KR101637507B1 - River crossing buried pipeline construction and pipeline laying method using the same - Google Patents

Abstract

A transverse pipe embedded structure according to an aspect of the present invention and a pipeline embedding method using the same are provided with a pair of first pipelines embedded in cables at both sides of a river, A pair of second conduits connected to the bottom of the slope formed at the lower end of the slope to allow the cable to pass through the lower slope of the slope and both ends connected to the pair of second conduits, And a third conduit through which the cable inserted through the first conduit traverses the lower end of the stream to reach another of the first conduits on the opposite side.

Description

Technical Field [0001] The present invention relates to a bridge structure for a river crossing pipe,

The present invention relates to a structure embedded in a river transverse pipe and a method for burying a pipe using the same. More particularly, the present invention relates to a structure for an excavation and repair of a river crossing pipe that can be excavated and restored at the same time.

Generally, when a pipeline traversing a subsea channel and a river is buried, a low depth region is selected and a mud layer or a river bottom is widely installed and buried (an open type method), or a method of buried using a sheet pile method .

At this time, the open-type method and the sheet-file method have a problem that extensive environmental destruction occurs. That is, in order to protect the pipeline from typhoon, tidal wave, and dredging equipment when the pipeline crossing the underwater pipeline and the river is buried, the pipeline should be buried to a certain depth or more. In the open type and the sheet pile method, , Which destroys ecosystems and causes serious environmental problems.

On the other hand, the non-installation type excavation method is a construction method of making a tunnel in the ground without directly excavating the road, as in "Korean Registration No. 10-1436816 (2014.08.27)". Such an unbonded excavation method is known as a horizontal directional drilling method (H.D.D. method), and this method is recognized to be superior to other methods in reducing social cost and securing safety.

However, due to the nature of such a directional indentation method, there is a problem that a large amount of bentonite sludge (bentonite mixture mixed in excavation, clay, sand, foreign matter, etc.) generated in the excavation process causes serious environmental damage and pollutes the surrounding environment. It is difficult to process such as making a tunnel on the surface of the substrate, which is time consuming.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide a transverse pipe-laying structure capable of excavating and repairing on the same day,

The present invention also provides a structure embedded in a transversal pipeline capable of laying a pipeline without damaging the flat surface, and a method of burying pipelines using the same.

Further, it is an object of the present invention to provide a structure for installing a transversal pipe having excellent workability and economic efficiency, and a method for burying a pipe using the same.

According to an aspect of the present invention, there is provided a transversely installed pipeline structure, comprising: a pair of first pipelines embedded in a bottom of a square formed on both sides of a river, A pair of second conduits connected to the first conduit and embedded in the bottom of the slit formed between the stream and the slab so as to allow the cable to pass the bottom of the slit and both ends connected to a pair of the second conduits, And a third conduit buried so that the cable inserted through the first conduit traverses the bottom of the stream and reaches another conduit on the opposite side.

The first conduit includes an upper manhole buried in a road provided at an upper portion of a slab, a lower manhole buried in a lower portion of the slab, a steel pipe having both ends connected to the upper manhole and the lower manhole, .

The lower manhole may be formed as an inclined surface having one side facing the upper manhole.

The second channel may include a corrugated pipe having one end connected to the lower manhole and embedded in the lower end of the corrugated pipe, and a cover provided on the corrugated pipe to protect one side and the other side in the longitudinal direction of the corrugated pipe.

Wherein the cover includes a main plate covering one longitudinal side of the corrugated tube, a pair of side plates extending from both ends of the main plate to cover the side of the corrugated tube, and a pair of side plates sandwiching the main plate, The mounting hole can be provided.

The cover may include a cover that covers an upper portion of the cover when the main plate is brought into contact with the ground, and the side plate may have a coupling groove into which the cover is fitted.

The third conduit may include a synthetic resin straight pipe in which the corrugated pipe is connected to both ends of the stream, and a case coupled to the synthetic resin straight pipe to support and fix the synthetic resin straight pipe.

The case may include an outer member for forming a three-dimensional inner space, and an inner member provided in the inner space formed by the outer member for enhancing the rigidity of the outer member and dividing the inner space.

Wherein the outer member includes a pair of transverse members formed to be long along the longitudinal direction of the synthetic resin straight pipe, a pair of longitudinal members connecting both ends of the pair of transverse members, A pair of frames provided adjacent to each other in the vertical direction and having a connecting member for connecting the pair of the horizontal members to each other; And a pair of reinforcing members for reinforcing the rigidity of the frame by connecting the first and second pillars to each other, a first pillar for integrating the edges of the pair of the frames facing each other, A pillar member having a pair of the frames integrated with each other; .

Wherein the inner member includes a plurality of upper and lower partition members which are provided between the column members facing each other in the width direction of the horizontal member and divide the space between the column members facing each other in the width direction of the horizontal member into upper and lower directions; A plurality of left and right partition members which are coupled with the upper and lower partition members so as to form a vertical direction with respect to the upper and lower partition members and divide the space between the pillars facing each other in the width direction of the cross member in the left and right directions; A plurality of insertion holes formed by the upper and lower partitioning members and the right and left partitioning members and passing through the synthetic resin straight pipe; And a support member which is respectively engaged with the upper surfaces of the plurality of upper and lower partitioning members and which is elongated along the longitudinal direction of the transverse member and supports the synthetic resin straight pipe.

The first pillar may be provided with a fixing part extending from the first pillar in the direction of the ground to fix the case to the ground.

And a plurality of loss prevention piles provided on an outer surface of the case to prevent loss of the case.

Wherein the synthetic resin straight pipe includes a body, an insertion portion formed at one end of the body, a coupling portion into which an insertion portion of another adjacent synthetic resin straight pipe formed at the other end of the body is inserted, A rubber ring for increasing a coupling force between the engaging portion and another adjacent inserting portion of the synthetic resin straight pipe inserted into the engaging portion and a plurality of spacers provided at regular intervals on an outer circumferential surface of the body.

According to another aspect of the present invention, there is provided a method for laying a pipeline using a transversely installed pipeline structure, the method comprising the steps of: A step of disposing a trench for turning the trench and the bottom of the river located in the direction of the other side of the floor, a step of burying the trench and the bottom of the river, A step of dismantling the water film, a step of disposing the water film for turning the water path of the stream in the direction of the other side of the river, the step of tearing the bottom side and the bottom of the river located in the side direction of one side, A second channel and another third channel; and forming a slope and a river bottom surface and disassembling the water film.

The step of burying the first conduits on the lower surface of the slope formed on both sides of the river includes the steps of embedding the lower manholes in the lower part of the slab, inserting the steel pipes after drilling the lower part of the slab, And a step of burying the upper manhole.

Wherein the step of embedding the second channel and the third channel comprises the steps of connecting the corrugated pipe of the second conduit to the steel pipe buried in the direction of the other side surface, installing a cover on the corrugated pipe, Coupling the synthetic resin straight pipe of the synthetic resin pipe to the case, and connecting the synthetic resin pipe connected to the case to the wave pipe.

The step of embedding the second pipe and the third pipe may further comprise the steps of connecting the corrugated pipe of the second conduit to the steel pipe embedded in one direction of the lateral direction, Connecting the synthetic resin straight pipe of the third pipe to the case, connecting the synthetic resin straight pipe coupled to the case to the wave pipe, connecting the synthetic pipe straight pipe of one side direction to the synthetic pipe straight pipe of the other side direction The method comprising the steps of:

According to the present invention, it is possible to excavate and repair at the same time, thereby shortening the air.

In addition, the pipeline can be buried without damaging the flat surface.

In addition, it is possible to provide a method of burying a pipe with excellent workability and economic efficiency.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a cross-sectional view showing a structure in which a transverse pipe embedded structure according to an embodiment of the present invention is installed. FIG.
FIG. 2 is a perspective view showing a second channel of a structure embedded in a river cross-section pipe shown in FIG. 1; FIG.
FIG. 3 is a perspective view showing a third channel of a structure embedded in a river cross-section pipe shown in FIG. 1; FIG.
4 is an exploded perspective view showing a case of the third conduit shown in Fig.
FIG. 5 is a perspective view showing a modification of the third conduit shown in FIG. 3; FIG.
FIG. 6 is a perspective view showing still another modification of the third conduit shown in FIG. 3; FIG.
7 is a view showing the synthetic resin straight pipe of the third pipe shown in Fig. 3; Fig.
FIG. 8 is a flowchart illustrating a method of burying a pipeline using a transversal pipe embedded structure according to an embodiment of the present invention. FIG.
FIG. 9 is a flow chart showing a detailed process of a pipeline burial method using a transversal pipeline buried structure shown in FIG. 8. FIG.
FIG. 10 is a view showing a method of burying a pipeline using the transversal pipe embedded structure shown in FIG. 8. FIG.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG.

FIG. 1 is a cross-sectional view showing a structure in which a transverse pipe embedded structure according to an embodiment of the present invention is installed.

As shown in FIG. 1, the transverse pipe embedded structure according to an embodiment of the present invention may include a first pipe line 100, a second pipe line 200, and a third pipe line 300.

The first conduits 100 are provided in a pair and can be embedded in the lower end of the rectangular surface 20 formed on both sides of the river 10 around the river 10 so that a cable (not shown) can be inserted.

The first channel 100 includes an upper manhole 110 buried in the road 40 provided on the upper surface 20, a lower manhole 120 buried in the lower part of the main body 20, And a steel pipe 130 to which both ends are connected to the lower manhole 120, respectively.

The steel pipe 130 may be embedded at the lower end of the sloping surface 20 along the slope of the sloping surface 20. The lower manhole 120 may be formed as a sloped surface 121 facing the upper manhole 110, The upper manhole 130 can be easily connected to the lower manhole 120.

The second duct 200 is provided in a pair in the same manner as the first duct 100 and each one end is connected to the first duct 100 and is formed between the river 10 and the side 20 So that a cable (not shown) can be passed through the lower end of the cutter 30.

The third conduit 300 is connected to the pair of second conduits 200 at both ends and embedded in the lower end of the stream 10 so that a cable (not shown) passes through the lower end of the stream 10.

The present invention has a structure in which a cable (not shown) is installed on a steel pipe 130 through an upper manhole 110 embedded in an upper road 40 located on one side of a river 10, And then passes through the lower manhole 120 and then passes through the lower end of the slit 30 through the second channel 200. [ The third channel 300 passes through the lower end of the stream 10 to move to the second channel 200 buried in the lower end of the cutter 30 located at the other side of the stream 10, The lower manhole 120, the steel pipe 130, and the upper manhole 110 connected to the main body 200 in this order.

A cable (not shown) inserted through a road 40 located at one side of the river 10 can reach the road 40 located at the other side across the river 10 through the above-mentioned moving process have. The construction method using the structure embedded in the river transverse pipe of the present invention will be described later.

Next, the second channel 200 will be described in more detail. In the following description, only different parts from the above-described embodiment will be described in detail and the same or similar parts will not be described in detail.

FIG. 2 is a perspective view showing a second channel of a structure embedded in a cross-river channel structure shown in FIG. 1. FIG.

Referring to FIGS. 1 and 2, a transverse pipe embedded structure according to an embodiment of the present invention includes a pair of first (first) and second The pipeline 100 is connected to a pair of the first pipelines 100 and is embedded at the lower end of the slit 30 formed between the river 10 and the sloping surface 20 so that a cable (not shown) A pair of second pipelines 200 passing through the bottom of the first channel 100 and a pair of second pipelines 200 connected to the pair of second pipelines 200 at both ends and embedded in the lower end of the stream 10, And a third conduit 300 for traversing the lower end of the stream 10 to reach another of the first conduits 100 on the opposite side.

The second conduit 200 is connected to a lower end manhole 120 and has a wave tube 210 embedded at the lower end of the cutter 30 and an upper portion of the wave tube 210, And a cover 220 for protecting the one surface and the side surface.

As shown in the figure, a plurality of the corrugated tubes 210 may be stacked, and the cover 220 may be formed of a plurality of corrugated tubes 210, And the like.

The cover 220 includes a main plate 221 covering one side in the longitudinal direction of the corrugated pipe 210, a pair of side plates 222 extending from both ends of the main plate 221 and covering side surfaces of the corrugated pipe 210, And a seating hole 223 provided in a shape surrounded by the pair of side plates 222 and on which the corrugated pipe 210 is seated.

The main plate 221 and the pair of side plates 222 may be formed so that the cover 220 is formed in a U shape and one end of the side plate 222 is set to face the ground, And may be provided so as to face the ground.

A cover 224 covering the top of the cover 220 is provided when the main plate 221 is brought into contact with the paper surface and a coupling groove 225 in which the cover 224 is inserted is provided on the side plate 222 .

As described above, since the cover 220 is provided, it is possible to prevent the corrugated tube 210 from being damaged or damaged by the load of the cutter 30 formed on the corrugated tube 210, The effect of increasing the service life can be exhibited.

Hereinafter, the third conduit 300 will be described in more detail. In the following description, only different parts from the above-described embodiment will be described in detail and the same or similar parts will not be described in detail.

FIG. 3 is a perspective view showing a third channel of the structure embedded in the cross-river channel structure shown in FIG. 1, and FIG. 4 is an exploded perspective view showing a case of the third channel shown in FIG.

1, 3 and 4, a transverse pipe embedded structure according to an embodiment of the present invention includes a cable (not shown) embedded in the bottom of a rectangular surface 20 formed on both sides of a river 10, A pair of first pipelines 100 to be inserted into the first duct 100 and a pair of first ducts 100 connected to the first duct 100 and embedded in the lower end of the slit 30 formed between the river 10 and the roof 20, A pair of second conduits 200 connected to the pair of second conduits 200 so that both ends of the second conduits 200 pass through a lower end of the ditch 30 and are connected to the first conduit And a third channel 300 for allowing a cable (not shown) inserted through the first channel 100 to cross the lower end of the river 10 to reach another channel 100 on the opposite side.

The third channel 300 is formed at a depth of 2 meters or more from the bottom of the river 10 so that the bottom surface of the river 10 has a sufficient thickness and the third channel 300 300 can be prevented from being exposed.

The third conduit 300 is connected to the synthetic resin straight pipe 310 and the synthetic resin straight pipe 310 by being connected to both ends of the wave tube 210 and connected to the synthetic resin straight pipe 310, And a case 320 that supports and fixes the battery.

The case 320 is provided in an inner space formed by the outer member 320a and the outer member 320a so as to form a three-dimensional inner space, thereby increasing the rigidity of the outer member 320a, And an inner member 320b for dividing the inner member 320b.

The outer member 320a may include a pair of frames 321 provided in the vertical direction and a column member 322 provided between the pair of frames 321.

The frame 321 includes a pair of transverse members 321a and 321a which are elongated along the longitudinal direction of the synthetic resin straight pipe 310 and a pair of longitudinal members 321a and 321b connecting both ends of the transverse member 321a And a connecting member 321c that connects the pair of horizontal members 321a to the pair of horizontal members 321a. The frame 321 is provided in the shape of a rectangle by a transverse member 321a and a transverse member 321b and a connection member 321c is formed in a space surrounded by the transverse member 321a and the transverse member 321b So that the rigidity of the frame 321 can be increased. Although the connecting member 321c is shown as being three in this embodiment, the connecting member 321c may be provided in various numbers depending on the situation.

The pillar member 322 includes a first pillar 322a for integrating the corners of opposite positions of the pair of frames 321, a second pillar 322b for integrating the lateral members 321a, And a reinforcing member 322c connecting the second column 322b and the second column 322b to increase rigidity.

The first pillar 322a may be provided at an edge of the pair of frames 321 to integrate the corner portions of the pair of frames 321 so that the overall shape of the outer member 320a may be formed.

The second column 322b is formed by integrating the transverse member 321a of the frame 321 located at the upper portion and the transverse member 321a of the frame 321 located at the lower portion relatively to reinforce the rigidity of the transverse member 321a, It is possible to prevent the lateral member 321a from being sagged by the load of the bottom surface of the river 10 and the river 10 formed at the upper portion of the frame 321. [ Although the connecting member 321c is shown as being three in this embodiment, the connecting member 321c may be provided in various numbers depending on the situation.

The reinforcing member 322c connects the first pillar 322a and the second pillar 322b or the second pillar 322b to increase the overall rigidity of the pillar member 322 so that the case 320 can be more securely secured to the synthetic resin pipe 310).

The inner member 320b may include upper and lower partition members 323, left and right partition members 324, insertion holes 325, and support members 326. [

The upper and lower partitioning members 323 are provided between the column members 322 facing each other in the width direction of the column member 321a to divide the space between the column members 322 facing each other in the width direction of the column member 321a into a vertical direction As shown in Fig. That is, a plurality of upper and lower partitioning members 321a and 322b are provided between the first pillar 322a and the first pillar 322a facing each other in the width direction of the cross member 321a and between the second pillar 322b and the second pillar 322b 323 may be respectively provided to divide the space between the pillar members 322 facing each other in the width direction of the lateral member 321a in the vertical direction.

The left and right partition members 324 can be engaged with the upper and lower partition members 323 to form a vertical direction with respect to the upper and lower partition members 323. A plurality of left and right partition members 324 may be coupled to one upper and lower partition member 323 so that a space between the column members 322 facing each other in the width direction of the horizontal member 321a may be divided in the left and right directions.

A plurality of insertion holes 325 may be formed by the upper and lower partitioning members 323 and the left and right partitioning members 324 in the space between the pillar members 322 facing each other in the width direction of the cross member 321a. The synthetic resin straight pipe 310 passes through the insertion hole 325 and is seated.

The support member 326 is connected to the upper surface of the upper and lower partitioning members 323 and extends along the longitudinal direction of the transverse member 321a to form a synthetic resin straight pipe 310 ). ≪ / RTI >

As described above, the plurality of synthetic resin straight pipes 310 can be secured and supported in a laminated form by the case 320, and can be safely protected from the bottom surface of the river 10 and the load of the river 10.

Next, a modification of the third conduit 300 will be described. In the following description, only different parts from the above-described embodiment will be described in detail and the same or similar parts will not be described in detail.

FIG. 5 is a perspective view showing a modification of the third duct shown in FIG. 3, and FIG. 6 is a perspective view showing still another modification of the third duct shown in FIG.

3 to 6, the third conduit 300 of the transverse pipe embedded structure according to an embodiment of the present invention is constructed such that the corrugated pipe 210 is connected to both ends thereof, And a case 320 for supporting and fixing the synthetic resin straight pipe 310 in combination with the synthetic resin straight pipe 310.

The case 320 is provided in an inner space formed by the outer member 320a and the outer member 320a to form a three-dimensional inner space, thereby increasing the rigidity of the outer member 320a, And an inner member 320b for dividing the inner member 320b.

The outer member 320a includes a frame 321 having a transverse member 321a, a longitudinal member 321b and a connecting member 321c, a first column 322a, a second column 322b, And a column member 322 having a plurality of column members 322c.

The inner member 320b may include upper and lower partition members 323, left and right partition members 324, insertion holes 325, and a support member 326.

Meanwhile, a plurality of the loss prevention piles 330 may be provided on the outer surface of the case 320. The loss prevention file 330 is fixed to the ground on which the case 320 is placed and is coupled with the case 320 to prevent the third duct 300 from being lost due to the flow velocity of the river 10 can do.

At this time, the loss prevention file 330 is provided on the outer surface of the case 320 facing the downstream side of the river 10 to support the case 320 from the flow velocity of the river 10 flowing from the upstream side to the downstream side . In the present embodiment, three pieces of the above-mentioned loss prevention file 330 are shown. However, the above-mentioned loss prevention file 330 is not limited to the type of the ground in which the third conduit 300 is buried or the flow rate of the river 10 And may be provided in various numbers.

Meanwhile, the first column 322a may be provided with a fixing portion 322d extending in the direction of the paper from the first column 322a. One end of the fixing portion 322d is formed in a pointed shape and can be inserted into the ground at a position where the third duct 300 is to be buried.

The third conduit 300 is fixed to the ground as the fixed portion 322d is inserted into the ground so that the third conduit 300 can be prevented from being lost due to the flow velocity of the river 10. [

Next, the synthetic resin straight pipe 310 of the third conduit 300 will be described. In the following description, only different parts from the above-described embodiment will be described in detail and the same or similar parts will not be described in detail.

Fig. 7 is a view showing the synthetic pipe straight line of the third channel shown in Fig. 3;

3 and 7, the third pipeline 300 of the transverse pipeline embedded structure according to the embodiment of the present invention is constructed such that the corrugated pipe 210 is connected to both ends thereof, And a case 320 for supporting and fixing the synthetic resin straight pipe 310 in combination with the synthetic resin straight pipe 310.

The synthetic resin straight pipe 310 may include a main body 311, an insertion portion 312, a coupling portion 313, a rubber ring 314, and a spacer 315.

The insertion portion 312 may be formed at one end of the main body 311 and the coupling portion 313 may be formed at the other end of the main body 311. The inserted portion 312 formed at one end of the main body 311 is inserted into the engaging portion 313 of the main body 311 of another synthetic resin straight pipe 310 so that the adjacent synthetic resin straight pipe 310 can be engaged.

At this time, the rubber ring 314 is provided on the inner side surface of the coupling part 313, and the insertion part 312 of another adjacent synthetic resin straight pipe 310 inserted into the coupling part 313 and the coupling part 313, It is possible to exhibit an effect of increasing the coupling between the two.

The spacers 315 are provided on the outer circumferential surface of the main body 311 at predetermined intervals to maintain a predetermined interval when the synthetic resin straight pipe 310 is installed. Next, a method of burying a pipeline using a transversal pipe embedded structure according to an embodiment of the present invention will be described.

FIG. 7 is a flowchart illustrating a method of embedding a pipeline using a transversal pipe embedded structure according to an embodiment of the present invention, and FIG. 8 is a flowchart illustrating a detailed process of a pipeline embedding method using a cross- And FIG. 9 is a view illustrating a method of burying a pipeline using the transverse pipe embedded structure shown in FIG.

8 to 10, a method of burying a pipeline using a transverse pipe embedded structure according to an embodiment of the present invention includes burying a first pipeline 100 at a lower end of a rectangular surface 20 formed on both sides of a river 10 A step S200 of setting a water channel 400 for turning the water of the river 10 in the direction of the one side 20 and a step S200 for turning the water channel of the river 10 in the direction of the other side 20, (S400) of sandwiching the bottom surface of the trough (10) and the bottom surface of the river (10), a step (S400) of sandwiching the second channel (200) and the third channel A step S600 of setting the water film 400 to turn the water of the river 10 in the direction of the other side 20 and the step S600 of disassembling the water film 400, A step S700 of digging the bottom surface of the slope 30 and the bottom of the stream 10 located in the direction of the slope 30 and a step S800 of inserting another second channel 200 and another third channel 300, And The composition of the bottom surface 30 and the stream 10, and may be provided with a step (S900) for dismantling the dam body (400).

The step S100 of burying the first channel 100 at the lower end of the side 20 formed on both sides of the river 10 includes a step S110 of burying the lower manhole 120 in the lower part of the side 20, A step S120 of inserting the steel pipe 130 after perforating the lower end of the flat surface 20 and a step S130 of burying the upper manhole 110 in the road 40 provided on the upper surface 20, .

By installing the first duct 100 through the above-described method, the natural stone can be minimized because the construction is performed in a state of being formed without damaging the moon surface 20, and the cost due to the non-moonlighting of the moon 20 can be minimized It is possible to exert a saving effect.

The step S400 of embedding the second channel 200 and the third channel 300 may be performed by inserting the corrugated pipe 210 of the second channel 200 into the steel pipe 130 embedded in the direction of the other side 20, A step S420 of installing a cover 220 on the corrugated tube 210 and a step S420 of coupling the synthetic resin straight pipe 310 of the third conduit 300 to the case 320 And connecting the synthetic resin straight pipe 310 coupled to the case 320 to the wave tube 210 (S440).

The step S800 of inserting the second pipeline 200 and the third pipeline 300 is performed by moving the corrugated pipe 210 of the second pipeline 200 in the direction of the one side 20 A step S820 of installing the cover 220 on the wave tube 210 and a step S820 of connecting the synthetic resin straight pipe 310 of the third pipe 300 to the case 320 A step S840 of connecting the synthetic resin straight pipe 310 coupled to the case 320 to the corrugated pipe 210 and a step S840 of connecting the synthetic resin straight pipe 310 to the synthetic resin straight pipe 310 in the direction of the other side surface 20, (S850) connecting the synthetic resin straight pipe 310 in the direction of the arrow 20 in FIG.

Based on the above, the order of constructing the structures embedded in the river crossing pipe is summarized as follows.

Referring to FIG. 10, first, a location for constructing a bridge cross-over structure is selected and a compartment space 50 is set. The water channel 400 is provided so as to face the one side surface 20 in the partition space 50 so that the water flows in the direction of the other side surface 20 in the partition space 50. [

The second channel 200 and the third channel 300 are connected to the bottom manhole 120 to which the steel pipe 130 is connected by treading the bottom surface of the river 10 in the direction of the one side surface 20 and the cut- The bottom surface of the stream 10 and the slant 30 are formed.

Thereafter, the water film 400 is installed so as to face the other side surface 20 in the compartment space 50 so that the water flows in the direction of the one side surface 20 in the compartment space 50.

The second channel 200 and the third channel 300 are connected to the bottom manhole 120 to which the steel pipe 130 is connected by making a bottom surface of the river 10 in the direction of the other side 20 and the cut- And a bottom surface of the stream 10 and a cutter 30 are formed after another third duct 300 is installed.

Finally, the water jacket 400 is disassembled from the compartment space 50 to complete the construction.

As described above, since a structure embedded in the river transverse pipe can be constructed by partially installing the river 10 and the slant 30 without damaging the flat surface 20, it is possible to perform excavation and restoration on the same day, It is possible to provide an effect of providing a method.

While the present invention has been described in connection with the embankment structure for a transversal pipeline according to an embodiment of the present invention, the concept of the present invention is not limited to the embodiments disclosed herein. Those skilled in the art, who understands the spirit of the present invention, can readily suggest another embodiment by adding, changing, deleting, or adding elements within the scope of the same idea, but this is also within the spirit of the present invention something to do.

10: Stream 20:
30: slit 100: first channel
200: second conduit 300: third conduit

Claims (17)

A pair of first conduits embedded in cables at both sides of a bottom surface of a river,
A pair of second conduits connected respectively to the pair of first conduits and embedded in the bottom of the slit formed between the stream and the slab so that the cables pass through the bottom of the slit,
And a third conduit connected to the pair of the second conduits at both ends thereof so that the cable embedded in the bottom of the stream and passing through the first conduit traverses the bottom of the stream and reaches the other first conduit on the opposite side ,
The first conduit includes an upper manhole buried in a road provided at an upper portion of a slab, a lower manhole buried in a lower portion of the slab, a steel pipe having both ends connected to the upper manhole and the lower manhole, And,
The second channel includes a corrugated pipe having one end connected to the lower manhole and buried in the lower end of the corrugated pipe, and a cover provided on the corrugated pipe for protecting one longitudinal side and side surfaces of the corrugated pipe,
Wherein the third pipe includes a synthetic resin straight pipe having the corrugated pipe connected to both ends thereof and buried in the lower end of the river, and a case coupled to the synthetic resin straight pipe to support and fix the synthetic resin straight pipe,
The case includes an outer member for forming a three-dimensional inner space, and an inner member provided in the inner space formed by the outer member to increase the rigidity of the outer member and divide the inner space,
Wherein the outer member includes a pair of transverse members formed to be long along the longitudinal direction of the synthetic resin straight pipe, a pair of longitudinal members connecting both ends of the pair of transverse members, A pair of frames provided adjacent to each other in the vertical direction and having a connecting member for connecting the pair of the horizontal members to each other; And a pair of reinforcing members for reinforcing the rigidity of the frame by connecting the first and second pillars to each other, a first pillar for integrating the edges of the pair of the frames facing each other, And a pillar member having a pair of the frames integrated with each other,
Wherein the inner member includes a plurality of upper and lower partition members which are provided between the column members facing each other in the width direction of the horizontal member and divide the space between the column members facing each other in the width direction of the horizontal member into upper and lower directions; A plurality of left and right partition members which are coupled with the upper and lower partition members so as to form a vertical direction with respect to the upper and lower partition members and divide the space between the pillars facing each other in the width direction of the cross member in the left and right directions; A plurality of insertion holes formed by the upper and lower partitioning members and the right and left partitioning members and passing through the synthetic resin straight pipe; And a support member which is respectively engaged with the upper surfaces of the plurality of upper and lower partitioning members and which is elongated along the longitudinal direction of the transverse member and supports the synthetic resin straight pipe.
delete The method according to claim 1,
Wherein the lower manhole is formed with a sloped surface on one side facing the upper manhole.
delete The method according to claim 1,
The cover includes a main plate covering one longitudinal surface of the corrugated tube,
A pair of side plates extending from both ends of the main plate to cover side surfaces of the corrugated tube,
And a seating hole formed in a shape surrounded by the main plate and a pair of the side plates and on which the corrugated tube is seated.
6. The method of claim 5,
Wherein the cover includes a cover covering an upper portion of the cover when the main plate is brought into contact with the ground,
Wherein the side plate has a coupling groove into which the cover is fitted.
delete delete delete delete The method according to claim 1,
Wherein the first pillar is provided with a fixing part extending from the first pillar in the direction of the ground to fix the case to the ground.
The method according to claim 1,
And a plurality of liquefying prevention piles provided on an outer surface of the case to prevent leakage of the case.
The method according to claim 1,
The synthetic resin straight pipe includes a body,
An insertion portion formed at one end of the main body,
An insertion portion of another synthetic resin straight pipe adjacent to the other end of the body,
A rubber ring provided on an inner surface of the coupling portion to increase a coupling force of the engaging portion and another adjacent inserting portion of the synthetic resin straight pipe inserted into the coupling portion,
And a plurality of spacers provided at regular intervals on an outer circumferential surface of the main body. delete delete delete delete

Images