KR19990018097U - Heat dissipation pipe structure of the refrigerator - Google Patents

Abstract

The present invention relates to a connection structure of the heat dissipation pipe of the refrigerator.

According to the present invention, a multi-bending part bent in multiple stages is formed between a connection part of a heat dissipation pipe connected to a part of a refrigeration cycle, and a fixing part of a heat dissipation pipe that enters an outer casing to be disposed at the front of the refrigerator. It is configured to absorb external shocks.

Description

Heat dissipation pipe structure of the refrigerator

The present invention relates to a structure of a heat dissipation pipe of a refrigerator, and more particularly, a structure of a heat dissipation pipe that bends the connection portion of the heat dissipation pipe in multiple stages to give its own vibration attenuation ability and to facilitate workability of the connected portion. It is about.

The heat line pipe in the refrigerator refers to a portion that allows a high temperature refrigerant to pass through the front of the refrigerator, and the dew line phenomenon occurs in the door part of the front of the refrigerator by configuring the refrigerant to pass through the front of the refrigerator. Is preventing.

The heat dissipation pipe is guided through the suction pipe in the evaporator, compressed by the compressor, and then introduced into the refrigerant in a liquefied state by the cone sensor, and then connected to a capillary tube through the above-described path to lower the refrigerant. The configuration will be described with reference to FIG. 1 illustrating such a connection structure.

The refrigerant from the evaporator (not shown) is in a gaseous state, which is guided through the suction pipe 2 and compressed by a compressor 4 installed inside the machine room 1 of the refrigerator. The refrigerant compressed by the compressor (4) is liquefied while passing through the condenser (6). At this time, the coolant is in a high temperature state, and the coolant in such a high temperature state is connected to the heat dissipation pipe inlet 10a through the connection portion Ca. The heat dissipation pipe 10 passes through the path as described above, and then leads to the heat dissipation pipe outlet 10b connected to the machine room again. The heat dissipation pipe outlet 10b is connected to the dryer 8 through a connection part Cb. The refrigerant leaving the heat dissipation pipe 10 is supplied to a capillary tube (not shown) after the moisture is removed from the dryer 8 and lowered into the evaporator.

It can be seen that the heat dissipation pipe has two connection parts Ca and Cb on such a path, and the connection parts Ca and Cb are usually connected by welding. And in order for the heat dissipation pipe 10 to go to the front side of the refrigerator, it must enter the inside of the outer casing 11 of the refrigerator, at which time it is supported in a fixed state with the outer casing in which the foam is filled.

When the above-mentioned refrigeration cycle is driven, vibration is inevitably generated by components such as a compressor. Such vibration may cause noise and damage connection parts Ca and Cb of the heat dissipation pipe 10. That is, as described above, the heat dissipation pipe 10 has two connection parts Ca and Cb and is fixed to the outer casing of the refrigerator at a portion adjacent to the connection parts Ca and Cb. That is, when one end of the connection parts Ca and Cb is fixed, when vibration is applied to the connection part, stress is concentrated on the welded part, and thus, the heat radiation pipe 10 may be damaged such as cracks. Damage to the heat radiation pipe 10 generated in this way has a fatal adverse effect on the refrigerator, such as leakage of the refrigerant.

And in order to connect the heat dissipation pipe 10 with other parts in the connecting portion, welding is required. In order to perform the welding, the heat dissipation pipe needs to be bent in a predetermined position, for example, in a vertical state. In the state where one end of (10) is fixed, there is a disadvantage that this operation is not easy.

An object of the present invention is to provide a structure of a heat dissipation pipe having a dustproof ability against vibration generated in the refrigerator.

Another object of the present invention is to provide a heat dissipation pipe that is easily connected to the surrounding pipe.

1 is a rear view of a refrigerator showing a connection structure of a conventional heat dissipation pipe;

Figure 2 is a rear view of the refrigerator showing a connection structure of the heat dissipation pipe according to the present invention.

* Explanation of symbols for main parts of the drawings

20: heat dissipation pipe 20a: heat dissipation pipe inlet

20b: Heat dissipation pipe outlet 20f, 20g: Fixed part

27a, 27b: multiple bending part 29: outer casing

Wa, Wb: Connection

According to the present invention for achieving the above object, between the inlet and the outlet of the heat dissipation pipe connected to a portion of the refrigeration cycle, and between the fixing portion of the heat dissipation pipe to enter into the outer casing to be disposed in the front of the refrigerator, respectively It is characterized by forming a bent multi-bending portion. Since the multi-bending part absorbs vibration generated in the refrigerator, it is possible to prevent the stress from being concentrated due to the connection part of the heat dissipation pipe.

According to one embodiment of the multi-bending part, it is bent in the vertical direction to the installation state of the heat dissipation pipe, it is configured to absorb the vibration more effectively.

Next, the present invention will be described in more detail with reference to the embodiments shown in the drawings.

As shown in FIG. 2 showing the configuration of the heat dissipation pipe according to the present invention, the heat dissipation pipe 20 is configured to attenuate the vibration generated in the refrigerator by forming the multiple bending portions 27a and 27b. It is a technical point.

The configuration will be described in more detail. The heat dissipation pipe 20 according to the present invention is configured to receive a refrigerant in a high temperature state liquefied in the condenser 26 through a connecting portion Wa, and to connect it to the front side of the refrigerator. At this time, the connecting portion Wa is connected by welding, and the heat dissipation pipe inlet 20a is supplied to the front of the refrigerator through the inside thereof in a state of being fixed to the outer casing 29. In addition, the multiple bending part 27a which is repeatedly bent from side to side is formed between the connection part Wa and the fixing part 20f of the outer casing. The multi-bending part 27a may be bent from side to side in the horizontal direction in consideration of the heat radiation pipe inlet 20a being connected to the outer casing 29 in the vertical direction.

The multiple bending part 27a is configured to absorb vibrations generated by the compressor 24 of the refrigerator, and thus, it is possible to prevent the stress concentration phenomenon occurring in the welded portion of the connection part Wa. In addition, by forming the multiple bending portions 27a at the heat dissipation pipe inlets 20a, the multi-bending portions 27a may have a predetermined margin with respect to the fixing portion 20f of the heat dissipation pipe 20 fixed to the outer casing 29. do. Therefore, during the operation of connecting the connecting portion Wa by welding, it will be possible to move or deform the heat dissipation pipe 20 to a desired position.

In addition, the heat dissipation pipe 20 introduced into the outer casing 29 by the heat dissipation pipe inlet 20a and circulated through the front side of the refrigerator again exits the outer casing 29 through the opposite side of the machine room. That is, the heat dissipation pipe outlet 20b is drawn out into the machine room through the fixing part 20g fixed to the outer casing 20g and is connected to the dryer 31. At this time, the connecting portion (Wb) connected to the dryer 31 is also connected to each other by welding, and another multiple bending portion between the fixing portion (20g) of the connecting portion (Wb) and the outer casing (29) (27b) is formed.

The role and function of the multiple bending part 27b is the same as the above-described multiple bending part Wa. That is, by absorbing the vibration generated by the compressor 24 or the like, the damage of the connection portion Wb with the dryer 31 is prevented, and at the same time, the heat dissipation pipe outlet 20b has a desired shape during the welding operation of the connection portion Wb. It becomes possible to bend by, and workability can be improved.

As shown in the drawing, the multiple bending part 27b is more effective to be bent several times in the vertical direction in consideration of the heat dissipation pipe shaft 20b and the dryer 31 being connected in a horizontal state.

According to the present invention configured as described above, it can be seen that a multi-bending portion is formed between the connection portion of the heat dissipation pipe and the fixing portion with the outer casing. Such a multi-bending part has the ability to absorb the vibration generated in the refrigerator, and thus, the connection parts Wa and Wb of the heat dissipation pipe connected by welding can be prevented from being damaged by the vibration. have.

In addition, since the multiple bending parts 27a and 27b also serve to provide the outer casing with an extra length of the heat dissipation pipe in the fixed fixing part, the work at the time of connection work by welding the connecting parts Wa and Wb is performed. To this end, it is possible to partially transform the heat dissipation pipe into a desired shape, thereby obtaining an effect of improving workability.

Claims (2)

A multi-bending portion bent in multiple stages is formed between the inlet and outlet of the heat dissipation pipe connected to a part of the refrigeration cycle and the fixing part of the heat dissipation pipe entering the outer casing to be disposed at the front of the refrigerator. Heat dissipation pipe structure of the refrigerator. The heat dissipation pipe structure of claim 1, wherein the multi-bending part is bent in a vertical direction to the installation state of the heat dissipation pipe.