SU1388676A1 - Two-chamber domestic refrigerator - Google Patents

Abstract

The invention relates to the field of refrigeration equipment, namely, in two-chamber refrigerators for domestic use, and allows to reduce energy consumption during operation of the refrigerator. Compressor 5 injects refrigerant vapor into condenser 6, where they condense. The condensate formed is fed to the main choke 7, and then to the choke 8 of the evaporator 2 of the cooling chamber (MC) 1 and the solenoid valve 10 connected in parallel. If the temperature of the refrigerating chamber (HC) 3 is not necessary, the refrigerant is supplied through both throttles 8 and 9 respectively to the evaporators (I) 2 and 4 MK 1 and XK 3, the refrigerant passing through I 4 lowers the temperature in XK 3 and then the vapor-liquid mixture formed is fed through the output channel 15 and 4 to the overflow pipe 11 and to the steam trap (P) 12 through its inlet channel 14, where the liquid boils and the vapors are sucked by the compressor 5. When the temperature in XK 3 reaches the set value solenoid valve 10 triggers Dagent is produced only through choke 8 to I 2, from which the refrigerant through inlet channel 13 is supplied to P 12 and then to suction in compressor 5. When the temperature of MK 1 is reduced to the specified value, compressor 5 will be disconnected. 1 Il. 2 (L with OS P

Description

The invention relates to refrigeration equipment, namely to two-chamber refrigerators for domestic use.

The purpose of the invention is to reduce energy consumption during operation of a refrigerator.

The drawing shows schematically the proposed two-chamber household refrigerator, a general view.

The refrigerator contains a freezing chamber 1 with an evaporator 2, a refrigerating chamber 3 with an evaporator 4, a compressor 5, a condenser 6, a main throttle 7, a throttle 8 an evaporator 2 of the freezing chamber 1, a throttle 9 an evaporator 4 of the refrigerating chamber 3, an electromagnetic valve 10, an overflow pipe 11. The evaporator 2 of the freezing chamber 1 is equipped with a steam trap 12, having two inlet channels 13 and 14, the inlet channel 13 is connected to the outlet of the evaporator 2 of the freezing chamber 1, and the inlet channel 14 through the overflow pipe 11 to the outlet channel 15 evaporating l 4 x Freezer 3. The main throttle 7 is connected to the throttle 8 of the evaporator 2 and through the solenoid valve 10 to the throttle 9 of the evaporator 4.

The refrigerator works as follows.

Compressor 5 injects refrigerant vapor into condenser 6, where it condenses. The condensate formed is supplied to the main choke 7, and then to the choke 8 of the evaporator 2 of the freezer compartment 1 and the solenoid valve 10, which are connected in parallel.

If the temperature of the refrigerating chamber 3 is higher than necessary, the refrigerant is supplied through both throttles 8 and 9, respectively, to the evaporators 2 and 4 of the freezing 1 and cooling 3 chambers.

The refrigerant passing through the evaporator 4 lowers the temperature in the refrigerating chamber 3, and then the vapor-liquid mixture formed through the outlet channel 15 of the evaporator 4 of the refrigerating chamber 3 to the overflow pipe 11 and the vapor collector 12 through its inlet 14, where the liquid boils and the vapors are sucked off

By the compressor 5. When the temperature in the refrigerating chamber 3 reaches a predetermined value, the solenoid valve 10 is activated and the refrigerant is supplied only through the throttle B to the evaporator 2 of the freezing chamber 1, from which the refrigerant through the inlet channel 13 is fed to the steam collector 12, and then for suction in compressor 5. When the temperature of the freezer compartment 1 is lowered to a predetermined value, the compressor 5 is turned off.

The presence of a steam collector 12 in the evaporator 2 of the freezer compartment 1 allows separating refrigerant vapor entering through the overflow pipe 11 from the evaporator 4 of the refrigerating compartment 3. Due to this, the refrigerant vapor does not pass through the entire evaporator 2 of the freezing compartment 1, and is sucked off by the compressor 5, which leads to lowering the temperature of the evaporator 2, since the heat transfer coefficient from the liquid phase of the refrigerant to the wall of the evaporator 2 is much higher than that from the vapor phase. This provides an increase in the thermodynamic efficiency of the refrigerator and, consequently, energy consumption during its operation.

Claims (1)

Invention Formula A two-chamber household refrigerator containing a freezer and a refrigerating chamber with evaporators located therein, a series-connected compressor, a condenser and a main choke, parallel-connected throttles of the freezing and refrigerating chamber evaporators, a solenoid valve installed in front of the cooler’s evaporator and - a pouring conduit, characterized in that, in order to reduce energy consumption, the freezer evaporator is equipped with a steam collector, one which the input channels to an outlet of the freezing chamber evaporator. The other is connected to the overflow pipe, and the outlet of the steam trap is connected to the compressor inlet.