KR830001672Y1 - Refrigerated refrigerators with coolers to focus the idea of freezers - Google Patents

Abstract

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Description

Refrigerated refrigerators with coolers to focus the idea of freezers

1 is a longitudinal sectional view of the present invention.

2 is an enlarged perspective view of the rear of the freezer compartment cooler.

3 is a schematic diagram of a cooling circulator.

4 is a schematic diagram of a cooling cycle in another embodiment of the present invention.

5 is a schematic diagram of a cooling cycle in another embodiment of the present invention.

The present invention relates to a refrigerator in which a minimum temperature portion is formed in a part of a freezer cooler.

In a so-called direct-cooling refrigerator in which the freezer compartment cooler is formed into a substantially rectangular box and the inside thereof is used as a freezer compartment, the freezer compartment is actually cooled uniformly from approximately the entire area of the inner side of the cooler. However, in this type of refrigerator, during the cooling operation, frost adheres to the entire area of the inner surface of the cold compartment cooler. Since this frost has a thermal insulation effect, it creates a drawback of reducing the cooling effect. Moreover, there is an inconvenience of frost on objects such as ice trays installed in the freezer compartment.

Therefore, the object of the present invention is that the freezer compartment cooler is composed of a low temperature section cooler and a minimum temperature partial cooler, so that the frosted area of the cooler of the freezer compartment can be reduced, and the cooling efficiency of the freezer compartment also increases, so that the accessories such as an ice tray etc. It is to provide a refrigeration cooler that can prevent the frost is attached.

Another object of the present invention is to provide a freezer cooler characterized in that the low temperature partial cooling zone and the lower temperature partial cooling zone is installed in the freezer compartment.

Another object of the present invention is to provide a freezer cooler characterized in that the cooler providing the low temperature partial cooling zone and the cooler providing the lowest temperature partial cooling zone are constituted by a single cooling cycle.

An embodiment of the present invention will be described in more detail below with reference to the accompanying drawings. 1 shows a refrigerator, where 1 is the main body of the refrigerator, and a cooling chamber 2 is formed inside the refrigerator, and a freezing chamber cooler 4 is installed in an upper region of the cooling chamber 2, and a freezing chamber 3 is formed inside. 5 is a cooler of a cooling chamber, and the cooler is installed in the upper part of the cooling chamber 2. As shown in FIG. 6 and 7 are condensers and compressors installed at the rear of the refrigerator and below the rear of the refrigerator, respectively. The freezer compartment cooler 4 as shown in FIG. 2 is constructed by, for example, welding two long evaporating tubes 9 and 10 to the outside of the body 8 of the cooler in a thermally conductive manner. The body 8 of the cooler is made of aluminum plate, has the shape of a rectangular box and its front face is open. A portion of the cooler body 8, for example, the upper portion 8a, forms the cooler 11 which provides the lowest temperature partial region. One evaporator 9 is mounted on the cooler 11 and the other evaporator 10 is mounted on the bottom 8d and left and right sides 8b and 8c of the cooler body 8.

As will be apparent from the description below, the cooler 11 is structured to provide a low temperature region and to reach a low temperature at least 5 ° C. lower than the coolers that make up the other parts of the cooler body 8, ie the left and right portions 8b, 8c and bottom 8d. It is. 12 is the door to the freezer compartment and 13 is the door to the freezer compartment.

The cooling cycle will be described with reference to FIG. In this cycle, between the inlet 7b and the outlet 7a of the compressor 7, another evaporator 10 which acts as a cooler for the condenser 6, the capillary tube 14, the cooler section 4 of the freezer compartment, and the cooler 5 for the freezer compartment, the freezer compartment The evaporator 9, which acts as a cooler for the cooler zone of cooler 4, is connected in sequence.

Explain the operation of this structure. When compressor 7 is operated, liquid coolant passing through condenser 6 and capillary 14 flows sequentially into evaporation tube 10, cooling chamber cooler 5 and evaporation tube 9, thereby cooling cooling chamber 2 and freezing chamber 3. However, the evaporation temperature of the liquid coolant in the evaporator tube 10, the cooling chamber cooler 5, and the evaporator tube 9 drops in the order of the evaporator tube 10, the cooling chamber cooler 5, and the evaporator tube 9. The reason is that when the pressure of the liquid coolant drops, evaporation occurs at low temperatures, and when the inlet 7b of the compressor 7 approaches, the pressure drops by the suction effect of the compressor 7. The cooler 11 in the lowest temperature zone provided by the evaporator 9 thus reaches a temperature at least 5 ° C. lower than the temperature of the cooler consisting of the other parts of the cooler body 8, ie the left and right parts 8b, 8c and the bottom 8d.

In general, frost is formed when the temperature of the cooler drops below 0 ° C. and attaches to the cooler. However, in this cooler there is a lowest temperature region where the temperature is lower than the other portions of the cooler, so that frost attached to the other portion of the cooler and sublimated at a relatively high temperature sublimes and collects in the lowest temperature region. This phenomenon occurs when the lowest temperature is at least 5 ° C lower than the other.

Thus, when frost attaches to the inner wall of the freezer compartment 3, i.e., the inner side of the freezer compartment cooler 4, there is a cooler body in the freezer cooler 4, because there is a minimum temperature cooler 11 at least 5 ° C lower than the rest of the cooler body. The frost caught on the coolers at the left and right portions 8b, 8c and 8d at the bottom portion 8 gradually sublimates to vapor.

The steam becomes West 21 on cooler 11 in the lowest temperature section and attaches to it. Thus, frost is concentrated in the lowest temperature zone 11 and no frost is trapped elsewhere.

Thus, in this embodiment, the frost attachment is concentrated on the lowest temperature cooler 11 and thus frost is prevented from being caught in the low temperature cooler composed of the left and right portions 8b, 8c and the bottom 8d of the cooler body 8. Thus, in contrast to the conventional refrigerators in Rigaki in the entire area of the inner surface of the choura of the freezer compartment, the cooling efficiency of the freezer compartment cooler 4 is greatly increased compared with the conventional refrigerators. Moreover, even if the heat installed in the refrigerator frosts on the tray-like body, the frost on the object is released from the object and moves to the lowest temperature cooler 11 immediately after insertion due to the sublimation effect described above. Thus, frost attachment to the refrigerated object is prevented permanently in a reliable manner.

In particular, in this embodiment, since the lowest temperature cooler 11 is installed in the upper part 8 of the cooler body 8, the frost is effectively concentrated on the lowest temperature cooler 11. The reason for this is that when the outside air enters the freezer compartment 3 due to the opening of the freezer compartment door 12, relatively hot moisture that enters the outside air enters the upper part of the freezer compartment 3, that is, the region of the lowest temperature cooler 11. Therefore, the moisture immediately attaches to the lowest temperature section 11 frost before being able to attach to the lower temperature section cooler.

The lowest temperature portion 11 need not be installed in the upper portion 8a of the cooler body 8, but may be of any desired purpose as long as it is installed in a part of the freezer compartment cooler 4.

Next, a cooling cycle adopted in another embodiment of the present invention will be described with reference to FIG. Evaporation tube for condenser 6, main tubing 14, solenoid valve 15, auxiliary capillary 16, freezer cooler 4, in sequence from outlet 7a between inlet 7b and outlet 7a of compressor 7 9 are lined up.

Thus, the evaporation tube 11 for the lowest temperature portion is arranged on the side of the inlet 7b of the compressor 7 of the series circuit consisting of the cooling chamber cooler 5 and the low temperature portion local evaporation tube 10. 17 is an axial passage capillary, one end of which is connected to the inlet of the solenoid valve 15 and the other end of which is connected to the outlet of the cooling chamber cooler 5. The side passage 18 is thus arranged in parallel with the series circuit consisting of the evaporator tube 10 and the cooling chamber cooler 5. The solenoid valve 15 is opened by a temperature controlled device (docean dome) when the temperature inside the cooling chamber 2 rises above the set degree and is closed when the temperature is lower than the set temperature.

When the compressor 7 is operated, the hot high pressure gaseous coolant compressed by the compressor 7 is supplied to the condenser 6 where it is converted to the low temperature high pressure liquid coolant. It passes through the main capillary 14 where its pressure is attenuated, and then when the solenoid valve 15 is opened, when the inside temperature of the cooling chamber 2 is lower than the set temperature, it passes through the solenoid valve 15 and the auxiliary capillary tube 16 and the The cooling chamber 5 is supplied to the cooling chamber cooler 5 and the evaporation tube 9 to be evaporated, and thus is converted into a gaseous coolant of low temperature and low pressure and returned to the compressor 7. Thus, the cooling chamber 2 and the freezing chamber 3 are cooled. However, the evaporation temperature of the liquid coolant in the evaporator 9 is lower than the temperature in the other evaporator 10. The reason is that the pressure of the liquid coolant is lowered and the temperature of evaporation is lowered and the pressure is reduced by the suction effect of the compressor 7 when approaching the inlet 7b of the compressor 7, while in particular the other evaporator 12 and the cooling chamber cooler 5 This is because it provides a pressure reducing effect on the evaporation tube 6.

Thus, the lowest temperature portion 9 provided by the evaporation tube 9 has a temperature of at least 5 ° C. lower than the temperature of the lowest temperature portion 8 provided by the other evaporation tube 10. That is, as described above with reference to FIG. 3, the frost concentrates on the lowest temperature portion, and this phenomenon is particularly observed when the temperature difference is 5 ° C or more.

When frost is trapped on the inner wall of the freezer compartment 3, i.e. the inner surface of the freezer compartment cooler 4, it attaches to the cold compartment cooler of the cooler body 11 since the lowest temperature cooler 11 is installed at a temperature of at least 5 ° C lower than that of the freezer compartment cooler 4. The frost gradually sublimates to vapor and reattaches again as frost to the cooler section 11. Thus, frost concentrates on the coolest part cooler 11 and no frost attaches to other parts.

The solenoid valve 15 is closed when the inside of the cooling chamber 2 is overcooled, that is, when the temperature in the cooling chamber 2 falls because of the set temperature. Thus, the liquid coolant passing through the main capillary 14 is directed to the evaporation tube 9 through the side passage 18 and bypasses the other evaporation tube 10 and the cooling chamber cooler 5.

Thus, overcooling of the cooling chamber 2 is prevented and therefore always maintained at the set temperature. Thus, the lowest temperature cooler 11 is cooled regardless of the incubation of the cooling chamber cooler 5 and the lower temperature cooler so that the above-mentioned frost concentration effect is permanently performed.

Thus, as described above, in this embodiment, the freezer compartment cooler 4 is divided into a cooler for the lowest temperature zone and a cooler for the low temperature zone, and into another evaporator tube 10, that is, a cold zone cooler and a cooling chamber cooler. In the configured series circuit, the connection of the evaporator 9, i.e. the lowest temperature zone cooler, is formed such that it is arranged inside the inlet 7b of the compressor 7.

Thus, the cold zone zone cooler 3 has a lower temperature than the cold zone zone cooler. As a result, frost on the cooler zone cooler is prevented and thus the cooling efficiency is significantly increased. Moreover, even if frost is attached to an object such as an ice tray housed in freezer 3, immediately after their insertion, due to the sublimation effect described above, frost on the object is liberated and the cooler is transferred to the cooler area cooler so that frost adheres to the attached object. Permanently and reliably prevented.

Furthermore, since the solenoid valve 15 which controls the flow of the liquid coolant to the series circuit is installed and the bypass line 18 for the series circuit is installed, the lowest temperature zone cooler is the cooling chamber cooler 5 and the lower temperature zone cooler. It can be cooled regardless of the load on it.

The connection position of the solenoid valve 15 and the connection relationship between the cooling chamber cooler 5 and the low temperature part regional cooler (other evaporator tube 10) are as shown in FIG. 5, where the same parts are given the same numbers as in FIG. In particular, in Fig. 5, the connection between the low temperature section cooler (other evaporator 10) and the cooling chamber cooler 5 is reversed, and the solenoid valve 15 is installed on the bypass line 18. In this case, the solenoid valve 15 is closed when the temperature in the cooling chamber 2 is higher than the set temperature. Further, instead of using the solenoid valve 15 as the flow control means, flow control can be performed by heat from a heater provided to heat the auxiliary capillary tube 16 to an appropriate range.

The invention is not limited to the embodiments shown in the drawings and described above, but can be variously modified without departing from the spirit thereof.

As described above, the present invention reduces the frost-attached area to the cooler of the freezer, thereby increasing the cooling efficiency and prevents frost-attached to an accessory such as an ice tray, and the lowest-temperature zone cooler is a cold zone zone cooler. And a refrigerator which can be cooled regardless of the load on the cooling chamber cooler.

Claims (1)

The compressor 7, the condenser 6, which is connected to the freezing chamber 3, the refrigerating chamber 2, the condenser 6, the capillary tube 14, and the like and circulates the refrigerant, is provided in the freezing chamber 3. In the known freezer having a low temperature cooler (10) connected to the capillary tube (14) and forming a low temperature portion in the freezer compartment (3), the implantation of the freezer compartment (3) is the lowest temperature cooler (9). And a minimum temperature cooler (9) installed in the freezer compartment (3) to be separated from the low temperature cooler (10) and cooled to a lower temperature than the low temperature cooler (10).