13, and 14 which are thermally insulated and passed through the wall 15.

The principle of operation of the inventive refrigerator.

The upper and lower temperature limits are monitored by temperature controls. In the summer, one half of unit 2 is operating, namely, a compressor 7, a condenser 4, a filter dryer 6, a capillary tube 16 and one of the channels 9 of the heat exchanger 5 located in block 1. The compressor 7 pumps the refrigerant into the condenser 4 through the filter dryer 6, the capillary tube 16 through the pipe 11 into one of the channels of the heat exchanger 5 (block 1), and specifically into the channel 9, where it boils at a negative temperature, cooling the cabinet freezer, and returns through the pipe 14 to the compressor crankcase 7.

The temperature in this chamber is set by the temperature controller 8, and both its lower and upper limits are monitored.

In the winter period, when the onset of cold weather, at the command of the temperature sensor 22, located in the radiator 20, the automation disconnects the electrical power to the compressor 7 from the mains. This opens the electromagnetic valves 17 and 18. The pump 19 is turned on, and the coolant cooled to minus temperature is pumped from the radiator 20 through the pipe 23 through the electromagnetic valve 17, through the hole in the wall 15 through the pipe 13 into the second channel 10 of the heat exchanger 5, located in block 1 , the freezer compartment of the cabinet 3. Thus, the coolant cooled by the ambient air, moving through the channel 10 of the heat exchanger 5 (block 1), cools the freezer, while the electricity is consumed only by suction, and the coolant through the tube 12 through the electromagnetic valve 18 is returned to the radiator 20.

The pump for transferring the coolant to the low-temperature circuit has a very low power consumption, about 10-12% of the compressor power.

Automation monitors the temperature in the chamber and, in case of warming, restores the refrigerator to its original mode. That is, to work with compressor 7. In this case, the power supply to the pump 19 and the electromagnetic valves 17 and 18 is automatically turned off. The circulation of the coolant is stopped.

The following results have been achieved. The heat emitted by the compressor and condenser does not spread to the room where the refrigerator is located, this is especially significant in the summer period, there are no noises emitted by the compressor during start-up, operation and shutdown. The size and configuration of the vegetable chamber are increasing due to the removal of the compressor in unit 2. And most importantly, the energy consumption in winter is significantly reduced.

A new technical solution is proposed that can significantly improve the operational and energy parameters of the refrigerator with significant energy savings. At the same time, the specified discomfort is not created, the volume of the vegetable chamber increases and its configuration changes to a more convenient one, the indoor microclimate in the summer is improved, and energy is significantly saved. The upper and lower temperature limits in the freezer are maintained automatically. If the temperature of the heat exchanger 5 is excessively lowered, the power supply to the electromagnetic valves 17 and 18 and the transfer pump 19 automatically shuts off. At the same time, the coolant circulates until the next automatic transfer of the transfer pump 19 and the electromagnetic valves 17 and 18.

The refrigerator will work in this mode until the ambient temperature in the street rises above the set temperature. When the temperature rises above the set, the automatics will turn off the power of the pump 19 pumping the coolant, turn off the power of the electromagnetic valves 17, 18, and turn on the compressor motor 7 of the refrigerator. It will be a summer mode of operation. Compared with the prototype, the inventive refrigerator has the following advantages.

1. The dimensions of the vegetable chamber are increased and its shape is changed to a more convenient and capacious one.

2. Eliminated noise emitted by the motor and compressor during start-up, operation and shutdown.

3. Heat from the electric motor, compressor and condenser does not spread throughout the room where the refrigerator is installed - comfort is improved.

4. Significantly saved electricity in the winter.

Claims (1)

A household refrigerator containing a thermally insulated cabinet, a compressor, a condenser, a temperature regulator, a filter drier, a heat exchanger, characterized in that a compressor, a condenser filter drier, a sealed radiator with a coolant, a temperature sensor, electromagnetic valves, an electric pump, a freezer compartment heat exchanger channel the cabinet is allocated in a separate block, taken out of the premises and located on the outside of the building, connected by heat-insulated pipes to the heat exchanger, located m in the refrigerator.