KR20140129630A - Module for freezing pipe rapidly - Google Patents

Abstract

Disclosed in the present invention is a module for rapidly freezing a pipe, which is manufactured in a module shape and is conveniently installed at a work site in order to form a pipe freezing system. The disclosed module for rapidly freezing a pipe comprises a first half module and a second half module which are combined with each other and surround the external circumference of a pipe. The first half module comprises: a first housing which has a half pipe shape; and a first cooling coil which is aligned inside the first housing in order to allow a refrigerant to flow and whose one side end, which is connected with a refrigerant cooling device in order to allow the refrigerant to flow, protrudes to the outside of the first housing. The second half module comprises: a second housing which has a half pipe shape; and a second cooling coil which is aligned inside the second housing in order to allow the refrigerant to flow and whose one side end, which is connected with the refrigerant cooling device in order to allow the refrigerant to flow, protrudes to the outside of the second housing. When the first half module and the second half module are combined, the other side end of the first cooling coil and the other side end of the second cooling coil are connected in order to allow the refrigerant to flow.

Description

[0001] The present invention relates to a module for freezing freezing pipe,

The present invention relates to a pipe freezing system for preventing leakage of water by freezing a proper part of a pipe to repair or replace a pipe at a point where leakage of water occurs, such as water, water, sewage, .

A pipeline is connected to a plant including a power plant, a general household such as a water supply system or a school system such as a school, and the flow of the system water is guided. It is necessary to freeze the front end and the rear end of the piping when it is necessary to repair the piping system due to leakage or damage of the piping system or when it is necessary to check the piping system. Or isolation is not possible.

Fig. 1 shows a device for rapidly freezing a pipe disclosed in Korean Patent Laid-Open No. 2008-0107297. 1, a cooling coil 23 is wound on two outer sides of a water pipe 30 to be wired in a water pipe exposed for regular maintenance or replacement of the water pipe, Is sealed by a coil jacket (26). The closed cooling coil 23 is then connected to the refrigerant cooling device (not shown) by way of the connection tubes 22, 24.

In this configuration, the discharged liquid refrigerant cooled in the refrigerant cooling apparatus (not shown) is supplied to the cooling coil 23 through the connection pipe 22, and the supplied liquid refrigerant is supplied to the cooling coil 23 , And is returned to the coolant cooling apparatus through the connection pipe (24). The inside of the closed coil jacket 26 is rapidly cooled by the refrigerant circulation process of the refrigerant circulation system, so that the water in the water pipe 30 wound around the cooling coil 23 is rapidly frozen.

However, since the piping freezing apparatus shown in Fig. 1 is a device for bending the cooling coil 23 in accordance with the outer diameter of the pipe 30 in the field, it takes a long time to work. Specifically, the cooling coil 23 may be a metal tube such as a copper tube having a good heat transfer coefficient, and it is difficult to bend the metal tube precisely along the outer circumferential surface of the cylindrical tube 30 in a working environment in which the metal tube is bent and installed directly in the field, It takes a long time. Therefore, the maintenance time and cost of the piping are increased.

The present invention provides a piping rapid freezing module that can be constructed in a module form in advance and simply installed at a work site to form a piping freezing system.

The present invention also provides a piping rapid freezing module capable of reducing the time and cost of piping maintenance work at a work site.

The present invention provides a refrigerator comprising a first half module and a second half module which are coupled to each other to surround and surround an outer circumferential surface of a pipe, the first half module comprising: a first housing in the form of a half pipe; And a first cooling coil which is arranged so as to allow a refrigerant to flow inside the first housing and which has one end portion connected to the refrigerant cooling device so as to be able to flow the refrigerant protruded to the outside of the first housing, The second half module includes a second housing in the form of a half pipe and a second housing which is arranged so as to allow the refrigerant to flow inside the second housing and has one end connected to the refrigerant cooling device so as to flow therethrough, And a second cooling coil protruded outside the second housing, wherein when the first half module and the second half module are coupled to each other, the other end of the first cooling coil and the other end of the second cooling coil Rapid pipe for refrigerant is connected to be able to flow provides a freezing module.

The other end of the first cooling coil and the other end of the second cooling coil may be connected by a male and female coupling structure.

According to the piping rapid freezing module of the present invention, in a field requiring piping repair or replacement, a pair of half modules are coupled to each other so as to surround the piping, and the end of the refrigerant coil is connected to the refrigerant cooling device, An icing system can be constructed. Therefore, the working time of piping maintenance in the field is shortened and the cost is reduced.

In addition, the piping rapid freezing module of the present invention can be disassembled into a pair of half modules after work in the field, and reused in other work sites, thereby reducing cost and waste of resources.

1 is a cross-sectional view showing a conventional pipe freezing apparatus.
FIG. 2 is a block diagram illustrating a piping freezing system having a piping rapid freezing module according to an embodiment of the present invention. Referring to FIG.
3 is an exploded perspective view of a piping rapid freezing module according to an embodiment of the present invention.
4 is a cross-sectional view taken along line IV-IV in FIG. 3, and shows a state in which the pair of half modules of FIG. 3 are coupled to each other.

Hereinafter, a piping rapid freezing module according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. The terminology used herein is a term used to properly express the preferred embodiment of the present invention, which may vary depending on the intention of the user or operator or the custom in the field to which the present invention belongs. Therefore, the definitions of these terms should be based on the contents throughout this specification.

FIG. 2 is a block diagram illustrating a piping freezing system having a piping rapid freezing module according to an embodiment of the present invention. Referring to FIG. Referring to FIG. 2, the piping freezing system 100 has a structure in which a part of the pipe 30 that guides the flow of the system water such as a water supply of a power plant, a factory, It is possible to easily and inexpensively maintain the system facility by freezing the systematic water only in the necessary part in the piping 30. [ The piping freezing system 100 is applied to the piping 30 on both sides of the valve 35 when a failure occurs in the valve 35 among the systematic water paths composed of the piping 30 and the valve 35 in Fig. Freeze the systematic part of the part. Accordingly, since the systematic water does not flow through the valve 35, the operation for replacing the valve 35 can smoothly proceed.

FIG. 3 is an exploded perspective view of a piping rapid freezing module according to an embodiment of the present invention, FIG. 4 is a cross-sectional view taken along line IV-IV in FIG. 3, to be. Referring to FIGS. 2 and 3, the tubing quick freezing module 110 according to the embodiment of the present invention includes a pair of first and second half modules 111 and 131. The pair of half modules 111 and 131 are coupled to each other to surround and surround the outer circumferential surface of the pipe 30.

The first half module 111 includes a first housing 112 and a first cooling coil 122. The first housing 112 is made in the shape of a half pipe and is formed by the joining of the shell plate 113, the inner plate 116, and the pair of side plates 119. The inner plate (116) is in surface contact with the outer peripheral surface of the pipe (30). The inner plate 116 is formed of a material having excellent heat transfer characteristics such as aluminum or an aluminum alloy and having a light weight. The outside sheathing 113 and the side sheathing 119 may be formed of the same material as the inner sheathing 116, but may be formed of a plastic material whose thermal insulation characteristics are relatively superior to those of the metal.

The first cooling coil 122 is arranged so as to allow the refrigerant to flow into an internal space formed inside the first housing 112. As the cooling coil 122, a metal tube of a copper (Cu) material commonly called a copper tube is used. This is because the heat transfer performance is excellent and it is relatively easy to bend and process. However, not only the copper tube is used for the cooling coil 122, but an alloy material containing copper (Cu) or a metal tube made of another metal material may be used.

The first cooling coil 122 in the inner space of the first housing 112 is bent along the zigzag path so as to be evenly distributed over the entire area of the inner plate 116. [ When the first cooling coil 122 is bent, the flow path inside the cooling coil 122 must be gently bent so as not to be blocked, and if the first cooling coil 122 is bent to be bent, the cooling coil 122 may be blocked . On the other hand, the method of bending the cooling coil 122 is not limited to bending along the zigzag path. One end of the first cooling coil 122 becomes a coolant inflow portion 123 to be flowably connected to the coolant cooling apparatus 105 and protrudes out of the first housing 112 through the side plate 119 .

The second half module 131 includes a second housing 132 and a second cooling coil 142. The second housing 132 is made in the shape of a half pipe and is formed by the joining of the shell plate 133, the inner plate 136, and the pair of side plates 139. The inner plate (136) is in surface contact with the outer peripheral surface of the pipe (30). The inner plate 136 is formed of a material having excellent heat transfer characteristics such as aluminum or an aluminum alloy and having a light weight. The outer plate 133 and the side plate 139 may be formed of the same material as the inner plate 136, but may be made of a plastic material having a thermal insulation property that is relatively superior to that of the metal.

The third cooling coil 142 is arranged so as to allow the refrigerant to flow into the inner space formed inside the first housing 132. As the second cooling coil 142, a metal tube of a copper (Cu) material commonly called a copper tube is used. This is because the heat transfer performance is excellent and it is relatively easy to bend and process. However, not only the copper tube is used for the second cooling coil 142, but an alloy material containing copper (Cu), or a metal tube of another metal material may be used.

The second cooling coil 142 in the inner space of the second housing 132 is bent along the zigzag path so as to be evenly distributed over the entire area of the inner plate 136. [ When the second cooling coil 142 is bent, the flow path inside the cooling coil 142 should be gently bent so as not to be blocked, and if the second cooling coil 142 is bent to be bent, the cooling coil 142 may be blocked . On the other hand, the method of bending the cooling coil 142 is not limited to bending along the zigzag path. One end of the second cooling coil 142 becomes a refrigerant outflow portion 143 to be flowably connected to the refrigerant cooling apparatus 105 and protrudes out of the second housing 132 through the side plate 139 .

The first half module 111 and the second half module 131 are coupled to each other so as to have a cylindrical shape when they are put together with the pipe 30 interposed therebetween. When the first half module 111 and the second half module 131 are coupled to each other, the other end of the first cooling coil 122, that is, the opposite end of the cooling medium inlet 123, 142, that is, the opposite side end of the refrigerant outflow portion 143 is connected to allow the refrigerant to flow through a male and female coupling structure.

3 and 4, the other end of the first cooling coil 122 protrudes slightly to the outside of the inner plate 116 of the first housing 112 as the male coil connecting portion 125. The inner plate 136 of the second housing 132 is formed with a cooling coil connection hole 137 so that the male coupling part 125 can be inserted when the first and second half modules 111 and 131 are coupled. The other end of the second cooling coil 142 is fixedly installed so as to be aligned with the cooling coil connection aperture 137 as a female coil connection 145. The diameter OD1 of the male-type coil connecting portion 125 is slightly smaller than the diameter OD2 of the female-type coil connecting portion 145. [ When the first half module 111 and the second half module 131 are coupled with each other, the male-type coil connecting part 125 is inserted into the cooling-coil connecting through-hole 137 and the distal end of the male- So that the first cooling coil 122 and the second cooling coil 142 are connected in series so that the refrigerant can flow.

Referring to FIG. 2 again, the first and second half modules 111 and 131 are coupled to each other to connect the first and second refrigerant coils 122 and 142, and then the module fixing unit 150 It is preferable to hold the joint firmly so as not to be separated during the operation. The first and second half modules 111 and 131 coupled to at least one module fixing part 150 are tightly wound. For example, the module fixture 150 may be a string of fabric or a synthetic resin, or a metal wire. Alternatively, the strip may be a removable strip formed by forming male and female velcro pads at both ends.

The piping rapid freezing module 110 is manufactured as described above and installed on the outer circumferential surface of the pipe 30. The refrigerant cooling device 105 is connected to the first and second cooling coils 122 and 142 connected in series, The refrigerant flows into the first and second cooling coils 122 and 142 to freeze the inside of the pipe 30. For example, liquefied nitrogen, freon gas, or the like is used as the refrigerant. Specifically, the refrigerant supply connection pipe 106 of the refrigerant cooling apparatus 105 is connected to the refrigerant inlet 123 through the connection hole 106a, and the refrigerant recovery connection pipe 107 is connected to the refrigerant outlet And the refrigerant cooling device 105 is connected to the piping rapid freezing module 110. [

When the refrigerant cooling apparatus 105 is operated, the refrigerant circulates through the heat exchange path composed of the refrigerant cooling apparatus 105 and the first and second cooling coils 122 and 142. For example, when liquid nitrogen is used as the refrigerant, the liquid refrigerant flowing out from the refrigerant cooling apparatus 105 flows into the first and second cooling coils 122 and 142 to absorb the ambient heat It evaporates. Then, the vaporized refrigerant is recovered by the refrigerant cooling apparatus 105, releases heat, and is liquefied again. The inside of the pipe 30 is frozen in a process in which the coolant is repeatedly circulated between the coolant cooling device 105 and the first and second cooling coils 122 and 142.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention. Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

30: piping 35: valve
100: piping freezing system 110: piping rapid freezing module
111, 131: half module 112, 132: housing
122, 142: cooling coil 150: module fixing section

Claims (2)

And a first half module and a second half module which are coupled to each other to surround and surround the outer circumferential surface of the pipe,
The first half module includes a first housing having a half pipe shape and a first housing arranged so as to allow the refrigerant to flow inside the first housing and having one end connected to the refrigerant cooling device so as to flow therethrough And a first cooling coil protruding outside the first housing,
The second half module includes a second housing in the form of a half pipe and a second housing which is arranged so as to allow a refrigerant to flow inside the second housing and is connected to the refrigerant cooling device through one end And a second cooling coil protruded outside the second housing,
Wherein when the first half module and the second half module are coupled to each other, the other end of the first cooling coil and the other end of the second cooling coil are connected to allow the refrigerant to flow therethrough. . The method according to claim 1,
Wherein the other end of the first cooling coil and the other end of the second cooling coil are connected by a male and female coupling structure.

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