KR20130014008A - A capillary tube distributor for refrigeration cycle device - Google Patents

Abstract

PURPOSE: A capillary tube distributor for a refrigeration cycle device is provided to strengthen the bond strength of the capillary tube and to easily assembly the capillary tube distributor. CONSTITUTION: A capillary tube distributor for a refrigeration cycle device comprises a main body of a distributor(10), a capillary tube fastening stopper(30), and a capillary tube(20). The main body of the distributor is connected to the one side of a refrigerant pipe. And a mesh for a refrigerant dispersion is inserted into the refrigerant pipe. The capillary tube fastening stopper is a rear plate which is welded and is connected at the other side of the distributor in which a plurality of the through-holes is penetrated and is formed to the circular form. The capillary tube is inserted and is welded into the through-hole of the capillary tube fastening stopper. The capillary tube fastening stopper is welded and is connected to the capillary tube, is coupled to the main body of the distributor, and is completed. The main body of the distributor inserts a mesh and forms a forcing groove(11) for fixing the mesh location around the circle. The main body of the distributor forms the forcing groove for fixing the capillary tube location around the circle.

Description

A Capillary Tube Distributor for Refrigeration cycle device

The present invention provides a capillary distribution container for a refrigeration cycle apparatus, comprising: a distributor body having a refrigerant pipe connected to one side thereof and a refrigerant dispersing mesh inserted into the refrigerant pipe side; A thick plate weld-bonded to the other side of the distributor, the capillary binding stopper having a plurality of through-holes through which a capillary is inserted; A capillary tube inserted into the through hole of the capillary binding plug and welded; The capillary dispensing container of the refrigerating cycle device, characterized in that the capillary tube is welded to the capillary binding stopper, and then completed by binding to the distributor body.

In general, a refrigeration cycle device is a device using a thermal cycling principle, and is widely used for storing food and cooling indoors, such as a refrigerator or an air conditioner.

The refrigeration cycle device is largely composed of a compressor, a condenser, an expansion valve, an evaporator as follows.

The compressor (COMPRESSOR MOTOR) is a device for increasing the pressure to the saturation pressure corresponding to the condensation temperature to suck the low-temperature low-pressure gas refrigerant evaporated in the evaporator to liquefy condensation in the next condenser.

The condenser CONDENSER is a device (condensation heat exchanger) to heat the high-temperature, high-pressure gas refrigerant discharged from the compressor to the surrounding air or cooling water to release the heat of the gas refrigerant to condense and liquefy.

EXPANSION VALVE is a device in which the condensed and liquefied refrigerant is rapidly released through a narrow place to a wide place (cross action), and the refrigerant is released from pressure and starts to evaporate.

The evaporator (EVAPORATOR) is a device (evaporation heat exchanger) for introducing a low-temperature low-pressure refrigerant passing through the expansion valve and heat exchanged with the object to be cooled (evaporation heat exchanger), a part that achieves the purpose of refrigeration using the heat of evaporation of the refrigerant.

The compressor increases the pressure to a saturation pressure corresponding to the condensation temperature so as to suck the gas refrigerant of low temperature and low pressure evaporated from the evaporator to liquefy condensation in the next condenser.

The compressor, the condenser, the expansion valve and the evaporator of the refrigeration cycle are connected to the refrigerant pipe.

The heat exchanger constituting the refrigerating cycle as described above is provided with a manifold for improving heat exchanger efficiency, and the refrigerant passing through the heat exchanger during the operation of the refrigerating cycle is arranged in the transverse direction inside the main body of the heat exchanger. A plurality of refrigerant pipes pass through a plurality of branching pipes and flow out to the lamination pipes, or flow through the lamination pipes and repeat the process of distributing the plurality of branching pipes.

The heat exchanger formed of the plurality of multi-branched tubes is connected to each of the capillaries, and has a capillary distribution tube to distribute the refrigerant to the plurality of capillaries.

5 is a side cross-sectional view of a capillary distribution container of the prior art, according to the structure of the capillary distribution container according to the prior art of FIG. 5, a plurality of capillaries are welded to the capillary distribution container, and a constant refrigerant flows into each capillary. It is introduced into the heat exchanger formed of a plurality of multi-branched tube through the capillary shape.

In general, the capillary tube is welded to the capillary distribution tube by hand, according to the prior art method, the coupling position of the capillary tube is not uniform, so that the insertion depth is perpendicular to the plane to be different for each capillary and horizontally coupled to each capillary tube There is a problem that is very difficult.

Such capillary causes a problem that the heat exchange capacity of a heat exchanger formed of a multi-branched tube is rapidly lowered because a uniform amount of refrigerant is not distributed in the capillary distribution tube.

In addition, there is a problem that the production efficiency of the capillary distribution container is also very low.

In order to solve the above problems, Patent Registration 10-0813293 proposes a structure in which a cap that is divided up and down in a capillary distribution container as a cap and a cap is formed by forming a hole in the cap.

However, according to the pre-registered patent, the stopper is separated up and down, it is difficult to match the through-holes provided separately in the up and down during assembly, there is a problem that the work maneuver increases.

In addition, there is a problem that the assembly difficulty of the capillary tube still remains even according to the above-mentioned patent.

Patent Registration 10-0813293

The present invention is to solve the above problems, the insertion depth of the capillary tube is fixed only by the process of inserting the capillary tube into the capillary distribution container, reinforcing the strength of the capillary tube, easy assembly of the capillary distribution container To provide a capillary dispensing container.

In order to achieve the above object, the present invention provides a capillary distribution container of a refrigeration cycle apparatus, comprising: a distributor body having a refrigerant pipe connected to one side and a refrigerant dispersing mesh inserted into the refrigerant pipe side; A thick plate weld-bonded to the other side of the distributor, the capillary binding stopper having a plurality of through-holes through which a capillary is inserted; A capillary tube inserted into the through hole of the capillary binding plug and welded; The capillary dispensing container of the refrigeration cycle device is characterized in that it is completed by welding the capillary to the capillary binding stopper, and then bound to the distributor body.

According to claim 1, wherein the distributor body is preferably a capillary distribution container of the refrigeration cycle device, characterized in that the mesh position fixing indentation groove for fixing the mesh is formed around the circumference after the insertion of the mesh.

In addition, the distributor body is preferably a capillary distribution container of the refrigeration cycle device, characterized in that the capillary position fixing indentation groove for defining the insertion distance of the capillary binding stopper is formed around the circumference.

In addition, the through hole of the capillary binding stopper is preferably a capillary distribution container of the refrigeration cycle device, characterized in that to form a capillary insertion stopper to form an inward step at the end to limit the insertion distance of the capillary.

The present invention provides a capillary distribution container of a refrigerating cycle apparatus, in which the depth of insertion of the capillary tube is fixed by only the step of inserting the capillary into the capillary distribution container, reinforcing the bond strength of the capillary tube, and the assembly of the capillary distribution container is easy. There is an advantage.

1 is a side cross-sectional view and a front view of the present invention
Figure 2 is a side cross-sectional view and a front cross-sectional view of another embodiment of the present invention
Figure 3 is a side cross-sectional view of the capillary binding plug of Figure 1
Figure 4 is a side cross-sectional view of the capillary binding plug of Figure 2
Figure 5 is a side cross-sectional view and a front view of the prior art method

Hereinafter, the present invention will be described with reference to the drawings. In the following description of the present invention, a detailed description of related arts or configurations will be omitted when it is determined that the gist of the present invention may be unnecessarily obscured will be.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to be exemplary, self-explanatory, allowing for equivalent explanations of the present invention.

1 is a side cross-sectional view and a front view of the present invention, FIG. 2 is a side cross-sectional view and a front cross-sectional view of another embodiment of the present invention, FIG. 3 is a side cross-sectional view of the capillary binding plug of FIG. 1, and FIG. 4 is of FIG. 2. Side cross-sectional view of the capillary binding plug, Figure 5 is a side cross-sectional view and a front view of the prior art method.

As shown in the figure, the present invention relates to a capillary distribution container of a refrigeration cycle device, and is composed of a mesh 40, a distributor body 10, a capillary 20, and a capillary binding stopper 30.

The refrigeration cycle apparatus used in the present invention is a device using a thermal circulation principle, widely used in the storage of food and indoor cooling, such as a refrigerator or air conditioner, the heat exchanger constituting the refrigeration cycle manifold (Manifold) to improve the heat exchanger efficiency Is installed, the refrigerant passing through the heat exchanger during the operation of the refrigeration cycle passes through the plurality of branch pipes through a plurality of refrigerant pipes are arranged in the transverse direction inside the body of the heat exchanger flows out to the lamination pipe, or the lamination pipe Introduced through it is to repeat the process of dispensing into the plurality of multi-branched tube.

As such, the heat exchanger formed of a plurality of multi-branched tubes is connected to each of them by a capillary tube, and has a capillary distribution tube as in the present invention for distributing refrigerant to the plurality of capillary tubes.

As shown in FIG. 1, the distributor body 10 of the present invention is a cylinder in which a refrigerant pipe 50 is connected to one side and a refrigerant dispersing mesh 40 is inserted into the refrigerant pipe 50.

The refrigerant dispersion mesh 40 is a well-known component generally known to uniformly disperse the refrigerant flowing from the capillary tube 20.

The distributor body 10 is a connection between the coolant tube 50 and the capillary tube 20, and the coolant equal distribution function of the coolant tube 50 and the capillary tube 20 should be performed.

On the other hand, the capillary tube 20 is composed of a multi-branched tube, the capillary tube 20 should have the same coupling structure to the distributor body 10 in order to perform the above-described refrigerant uniform dispersion function.

In addition, it is noted that, in terms of productivity, it is possible to improve productivity when welding convenience is provided, whether manual welding or automatic welding.

1 and 2, the capillary binding plug 30 is included to improve productivity while forming the same coupling structure of the capillary tube 20 as shown in FIGS.

Capillary binding plug 30 of the present invention is a thick plate welded to the other side of the distributor main body 10, a plurality of through-holes for inserting the capillary tube 20 is a stopper formed in a circular shape.

3 and 4, the capillary binding stopper 30 of the present invention is formed of a thick plate having a predetermined thickness, and is formed of a stopper blocking the distributor body 10 formed of a tubular body. It has three features formed through the through-hole 31 to charge.

First, to form the same coupling structure, the capillary binding plug 30 is a capillary binding plug 30 formed in a circular shape so as to equally connect a plurality of capillaries 20 forming a multi-branched tube at equal intervals. The centrifugal of the circular centers are arranged at equal intervals and are combined.

The through hole 31 is formed for the coupling of the capillary tube 20, as shown in FIGS. 1 and 2 are formed at equal intervals around the centrifugal capillary stopper 30, the capillary tube 20 Is inserted into the through hole and welded together.

The thickness of the capillary binding plug 30 determines the insertion depth of the capillary 20, and the insertion depth of the capillary 20 ensures the tightness of the coupling and the uniformity of the coupling.

2 and 4, the end of the through-hole 31 of the capillary binding stopper 30 is formed inwardly to provide a capillary insertion stopper 32. .

According to such a structure, the insertion distance of the capillary tube 20 is equally determined when the capillary tube 20 is inserted.

The cap form of the capillary binding plug 30 is an element that allows the cap of the capillary 20 is pre-coupled as described above to be inserted into the distributor body 10 and brazed, thereby providing an advantage in improving productivity.

On the other hand, when brazing the stopper to the distributor body 10, there is a fear that the material penetrates into the distributor body 10 through the gap of the stopper to block the capillary, the thickness of the thick plate of the capillary binding plug 30 Will also perform the function of blocking the penetration of these materials.

Therefore, the capillary binding cap 30 preferably has a thickness larger than the penetration distance of the material during welding.

As such, the present invention is to assemble the capillary binding plug 30 to which the capillary tube 20 is coupled to the distributor body 10 in advance, and the insertion distance of the capillary binding plug 30 to the distributor body 10 is also divided into the distributor body 10. ) It is an important functional factor to determine the internal capacity, and the insertion distance should be equal for even production quality.

In the present invention, for this purpose, the indentation groove for fixing the position of the mesh 40 to the outside of the distributor body 10 and defining the insertion distance of the capillary binding stopper 30 is formed around the periphery.

That is, the indentation groove is divided into a mesh position fixing indentation groove 11 and the capillary position fixing indentation groove 12 is formed.

It will be apparent to those skilled in the art that the present invention may be embodied in many other specific forms without departing from the spirit or essential characteristics thereof.

Therefore, the present invention is not limited to the above-described embodiments, and various changes can be made by any person having ordinary skill in the art without departing from the gist of the present invention as claimed in the following claims. It will be said that the technical spirit of this invention is to the extent possible.

10: distributor body 11: press-fitting groove for fixing the mesh position
12: press-fit groove for fixing the capillary position 20: capillary tube
30: capillary binding stopper 40: mesh
50: refrigerant tube

Claims (5)

In the capillary distribution container of the refrigeration cycle device,
A distributor body having a refrigerant pipe connected to one side and a refrigerant dispersing mesh inserted into the refrigerant pipe inside;
A thick plate weld-bonded to the other side of the distributor, the capillary binding stopper having a plurality of through-holes through which a capillary is inserted;
A capillary tube inserted into the through hole of the capillary binding plug and welded;
Consist of
A capillary dispensing container of a refrigeration cycle device, characterized in that the capillary tube is welded to the capillary stopper and then joined to the distributor body. According to claim 1, wherein the distributor body
Capillary distribution container of the refrigeration cycle apparatus, characterized in that the mesh position fixing indentation groove for fixing the mesh is formed around the circumference after the mesh is inserted. The distributor body of claim 2, wherein
Capillary dispensing container of the refrigeration cycle device, characterized in that the capillary position fixing indentation groove for defining the insertion distance of the capillary binding stopper formed around the circumference. The through-hole of the capillary binding cap according to any one of claims 1 to 3
Capillary distribution container of the refrigeration cycle device, characterized in that to form a capillary insertion stopper by forming an inward step at the end to limit the insertion distance of the capillary tube. The thickness of the capillary binding stopper is
Capillary distribution container of the refrigeration cycle device, characterized in that greater than the penetration distance of the material during welding.

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