KR20000005823U - Refrigerant distributor for air conditioners - Google Patents

Abstract

This paper relates to an air conditioner, in particular by welding the branch tubes to the distributor by joining a barrier plate forming a plurality of coupling holes to a distributor for distributing the gas and liquid refrigerant supplied to the inlet pipe through the capillary to the evaporator. When combined, even though the melt penetrates into the distributor, the refrigerant of the distributor can be uniformly supplied for each path of the evaporator, thereby improving the cooling capacity.

Distributor that mixes refrigerant passing through the compressor, condenser and capillary to the evaporator

When the plurality of branch pipes are joined by welding, the air conditioner is provided with a blocking plate for creating a space in the distributor to prevent the melt of the electrode from flowing into the distributor and supplying a non-uniform amount of refrigerant. A refrigerant distributor for air is provided.

Description

Refrigerant distributor for air conditioners

This paper relates to an air conditioner, in particular by welding the branch pipes to the distributor by joining a barrier plate forming a plurality of coupling holes to a distributor for distributing the gas and liquid refrigerant supplied to the inlet pipe through the capillary to the evaporator. When combined, even when the molten liquid penetrates into the distributor, it is possible to uniformly supply the refrigerant of the distributor by each path (Path) of the evaporator relates to a refrigerant distributor for an air conditioner to improve the cooling capacity.

The refrigeration cycle of a general air conditioner is shown in FIG.

The refrigeration cycle is a compressor (1) for sucking the low-temperature, low-pressure gas refrigerant to compress at high temperature, high pressure,

A condenser (2) for dissipating the high-temperature, high-pressure gas refrigerant supplied from the compressor (1) into air and liquefying it;

A plurality of capillary tubes 3 for liquefying the medium and high pressure liquids supplied from the condenser 2 to low temperature and low pressure, and

A distributor 5 for supplying and branching the refrigerant of the capillary tube 3 through the inlet tube 4,

A low temperature low pressure refrigerant branched from the distributor 5 is supplied for each pass to provide an evaporator 9 for absorbing and evaporating external heat.

In addition, the distributor 5 has a structure in which the inside is composed of a space portion, and the plurality of branch pipes 7 are coupled to the plurality of through holes 6 to be fixed by welding.

Referring to the operation and effect according to the conventional configuration as described above are as follows.

First, as a means for coupling the plurality of branch pipes 7 to the distributor 5 is a typical means for coupling by a welding operation.

That is, when the branch pipe (7) separately made with a plurality of through holes (6) formed in the distributor (5) as shown in Figure 2, the stopper 10 of the branch pipe (7) to the inlet of the through hole (6) To be joined in contact.

Then, by fixing the contact portion of the through hole 6 and the stopper 10 by welding, the joining operation of the branch pipe 7 is completed as shown in FIG.

At this time, the melt 8 generated during the welding operation is in a state of infiltrating into the distributor 5 through the through hole 6 as shown in FIG.

As described above, when the molten liquid 8 generated during welding penetrates into the distributor 5 and coagulates, a sharp imbalance occurs in the amount of the refrigerant supplied to the branch pipe 7.

That is, the gas and the liquid refrigerant after passing through the compressor 1, the condenser 2 and the capillary tube 3 are supplied to the distributor 5 through the inlet pipe 4 as shown in FIG. It is supplied for each pass of the evaporator (9) through 7), the refrigerant supplied to the distributor (5) hit the melt (8), the refrigerant is not supplied smoothly to the branch pipe (7) distributor ( 5) Since the time of staying inside increases, the amount of refrigerant supplied to each branch pipe 7 naturally becomes uneven.

Therefore, there is a problem that the cooling performance is lowered due to the non-uniformity of the refrigerant supplied to each of the branch pipes (7).

The purpose of this article for solving and solving such a conventional problem,

The purpose of improving the cooling capacity of the entire evaporator by uniformly distributing the refrigerant by supplying the gas and liquid refrigerant from the capillary tube naturally in the distributor and then uniformly supplying the path of the evaporator through a plurality of branch pipes. To provide.

In order to achieve the above object,

The purpose of this paper can be achieved by incorporating a barrier plate for forming a space in the distributor so that the refrigerant supplied into the distributor can be supplied uniformly to the branch pipe without hitting the melt generated when welding the branch pipe by welding. Will be.

1 is a view showing the configuration of a distributor coupled to a conventional refrigeration cycle

Figure 2 is a separate cross-sectional view showing a branch pipe coupled to a conventional distributor

Figure 3 is a cross-sectional view showing a branch pipe coupled to a conventional distributor

4 is a view showing the configuration of a distributor coupled to the refrigeration cycle of the present invention

5 is a cross-sectional view showing a branch pipe coupled to the dispenser of the present invention

6 is a cross-sectional view showing the branch pipe coupled to the dispenser of the present design

<Code Description of Main Parts of Drawing>

101-Compressor 102-Condenser

103-capillary 111-dispenser

112-Branch 113-Block

114-engagement hole 115-space

116-stopper 117-via

4 to 6 will be described in detail.

The melt of the welding rod when the plurality of branch pipes 112 are joined by welding to the distributor 111 which mixes the compressor 101, the condenser 102, and the refrigerant passing through the capillary tube 103, and supplies the refrigerant to the evaporator 104. In order to prevent the flow of the inside of the distributor 111 and the amount of refrigerant supplied unevenly, the blocking plate 113 is provided to make the space 115 inside the distributor 111.

In addition, a plurality of coupling holes 114 formed in the blocking plate 113 are provided in order to couple the plurality of branch pipes 112 into the interfit by the blocking plate 113.

The operation of this paper is as follows.

First, when the plurality of branch pipes 112 are coupled to the distributor 111 of the present disclosure, the branch pipes 112 are coupled holes formed in the through hole 117 and the blocking plate 113 formed in the distributor 111 as shown in FIG. 5. (114).

At this time, since the size of the coupling hole 114 of the blocking plate 113 is almost the same as the diameter of the branch pipe 112, the intermediate fitting is combined.

Then, when the coupling of the branch pipe 112 is completed, the stopper 116 and the inlet of the through hole 117 of the branch pipe 112 is in contact with the bar, the work is welded to the portion of the branch pipe 112 firmly ) Is fixed.

As described above, the molten liquid generated when the stopper 116 of the branch pipe 112 is welded around the branch pipe 112 is introduced into the distributor 111 between the through hole 117 and the outer diameter of the branch pipe 112. Most of the molten liquid remains as shown in FIG. 6 only in the space 115 formed by the blocking plate 113 of the distributor 111.

Therefore, the compressor 101 of the refrigerating cycle sucks gas refrigerant of low temperature and low pressure, compresses it to high temperature and high pressure, supplies it to the condenser 102, and the condenser 102 supplies the gas refrigerant of high temperature and high pressure into the air. It dissipates and liquidizes.

In addition, the medium-temperature, high-pressure liquid refrigerant liquefied in the condenser 102 is reduced in pressure by the capillary tube 103 to be liquefied to low temperature, low pressure is supplied to the distributor 111.

In addition, the refrigerant supplied to the distributor 111 may be smoothly supplied to the plurality of branch pipes 112 while hitting the blocking plate 113.

In particular, since the branch pipe 112 coupled to the coupling hole 114 of the blocking plate 113 is coupled by the intermediate fitting, the gap does not occur in the coupling portion, so that the refrigerant leaks into the space 115. There is no work.

As described above, it is possible to expect the improvement of the cooling capacity by the distribution of the refrigerant uniformly supplied in each pass of the evaporator 104.

In this way, the present invention combines a blocking plate for forming a space in the distributor so that the refrigerant supplied into the distributor can be uniformly supplied to the branch tube without colliding with the melt generated when welding the branch tube by welding.

The gas and liquid refrigerant supplied from the capillary tube are naturally induced in the distributor, and then uniformly distributed through a plurality of branch pipes to pass through the evaporator to improve the cooling ability of the entire evaporator by the uniform distribution of the refrigerant. Has

Claims (2)

Distributor that mixes refrigerant passing through the compressor, condenser and capillary to the evaporator When the plurality of branch pipes are joined by welding, the air conditioner is provided with a blocking plate for creating a space in the distributor to prevent the melt of the electrode from flowing into the distributor and supplying a non-uniform amount of refrigerant. Refrigerant distributor. The method of claim 1, And a plurality of coupling holes formed in the blocking plate to couple the plurality of branch pipes to the blocking plate in an intermediate fit.