KR100784782B1 - Trenchless repairing apparatus of pipeline and trenchless repairing method using the same - Google Patents

Abstract

A trenchless pipeline repair apparatus and a trenchless pipeline repair method using the same are provided to cut off air leak completely when supplying a reinforcing tube to the inside and to secure a working space for supplying radiant heat to harden a reinforcing tube sufficiently by separating and opening a shuttle body temporarily when hardening the reinforcing tube. A trenchless pipeline repair apparatus for inversing a reinforcing tube and attaching it to the inside of a pipeline buried under the ground without excavating the ground comprises a fixing body(10) installed on a base plate(11) and provided with an inversion support(12), an opening(13) having a binding holder(14) and an air chamber(17), a shuttle body(20) installed to be movable along a transport rail(22) installed at the base plate, provided with a supply path(23) supplied with a reinforcing tube(1) and fitted to the binding holder, a primary air leak prevention chamber(30) provided to the upper part of a block support formed on the rear part of the supply path and provided with a primary blotter vertically slidable, a secondary air leak prevention chamber(40) provided to the upper part of an air bag support formed on the rear part of the block support and provided with a secondary blotter vertically slidable, an elastic body(50) put on the block support and provided with a tube groove to pass the reinforcing tube while elastically pressurizing, a pair of air bags(60) attached closely to the air bag support and an insert formed on the secondary blotter, and an inversion prevention plate(70) installed on the upper part of a double partition(16) to be vertically slidable and fitted to an insertion groove of the double partition when hardening.

Description

Trenchless repairing apparatus of pipeline and trenchless repairing method using the same

The present invention relates to the overall repair of the pipeline to invert the reinforcement tube without digging the ground and to attach to the inner surface of the underground pipe, more specifically, when the reinforcement tube is supplied to the interior of the unexcavated total repair device Completely sealed while passing through the block and a pair of airbags to completely prevent leakage, and the elastic block and the airbags are fitted and detached to fit various specifications of the reinforcement tube, and connected to the distal end of the reinforcement tube. Silicon Lava Heater supports the reinforcement tube for safety during hardening work, as well as heat conduction radiating hoses placed outside the Silicon Lava Heater are mounted in the center of the pipeline to distribute the temperature evenly inside the reinforcement tube for perfect curing work. On the other hand, the radiant heat for curing the reinforcing tube by separating and opening the shuttle body during the curing operation of the reinforcement tube Ensure sufficient working space according to the curing operation for feeding box is, of course, relates to trenchless entire repair process of the channel using trenchless entire repair device in the pipeline, and this to allow be the complete quality control during construction conduit between the large-diameter or gear.

In general, in order to repair old water and sewage pipes and industrial pipes (gas, electricity, communication, etc.) that are buried underground, the method of replacing old pipes with new pipes or partially repairing them is excavated.

However, this ground excavation method, along with damage to the surrounding environment, after the construction is completed, not only occurs ground subsidence due to soil erosion, but also causes problems such as traffic jams and inconvenience to citizens in crowded urban areas.

Therefore, in recent years, a non-excavation repair method that can repair a pipeline without digging the ground or road where the pipeline is buried has been developed and implemented to meet the domestic reality.

The non-excavation repair method is divided into a traction method and an inversion method. However, when applying a soft reinforcement tube to the inner surface of an existing pipe, the moisture and foreign substances attached to the existing tube are reversed when the reinforcement tube is reversed and reversed. The reversal method having the characteristic of pushing in the direction is superior to the reinforcement method, and the reinforcement tube has excellent adhesion force and is very effective in repairing the partial breakage portion of the existing pipeline.

In addition, the reversal method is divided into hydraulic pressure reversal using the water head difference and air pressure reversal using the air pressure, the former hydraulic pressure reversal is to fill the water in the existing pipe and to harden the soft reinforcement tube It takes a lot of time and money to warm up above 70 ℃, and the water discharged to the river after the reversal operation is easy to disturb the ecosystem and destruction, especially in the downtown of the supply of water filled in the existing pipeline is very difficult situation.

On the other hand, the latter reversal of air pressure is very economical as it is not affected at all by time and place by using an air compressor, and can be applied to reverse gradient pipelines, and it is widely used in most construction sites due to the advantage of freely adjusting the reversal speed. Apply.

As an example of such an inverting device using air pressure, a "non-excavation inverting device for repairing a pipeline", which has been filed in advance by the applicant of the present invention and granted a patent registration, has been proposed.

The above-described pre-invention can improve the structure of the feeding part through which the tube is supplied and the feeding part through which the tube is inverted by the pressure of the compressed air, thereby greatly reducing the overall volume of the inverting device so that the operation can be carried out in a convenient space and a narrow space In addition, since the pressure is increased by effectively suppressing the leakage of compressed air in the supply portion to which the tube is supplied, it was to provide a useful effect that the operation proceeds smoothly.

However, the pre-registered invention may provide an effect of partially blocking the leakage of compressed air in the supply unit for supplying the reinforcement tube, but air is generated through the air gap during the reversal operation due to the generation of air gaps between the gate and the reinforcement tube installed in the supply unit. It is a situation that the problem of pressure leakage caused a decrease in the efficiency of the reversal operation.

In addition, a sufficient working space for supplying steam to the curing heat hose after the reversal of the reinforcing tube is completed cannot be secured, and a peripheral device for curing the reinforcing tube by supplying the steam is not properly provided. .

The present invention is to actively solve some of the improvements included in the above-described prior invention, to completely block the occurrence of leakage in the process of supplying the reinforcing tube into the non-excavation total repair device, the reinforcement tube Irrespective of the various specifications of, it comprehensively accommodates and keeps the leakage from occurring continuously, and connects the silicone lab heater and the heat conduction radiating hose to the distal end of the reinforcement tube, so that the heat conduction radiating hose is in the center of the reinforcement tube during hardening. In addition to improving the efficiency and quality of hardening operations, safety management can be achieved effectively.

In addition, while ensuring a sufficient working space according to the curing operation of the reinforcement tube is to be able to uniformly provide the appropriate curing temperature to the entire area of the reinforcement tube.

According to the present invention, when the reinforcing tube passes through a tube groove formed in the elastic block, the reinforcing tube is elastically pressed to block leakage of the primary, as well as the reinforcing tube passes through a pair of airbags that are in close contact with each other. When pressurization is made to secondary leakage to block the occurrence of the seal to maintain a completely sealed state to provide the effect of completely blocking the leakage occurring in the supply process of the reinforcement tube as well as the efficiency of the reversal operation.

In addition, the present invention is that the elastic block and the air bag is manufactured in various sizes according to the specifications of the reinforcement tube to replace the elastic block and the air bag in accordance with the standard of the reinforcement tube to comprehensively accommodate the reinforcement tube of various specifications as well as to change the standard Regardless of the time, it provides the effect of completely preventing leakage.

Furthermore, when hardening the reinforcement tube, the shuttle body is separated and opened from the fixed body to secure a sufficient working space for supplying a uniform temperature to the inside of the reinforcement tube. It is sealed to provide an effect of preventing air from leaking to the outside.

In addition, the curing work is carried out using the radiant heat generated by the heat generated by the silicon lava heater, which eliminates the large boiler and suppresses the noise by using the small generator, and does not interfere with the traffic flow. It will eliminate the cost of construction.

The configuration of a preferred embodiment for effectively achieving the object of the present invention will be described in detail with reference to the accompanying drawings.

When looking at a specific configuration for a preferred embodiment of the present invention, as shown in Figures 1 to 3, the upright installed on the upper portion of the base plate 11 and the reverse support portion 12 is formed on one side and the other side open portion (13) a fixing body 10 having a binding holder 14 formed at the front end, and an air chamber 17 provided at one side thereof; A supply path 23 is installed to be movable along the transfer rail 22 installed on the base plate 11 and is provided with a reinforcement tube 1 on one side thereof, and the other end is fitted to the binding holder 14. Shuttle body 20 is bound; A first leakage preventing chamber 30 provided at an upper portion of the block support 31 formed at the rear end of the supply path 23 and provided with a first blotter 32 to be movable up and down; A second leakage preventing chamber 40 provided at an upper portion of the airbag support 41 formed at a rear end of the block support 31 and provided with a second blower 42 for sliding upward and downward; An elastic block 50 seated on the block support 31 and having a tube groove 51 for elastically pressing the reinforcing tube 1 through the center thereof; A pair of airbags 60 in close contact with each other in a state of being seated on the inserting portions 42a formed in the airbag support 41 and the second blotter 42; The organic coupling configuration of the inverted membrane plate 70 is installed to be slidably moved up and down on the upper part of the double partition 16 and the lower end is inserted into the insertion groove 16-1 of the double partition 16 during the hardening operation. It can be seen that.

Hereinafter, the present invention made of the above schematic configuration will be described in more detail.

First of all, the non-excavation overall repair device of the present invention is a fixed body 10 installed in a fixed state to avoid the main body is composed of an integral component of the shuttle body 20 detachably coupled to the fixed body (10) Each is separated by.

The fixed body 10 is installed upright on the upper side of the base plate 11 to maintain a fixed state, one side of the inverted support portion 12 for supporting the one end of the reinforcing tube (1) upside down is installed open On the other side, an opening 13 is formed, and a binding holder 14 having a binding groove 14a to which the shuttle main body 20 is selectively fitted is formed along the tip circumferential surface of the opening 13. The shuttle body 20 forms a binding state with the fixed body 10 to form a condition for the reversal operation, as well as to temporarily open the state by separating from the fixed body 10 when curing the reinforcement tube 1 is completed It can be maintained.

In addition, the partition body 15 and the double partition wall 16 are vertically spaced apart in the interior of the fixed body 10, and internal spaces are partitioned on both sides thereof, and an air of an independent type for supplying air in one side of the inverting operation. The chamber 17 is provided. At this time, even if the air chamber 17 is provided, the reinforcing tube 1 forms the gap L between the partition wall 15 and the double partition wall 16 so that the gap L is formed. Through the reverse support 12 can be smoothly supplied.

The fixed main body 10 and the shuttle main body 20 formed in a set is provided with a feed roller 21 at the bottom, the feed roller 21 is seated on the feed rail 22 installed on the base plate 11 It is movable left and right along the conveying rail 22, one side is provided with a supply path 23 for supplying the reinforcing tube (1) inside, the other end of the supply path 23 is fixed body ( 10) is held in the binding holder (14).

Therefore, the shuttle body 20 may be integrated with the fixed body 10 or separated from the fixed body 10, the stopper device or locking device for limiting the movement of the shuttle body 20 is known It is also possible to combine the general composition.

Shuttle body 20 having such a configuration is a method for smoothly supplying the reinforcing tube (1) to the front side of the supply path 23 as shown in Figure 11 separate cloud plate 80 through the hinge shaft 81 It is installed rotatably in the shuttle main body 20, the pneumatic cylinder (82) filled with compressed air is connected between the rolling plate 80 and the shuttle main body 20 to maintain the unfolded state in normal, while the rolling plate When pressing 80 downward, the pneumatic cylinder 82 is contracted and the rolling plate 80 is folded, and the pneumatic cylinder 82 can be automatically stored in the housing 83.

On the other hand, the rear end of the supply path 23 is provided with a block support 31 for mounting the elastic block 50 to block leakage primarily during the supply of the reinforcing tube (1), the block of support (31) In the upper portion, a first leak prevention chamber 30 having a first pusher 32 for fixing the elastic block 50 in a crimped state to be slidably moved up and down is provided.

In addition, a second leakage prevention chamber 40 is further provided to completely block leakage of the leakage during the supply process of the reinforcing tube 1 continuously in the rear of the first leakage prevention chamber 30. do.

That is, the airbag support 41 is formed at the rear end of the block support 31, and the second leakage preventing chamber 40 is installed on the upper portion of the airbag support 41 so as to slide upward and downward. ) Is provided.

The elastic block 50 for blocking the primary leakage during the supply process of the reinforcing tube (1) is seated on the block support 31, made of silicon as an raw material, the reinforcement tube (1) ) Is formed with a tube groove 51 that elastically presses through.

At this time, the tube groove 51 is formed to a thickness thinner than the thickness of the reinforcing tube (1), so that when the reinforcing tube (1) passes through the tube groove 51 naturally elastically press the reinforcing tube (1) While the compressed air is prevented from leaking through the tube groove 51, the elastic block 50 has a shape of a single piece in which tube grooves 51 having various sizes are individually formed according to the size of the reinforcement tube 1. By supplying to the reinforcement tube (1) by replacing the elastic block 50 in accordance with the standard of the reinforcement tube (1) can be applied comprehensively.

In addition to preventing leakage by the elastic block 50, a pair of air bags 60 which further block leakage of compressed air are made of urethane having a relatively strong but relatively tough urethane as an raw material, and the airbag support 41 and the first. 2 are fitted to the inserting portion 42a formed in the tack 42, and are in close contact with each other.

Therefore, as the reinforcing tube 1 passes between the air bags 60 in close contact, the air bag 60 presses the upper and lower portions of the reinforcing tube 1 so that no gap is generated, so compressed air leaks. It is blocked by, it is possible to arbitrarily control the pressing force by adjusting the vertical displacement of the second pusher 42.

In addition, an inverted membrane plate 70 having a lower end fitted in the insertion groove 16-1 of the intermediate partition 16 during the hardening operation is disposed on the upper portion of the double partition 16 formed in the fixed body 10. The inversion membrane plate 70 is installed to be slidably moved up and down on the guide rail 15a formed on one side of the partition wall 15.

Here, the double partition 16 is formed with a semi-circular through-hole 16-2 through which the lower side of the heat conduction radiating hose 95 which selectively expands as air is supplied is formed, and the double partition 16 is formed. The inverted membrane plate 70 fitted into the insertion groove 16-1 of the inverted membrane plate 70 completely passes the compressed air to the outside of the air chamber 17 while passing the upper side of the heat conduction radiating hose 95 in a wrapped state. The through hole 71 is formed.

Therefore, when the steam is supplied to the heat conduction radiating hose 95, the through holes 16-2 and 71 formed in the double partition 16 and the inverted membrane plate 70 may move the outside of the expanded heat conduction radiation hose 95 to each other. By sealing completely, it is possible to fundamentally prevent the air in the air chamber 17 from leaking out during the curing operation.

On the other hand, the first pusher 32, the second pusher 42 and the reverse plate 70 is installed in the shuttle body 20 and the partition wall 15 as shown in FIG. It is coupled to each of the guide rails (35) (45) (15a) installed, the upper screw shaft 101 that is rotated in accordance with the operation of the handle 100 is rotatably arranged on both side walls (102), The moving holder 104 is coupled to the threaded portions 103 formed in different directions on both sides of the screw shaft 101, and the moving holder 104, the first pusher 32, the second pusher 42 and The reverse membrane plate 70 is freely connected through the link stage 105, so that the first pusher 32, the second pusher 42 and the reverse membrane plate in accordance with the rotation operation of the screw shaft 101 The 70 can slide up and down.

Therefore, after elevating the first and second tacks 32 and 42, the elastic block 50 or the airbag 60 can be quickly replaced by a simple method.

The present invention made of this configuration is connected to one side of the silicone lava heater 90 and the heat conduction radiating hose 95 to the distal end of the reinforcing tube (1) that is supported in an inverted support 12 in a preferred state for the reverse operation Connected integrally using the 92, the other side of the silicone lava heater 90 is fixed integrally to the heater fixture 98 installed on the outer surface of the shuttle body 20, in particular the silicone lava heater 90 Is disposed at the inner center of the thermally conductive radiating hose (95).

The silicon lava heater 90 acts as a heat source for hardening the reinforcement tube by dissipating high temperature heat by operating a small generator, very low operating costs, evenly apply heat to the entire pipe At the same time, the silicone lava heater to maintain the tension as well as suppress the occurrence of safety accidents by supporting the reinforcement tube (1) until the reversal and curing of the reinforcement tube (1) is completed. (90) serves to hold the heat conduction radiating hose (95) is located in the inner center of the reinforcement tube (1) by the uniform heat applied to the reinforcement tube (1) during the hardening work hardening efficiency and To dramatically improve the work quality.

In addition, the thermally conductive radiating hose (95) prevents radiant heat generated from the silicon lab heater (90) from being directly transmitted to the reinforcing tube (1), and the inner side of the reinforcing tube (1) in a state in which heat is evenly distributed in the inner space. By indirectly radiating heat to the entire area, the efficiency of the curing operation can be further improved.

And the present invention is a heater rod 120 is additionally installed at the tip of the reinforcing tube (1) in the other direction of the silicon lava heater 90 as shown in Figure 13 while the heater rod 120 dissipates heat during the reversal operation It can additionally provide a special effect of removing water remaining inside the pipeline.

Meanwhile, reference numeral 110, which is not described in the drawings, is provided on the upper and lower sides of the reinforcing tube 1 and is a supply roller that more smoothly supplies the reinforcing tube 1 while being rotated to engage with each other.

Next, the non-excavation overall repair method for repairing a pipe by non-excavation using the non-excavation overall repair apparatus of the present invention will be described.

1) silicone Lava Heater  And heat conduction Yarn hose  Installation process

This process is carried out before reversing the reinforcing tube (1), and is a process for improving the efficiency and quality of the reversing operation and ensuring safety.

To this end, one end of the silicon lab heater (90) and the heat conduction radiating hose (95) is connected to the distal end of the reinforcing tube (1) supported by the inverted support (12) of the fixed body (10) by a connecting string (92). Then, after passing through the tube groove 51 of the elastic block 50 and the pair of air bags 60 in order to fix the other side integrally to the heater fixture 98 of the shuttle body (20).

Therefore, the silicon lab heater 90 not only supports the reinforcing tube 1 until the reversal work and the curing work are completed, but also performs the hardening work by being located at the inner center of the reinforcing tube 1 during the reversing process. Create conditions

2) Reinforcing tube reversal process

After the installation of the silicon lab heater 90 and the heat conduction radiating hose 95 is completed, the reinforcement tube 1 is inverted by the pressure of the air by injecting a high pressure air into the air chamber 17, and thus, It can be in close contact with the cast.

In this reversal process, the compressed air is not leaked to the outside by any of the pair of airbags 60 and the elastic block 50 so that the reversal operation can be performed smoothly.

3) Shuttle Body Separation Process

When the reversal of the reinforcing tube (1) is completed, the shuttle main body 20 is moved by sliding the shuttle main body 20 from the fixed main body 10 by temporarily moving, opening the opening 13 of the fixed main body 10 ) Can be prepared for the hardening operation in the open portion 13 by maintaining the state exposed to the outside, at this time doubles the efficiency of the hardening operation by securing a wide working space.

4) heat conduction Yarn hose  Expansion process

This process expands the heat conduction radiation hose (95) by supplying additional air into the heat conduction radiation hose (95) to evenly distribute the radiant heat emitted from the silicon lab heater (90) to supply the inside of the reinforcement tube (1). It is a process for doing this.

That is, by supplying air to the heat conduction radiation hose (95), the heat conduction radiation hose (95) does not crush in the curing operation to maintain the expanded form continuously.

5) Inverted board  Blocking process

This process is to effectively prevent the air in the air chamber 17 leaks to the opening 13 and the outside during the curing process of the reinforcing tube (1), it wraps around the upper portion of the thermally conductive radiating hose (95) in the expanded state When the inverted diaphragm 70 is lowered so that the through holes 71 and 16-2 formed in the inverted diaphragm 70 and the double partition 16, respectively, completely seal the outside of the heat conduction radiating hose 95. The leakage of the chamber 17 is essentially blocked to increase the efficiency of the curing operation.

6) Reinforcing tube curing process

Through the blocking of the inverted membrane plate 70, the silicon lava heater 90 disposed in the center of the heat conduction radiating hose 95 is heated in a state where airtightness in the air chamber 17 is maintained.

At this time, the high-temperature radiant heat generated by the silicon lab heater 90 is not directly transferred to the reinforcing tube 1, but is dispersed in the heat conduction radiating hose 95, and then indirectly heats the entire area of the reinforcing tube 1 evenly. It is possible to more firmly attach the reinforcement tube (1) to the inner circumference of the pipeline.

In addition, the silicon lava heater 90 is provided with a temperature sensor and an automatic temperature control function to provide the effect of maintaining the optimum temperature suitable for the curing operation.

As a result, the present invention improves the smoothness of the reversal work, as well as ensures a sufficient working space according to the hardening work by separating and opening the shuttle body 20 during the hardening work, as well as in the case of large diameter and long-long pipe lines. (90) and the thermally conductive radiating hose (95) in the state located in the inner center of the reinforcing tube (1) can be said to provide a special effect to facilitate the hardening operation can be easily performed.

On the other hand, in the present invention, the coefficient of thermal expansion between the reinforcing tube (1) and the water supply pipe is different in the overall repair of the water supply pipe (steel pipe, cast iron pipe), it is more preferable to install the expansion pipe expansion pipe for every predetermined section.

1 is a longitudinal cross-sectional view of an embodiment of a non-excavation overall repair device to which the present invention is applied.

Figure 2 is a perspective view of the elastic block of the present invention

3 is a perspective view of the present invention airbag

Figure 4 is an operating state of the first pusher for the removal, attachment of the elastic block of the present invention

Figure 5 is an operating state of the second pusher for the removal, attachment of the airbag of the present invention

Figure 6 is a side cross-sectional view of the operating means of the first, second pusher and the reverse membrane of the present invention

Figure 7 is a state diagram to separate the shuttle body of the present invention

8 is a longitudinal cross-sectional view of the fixed body of the shuttle body of the present invention separated state

Figure 9 is a connection state diagram of the present invention silicon lava heater and heat conduction radiating hose

10 is a perspective view of the inverted diaphragm and double partition wall of the present invention

11 is a state in which the inverted membrane plate and the double partition wall of the present invention to closely wrap the outside of the heat conduction radiating hose

12 is an enlarged cross-sectional view of the folded state of the present invention cloud plate

13 is a state in which the heater rod is installed on the front end of the reinforcing tube of the present invention

[Explanation of symbols on the main parts of the drawings]

1: reinforcing tube 10: fixed body

14: binding holder 15a, 35, 45: guide rail

16: double bulkhead 16-2, 71: through hole

17: air chamber 20: shuttle body

21: feed roller 30: the first leak-proof chamber

32: first tack 40: second leak prevention chamber

42: second pusher 50: elastic block

51: tube groove 60: airbag

70: inversion plate 80: cloud plate

82: pneumatic cylinder 90: silicone rubber heater

95: thermally conductive radiation hose 100: handle

101: screw shaft 105: link stage

Claims (7)

The uprights of the base plate 11 are installed upright, and the inverting support part 12 is formed at one side, and the binding holder 14 is formed at the tip of the opening part 13 on the other side, while the partition wall 15 and the vertically spaced apart part are provided. A fixed body 10 partitioned through the partition wall 16 and provided with an air chamber 17 at one side thereof; A supply path 23 is installed to be movable along the transfer rail 22 installed on the base plate 11 and is provided with a reinforcement tube 1 on one side thereof, and the other end is fitted to the binding holder 14. Shuttle body 20 is bound; A first leakage preventing chamber 30 provided at an upper portion of the block support 31 formed at the rear end of the supply path 23 and provided with a first blotter 32 to be movable up and down; A second leakage preventing chamber 40 provided at an upper portion of the airbag support 41 formed at a rear end of the block support 31 and provided with a second blower 42 for sliding upward and downward; An elastic block 50 seated on the block support 31 and having a tube groove 51 for elastically pressing the reinforcing tube 1 through the center thereof; A pair of airbags 60 in close contact with each other in a state of being seated on the inserting portions 42a formed in the airbag support 41 and the second blotter 42; It is installed on the upper portion of the double partition 16 to be slidably moved up and down, it is characterized in that the inverted membrane plate 70 is inserted into the lower end inserted into the insertion groove (16-1) of the double partition 16 during the curing operation. Non-excavation total repair device of the pipeline. The method of claim 1, The first tack 32, the second tack 42 and the inverted diaphragm 70 are coupled to the guide rails 35, 45, 15a installed on the shuttle body 20 and the partition wall 15, respectively. The upper part of the screw shaft 101 is rotatably arranged in accordance with the operation of the handle 100, and the movement holder 104 coupled to the screw part 103 formed in different directions on both sides of the screw shaft 101. ) Is a non-excavation overall repair device for a pipe line, characterized in that the flow is connected freely with the first lancer 32, the second lancer 42 and the inversion membrane plate 70 via a link (105). The method of claim 1, The reinforcement tube 1 supported in an inverted state in the inverted support part 12 has a silicon lab heater 90 and a heat conduction radiating hose 95 integrally connected to a distal end thereof, and the silicon lab heater 90 is a shuttle body 20. It is fixed to the heater fixture (98) installed in the), the silicon Lava heater (90) is a non-excavation overall repair device of the pipeline, characterized in that disposed in the inner center of the heat conduction radiating hose (95). The method of claim 3, wherein Non-excavation overall repair device for a pipeline, characterized in that the other side of the silicone lava heater 90, the heater rod 120 is further installed at the tip of the reinforcement tube (1) to remove the water remaining in the pipeline during the reversal operation. The method of claim 1, The double partition 16 is formed with a through-hole 16-2 through which the lower side of the thermally conductive radiating hose 95 that expands during air supply is formed, and the insertion groove 16-1 of the double partition 16 is formed. The inverted diaphragm 70 inserted into the through hole 71 is formed to pass through the upper side of the thermally conductive radiating hose 95 so that the double partition 16 and the inverted diaphragm 70 are electrically conductive during the hardening operation. Completely sealing the outside of the radiating hose (95) to prevent the air of the air chamber (17) is leaked to the outside, characterized in that the non-excavation overall repair device for the conduit. The method of claim 1, In front of the supply path 23, a rolling plate 80 for smoothly supplying the reinforcement tube 1 is rotatably installed in the shuttle body 20, and between the rolling plate 80 and the shuttle body 20 Pneumatic cylinder 82 is connected, when the folding of the rolling plate (80) pneumatic cylinder 82 is a non-excavation overall repair device of the pipe, characterized in that it is received in the receiving portion (83). After connecting one side of the silicon lab heater 90 and the heat conduction radiating hose 95 to the distal end of the reinforcing tube 1 supported in the inverted support 12 of the fixed body 10, a pair of airbags ( A silicon lab heater and a heat conduction radiating hose installation process for sequentially fixing the other side to the heater fixture 98 of the shuttle body 20 by sequentially passing between the tube grooves 51 of the elastic block 50 and between 60; Reinforcing tube reversal step of inverting the reinforcement tube (1) in the interior of the pipe by injecting air into the air chamber (17) of the fixed body (10); After the reversal of the reinforcing tube (1) is completed, the shuttle body separation step of sliding and transporting the shuttle body 20 to temporarily separate, open from the fixed body (10); A thermally conductive radiant hose expansion step of expanding the thermally conductive radiant hose (95) to maintain the shape by injecting air into the thermally conductive radiant hose (95); The inverted diaphragm 70 is lowered to surround the upper portion of the expanded thermally conductive radiation hose 95 so that the through holes 71 and 16-2 formed in the inverted diaphragm 70 and the double partition 16 are heat conducting. An inverted membrane plate blocking step of completely sealing the outside of the hose 95 to prevent air from leaking in the air chamber 17; By heating the silicon lava heater 90 disposed in the center of the thermally conductive radiating hose (95), the high temperature radiant heat is dispersed inside the thermally conductive radiating hose (95), and then evenly applied to the entire area of the reinforcing tube (1). Non-excavation overall repair method of the pipeline, characterized in that consisting of a reinforcing tube hardening process for firmly attaching the reinforcing tube (1) to the inner circumference of the.

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