KR20030052280A - Structure of thermostat-sensor-portion for refrigerator - Google Patents

Abstract

PURPOSE: A structure of a thermostat part of a refrigerator is provided to selectively sense not only the interior thermostat of a freezer compartment but also the interior thermostat of a refrigerator compartment. CONSTITUTION: A structure of a thermostat part of a refrigerator(30) includes a dividing member diving a freezer compartment(40) and a refrigerator compartment(50) for storage of articles; a temperature sensor(70) installed to the freezer compartment, to sense the interior thermostat; and an opening and shutting plate(92) formed near the temperature sensor. The opening and shutting plate opens and shuts a thermostat-sensing hole(86) formed through the diving member. The interior thermostat of the freezer compartment and refrigerator compartment is sensed by selectively opening and shutting the thermostat-sensing hole with the opening and shutting plate and thus, the interior thermostat of the refrigerator is properly controlled.

Description

Structure of temperature sensor unit of refrigerator {Structure of thermostat-sensor-portion for refrigerator}

The present invention relates to a refrigerator, and more particularly to a structure of a temperature sensor unit for detecting the internal temperature of the direct-cooling 1-door refrigerator.

Refrigerators are largely divided into indirect cooling (hereinafter referred to as intercooling) and direct cooling (direct cooling) according to the cooling method. In the intercooled refrigerator, the evaporator is installed in a space separate from the storage space of the refrigerator, and the inside air of the refrigerator is flow circulated using an air flow device such as a fan to maintain the inside of the refrigerator at a desired temperature. In general, the storage capacity is applied to medium and large refrigerators.

In contrast, in a small refrigerator having a relatively small storage capacity, the evaporator is mounted to directly expose the storage space of the refrigerator. The inside of the refrigerator is maintained at a desired temperature by directly exchanging heat with the air in the storage space.

1 is a side cross-sectional view showing the internal configuration of a conventional direct-cooling refrigerator. As shown in the drawing, in general, the refrigerator 1 is divided into a freezer compartment 3 and a refrigerating compartment 5. The freezing compartment 3 and the refrigerating compartment 5 are partitioned by a plate-shaped partition 7, and are closed when the door 9 forming the front appearance of the refrigerator 1 is closed.

And, the inside of the freezing chamber (3) is installed so that the direct cooling evaporator 11 is directly exposed. In the direct cooling evaporator 11, the working fluid flowing and circulating between components constituting the refrigerating cycle and the internal air of the freezing chamber 3 in contact with the surface of the direct cooling evaporator 11 are exchanged.

As such, the internal air of the freezing chamber 3 is cooled to a relatively low temperature by heat exchange, and the cold air is naturally convection through a gap formed between the front end of the partition 7 and the inner surface of the door. It is delivered to the refrigerating compartment (5) located in the lower portion of the freezing compartment (3).

On the other hand, the temperature sensor 13 is mounted on one surface of the direct cooling evaporator (11). The temperature sensor 13 is mounted in close contact with the surface of the direct-cooling evaporator 11, and detects the temperature of the air inside the freezing chamber 3 in contact with the temperature sensor 13, so that the inside of the refrigerator 1 is appropriate. The internal temperature of the refrigerator 1 is controlled to maintain the temperature.

However, the structure of the temperature sensor unit of the refrigerator according to the prior art as described above has the following problems.

As described above, in the conventional direct-cooling 1-door refrigerator 1, the freezing chamber 3 and the refrigerating chamber 5 are partitioned by the partition 7 and the temperature sensor 13 which senses the internal temperature of the refrigerator 1. ) Is attached to the direct cooling evaporator 11 installed in the freezing chamber 3.

As such, the temperature sensor 13 installed in the freezer compartment 3 has the freezer compartment 3 and the freezer compartment by the partition 7 when a large amount of load such as food or beverage is stored in the refrigerator compartment 5 only. 5) is partitioned, so that the load of the refrigerating compartment 5 is not sensed, so that the internal temperature of the refrigerating compartment 5 cannot be properly controlled.

Therefore, when a large amount of load is mainly stored in the refrigerating compartment 5, the internal temperature is not properly controlled, resulting in a problem that the food stored in the refrigerating compartment 5 is damaged or the beverage is deteriorated.

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, to provide a structure of the temperature sensor unit of the refrigerator to selectively detect and control not only the internal temperature of the freezer compartment but also the internal temperature of the refrigerator compartment as needed. will be.

1 is a side cross-sectional view showing the internal configuration of a conventional direct-cooling one-door refrigerator.

Figure 2 is a side cross-sectional view showing the structure of the temperature sensor unit of the refrigerator according to a preferred embodiment of the present invention.

Figure 3 is a partial cutaway perspective view showing the structure of the temperature sensor unit of the refrigerator in the present embodiment.

Figure 4 is a partial cutaway perspective view showing the configuration of the partition in the present embodiment.

Explanation of symbols on the main parts of the drawings

30: refrigerator 40: freezer

50: freezing chamber 60: direct cooling evaporator

70: temperature sensor 80: partition

81: door 82: top plate

83: lower plate 84: fastening ring

86: Temperature sensing ball 87: Tightening groove

88: guide rib 89: opening and closing plate seat

90: guide channel 92: opening and closing plate

94: opening and closing handle

According to a feature of the present invention for achieving the above object, the present invention, a partition member for partitioning the freezer compartment and the refrigerating compartment for storing the storage, a temperature sensor installed in the freezer compartment for sensing the internal temperature, And an opening and closing plate adjacent to the temperature sensor and opening and closing the temperature sensing hole formed through the partition member.

According to the present invention, the opening and closing plate is fitted to both ends of the guide channel formed on one side of the partition member is fastened and guided in a sliding manner to open and close the temperature sensing hole.

The present invention as described above by controlling the internal temperature of the freezer compartment as well as the freezer compartment of the refrigerator, if necessary, there is an effect of preventing the food or beverage stored in the refrigerating chamber to be damaged or altered.

Hereinafter, a preferred embodiment of the temperature sensor unit structure of the refrigerator of the present invention as described above will be described in detail with reference to the accompanying drawings.

Figure 2 is a side cross-sectional view of the structure of the temperature sensor unit of the direct-cooling 1-door refrigerator according to a preferred embodiment of the present invention. As shown in the drawing, the refrigerator 30 includes a freezing compartment 40 and a refrigerating compartment 50. In general, the freezer compartment 40 is located at the top of the refrigerator 30, the refrigerating chamber 50 is located at the bottom of the refrigerator (30). In addition, the inside of the freezer compartment 40 and the refrigerating compartment 50 stores a storage such as food or drink.

Inside the freezing chamber 40, a direct cooling evaporator 60 is installed to directly expose the storage space. The direct-cooling evaporator 60 lowers the internal air temperature of the freezing compartment 40 by allowing the working fluid to flow and circulate between components constituting the freezing cycle and the internal air of the freezing compartment 40.

In addition, a temperature sensor 70 is closely attached to the surface of the direct cooling evaporator 60 between the direct cooling evaporator 60 and the partition 80 to be described below. The temperature sensor 70 detects the internal temperatures of the freezer compartment 40 and the refrigerating compartment 50 as necessary to allow the temperature adjusting means to adjust the internal temperature of the refrigerator 30.

On the other hand, the freezing compartment 40 and the refrigerating compartment 50 is partitioned by a plate-shaped partition 80, it is sealed by a door 81 that forms the front appearance of the refrigerator (30). The partition 80 includes an upper plate 82 forming an upper surface and a lower plate 83 forming a lower surface. A plurality of fastening rings 84 are formed at side edges of the upper plate 82. The fastening ring 84 is inserted into the fastening groove 87 of the lower plate 83 to be described below serves to fasten the upper plate 82 and the lower plate 83.

In addition, a temperature sensing hole 86 is formed through one side of the upper plate 82. The temperature sensing hole 86 is formed at a position corresponding to the temperature sensor 70 and is opened and closed by an opening and closing plate 92 to be described below.

A plurality of fastening grooves 87 corresponding to the fastening rings 84 are formed at side edges of the lower plate 83. The fastening ring 84 is inserted into the fastening groove 87. In addition, a temperature sensing hole 86 is formed at one side of the lower plate 83. The temperature sensing hole 86 of the upper plate 82 and the temperature sensing hole 86 of the lower plate 83 are formed at positions corresponding to each other. When the upper plate 82 and the lower plate 83 are coupled, the partition 80 Is formed to penetrate).

In addition, as illustrated in FIG. 4, the guide ribs 88 protrude from the upper surface of the lower plate 83 around both side surfaces of the temperature sensing hole 86 to prolong the front and rear directions of the refrigerator 30. Is formed. When the upper plate 82 and the lower plate 83 are fastened to each other, the guide rib 88 forms a guide channel 90 together with the lower surface of the upper plate 82 adjacent to the temperature sensing hole 86. The guide channel 90 serves to guide the opening and closing plate 92 to slide in the front-rear direction of the refrigerator 30.

In addition, the opening and closing plate 92 is seated when the temperature sensing hole 86 is opened in one side of the upper surface of the lower plate 83 adjacent to the temperature sensing hole 86, that is, in the front direction of the refrigerator 30. Opening and closing plate mounting portion 89 is formed.

The upper plate 82 and the lower plate 83 formed as described above are fastened by the fastening ring 84 and the fastening groove 87 to open the freezing chamber 40 and the refrigerating chamber 50 of the refrigerator 30. The partition 80 which partitions is formed.

3, the opening and closing plate 92 is formed in the shape of a square plate, and the side end portions of the opening and closing plate 92 are respectively inserted into the guide channel 90 to guide the sliding plate to open and close the temperature sensing hole 86. In addition, an opening / closing handle 94 for manually manipulating the opening and closing plate 92 is protruded downward on one side of the lower surface of the opening and closing plate 92.

Hereinafter, the operation of the temperature sensor unit structure of the refrigerator according to the present embodiment configured as described above will be described in detail.

First, referring to Figure 2, looks at the internal air flow of the direct-cooling 1-door refrigerator. In the freezing compartment 40, the working fluid inherent in the direct cooling evaporator 60 and the internal air of the freezing compartment 40 are heat-exchanged, so that the internal air is cold at a relatively low temperature. The cold air is transferred from the freezer compartment 40 to the refrigerating compartment 50 in a natural convection manner through a gap formed between the front end of the partition 80 partitioning the freezing compartment 40 and the refrigerating compartment 50 and the inner surface of the door. The inside of the refrigerating compartment 50 is maintained at an appropriate temperature.

When the direct-cooling one-door refrigerator is mainly used in the refrigerating compartment 50, or when a large amount of load such as food or beverage is stored in the refrigerating compartment 50, the opening and closing plate 92 is operated to form the partition 80. The temperature sensing hole 86 is opened.

The opening and closing plate 92 having side ends respectively fitted to the guide channel 90 pulls the opening and closing handle 94 in the direction of the door 81, and is guided by the guide channel 90 in a sliding manner to open and close the opening and closing plate 94. It is seated on the plate mounting portion 89, and opens the temperature sensing hole (86). When the temperature sensing hole 86 is opened, the internal air of the refrigerating chamber 50 is in contact with the temperature sensor 70.

The temperature sensor 70 installed adjacent to the temperature sensing hole 86 may detect the internal air temperature of the refrigerating chamber 50 through the temperature sensing hole 86 opened as described above. The inside of the can be controlled to the proper temperature.

In addition, when the refrigerator 30 is used mainly in the freezing chamber 40 or when there is no load in the refrigerating chamber 50, the temperature sensor 70 is sealed by the opening and closing plate 92 so that the temperature sensor 70 is closed. The internal air temperature of the freezer compartment 40 is sensed. At this time, since the temperature sensing hole 86 is sealed by the opening and closing plate 92, the temperature sensor 70 is not affected by the internal air temperature of the refrigerating chamber 50 as in the prior art.

As described above, the present invention is configured to sense not only the freezing chamber 40 but also the internal air temperature of the refrigerating chamber 50, so that the internal temperature of the refrigerator 30 can be appropriately controlled.

Within the scope of the basic technical idea according to the present invention, other modifications will be possible to those skilled in the art.

As described above in detail, the present invention is a direct-cooling one-door refrigerator in which the evaporator and the temperature sensor are installed in the freezer compartment, through which a temperature sensing hole is formed at one side of the partition adjacent to the temperature sensor, and the temperature sensing hole is opened and closed as necessary. By opening and closing, the internal air temperature of the refrigerating compartment as well as the freezer compartment can be sensed at the same time to control the inside of the refrigerator to an appropriate temperature.

Therefore, when a large amount of load such as food or drink is stored in the freezer compartment, the temperature sensor detects this and maintains the inside temperature of the freezer compartment appropriately, thereby preventing food from being damaged or deteriorated. There is.

Claims (2)

A partition member for partitioning a freezer compartment and a refrigerating compartment for storing stocks; A temperature sensor installed in the freezing chamber and detecting an internal temperature; A structure of a temperature sensor unit of a refrigerator, comprising: an opening / closing plate adjacent to the temperature sensor and opening and closing a temperature sensing hole formed through the partition member. The structure of claim 1, wherein the opening and closing plate is fitted with both ends coupled to a guide channel formed at one side of the partition member and guided in a sliding manner to open and close the temperature sensing hole.