KR20230060152A - Refrigerant distribution device using round tube - Google Patents

Abstract

The present invention relates to a refrigerant distribution device using a circular tube, which can be easily manufactured through compression processing of a circular tube, and can prevent corrosion, which is a problem caused by existing welding of different materials, when a pipe and the refrigerant distribution device are welded. To this end, the present invention provides the refrigerant distribution device comprising: a distributor body to one end of which a pipe connected to an expansion valve is coupled, to the other end of which a plurality of capillaries coupled to an evaporator are coupled, and which is formed by machining a circular tube, to include a refrigerant distribution part for distributing, to the plurality of capillaries, refrigerant flowing thereinto from the expansion valve; and an inner insert tube which is installed inside the distributor body and has an orifice-type nozzle hole formed in the center thereof to increase the flow rate of the refrigerant flowing into the distributor body and flowing to the refrigerant distribution part. The refrigerant distribution part includes: a plurality of cylindrical distribution channels divided in the circumferential direction of the distributor body; and a plurality of connections provided between the two adjacent cylindrical distribution channels to connect the two cylindrical distribution channels, and making close contact with each other at the center of the refrigerant distribution part to close open side portions of the cylindrical distribution passages. The cylindrical distribution passages are formed by deforming, into a cylindrical shape, first regions located on the circumference of the circular tube forming the distributor body, by rolling. The connections are formed by deforming the first regions and second regions located between the first regions, from the outside of the circular tube toward the center.

Description

Refrigerant distribution device using round tube

The present invention relates to a refrigerant distribution device for a refrigerating apparatus, and more particularly, to insert an inner tube having an orifice-shaped nozzle hole into a circular tube, and press-processing a part of the circular tube, wherein the inner tube is embedded and a number of It relates to a refrigerant distribution device configured using a circular tube made to easily configure a refrigerant distribution device in which a cylindrical distribution passage is formed.

In general, a refrigeration warehouse is a facility for storing stored goods such as fish or meat so as not to deteriorate, and is configured to prevent decay or deterioration of stored goods by maintaining an internal temperature at a low state.

In this way, a refrigerating device is used to maintain the internal temperature of the refrigerated warehouse at a low temperature below freezing.

The refrigerating device includes a compressor that compresses refrigerant and discharges it in a high-temperature, high-pressure gas state, a condenser that exchanges heat with air (heat release) to change the compressed refrigerant into a high-temperature and high-pressure liquid state, and adiabatically expands the condensed refrigerant to lower temperatures. It consists of an expansion valve that changes to a low-pressure liquid state and an evaporator that cools the surrounding air by exchanging heat with air (heat absorption) of the low-temperature and low-pressure liquid refrigerant. The refrigerant from the evaporator is returned to the compressor and It is made to cycle the condenser and expansion valve again.

1 is a perspective view showing an example of a conventional refrigerating apparatus for a refrigerating warehouse, and FIG. 2 is a schematic diagram showing an internal structure of a conventional refrigerating apparatus for a refrigerating warehouse.

In the refrigerating device for a freezer warehouse, a blowing fan 14 is installed on one side of a case constituting a main body 12, and the blowing fan 14 is connected to an electrically operated motor 16 to flow air while operating. It is done.

Inside the main body 12, an evaporator 20 connected to an expansion valve (not shown) and a compressor (not shown) is installed.

In the refrigerating apparatus for a refrigerated warehouse configured as described above, the evaporator 20 receives a low-temperature and low-pressure refrigerant liquid from an expansion valve and cools the surrounding air through heat exchange between the surrounding air and the refrigerant, and the cooled air around the evaporator is blown by a fan ( 140) is supplied to the inside of the freezer.

Meanwhile, the evaporator 20 is configured to receive the low-temperature, low-pressure refrigerant liquid supplied from the expansion valve through the refrigerant distributor 30 .

3 shows an internal structure diagram of a conventional refrigerant distributor.

The refrigerant distributor 30, which is widely used in the prior art, is composed of one refrigerant inlet 31 formed on one side and a plurality of distribution passages 32 formed on the other side, and the refrigerant inlet 31 and the distribution passage ( 32) are connected to each other so that the refrigerant introduced through the refrigerant inlet 31 is distributed through a plurality of distribution passages 32.

Meanwhile, a pipe extending from an expansion valve is coupled to the refrigerant inlet 31, and a capillary tube connected to an evaporator circuit is coupled to each refrigerant distribution channel 32.

Therefore, the refrigerant flowing into the refrigerant inlet 31 from the expansion valve through the pipe is dispersed into several branches through the plurality of distribution passages 32 inside the refrigerant distributor 30, and through the plurality of capillaries provided in the evaporator. supplied to the evaporator circuit.

On the other hand, the refrigerant flowing into the refrigerant distributor 30 from the expansion valve is in the form of a mixture of liquid and gas, in order to prevent the refrigerant from being uniformly dispersed into the plurality of distribution passages 32 due to the difference in flow velocity between the liquid and the gas. To this end, an orifice-shaped nozzle hole 33 is formed at the refrigerant inlet 31 to increase the flow rate of the refrigerant.

Although the conventional refrigerant distributor configured as above is manufactured by processing brass, there is a problem in that it is not easy to manufacture due to the difficulty of processing so that the refrigerant inlet and the plurality of distribution channels are connected to each other inside.

In addition, in order to weld and combine the pipe and capillary made of copper pipe to the refrigerant distributor made of brass, the welding rod used for welding the refrigerant pipe (copper pipe + copper pipe) cannot be used, and a welding rod suitable for welding copper and brass must be used. This is cumbersome, and welding of different materials is not good, so a high skill level of the operator is required, and after welding, there is a problem in that corrosion and leakage occur frequently compared to a welded part of the same kind of material.

Registered utility model registration number 20-0246414 (2001.10.17. notice)

The present invention has been made in consideration of the above problems, and an object of the present invention is a method of inserting an inner tube having an orifice-type nozzle hole into the circular tube and pressing a part of the circular tube into which the inner tube is inserted. It is an object of the present invention to provide a refrigerant distribution device configured by using a circular tube to easily manufacture a refrigerant distribution device having an orifice and a plurality of distribution passages formed therein.

Another object of the present invention is to weld and combine a pipe connected to an expansion valve and a capillary tube connected to an evaporator to a refrigerant distribution device, thereby preventing the occurrence and progress of corrosion due to welding of existing dissimilar materials in advance to achieve a more sound quality A refrigerant distribution device configured using a circular pipe that can prevent refrigerant from leaking at the junction between the refrigerant distributing device and the pipe by implementing a welded portion and can more easily weld the pipe and the refrigerant distribution device. is in providing

The present invention, which achieves the above object and eliminates the conventional defects, has a pipe connected to the expansion valve coupled to one end, a plurality of capillaries coupled to the evaporator coupled to the other end, and expanding a distributor body formed by processing a circular tube to include a refrigerant distribution unit for distributing refrigerant introduced from the valve to a plurality of capillary tubes; and an inner pipe body installed inside the distributor body and having an orifice-type nozzle hole formed in the central portion to increase the flow rate of the refrigerant flowing into the distributor body and flowing into the refrigerant distribution unit. A plurality of cylindrical distribution passages formed to be dispersed in a direction, and a plurality of connecting parts formed to connect two cylindrical distribution passages between two adjacent cylindrical distribution passages and to close the open side portions of the cylindrical distribution passages by being in close contact with each other at the center of the refrigerant distribution section. The cylindrical distribution flow path is formed by deforming a first region located on the circumference of a circular tube forming a distributor body into a cylindrically rolled shape, and the connection portion is formed between the first region and the first region It provides a refrigerant distribution device configured using a circular tube, characterized in that the second region located is formed by deforming from the outside of the circular tube toward the center.

Meanwhile, in the refrigerant distribution device configured using the circular tube, the distributor body includes: a large-diameter portion processed into the refrigerant distribution portion by compression processing; a small diameter portion formed to have a relatively smaller inner diameter than the large diameter portion; and a joint formed to connect the large diameter part and the small diameter part between the large diameter part and the small diameter part to form a distributor body together with the large diameter part and the small diameter part, and have an inner diameter gradually expanding from the small diameter part to the large diameter part; may consist of

On the other hand, in the refrigerant distribution device configured using the circular tube, the inner tube body includes: a cylindrical support having an outer circumferential surface for supporting the small diameter portion from the inside while being in close contact with the inner circumferential surface of the small diameter portion; And a conical support formed at one end of the cylindrical support in an integral structure and having an outer circumferential surface for supporting the joint from the inside while being in close contact with the inner circumferential surface of the joint. The portion may be made to support it without being deformed.

On the other hand, in the refrigerant distribution device configured using the circular pipe, the distributor body is formed through a process of expanding a part of the copper pipe having the same inner / outer diameter as the small diameter part, so that the large diameter part, the small diameter part and the joint are integrally structured. can be formed

Meanwhile, in the refrigerant distribution device configured using the circular tube, a concavo-convex portion formed by additionally bending a portion of the connection portion to prevent the refrigerant from flowing through the connection portion may be further formed in the connection portion.

According to the present invention having the above characteristics, a refrigerant distribution device having a plurality of distribution passages can be easily configured by arranging an inner pipe body inside a distributor body composed of a large diameter part, a small diameter part, and a connection part, and compressing and processing the large diameter part. be able to

In addition, when the distributor body is made of copper pipe, it is possible to improve productivity by increasing the convenience of welding work that connects the pipe extending from the expansion valve and the capillary pipe connected to the evaporator to the refrigerant distributor, as well as improving the quality of the welded part. It is possible to prevent leakage of refrigerant due to defects and corrosion of a welded portion formed between the refrigerant distribution device and the pipe.

In addition, the uneven portion formed in the cylindrical distribution passage and the connecting portion connecting the cylindrical distribution passage prevents the refrigerant from flowing through the connecting portion, thereby enabling a more uniform distribution of the refrigerant.

1 is a perspective view showing an example of a conventional refrigeration apparatus for a refrigerated warehouse;
2 is an internal configuration diagram briefly showing the internal structure of a conventional refrigeration apparatus for a refrigerated warehouse;
3 is an internal structure diagram of a conventional refrigerant distributor;
4 is a perspective view of a refrigerant distribution device according to a preferred embodiment of the present invention;
5 is a front view of a refrigerant distribution device according to a preferred embodiment of the present invention;
6 is a plan view of a refrigerant distribution device according to a preferred embodiment of the present invention;
7 is a cutaway perspective view showing the internal structure of a refrigerant distribution device according to a preferred embodiment of the present invention;
8 is a perspective view showing a state before the inner tube according to the present invention is inserted into the distributor body;
9 is a plan view of a refrigerant distribution unit showing a state in which irregularities are further formed at the joint according to the present invention;
10 is a cross-sectional view of an inner pipe body according to the present invention;
11 is a plan view showing a state in which the large-diameter portion of the dispenser body according to the present invention is pressed and processed into a plurality of cylindrical distribution passages;
12 is a perspective view showing a state in which a refrigerant distribution device according to the present invention is connected to an expansion valve and a pipe extending from an evaporator;

Hereinafter, a preferred embodiment of the present invention will be described in detail in connection with the accompanying drawings. In describing the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description will be omitted.

Figure 4 is a perspective view of a refrigerant distribution device according to a preferred embodiment of the present invention, Figure 5 is a front view of the refrigerant distribution device according to a preferred embodiment of the present invention, Figure 6 is a refrigerant distribution device according to a preferred embodiment of the present invention 7 is a cutaway perspective view showing the internal structure of the refrigerant distribution device according to a preferred embodiment of the present invention, Figure 8 is a perspective view of the inner tube body 120 according to the present invention is inserted into the distributor body 110 Figure 9 is a plan view of the refrigerant distribution unit 114 showing a state in which the concavo-convex portion 117 according to the present invention is further formed at the joint 113, Figure 10 is an internal 11 is a plan view showing a state in which the large-diameter portion 111 of the distributor body 110 according to the present invention is compressed and divided into a plurality of cylindrical distribution passages, and FIG. 12 is a cross-sectional view of the tube body 120 according to the present invention A perspective view showing a state in which the refrigerant distribution device according to is connected to the expansion valve and the pipe P1 extending from the evaporator is shown.

The refrigerant distribution device configured using a circular tube according to a preferred embodiment of the present invention is configured to be configured using the same copper tube as the pipe (P1) connected to the expansion valve and the capillary tube (P2) connected to the evaporator. It consists of a body 110 and an inner tube body 120.

The distributor body 110 has a two-stage structure of a large diameter part 111 and a small diameter part 112, and a cone-shaped joint 113 is formed between the large diameter part 111 and the small diameter part 112. It is formed to connect the neck portion 111 and the small diameter portion 112.

On the other hand, the small diameter portion 112 may be composed of a cylindrical copper pipe having an inner diameter slightly larger than the outer diameter of the pipe P1 so that the pipe P1 extending from the expansion valve can be inserted into and coupled thereto. The neck portion 111 may be composed of a copper pipe having a larger inner diameter than the small diameter portion 112, and the joint portion 113 connects one end of the small diameter portion 112 and one end of the large diameter portion 111 to each other, It may be composed of a copper tube formed to have an inner diameter that gradually expands from the small diameter portion 112 toward the large diameter portion 111.

In this way, the large-diameter portion 111, the small-diameter portion 112, and the joint portion 113 forming the distributor body 110 are separately manufactured, and then coupled to each other through welding to form one distributor body 110. However, in order to completely eliminate the risk of leakage through integration of the large diameter part 111, the small diameter part 112, and the joint part 113, the same as the small diameter part 112 of the distributor body 110 to be manufactured The large diameter part 111, the small diameter part 112, and the joint part 113 are integrally formed through a process of expanding one end of a copper pipe having an inner/outer diameter to the same size as the large diameter part 111 (110). ) is preferably formed.

On the other hand, the large-diameter portion 111 is formed to form the refrigerant distribution portion 114 while being deformed by compression processing.

The refrigerant distribution unit 114 includes a plurality of cylindrical distribution passages 115 formed to be distributed in the circumferential direction of the distributor body 110 and two cylindrical distribution passages 115 between two adjacent cylindrical distribution passages 115. It is composed of a plurality of connection parts 116 formed to connect and close the open side part of the cylindrical distribution passage 115 by being in close contact with each other at the central part of the refrigerant distribution part 114.

In order for such a refrigerant distribution part 114 to be formed by compression processing of the large diameter part 111, a plurality of first regions 111a forming cylindrical distribution passages 115 around the circumference of the large diameter part 111. ) and a plurality of second regions 111b forming the connection portion 116, the second region 111b is located between the first regions 111a and the first regions 111a, The first region 111a and the second region 111b are repeatedly continuous along the circumference of the large diameter portion 111 so that the first region 111a is located between the region 111b and the second region 111b. do.

On the other hand, the cylindrical distribution passage 115 is formed by deforming the first region 111a into a cylindrical shape, and the connection portion 116 is formed by pressing the second region 111b from the outside of the large diameter portion 111 It can be formed while being deformed in the direction of the center of the large diameter portion 111.

More specifically, the second area 111b located on the circumference of the large diameter portion 111 having a cylindrical cross section is locally pressed from the outside of the large diameter portion 111 toward the center using a compression tool T, While deforming, the large-diameter portion 111 is compressed so that the plurality of second regions 111b located on the circumference of the large-diameter portion 111 are simultaneously deformed, and the plurality of second regions 111b are formed of the large-diameter portion 111. The second region 111b is compressed until they meet and come into close contact with each other at the center, and in the process of compressing and deforming the second region 111b in this way, a The located first region 111a is rolled to form a cylindrical distribution channel 115 .

Meanwhile, the large-diameter portion 111 of the distributor body 110 according to a preferred embodiment of the present invention is formed by compression processing to form three cylindrical distribution passages 115 .

The three cylindrical distribution passages 115 formed in the above manner have the same inner/outer diameter, and the capillary tube P2 is inserted into each cylindrical distribution passage 115 and coupled thereto.

In addition, a concavo-convex portion 117 may be further formed on the connection portion 116 of the distributor body 110 according to the present invention.

The uneven portion 117 may be formed by additionally bending a portion of the connecting portion 116 so that a portion of the connecting portion 116 has a structure in which a portion of the connecting portion 116 protrudes convexly in the lateral direction of the connecting portion 116. ) closes the gap between the connecting parts 116 more effectively, so that the refrigerant in the cylindrical distribution passage 115 passes through the gap between the connecting parts 116 and the other cylindrical distribution passage 115. It blocks the flow to the refrigerant, and through this, more uniform distribution of the refrigerant is possible.

The inner tube body 120 increases the flow rate of the refrigerant flowing into the small diameter portion 112 so that the refrigerant is uniformly distributed in a plurality of cylindrical distribution passages 115, and is fixedly installed inside the distributor body 110. And, the orifice type nozzle hole 121 for increasing the flow rate of the refrigerant introduced through the small diameter portion 112 is formed in the central portion.

Meanwhile, in the process of forming the refrigerant distribution part 114 by compressing the large diameter part 111, the inner tube body 120 supports the small diameter part 112 and the joint part 113 from the inside to form the small diameter part 112 and the small diameter part 112. It is desirable to prevent the joint 113 from being deformed.

To this end, the inner tube body 120 according to a preferred embodiment of the present invention is in close contact with the inner circumferential surface of the small diameter portion 112, the cylindrical support portion 122 having an outer circumferential surface for supporting the small diameter portion 112 from the inside, and the cylindrical support portion ( 122) is formed as an integral structure at one end of the joint portion 113, and consists of a conical support portion 123 formed with an outer circumferential surface that supports the joint portion 113 from the inside while being in close contact with the inner circumferential surface of the joint portion 113.

Meanwhile, the cylindrical support 122 and the conical support 123 have an integral structure, and the orifice-shaped nozzle hole 121 is formed from the cylindrical support 122 through the conical support 123.

On the other hand, the orifice-type nozzle hole 121 has a first section 1211 in which the passage area gradually decreases, a second section 1212 in which the reduced passage area is maintained at a certain interval, and a passage area gradually increased. It consists of a third section 1213, and the first section 1211, the second section 1212, and the third section 1213 are formed sequentially and continuously based on the flow direction of the refrigerant, so that the refrigerant enters the inner tube 120 ) It is configured to form an orifice-type nozzle hole 121, which is a passage passing through.

Such an inner tube body 120 may be made of a material different from that of a copper tube, such as brass.

The refrigerant distribution device according to the present invention configured as above is a distributor body including a large diameter part 111, a small diameter part 112 and a joint part 113 through a process of expanding one end of a copper pipe having a constant diameter ( 110), and in a state where the prepared inner tube body 120 is inserted into the distributor body 110, the second regions 111b located on the circumference of the large diameter portion 111 of the distributor body 110 are locally formed. Manufactured through pressurization.

On the other hand, the inner tube body 120 is inserted into the distributor body 110 through the large diameter portion 111, and a portion of the outer circumferential surface of the inner tube body 120 inserted into the distributor body 110 is a small diameter portion 112 Is in close contact with the inner circumferential surface of and the remaining part is in close contact with the inner circumferential surface of the joint (113).

The distributor body 110 into which the inner tube 120 is inserted is put into a dedicated press, and the dedicated press locally presses the second region 111b located on the circumference of the large diameter portion 111 of the distributor body 110 to In this process, the first region 111a is rolled to form a cylindrical distribution passage 115, and the second region 111b is closely attached to each other to close the side portion of the cylindrical distribution passage 115. to form a structure.

In the large-diameter portion 111 processed in the above manner, the pressurized and deformed portion, that is, the second region 111b, contacts the inner tube body 120 while the inner tube body 120 moves inside the distributor body 110 or the distributor body 110. It is desirable to prevent separation from the body 110 .

The refrigerant distribution device according to the present invention manufactured through the above process is disposed between the evaporator and the expansion valve constituting the refrigerating device, and the pipe P1 extending from the expansion valve is inserted into the small diameter portion 112. are combined, and a plurality of capillaries (P2) extending from the evaporator circuit of the evaporator are inserted into and coupled to the cylindrical distribution passage (115) formed in the large diameter portion (111).

Meanwhile, since the pipe (P1) extending from the expansion valve, the capillary pipe (P2) extending from the evaporator circuit, and the refrigerant distribution device are all equally made of copper, the pipe (P1) and the capillary pipe (P2) are fixed to the refrigerant distribution device. In doing so, it is possible to perform the work while applying the welding rod and welding method used when combining the existing copper pipes and copper pipes as they are, so the convenience of work is improved, and the refrigerant distribution device and pipe (P1) and the refrigerant distribution device and capillary (P2 ), it is possible to prevent leakage of refrigerant from the welded portion even during long-term use by improving the quality of the welded portion formed between the welded portion.

The present invention is not limited to the specific preferred embodiments described above, and various modifications can be made by anyone having ordinary knowledge in the art to which the present invention belongs without departing from the gist of the present invention claimed in the claims. Of course, such changes are within the scope of the claims.

<Description of symbols for main parts of drawings>
110: distributor body 111: large diameter part
112: small diameter portion 113: joint portion
114: refrigerant distribution unit 115: cylindrical distribution passage
116: connection part 120: inner pipe body
121: orifice type nozzle hole 122: cylindrical support
123: conical support

Claims (5)

A pipe (P1) connected to the expansion valve is coupled to one end, a plurality of capillary tubes (P2) coupled to the evaporator are coupled to the other end, and the refrigerant flowing from the pipe (P1) is passed through the plurality of capillary tubes (P2). a distributor body 110 formed by processing a circular tube to include a refrigerant distribution unit 114 for distribution; and
It is installed inside the distributor body 110, and an orifice-type nozzle hole 121 is formed in the central portion to increase the flow rate of the refrigerant flowing into the distributor body 110 and flowing into the refrigerant distribution unit 114. ); is composed of,
The refrigerant distributor 114 includes a plurality of cylindrical distribution passages 115 formed to be distributed in the circumferential direction of the distributor body 110, and two cylindrical distribution passages 115 between two adjacent cylindrical distribution passages 115. It is composed of a plurality of connection parts 116 formed to close the open side part of the cylindrical distribution passage 115 by being in close contact with each other in the central part of the refrigerant distribution part 114,
The cylindrical distribution passage 115 is formed by deforming the first area 111a located on the circumference of the circular tube forming the distributor body 110 into a cylindrical shape, and the connection part 116 is formed by first A refrigerant distribution device configured using a circular tube, characterized in that the second area 111b located between the area 111a and the first area 111a is formed by deforming from the outside of the circular tube toward the center.
The method of claim 1,
The distributor body 110,
A large-diameter portion 111 processed into the refrigerant distribution portion 114 by compression processing;
a small diameter portion 112 formed to have a relatively smaller inner diameter than the large diameter portion 111; and
The large diameter part 111 and the small diameter part 112 are connected between the large diameter part 111 and the small diameter part 112 to form the distributor body 110 together with the large diameter part 111 and the small diameter part 112. A refrigerant distribution device configured using a circular tube, characterized in that composed of;
The method of claim 2,
The inner tube body 120,
A cylindrical support portion 122 having an outer circumferential surface for supporting the small diameter portion 112 from the inside while being in close contact with the inner circumferential surface of the small diameter portion 112; and
It is formed as an integral structure at one end of the cylindrical support part 122, and is in close contact with the inner circumferential surface of the joint 113 while supporting the joint 113 from the inside. A refrigerant distribution device configured using a circular tube, characterized in that the small diameter part 112 and the joint part 113 are supported without being deformed in the process of compressing the neck part 111 into the refrigerant distribution part 114.
The method of claim 1,
The distributor body 110 is formed through a process of expanding a part of a copper pipe having the same inner/outer diameter as the small diameter part 112, so that the large diameter part 111, the small diameter part 112, and the joint part 113 are integrated. A refrigerant distribution device configured using a circular tube, characterized in that formed in the structure.
The method of claim 1,
Constructed using a circular tube, characterized in that a concave-convex portion 117 is formed by additionally bending a part of the connection portion 116 to prevent the refrigerant from flowing through the connection portion 116 is further formed on the connection portion 116. Refrigerant distribution system.

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