KR19990046872A - Direct Cooling Small Freezer - Google Patents

Abstract

The present invention relates to a direct cooling small freezer using a direct evaporator in the form of a direct cold plate, wherein the freezing evaporator self-compensates itself when the first freezing evaporator and the second freezing evaporator are installed in a freezing compartment and the outside air temperature is low. By making it possible to reduce the manufacturing cost and power consumption compared to the conventional refrigerator freezer using a separate heater for low temperature compensation.

The present invention provides a direct refrigeration small freezer comprising a compressor, a condenser, a capillary tube, a first freezing evaporator and a refrigeration evaporator, wherein a second freezing evaporator is installed between the first freezing evaporator and the freezing evaporator and the second freezing evaporator is installed. The refrigeration evaporator is a direct-cooling small freezer, characterized in that attached to the rear wall of the freezer compartment.

Description

Direct Cooling Small Freezer

The present invention relates to a direct cooling small freezer using an evaporator in the form of a direct cold plate, and in particular, to improve the structure of the freezer compartment evaporator to maintain the freezer compartment at a constant temperature even when the outside temperature is lowered.

1 is a cycle diagram of a conventional direct cooling small freezer.

The high temperature and high pressure refrigerant discharged from the compressor 1 is radiated while passing through the compressor 2, and is reduced in pressure through the capillary tube 3 to become a low temperature and low pressure refrigerant.

The low temperature low pressure refrigerant first absorbs heat while passing through the evaporator 5 of the freezing compartment 4, and then absorbs heat while passing through the evaporator 7 of the refrigerating compartment 5, and is then sucked into the compressor 1.

The freezing evaporator 6 installed in the freezer compartment and the refrigeration evaporator 7 installed in the refrigerating compartment are both direct-cooling plate type evaporators. (Top, bottom and both sides) are formed to cover the area, and the bent portion indicated by the dotted line is formed in a lattice to surround the top, bottom and both sides of the freezer compartment.

The refrigerating evaporator 7 of the refrigerating compartment is formed in a very small area compared to the freezer evaporator and is attached to the rear side of the refrigerating compartment.

In the direct-cooling freezer as described above, the operation of the compressor 1 is controlled according to the sensed temperature by detecting the surface temperature of the inner wall on which the evaporator 7 for the refrigerating compartment is mounted.

In other words, the direct-cooling freezer is designed to maintain the temperature of the freezer compartment and the refrigerator compartment at -18 ℃ and 3 ℃, respectively, the temperature of the freezer compartment and the refrigerator compartment is turned on or off according to the temperature detected in the interior wall of the refrigerator compartment To maintain the set temperature.

7 is a graph showing the compressor operation rate (compressor operation time / compressor operation time + compressor stop time) of the conventional direct-cooling freezer, and conventionally, the compressor 1 has an inner wall surface temperature on which a refrigerator evaporator is installed in the refrigerating compartment. Since it is turned on or off, the hatched portion, as shown in the graph, becomes a range in which the internal temperature can be maintained at -18 ° C and 3 ° C.

However, when the outside air temperature is 10 ° C. or less, since the external load of the refrigerating compartment is remarkably enjoyed compared to the external load of the freezing compartment, the compressor is turned off before the internal temperature of the freezing compartment reaches −18 ° C.

Therefore, in the conventional direct-cooling freezer, a separate heater (not shown) is installed in the refrigerating compartment so that when the outside temperature is 10 ° C. or less, an extra load (dummy load) is supplied to the refrigerating compartment as the heater is heated. That is, the low temperature of the outside temperature is compensated by the heater to prevent the operation of the compressor from being stopped until the temperature of the freezer compartment becomes -18 ° C.

However, the conventional heater-mounted low-temperature compensation direct-cooling freezer, such as the above, requires a large number of heaters and auxiliary electric equipment required for the heater, resulting in an increase in manufacturing cost and an increase in power consumption.

It is an object of the present invention to provide a direct-cooling small freezer that can maintain a freezer compartment at a set temperature at all times without using a separate electric equipment such as a heater.

According to an embodiment of the present invention for achieving the above object, a second freezing evaporator on a rear wall of the freezer compartment in which the freezing evaporator is installed in a freezer comprising a compressor, a condenser, a capillary tube, a freezing evaporator and a freezing evaporator. Provided is a direct-cooled small refrigerator.

1 is a cycle diagram of a conventional direct cooling small refrigerator

2 is a schematic diagram of a freezer compartment evaporator of a conventional direct-cooling small refrigerator.

3 is a configuration of a refrigerator compartment evaporator of a conventional direct cooling small refrigerator

4 is a cycle diagram of a direct-cooling small refrigerator in accordance with the present invention

5 is a block diagram of a freezer compartment evaporator of a direct-cooling small refrigerator according to the present invention.

6 is a block diagram of a refrigerator compartment evaporator of a direct-cooling small refrigerator according to the present invention.

7 is a graph showing the compressor operation rate of the conventional refrigeration refrigerator

8 is a graph showing the operation rate of the compressor of the refrigerator freezer according to the present invention

Explanation of symbols for main parts of the drawings

6: first refrigeration evaporator 7: refrigeration evaporator

8: second refrigeration evaporator

4 is a cycle diagram of a direct-cooling small freezer according to the present invention, the refrigerant of the high temperature and high pressure discharged from the compressor (1) is a heat dissipation passing through the condenser (2) and decompressed through the capillary tube (3) Becomes a refrigerant.

The low temperature low pressure refrigerant first absorbs heat while passing through the first freezing evaporator 6 and the second freezing evaporator 8 of the freezing chamber 4 and then passes through the refrigerating evaporator 7 of the refrigerating compartment. After absorbing it, it is sucked into the compressor.

The first freezing evaporator 6 installed in the freezer compartment is configured in a lattice form by bending a dotted line as shown in FIG. 5, and is installed in a form surrounding the top, bottom and both sides of the freezer compartment.

The second freezing evaporator 8 installed in the freezing compartment is in the form of a flat plate and is attached to the rear wall of the freezing compartment.

The freezer refrigerator of the present invention as described above will be shown even when the outside temperature is low when the freezing chamber reaches the -18 ℃ by the second freezing evaporator 8 installed in the freezer compartment.

Therefore, unlike the conventional freezer, which performs low temperature compensation by a separate heater even when the outside air temperature is low, since the low temperature compensation can be performed by the first freezing evaporator 7 and the second freezing evaporator 8 by itself, the heater and There is no need for electronics in this regard.

Figure 8 is a graph showing the compressor operation rate of the refrigerator according to the present invention shows that the operating range that can maintain the freezer compartment at -18 ℃, like the hatched portion over the entire range of the outside air temperature.

As described above, the direct-cooling freezer according to the present invention can compensate for the low temperature by using the evaporator for freezing without using a heater, thereby reducing manufacturing costs and reducing power consumption by eliminating expensive heaters and electrical equipment.

Claims (1)

In a direct-cooling small freezer comprising a compressor, a condenser, a capillary tube, a first freezing evaporator and a refrigeration evaporator, a second freezing evaporator is installed between the first freezing direct chiller and the refrigerated direct cooling evaporator, and the second freezing refrigerator is installed. Direct cooling evaporator is a small direct freezer, characterized in that attached to the rear wall of the freezer compartment.