KR20130072718A - Pipe connection apparatus and method thereof - Google Patents

Abstract

PURPOSE: A device and a method for connecting a pipe are provided to prevent the damage of a connecting part due to the pressure when being buried on the ground or an underground tunnel and to prevent the groundwater from flowing in the connecting part. CONSTITUTION: A device for connecting a pipe comprises first and second pipes (P1,P2), a shrinkable casing (C), a first welding mesh band (B1), and a second welding mesh band (B2). The shrinkable casing connects a first pipe and a second pipe to surround the end of the first and second pipes with both ends. The first welding mesh band is positioned between one end of the shrinkable casing and the end of the first pipe and parts of the shrinkable casing and the first pipe is mutually melted to surround. The second welding mesh band is surrounded by parts of the shrinkable casing and the second pipe through being melted.

Description

PIPE CONNECTION APPARATUS AND METHOD THEREOF

The present invention relates to a pipe connecting device and a method thereof.

Generally, heat generated from cogeneration plants and waste incinerators is supplied to large areas such as apartment complexes and commercial buildings through district heating systems. Normally, the heat supply is achieved by heating the water and then supplying the heated hot water to a building that requires heating and hot water supply through a heat transport pipe. Since the district heating system needs to supply hot water (heat) at a long distance from the heat source, it must supply hot water while minimizing heat loss. Double heat pipes are mainly used for heat transport pipes used to supply hot water.

The double insulation tube is composed of an inner tube, which is a steel pipe, an outer tube surrounding the outer circumferential surface of the inner tube, and a heat insulating material filled between the inner tube and the outer tube. Polyurethane is used as the insulation. The double heat insulation tube should not leak from the inner tube even after a long time, and the external water should not leak inside through the outer tube.

The piping lines constituting the district heating system are formed by connecting a plurality of double insulation pipes to each other. When connecting two double insulated pipes, there should be no leakage at the connection part.

FIG. 1 shows an example of a device for connecting a conventional double insulated pipe. As shown in Figure 1, the conventional double heat insulating tube connecting device is filled in the cylindrical heat shrink casing (C) and the heat shrink casing (C) surrounding the outer tube 11 of the two double heat insulating tube (10) Double-sided heat-sealed tape positioned between the heat insulating casing 13 to insulate the inner tube 12 of the double heat insulating tube 10 and the outer tube 11 of the heat shrink casing C and the double heat insulating tube 10. (14). The outer tube 11 of the double heat insulating tube 10 is made of high density polyethylene (HDPE; High Density PolyEthylene) material. The heat-shrinkable casing (C), both ends are respectively contracted so that one end is in close contact with the outer tube 11 of one double thermal insulation tube 10 and the other end is the outer tube of the other double thermal insulation tube 10 ( 11) An injection hole (not shown) is provided in the heat shrink casing C, and the injection hole is covered by a plug (not shown). When the double-sided heat fusion tape 14 is applied with heat, adhesives provided on both sides of the double-sided heat fusion tape 14 are melted to have an adhesive force. The double-sided thermal fusion tape 14 is also known as a mastic tape (MASTIC-TAPE).

The method of connecting the conventional double insulation tube 10 is as follows.

First, the heat shrink casing (C) is inserted into one of the two heat insulating tubes 10 of the two double heat insulating tubes 10 whose ends of the inner tube are exposed to the outside, and the inside of the two double heat insulating tubes 10 The two inner tubes 12 are connected to each other by welding while the end faces of the tubes 12 are in contact with each other. After the welding of the two inner tubes 12 is completed, the welded part is tested to determine that there is no risk of leakage, and the inner tube 12 exposed to the outside is covered with a heat shrink casing (C). Before covering the inner tube 12 portion exposed to the outside by the heat-shrinkable casing (C), the double-sided heat-sealed tape 14 is formed in a circular band shape at each end of the outer tube 11 of the two double heat insulating tubes 10. After attaching, cover the inner tube 12 portion exposed to the outside by the heat-shrinkable casing (C). Both ends of the heat-shrinkable casing C are heated with a torch lamp, respectively, to shrink both ends of the heat-shrinkable casing C to closely contact the outer tube 11. At this time, the double-sided heat fusion tape 14 located between the heat shrink casing (C) and the outer tube 11 is melted to seal between the heat shrink casing (C) and the outer tube (11). The urethane resin solution is foamed into the heat shrink casing C through the injection hole provided in the heat shrink casing C, and then the urethane resin is cured, and then the injection hole is sealed.

However, the device for connecting the conventional double thermal insulation tube 10 as described above, because the hot water flows into the inner tube 12 of the double insulation tube 10 in a state buried in the ground flows into the inner tube 12 Shrinkage and expansion occur due to the heat of the high temperature water, and after a long time, deformation occurs between the outer tube 11 and the heat shrink casing C of the double heat insulation tube 10 so that the outer tube 11 and the heat shrink casing C There is a gap in between. Groundwater is introduced into the interior of the double heat insulating tube 10 through the gap, which not only shortens the life of the double heat insulating tube 10, but also lowers the heat insulating performance of the double heat insulating tube 10. On the other hand, after sealing the inner tube 12 and the heat shrink casing (C) of the double heat insulation tube 10 with a double-sided heat-sealed tape 14, the connection portion of the inner tube 12 and the heat shrink casing (C) is waterproof tape ( (Not shown). However, even when the waterproof tape is wound, a gap is generated by long-term heat deformation.

An object of the present invention is to increase the watertightness and airtightness of the connection portion and to strengthen the connection strength when connecting not only the double heat insulation tube but also plastic tubes.

In order to achieve the object of the present invention as described above, the first tube and the second tube adjacent to each other; A heat shrink casing connecting the first tube and the second tube such that both ends thereof surround the end of the first tube and the end of the second tube; A first fusion mash band positioned between one end of the heat shrink casing and an end of the first tube, wherein a portion of the heat shrink casing and a portion of the first tube are fused and wrapped together; A pipe connecting device is provided between the other end of the heat shrink casing and the end of the second tube, the pipe connecting device including a second fusion mash band in which a portion of the heat shrink casing and a portion of the second tube are fused and wrapped together. .

The first and second fusion mash bands are formed in the same shape, and the first fusion mash band is a mash band surrounding the first tube in the circumferential direction so that both ends thereof are adjacent to each other, and terminals coupled to both ends of the mash band portion, respectively. It is preferable to include.

The terminal is formed in a rod shape having a predetermined thickness and length, and the width of the portion connected to the mesh band is preferably smaller than the width of the portion not connected to the mesh band.

It is preferable that a gap maintaining member is provided to maintain a gap between the terminal and the terminal, and the gap maintaining member is melted and filled between the terminal and the terminal.

Preferably, the two terminals are inclined to face each other.

The pipe connecting device may include a blocking tape provided between an end of the first pipe and one end of the heat shrink casing at a predetermined distance from the first fusion mesh band, and at a predetermined distance from the second fusion mesh band. It may further include a blocking tape provided between the end of the second tube and the other end of the heat shrink casing.

The pipe connecting device includes a fused double-sided heat fusion tape provided between an end of the first pipe and one end of the heat shrink casing at a predetermined distance from the first fusion mash band, and the first fusion mash band and both sides. A blocking tape which prevents the molten double-sided heat fusion tape from flowing into the first fusion mesh band between the heat fusion tapes, and an end of the second tube and the heat shrink casing at a predetermined distance from the second fusion mesh band. A fused double-sided heat fusion tape provided between the other end and a blocking tape to prevent the fused double-sided heat fusion tape from flowing into the second fusion mash band between the second fusion mesh band and the double-sided heat fusion tape. It may further include.

It is preferable that an inner tube through which fluid flows is provided in the first tube and the second tube, respectively, and a heat insulating material is provided between the outer circumferential surface of the inner tube and the inner circumferential surface of the first tube, the second tube, and the heat shrink casing.

In addition, in order to achieve the object of the present invention, the step of mounting the fusion mash band, double-sided heat-sealed tape, blocking tape on each end of the two tubes; The heat shrink casing connecting the two tubes such that both ends of the heat shrink casing cover each end of the two tubes; Melting both sides of the heat-shrinkable casing by heating and contracting the both ends of the heat-shrinkable casing; And applying a current to the fusion mesh band to weld a portion of the heat shrink casing and a portion of each end of the two tubes with resistance heat generated in the fusion mesh band.

The present invention connects two tubes with a heat shrink casing and a fusion mash band is provided between the heat shrink casing and the tube, and a portion of the tube and a portion of the heat shrink casing are fused to each other to surround the fusion mash band, so that the tube and the heat shrink The casings are connected by fusion to each other to prevent the inflow of gas or liquid between the tube and the heat shrink casing, as well as to increase the connection strength between the tube and the heat shrink casing.

In addition, the present invention, when the fusion mash band, double-sided heat fusion tape, blocking tape is provided between the tube and the heat shrink casing, a portion of the tube and a part of the heat shrink casing are fused to each other to surround the fusion mash band, and also Since the adhesive of the double-sided heat-sealed tape melts to bond and seal between the heat-shrinkable casing and the tube, the watertightness and airtightness between the tube and the heat-shrinkable casing are not only increased, but also the connection strength is increased. In addition, since the adhesive tape of the double-sided heat-sealed tape is melted and prevented from flowing into the fusion mesh band, the tape is prevented to increase the degree of fusion between the tube and the heat-shrinkable casing. If the adhesive of the double-sided heat fusion tape is melted and buried in the fusion mesh band, the fusion strength between the tube and the heat shrink casing is reduced by the film of the melted adhesive.

In the present invention, since the two pipes are connected by heat shrink casing, the connection strength is high, and the watertightness and airtightness are high, so that the connection part is not easily damaged by pressure when buried in the ground as well as the underground tunnel. It will prevent the inflow.

1 is a plan view showing an example of a device for connecting a conventional double thermal insulation tube,
2 is a plan view showing a first embodiment of a pipe connecting device according to the present invention;
3 is a plan view showing a fusion mash band and a spacing member constituting the first embodiment of the pipe connection device according to the present invention;
Figure 4 is a side view showing a fusion mash band and the spacing member constituting the first embodiment of the pipe connecting device according to the present invention,
5 is a side view showing another embodiment of the fusion mash band constituting the first embodiment of the pipe connection device according to the present invention;
Figure 6 is a plan view showing a second embodiment of the pipe connecting device according to the present invention.

Hereinafter, an embodiment of a pipe connecting apparatus according to the present invention will be described with reference to the accompanying drawings.

2 is a cross-sectional view showing a first embodiment of the pipe connecting device according to the present invention.

As shown in FIG. 2, the first embodiment of the pipe connecting device according to the present invention includes a first pipe P1, a second pipe P2, a heat shrink casing C, a first fusion mesh band B1, And a second fusion mesh band B2.

Preferably, the first pipe P1 and the second pipe P2 are circular in cross section. The first and second pipes may be rectangular, elliptical, hexagonal, or the like, respectively. Preferably, the first tube P1 and the second tube P2 are each made of plastic. In more detail, it is preferable that it is a high density polyethylene material. The first pipe P1 and the second pipe P2 may be made of nonferrous metal. Hereinafter, the case where the first pipe P1 and the second pipe P2 are each made of a high density polyethylene will be described.

The heat shrink casing (C) is preferably a tubular shape having a predetermined thickness and length. The heat shrink casing C contracts when a predetermined amount or more of temperature (heat) is applied. The inner diameter of the heat shrink casing C is larger than the outer diameter of the first and second pipes P1 and P2. One end of the heat shrink casing C surrounds the end of the first pipe P1, and the other end of the heat shrink casing C surrounds the end of the second pipe P2. That is, the end part of the 1st pipe | tube P1 and the end part of the 2nd pipe | tube P2 are inserted in the both ends of the said heat shrink casing C, respectively. The outer circumferential surface of the first tube P1 is in contact with the inner circumferential surface of one end of the heat shrink casing C, and the outer circumferential surface of the end of the second tube P2 is in contact with the inner circumferential surface of the other end of the heat shrink casing C. .

The first fusion mesh band B1 is located between the inner peripheral surface of one end of the heat shrink casing C and the outer peripheral surface of the end of the first pipe P1. The first fusion mash band B1 includes a mash band 31 surrounding the first tube P1 in the circumferential direction so that both ends thereof are adjacent to each other, and terminals 32 coupled to both ends of the mash band 31, respectively. Include. The mesh band 31 preferably has a uniform width and a band shape formed of a net. 3 and 4, the terminal 32 is formed in a rod shape having a predetermined thickness and length, and the width of the portion 32a connected to the mesh band 31 has the width of the mesh band 32. It is desirable to be smaller than the width of the portion 32b that is not connected.

It is preferable that a gap holding member E is provided to maintain a gap between the terminal 32 and the terminal 32 and the gap holding member E is melted and filled between the terminal 32 and the terminal 32. Do. Therefore, the gap holding member E is melted to fill the space between the terminal 32 and the terminal 32, so that a gap does not occur between the terminal 32 and the terminal 32, and the terminal 32 and the terminal ( The outer circumferential surface of the portion of the heat-shrinkable casing C and the portion of the pipes P1 and P2 corresponding to 32 are not concave.

One end of the terminal 32 is preferably exposed to the outside of the heat shrink casing (C). As shown in FIG. 5, the two terminals 32 are preferably formed such that upper surfaces of the two terminals 32 face each other. If the terminal 32 is provided with an inclined surface, molten material flows well between the two terminals 32. The first fusion mash band B1 is surrounded by the first pipe P1 and the heat shrink casing C by fusion of the first pipe P1 and the heat shrink casing C.

The first fusion mash band B1 is preferably made of stainless steel. The first fusion mash band B1 may be made of copper or a copper alloy material.

The second fusion mesh band B2 is located between the inner peripheral surface of the other end of the heat shrink casing C and the outer peripheral surface of the end of the second pipe P2. The second fusion mash band B2 includes a mash band 31 surrounding the second tube P2 in the circumferential direction so that both ends thereof are adjacent to each other, and terminals 32 coupled to both ends of the mash band 31, respectively. Include. The second fusion mash band B2 is preferably formed in the same shape as the first fusion mash band B1. The second fusion mash band B2 is surrounded by the second tube P2 and the heat shrink casing C by fusion of the second tube P2 and the heat shrink casing C.

The second fusion mash band B2 is preferably made of stainless steel. The second fusion mash band B2 may be made of copper or a copper alloy material.

Meanwhile, as a second embodiment of the pipe connecting device according to the present invention, as shown in FIG. 6, in the first embodiment, the first pipe ( The fused double-sided heat-sealed tape 14 provided between the end of P1) and one end of the heat-shrinkable casing C, and between the first fusion mesh band B1 and the double-sided heat-sealed tape 14 The molten double-sided thermal fusion tape 14 further includes a blocking tape 40 to prevent the first fusion mash band B1 from being introduced.

The double-sided heat-sealed tape 14 has an annular ring shape having a predetermined width and thickness, and when the adhesive is applied to both sides to apply heat, the adhesive of the double-sided heat-sealed tape 14 melts and the heat-shrinkable casing C and the first, It adheres to 2 pipes P1 and P2 and has strong adhesive force. As the double-sided heat fusion tape 14, a so-called mastic tape (MASTIC-TAPE) is used.

The blocking tape 40 has an annular ring shape having a predetermined width and thickness, and an adhesive is applied to one side thereof. The side to which the adhesive is applied is in contact with the first tube (including the second tube). The blocking tape 40 is compressed by the contraction of the heat shrink casing C, so that the blocking tape 40 attaches the heat shrink casing C and the first and second pipes P1 and P2. This increases the watertightness between the heat shrink casing C and the first and second pipes P1 and P2.

An inner tube 12 through which fluid flows is provided in the first tube P1 and the second tube P2 of the first and second embodiments, respectively, and the inner tube 12 and the heat shrink casing C are provided. Filling insulation 13 may be provided between.

Meanwhile, in the second embodiment, the double-sided heat fusion tape 14 may be excluded. That is, the first tube P1 and the heat shrink casing C are provided with only the first heat-sealing mesh band B1 and the cutoff tape 40 at one end thereof, and the second pipe P2 and the heat shrink casing C The other end portion may be provided with only the second heat-sealed mash band B2 and the blocking tape 40. At this time, the blocking tape 40 is sealed between the heat shrink casing (C) and the first tube (P1) once more, and the other cut off tape (40) is the heat shrink casing (C) and the second pipe (P2). You'll seal one more time.

Referring to the pipe connecting method according to the first embodiment of the pipe connecting device according to the present invention.

First, the heat shrink casing C is inserted into the first pipe P1 or the second pipe P2. The end of the first pipe (P1) and the end of the second pipe (P2) are positioned adjacent to each other. The first fusion mash band B1 is wound around the set position at the end of the first pipe P1 and then fixed using a fixing means (not shown). At this time, the two terminals 32 of the first fusion mesh band B1 are positioned at a predetermined interval from each other. It is preferable to position the space keeping member E between the two terminals 32. The second fusion mash band (B2) is wound around the set position of the end of the second tube (P2) and fixed using a fixing means. At this time, the two terminals 32 of the second fusion mesh band B2 are positioned at a predetermined interval from each other. It is preferable to position the space keeping member E between the two terminals 32 of the second fusion mesh band B2.

The first and second pipes P1 and P2 are connected to each other so that both ends of the heat shrink casing C are positioned at the end of the first pipe P1 and the end of the second pipe P2. One end of the heat shrink casing C is heated with a torch lamp (not shown) to shrink one end of the heat shrink casing C to closely contact the end of the first pipe P1. At this time, the first fusion mesh band B1 is located between the heat shrink casing C and the first pipe P1. Then, the other end of the heat shrink casing C is heated with a torch lamp to shrink the other end of the heat shrink casing C to closely contact the end of the second pipe P2. At this time, the second fusion mash band B2 is located between the heat shrink casing C and the second pipe P2.

An electric fusion machine (not shown) is connected to the terminals 32 of the first fusion mash band B1 exposed to the outside of the heat shrink casing C in a state in which one end of the heat shrink casing C is pressed by a crimping means (not shown). ) And then apply current to the first fusion mesh band B1. A portion of the first tube P1 and a portion of the heat shrink casing C positioned at the portion of the first fusion mesh band B1 are melted by the resistance heat of the first fusion mesh band B1 to melt the first fusion mesh band B1. It wraps and fuses with each other. In addition, the other end of the heat shrink casing (C) by the crimping means is connected to the terminals of the second fusion mash band (B2) exposed to the outside of the heat shrink casing (C), the electric fusion machine A current is applied to the second fusion mesh band B2. A portion of the second tube P2 and a portion of the heat-shrinkable casing C located at the portion of the second fusion mash band B2 are melted by the heat of resistance of the second fusion mash band B2 to melt the second fusion mash band B2. It wraps and fuses with each other.

Referring to the pipe connection method according to a second embodiment of the pipe connection device according to the present invention.

First, the first pipe P1 or the second pipe P2 is inserted into the heat shrink casing C. The end of the first pipe (P1) and the end of the second pipe (P2) are positioned adjacent to each other. The first fusion mash band (B1) is wound around the set position of the end of the first pipe (P1) and fixed using a fixing means. At this time, the two terminals 32 of the first fusion mesh band B1 are positioned at a predetermined interval from each other, and it is preferable to insert the interval maintaining member E between the two terminals 32. A double-sided heat fusion tape 14 is wrapped in the circumferential direction on the first pipe P1 at a predetermined distance from the first fusion mash band B1. Then, the blocking tape 40 is wrapped in the circumferential direction in the first pipe P1 to be positioned between the first fusion mesh band B1 and the double-sided heat fusion tape 14. Similarly to the first pipe P1, the second pipe P2 is also equipped with a second fusion mesh band B2, a double-sided heat fusion tape 14, and a blocking tape 40.

The first and second pipes P1 and P2 are connected to each other so that both ends of the heat shrink casing C are positioned at the end of the first pipe P1 and the end of the second pipe P2. At this time, between the one end of the heat shrink casing (C) and the first pipe (P1), the first fusion mesh band (B1), the double-sided heat fusion tape 14, the blocking tape 40 is located, the heat shrink casing (C) Between the other end of the second pipe (P2) and the second fusion mash band (B2), double-sided heat-sealed tape 14, the blocking tape 40 is located.

One end of the heat shrink casing (C) is heated with a torch lamp to contract one end of the heat shrink casing (C) to closely contact the end of the first pipe (P1), where the cutoff tape (40) is the heat shrink casing (C). This contraction causes the film to be compressed and adhered to the heat shrink casing C, and the adhesive of the double-sided heat fusion tape 14 is melted and adhered to the heat shrink casing C and the first pipe P1. The adhesive tape of the double-sided heat fusion tape 14 is melted by the blocking tape 40 to prevent the adhesive tape from flowing into the first fusion mash band B1. In addition, similarly to the said 1st pipe | tube P1 side, the other end of the said heat shrink casing C is heated with a torch lamp.

In the state in which one end of the heat shrink casing (C) is crimped by crimping means, an electric fusion machine is connected to the terminals 32 of the first fusion mash band B1 exposed to the outside of the heat shrink casing C, and then the first fusion is performed. A current is applied to the mesh band B1. A portion of the first tube P1 and a portion of the heat shrink casing C positioned at the portion of the first fusion mesh band B1 are melted by the resistance heat of the first fusion mesh band B1 to melt the first fusion mesh band B1. It wraps and fuses with each other. In addition, similarly to the first pipe P1 side, the terminal of the second fusion mash band B2 exposed to the outside of the heat shrink casing C while the other end of the heat shrink casing C is crimped by the crimping means. Connecting the electric fusion machine to the (32) and then applying a current to the second fusion mesh band (B2). A portion of the second tube P2 and a portion of the heat-shrinkable casing C located at the portion of the second fusion mash band B2 are melted by the heat of resistance of the second fusion mash band B2 to melt the second fusion mash band B2. It wraps and fuses with each other.

On the other hand, with reference to Figure 4, when the second embodiment according to the present invention is applied to the connection of two double thermal insulation tube, it will be described.

When the second embodiment according to the present invention is applied to the connection of two double thermal insulation tube, the first tube (P1) and the second tube (P2) respectively correspond to the outer tube of the two double insulation tube.

First, the heat shrink casing (C) is inserted into one of the two thermal insulation tube of the two double insulation tube exposed to the outside of the inner tube (12). Two double insulation tubes are referred to as first and second double insulation tubes. Then, the two inner tubes 12 are connected to each other by welding while the end surfaces of the inner tubes 12 of the first and second double heat insulating tubes are in contact with each other. After the welding of the inner tubes 12 of the first and second double insulation tubes is completed, the welded portion is tested. The first fusion mesh band B1, the double-sided heat fusion tape 14, and the blocking tape 40 are mounted on the outer tube P1 of the first double insulation tube in the same manner as described above. In addition, the second fusion mash band B2, the double-sided heat fusion tape 14, and the blocking tape 40 are mounted on the outer tube P2 of the second double insulation tube in the manner described above.

The outer pipe P1 of the first and second double heat insulating pipes so that both ends of the heat shrink casing C are positioned at the end of the outer pipe P1 of the first double heat insulating pipe and the end of the outer pipe P2 of the second double heat insulating pipe. Connect (P2). At this time, between the one end of the heat shrink casing (C) and the outer tube (P1) of the first double insulation tube (B1), the first fusion mesh band (B1), double-sided heat fusion tape 14, the blocking tape 40 is located, A second fusion mesh band B2, a double-sided heat fusion tape 14, and a blocking tape 40 are positioned between the other end of the heat shrink casing C and the outer tube P2 of the second double heat insulating tube.

One end of the heat shrink casing (C) is heated with a torch lamp to contract one end of the heat shrink casing (C) to closely adhere to the outer tube (P1) of the first double insulation tube, wherein the cutoff tape (40) is a heat shrink casing (C) is compressed and compressed to adhere to the heat shrink casing (C), the adhesive of the double-sided heat-sealed tape 14 is melted and bonded to the heat shrink casing (C) and the outer tube 11 of the first double heat insulating tube. In addition, similarly to the outer side pipe P1 side of the said 1st double heat insulation tube, the other end of the said heat shrink casing C is heated with a torch lamp.

In the state in which one end of the heat shrink casing (C) is crimped by crimping means, an electric fusion machine is connected to the terminals 32 of the first fusion mash band B1 exposed to the outside of the heat shrink casing C, and then the first fusion is performed. A current is applied to the mesh band B1. A portion of the outer tube 11 and a portion of the heat shrink casing C of the first double insulation tube positioned at the portion of the first fusion mesh band B1 are melted by the resistance heat of the first fusion mesh band B1 to melt the first fusion mesh. The band B1 is fused with each other while wrapping. In addition, the second fusion mash band exposed to the outside of the heat shrink casing (C) in the state that the other side of the heat shrink casing (C) is also compressed by the crimping means, similar to the outer tube (P1) side of the first double heat insulating tube A current is applied to the terminals 32 of B2 to fuse the heat shrink casing C and the outer tube P2 of the second double heat insulating tube to each other.

An injection hole (not shown) is formed in the heat shrink casing C, and the urethane resin solution is foamed into the heat shrink casing C through the injection hole to cure the urethane resin, and then seal the injection hole.

Hereinafter, the operation and effects on the pipe connection device and method according to the present invention will be described.

The present invention is provided with a first fusion mesh band (B1) between the end of the first pipe (P1) and one end of the heat shrink casing (C), the end portion of the first pipe (P1) and the heat shrink casing (C) Since a portion of one end of the fusion is fused to each other to surround the first fusion mash band (B1), not only the gas or liquid is prevented from flowing between the first pipe (P1) and the heat shrink casing (C), but also the first pipe (P1). ) And the heat shrink casing C become large. In addition, a second fusion mash band is provided between the end of the second pipe (P2) and one end of the heat shrink casing (C), the end portion of the second pipe (P2) and one end of the heat shrink casing (C). A portion of the fusion is fused to each other to surround the second fusion mash band to prevent the gas or liquid from flowing between the second tube (P2) and the heat shrink casing (C), as well as the second pipe (P2) and heat shrink casing (C) The connection strength of becomes large.

Therefore, not only the connection strength connecting the first and second pipes P1 and P2 is increased, but also the watertightness and airtightness of the connection portion of the first and second pipes P1 and P2 are increased.

In addition, a double-sided heat-sealed tape 14 and a barrier tape 40 are provided between the end of the first pipe P1 and one end of the heat shrink casing C, and the end of the second pipe P2 and the heat shrink casing C. When the double-sided heat-sealed tape 14 and the blocking tape 40 are provided between the other ends of the), the adhesive of the double-sided heat-sealed tape 14 is melted so that the end of the first pipe P1 and the heat shrink casing C And one end of the second pipe (P2) and the other end of the heat-shrinkable casing (C), respectively, will increase the connection strength connecting the first and second pipes (P1) (P2). In addition, the watertightness and airtightness of the connecting portion of the first and second pipes P1 and P2 are further enhanced. In addition, since the adhesive tape of the double-sided heat-sealed tape 14 is melted to prevent the tape 40 from being prevented from flowing into the fusion mesh band, the degree of fusion between the first pipe P1 and the heat-shrinkable casing C is increased. Further, the degree of fusion between the second pipe P2 and the heat shrink casing C is increased. If the adhesive of the double-sided heat-sealed tape 14 is melted and bound to the fusion mesh band, the first pipe P1, the heat shrink casing C, the second pipe P2, and the heat shrink casing are formed by the film of the melted adhesive. The fusion strength between (C) is lowered.

In this way, the connection strength between the first pipe and the second pipe is high, and the watertightness and airtightness of the connection portion between the first pipe and the second pipe are high, so that the connection part is not easily broken by pressure when buried underground. Not only that, but it also prevents groundwater from entering the connection.

P1; First tube P2; The second pipe
C; Heat shrink casing B1; First Fusion Mash Band
B2; Second fusion mesh band 14; Double sided heat-sealed tape
40; Blocking tape

Claims (9)

First and second tubes adjacent to each other;
A heat shrink casing connecting the first tube and the second tube such that both ends thereof surround the end of the first tube and the end of the second tube;
A first fusion mash band positioned between one end of the heat shrink casing and an end of the first tube, wherein a portion of the heat shrink casing and a portion of the first tube are fused and wrapped together;
And a second fusion mash band positioned between the other end of the heat shrink casing and the end of the second pipe, wherein a portion of the heat shrink casing and a portion of the second pipe are fused and wrapped around each other. The fusion band of claim 1, wherein the first fusion mash band is formed in the same shape, and the first fusion mash band includes a mash band surrounding the first pipe in a circumferential direction such that both ends thereof are adjacent to each other. Pipe connecting device comprising a terminal coupled to each end. The method of claim 2, wherein the terminal is formed in a rod shape having a predetermined thickness and length, and the width (width) of the portion connected to the mesh band is smaller than the width (width) of the portion not connected to the mesh band. Characterized by pipe coupling device. The pipe connecting device according to claim 3, wherein the two terminals are inclined to face each other. 3. The pipe connecting device according to claim 2, wherein a spacing member is provided to maintain a gap between the terminal and the terminal, and the spacing member is melted and filled between the terminal and the terminal. According to claim 1, wherein the first fusion mash band and a predetermined distance between the end of the first pipe and the end of the heat-shrinkable casing tape provided between, and the second fusion mash band at a predetermined interval And a blocking tape provided between the end of the second pipe and the other end of the heat shrink casing. According to claim 1, A fused double-sided heat-sealed tape provided between the end of the first tube and one end of the heat-shrinkable casing at regular intervals from the first fusion mash band, and the first fusion mash band A blocking tape which prevents the molten double-sided heat-sealed tape from flowing into the first fusion mesh band between the double-sided heat-sealed tape, an end portion of the second tube and the heat-shrink casing at a predetermined distance from the second fusion mesh band. A fused double-sided heat-sealed tape provided between the other end of the block and the molten double-sided heat-sealed tape between the second fusion mesh band and the double-sided heat-sealed tape to block the second fusion tape from entering the second fusion mesh band. Pipe connection device further comprising a tape. According to claim 1, wherein the inner tube through which the fluid flows inside the first tube and the second tube, respectively, and the heat insulating material between the outer circumferential surface of the inner tube and the inner circumferential surface of the first tube, the second tube, the heat shrink casing Pipe connection device characterized in that provided. Mounting a fusion mash band, a double-sided heat fusion tape, and a blocking tape at each end of the two tubes;
The heat shrink casing connecting the two tubes such that both ends of the heat shrink casing cover each end of the two tubes;
Melting both sides of the heat-shrinkable casing by heating and contracting the both ends of the heat-shrinkable casing;
And applying a current to the fusion mesh band to fusion a portion of the heat shrink casing and a portion of each end of the two tubes with resistance heat generated from the fusion mesh band.

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