KR20180009528A - Grouting forming method for buried-pipe structure using inversion tube - Google Patents

Abstract

A grouting forming method according to the present invention comprises: a first step of supplying an inverting tube to the inside of a pipeline built in a structure, and injecting water of a high pressure into the inverting tube to press the inverting tube to an inner wall of the pipeline; a second step of injecting a grout liquid into a crack formed in the structure; a third step of forming a cut portion at a point extracted to the outside of the pipeline, of the inverting tube if the injection of the grout liquid is completed; a fourth step of extracting a hold rope connected to a front end of the inverting tube through the cut portion; and a fifth step of continuously pulling the hold rope to extract the inverting tube pressed to the inner wall of the pipeline. By using the grouting forming method of the present invention, when a crack is generated in a structure in which a pipeline is built such as a bank and the like, it is possible to reinforce the structure by injecting a grout liquid into the crack, and the grout liquid injected into the crack is not leaked into the pipeline. Thus, unnecessary waste of the grout liquid and a pipeline inner diameter reduction phenomenon can be prevented, and damage to the pipeline induced by injection pressure of the grout liquid can be prevented.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a grouting forming method for a pipe structure using an inverted tube,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a reinforcement method for reinforcing a crack in a structure filled with a channel, such as a bank, by a grouting method. More particularly, the present invention relates to a method of reinforcing a grout- And more particularly, to a grouting forming method capable of stably reinforcing a structure without fear.

Generally, the embankment is installed to prevent the damage of farmland and private houses due to flooding of rivers caused by rainy season, heavy rain, typhoon. These embankments were constructed by selecting the slope through foundation compaction, underprotection, slope cover, etc., and then laying blocks on it.

However, the embankment according to the conventional construction method is not robust in structure and weak in durability, and therefore, it is easily deformed by external shear or non-small external pressure. Therefore, the embankment can not exhibit its function due to breakage and cracks have. In addition, since the embankment lacks rigidity, when the embankment penetrates, the entire ground of the embankment is eroded in succession, resulting in the loss and collapse of the embankment.

In order to maintain the function of the levee by repairing the leaking portion or collapse portion of the levee caused by the original failure of the levee as described above, frequent work was required, .

In addition, when timely maintenance and reinforcement are not carried out, rivers are collapsed due to the rainy season and heavy rains in summer, and floods and floods in private and agricultural areas lead to disasters such as human injury and flood damage. Resulting in financial losses and the like.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a conventional embankment structure will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view of a conventional embankment.

As shown in FIG. 1, the embankment 100 is provided with a stomach conduit 110 and a water gate 120 for supplying water of a reservoir to agricultural land or the like. At this time, the bank 100 is generally made of clay or made of concrete. As time elapses, there is a risk of cavitation due to the loss of soil and a large number of cracks 130, which may cause leakage and breakage do.

Therefore, when a large number of cracks 130 are formed in the bank 100, a method of reinforcing the bank 100 by injecting a grout liquid at a point where the crack 130 is formed may be proposed. When the gastric fluid is connected to the abdominal cavity conduit 110, a phenomenon that the grout fluid slips into the abdominal cavity conduit 110 occurs. If the leakage of the grout liquid occurs, the amount of the grout liquid used is unnecessarily increased. In addition, when the grout liquid flows into the gastro-intestinal channel 110, the inner diameter of the gastro-intestinal channel 110 becomes narrow. Of course, if the interior of the abdominal fluid pipeline 110 is cleaned after reinforcement of the bank 100, the problem of narrowing the inside diameter of the abdominal fluid pipeline 110 can be solved. However, there is a problem that labor is required to remove the cured grout fluid do.

In addition, when the grout liquid is injected at a high pressure in a state where a large number of cracks 130 are generated in the abdominal fluid pipeline 110, there is a serious problem that the abdominal fluid pipeline 110 may be broken by the grout fluid injection pressure.

In order to solve this problem, a reinforcing method of reinforcing the embankment by attaching a separate reinforcing structure to the embankment slope has been proposed. However, such a reinforcing method requires a lot of cost and time.

KR 10-0919252 B1

DISCLOSURE OF THE INVENTION The present invention has been proposed in order to solve the above problems, and it is an object of the present invention to provide a method of reinforcing a structure by injecting a grout liquid into a crack when cracks occur in a structure filled with a pipeline, The present invention provides a grouting forming method capable of preventing a grouting forming process.

According to another aspect of the present invention, there is provided a grouting forming method comprising: supplying a reverse tube to an inside of a conduit buried in a structure, injecting high-pressure water into the inside of the reverse tube to press the reverse tube to an inner wall of the conduit A first step; A second step of injecting the grout solution into a crack formed in the structure; A third step of forming an incision at a point of the inverted tube drawn out of the conduit when the injection of the grout liquid is completed; A fourth step of pulling the hold rope connected to the tip side of the inverting tube through the cutout; And a fifth step of continuously pulling the hold rope to pull out the inverted tube pressed on the inner wall of the pipe.

The first step is constituted so as to supply the inverting tube to the inside of the channel after the inner end of the channel is covered with a reversing film.

The reversal membrane comprises a support plate vertically erected at an inner end of the channel and a support leg for supporting the support plate so as not to be pushed by the reversing tube.

The first step further includes injecting high-pressure water into the inverting tube, and then sealing and fixing the rear end of the inverting tube with a finishing band.

The third step is configured to form a cutout at the same height as the top end of the inner space of the pipeline in the inverted tube.

The third step is constituted to form a cutout at a point which is a predetermined distance from the uppermost part of the inner space of the pipe in the reversing tube.

The grouting reinforcement method according to the present invention can reinforce a structure by injecting a grout solution into a crack when cracks are generated in a structure in which a pipeline is buried, such as a bank, and the grout solution injected into the cracks flows into the pipe It is possible to prevent unnecessary waste of the grout liquid and reduce the inner diameter of the piping, and it is possible to prevent breakage of the pipeline due to the grout liquid injection pressure.

1 is a cross-sectional view of a conventional embankment.
2 is a flowchart of a grouting forming method according to the present invention.
3 is a cross-sectional view of the embankment in which the inverted tube is injected into the abdominal duct.
4 is an enlarged view of the 'A' region shown in FIG.
FIGS. 5 to 7 are sectional views sequentially showing the process of removing the inverted tube from the abdominal fluid pipeline after the grout liquid is injected.

Hereinafter, embodiments of a grouting forming method according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a flowchart of a grouting forming method according to the present invention.

The grouting forming method according to the present invention is a method for reinforcing the structure by injecting the grouting solution into the crack when cracks are generated in the structure in which the channel is buried. The grouting solution injected into the cracks does not fall into the channel, And the pipeline is not broken by the injection pressure of the liquid.

That is, the grouting forming method according to the present invention includes a first step (S10) of feeding a high-pressure water into the inside of the inversion tube to pressurize the inversion tube to the inner wall of the conduit while supplying the inversion tube to the inside of the conduit buried in the structure A second step S20 of injecting a grout solution into a crack formed in the structure, a third step S30 of forming an incision at a point of the inverted tube drawn to the outside of the pipe after the injection of the grout solution is completed, A fourth step (S40) of withdrawing the hold rope connected to the tip side of the inverting tube through the cutout, a fifth step (S50) of pulling the inverted tube, which is squeezed on the inner wall of the conduit by continuously pulling the hold rope, .

When the grouting forming method according to the present invention is used, grout liquid can be injected into a crack to crack the structure when cracks are generated in a structure in which the pipeline is embedded, such as a bank, and the grout liquid injected into the crack It is possible to prevent unnecessary waste of the grout liquid and reduce the inner diameter of the piping, and it is possible to prevent breakage of the pipeline due to the grout liquid injection pressure. Another feature is that the reversing tube can be more easily removed by minimizing the frictional force between the reversing tube and the pipeline and the frictional force between the reversing tube when the reversing tube is pulled out.

The grouting forming method according to the present invention can be applied to any structure in which a channel is embedded. Hereinafter, the grouting reinforcement of the embankment in which the abdominal channel is embedded will be described in detail with reference to FIGS. 3 to 7.

3 is a cross-sectional view of a bank where a reversing tube is injected into the abdominal pain conduit, and FIG. 4 is an enlarged view of the 'A' portion shown in FIG.

Generally, the embankment 100 for storing the water of the reservoir is formed with a stomachic duct 110 at the lower side and has at least one water gate 120 for introducing and blocking the water of the reservoir into the stomach conduit 110. At this time, a number of cracks 130 are generated as the use period of the bank 100 elapses. The grouting forming method according to the present invention is used for reinforcing the bank 100 where the crack 130 is generated as described above .

When the crack 130 is to be reinforced by using the grouting forming method according to the present invention, the tip of the reversing tube 200 is first inserted to the outlet side of the gastric tube 110 (in this embodiment, Pressure water 10 is injected into the inverting tube 200 to compress the inverting tube 200 on the inner wall of the abdominal duct 110 as shown in FIG. At this time, when injecting the high-pressure water 10 into the inverting tube 200, the holding rope 210 connected to the tip of the inverting tube 200 is slowly released at a predetermined speed, So that the inverting tube 200 can maintain a state of pressing the inner wall surface of the gastric tube 110. The technical idea of gradually releasing the holding rope 210 in the process of reversing the reversing tube 200 to keep the internal pressure of the reversing tube 200 at the reference value or more is a practical technique for reversing the conventional reversing tube 200 And the detailed description thereof will be omitted.

The inverting tube 200 which is drawn into the abdominal duct 110 so as to prevent the leakage of the water while the inverting tube 200 maintains an appropriate magnitude for pressing the inner wall of the abdominal duct 110, It is preferable that the tip end portion is not inverted but the tip end side portion is not inverted as shown in Fig. For example, the length of the non-inverted portion of the reversing tube 200 may be set to about ten times the diameter of the abdominal pain line 110. [ Of course, the length of the non-inverted portion of the inverted tube 200 can be freely changed according to various conditions such as the characteristics of the abdominal duct 110, the material of the inverted tube 200, and the water pressure inside the inverted tube 200 .

The rear end of the inverting tube 200 is connected to the closing band 220 so that the water 10 in the inverting tube 200 does not flow out to the outside when the inverting tube 200 is sufficiently inverted and pulled into the inside of the gastric tube 110. [ And then sealing is performed. At this time, the finishing band 220 can be made of any material as long as the rear end of the reversing tube 200 can be bound and sealed. Of course, even if the rear end of the reversing tube 200 is bundled with the finishing band 220, the holding rope 210 should be kept in a pullable state.

When the inverted tube 200 is completely compressed in the abdominal fluid pipeline 110, the grout liquid is injected into the crack 130 to reinforce the embankment 100. Even if the crack 130 extends to the gastric tube 110, the entire inner surface of the gastric tube 110 is closely adhered by the inverting tube 200, and grout liquid is injected into the gastric tube 110, It will not be allowed to enter. Therefore, by using the grouting forming method according to the present invention, it is possible to prevent the wasted amount of the grout solution from being wasted, thereby reducing the construction cost, and the inside diameter of the gastric tube 110 is narrowed by the leaked grout solution The process of cleaning the inside diameter of the abdominal cavity canal 110 is advantageous.

When the grouting solution is injected into the crack 130, the grouting solution should be injected at a high pressure higher than a reference value. When the grouting forming method according to the present invention is used, the swirling tube 110 flows into the inverted tube 200, So that it is possible to prevent a phenomenon that the abdominal fluid channel 110 is broken due to the grout fluid injection pressure.

The inverting tube 200 may be inserted into the abdominal cavity of the abdominal cavity so that the inverted tube 200 can be press-fitted only to the inner end of the abdominal cavity tube 100 in the process of pushing the inverted tube 200 into the abdominal cavity channel 110. A process of closing the inner end of the abdominal fluid channel 110 with the reversal membrane 300 may be preceded.

When the inner end of the abdominal fluid channel 110 is kept blocked by the reversing membrane 300, the reversing tube 200 is press-fitted only until the reversing membrane 300 is pressed against the inverting tube 200, And the inner pressure of the inverting tube 200 can be sufficiently raised above the reference value, so that it can be reliably and stably pressed on the inner surface of the abdominal duct 110.

4, the reversing membrane 300 includes a support plate 310 vertically installed at an inner end of the conduit, a support plate 310 supported to support the support plate 310 by the reversing tube 200, And a support leg 320 for supporting the support member. In this embodiment, only the case where the support leg 320 extends in a downward inclined direction is shown, but the extending direction and the length of the support leg 320 may be any shape as long as they can stably support the support plate 310 Can also be replaced.

5 to 7 are sectional views sequentially showing the process of removing the inverted tube 200 from the abdominal fluid pipeline 110 after the grout liquid is injected.

When the injection of the grout liquid into the crack 130 is completed, the inverted tube 200 injected into the abdominal fluid conduit 110 must be removed. The inverted tube 200 is compressed by the internal water pressure to the abdominal fluid conduit 110 There is a problem in that it is difficult to pull out the inverting tube 200 from the abdominal duct 110 simply by pulling the inverting tube 200.

Accordingly, in order to draw the inverted tube 200 out of the gastric tube 110, the water 10 in the inverted tube 200 is first discharged to lower the internal pressure of the inverted tube 200, It should be withdrawn. However, if the water 10 in the reversing tube 200 is completely removed at one time, the reversing tube 200 is stacked on the bottom surface of the abdominal cavity tube 110, so that the sheets constituting the reversing tube 200 are superimposed, So that a large amount of force is still required to pull out the inverting tube 200. [

The grouting forming method according to the present invention does not cause a large frictional force between the sheets of the reversing tube 200 even if the internal pressure of the reversing tube 200 is lowered by discharging the water 10 in the reversing tube 200, The incision part 230 is formed at the point where the inverted tube 200 is pulled out of the abdominal duct 110 of the inverted tube 200 so that the inverted tube 200 can be pulled out from the abdominal duct 110, It is preferable to form the cutout 230 at the same height as the top end of the inner space of the gastric tube 110 in the inverted tube 200 as shown in FIG.

When the incision portion 230 is formed at the same height as the uppermost end of the internal space of the abdominal pain conduit 110, only water 10 higher than the incision portion 230 is discharged from the water 10 filled in the reversing tube 200 The water in the portion located in the abdominal fluid channel 110 is still filled in the reversing tube 200 and the phenomenon that the reversing tube 200 sheet contacts with the inner pressure of the reversing tube 200 drops Is not generated. 6, when the hold rope 210 is pulled out through the cutout 230 and the hold rope 210 is pulled out to pull the inverted tube 200 out of the abdominal cavity channel 110, The inversion tube 200 in the abdominal fluid channel 110 maintains a state in which the sheets constituting the cylindrical shape, that is, the inversion tube 200 are not stacked, so that the inversion tube 200 can be drawn out more smoothly.

Since the water 10 in the inverting tube 200 is discharged through the cutout 230 because the tip of the inverting tube 200 is transported along the holding rope 210, The water 10 in the inverting tube 200 is discharged.

If the incision 230 is formed at a position lower than the uppermost end of the inner space of the abdominal cavity 100 of the inverted tube 200, the water 10 in the abdominal cavity 110 of the inverted tube 200, The sheets of the reversing tube 200 may be stacked. Therefore, it is preferable that the cut-out portion 230 is formed at the same height as the uppermost end of the inner space of the gastric tube 110 as shown in the present embodiment, or at a position slightly higher than the uppermost end of the inner space of the gastric tube 110 .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the scope of the present invention is not limited to the disclosed exemplary embodiments. It will also be appreciated that many modifications and variations will be apparent to those skilled in the art without departing from the scope of the invention.

100: levee 110: abdominal duct
120: Water gate 130: Crack (solid line)
200: reversing tube 210: holding rope
220: Closing band 230:
300: inverting membrane 310: support plate
320: support leg

Claims (6)

A first step of supplying the inverting tube 200 to the inner side of the conduit buried in the structure and injecting high pressure water into the inverting tube 200 to press the inverting tube 200 on the inner wall of the conduit;
A second step of injecting the grout solution into the crack 130 formed in the structure;
A third step of forming an incision 230 at a point of the inverted tube 200 which is drawn out to the outside of the tube when the injection of the grout solution is completed;
A fourth step of withdrawing the hold rope 210 connected to the tip side of the inverting tube 200 through the cut-off part 230; And
A fifth step of continuously pulling the hold rope 210 and pulling out the inverted tube 200 that has been pressed on the inner wall of the pipe;
Wherein the grouting forming method comprises the steps of: The method according to claim 1,
In the first step,
And the inverting tube (200) is supplied to the inside of the pipe after the inner end of the pipe is covered with the reversing film (300). The method of claim 2,
The inverting membrane 300 includes a support plate 310 vertically installed at an inner end of the channel and a support leg 320 supporting the support plate 310 so as not to be pushed by the inverting tube 200 The grouting forming method comprising: The method according to claim 1,
In the first step,
Further comprising the step of injecting high-pressure water into the inverting tube (200) and then sealing and fixing the rear end of the inverting tube (200) with a finishing band (220). The method according to claim 1,
In the third step,
Wherein the cut-out portion (230) is formed at the same height as the uppermost end of the inner space of the tube in the inverting tube (200). The method according to claim 1,
In the third step,
Wherein the slits (230) are formed at a position higher than a predetermined distance from a top end of the inner space of the tube in the inverting tube (200).

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