KR101975527B1 - Fluid flow blocking apparatus for water pipe - Google Patents

Abstract

The present invention relates to a fluid pipe blocking apparatus, which includes a blocking plate (100) having a packing (110) along an edge portion in a disc shape, wherein the packing (110) has a contact part (112) formed to be inclined in a direction where fluid flows, prevents flow of the fluid while the contact part (112) comes in contact with an pipeline inner wall surface while the blocking plate (100) is inserted into the pipeline to be provided in a direction of being intersected with a longitudinal direction of a pipeline, wherein a pressure device is formed on one surface of the blocking plate (100) so that the pressure device pushes the contact unit (112) to be possible to press the same so as to adhere to the pipeline inner wall.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a fluid pipe cut-off device, and more particularly, to a fluid pipe cut-off device that is capable of firmly cutting off a fluid flow in a continuous end water process.

Pipes are used to supply fluids such as water, which are generally embedded in the ground. Such a pipeline is a situation in which a branch is to be installed in the existing pipeline or a part of the existing pipeline is to be removed in the case where a place to supply fluid to the existing building is added or a new demand site is required such as a building or a factory Lt; / RTI >

In the above case, a construction method is proposed in which a pipe having a large diameter is punctured and a shield plate is inserted into a perforated hole to cut off the duct, and then a bypass pipe is installed to install a branch pipe without splitting . It is a so-called endless hydraulic method.

Meanwhile, the above-mentioned blocking plate is formed in a structure in which the edges are folded and unfolded, and is inserted into the pipe in a folded state, and is then unfolded to block the pipe. Here, a pipe embedded in the ground is deformed into an elliptical shape having a longer left and right diameter while being pushed up and down by the earth pressure, or a shape of a pipeline is deformed when the upper and lower diameters are deformed into an elliptical shape . However, since the conventional blocking plate is formed as a garden when it is completely opened, it does not correspond to the shape of the deformed pipe, and a minute gap is generated, resulting in a problem that the fluid can be ejected into the gap.

(Document 1) Korean Patent Registration No. 10-0797443 (September 6, 2010)

It is an object of the present invention to provide a fluid pipe cut-off device that can reliably block pipelines deformed by external factors such as earth pressure, thereby reliably improving workability in the construction of the end-tapped water treatment method.

In the present invention, a packing is formed along an edge in a disk shape, and the packing includes a blocking plate having a contact portion inclined in a direction in which fluid flows, And a pressure device is formed on one surface of the blocking plate so that the pressure device can press the contact portion to be in close contact with the inner wall of the pipe to block the flow of the fluid, Device.

According to the present invention, since the packing in contact with the inner wall surface of the conduit can be strongly pressed, the fluid can be reliably blocked. In particular, if a pressing device is formed at a desired point so as to correspond to a deformed point in the pipe, it is possible to effectively block the deformed pipe, so that the fluid can be safely prevented while preventing the fluid from leaking You can help.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a perspective view of a fluid pipe cut-off device according to the present invention, Fig.
3 is an exemplary view showing another side of the fluid pipe cut-off device according to the present invention,
4 is an exemplary view showing the operation of the pressing device according to the present invention,
FIGS. 5 and 6 are views showing a process of putting a fluid pipe cut-off device according to the present invention into a pipe.

The present invention relates to a fluid pipe cut-off device which can reliably block pipelines deformed by external factors such as earth pressure,

Wherein the packing comprises a shield plate having a disc shape and having a contact portion formed at an edge thereof in a direction in which the fluid flows, the shield plate being disposed in a direction intersecting the longitudinal direction of the channel, And a pressing device is formed on one surface of the blocking plate so that the pressing device can press the contact portion to be in close contact with the inner wall of the pipe while blocking the flow of the fluid while the contact portion contacts the inner wall surface of the pipe. do.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a fluid pipe cut-off device according to the present invention; FIG.

As shown in the drawings, the fluid pipe cut-off device according to the present invention includes a shield plate 100 as a whole. The packing 110 is formed at the periphery of the blocking plate 100. The packing 110 is provided with a contact portion 112 which is inclined at a predetermined angle in the flow direction of the fluid. When the blocking plate 100 is inserted into the conduit and disposed in a direction intersecting with the longitudinal direction of the conduit, the contact portion 112 contacts the inner wall surface of the conduit to shut off the conduit, thereby blocking the flow of the fluid.

Here, a pressing device is formed on one surface of the blocking plate 100 (the surface on which the fluid flows, hereinafter the same). The pressing device functions to push the contact portion 112 to be closely attached to the inner wall of the pipe. Such a pressing device can be formed so as to push the contact portion 112 corresponding to a point where deformation occurs in the pipe. When the left and right diameters are deformed longer than the upper and lower diameters due to the earth pressure So that it is formed to push the contact portion 112 from the left and right sides of the blocking plate 100 and push the contact portion 112 toward the left and right inner walls inside the pipe. This makes it possible to prevent the fluid from leaking even if it is a deformed pipe.

A plurality of the pressing devices may be formed at positions where it is necessary to press the contact portions 112.

The blocking plate 100 may have a three-divided structure. And includes a base 120 having a predetermined length and a rotary plate 130 rotatably connected to both sides of the base 120. The rotary plate 130 is hingedly coupled to the base 120 so that the rotary plate 130 can be folded or unfolded.

The blocking plate 100 enters the inside of the pipe through a hole formed in the pipe. When the blocking plate 100 is formed in a three-division manner as described above, the blocking plate 100 is introduced into the pipe in a folded state The pipe can be blocked by opening it again. The configuration in which the rotary plate 130 is folded and unfolded can be performed by a stretchable bar 180 whose one end is fixed to the rotary plate 130 and the other end is fixed to another point. Or the expansion and contraction bar 180 may be stretched or shrunk by hydraulic pressure, air pressure, or the like.

In the above structure, the base 120 is formed in a substantially rectangular shape and the upper and lower ends are formed into a convex arcuate shape. When the rotary plate 130 is coupled to both sides of the base 120, the rotary plate 130 has a circular plate shape. In this configuration, the pressing device may be formed on the rotary plate 130.

The pressing device includes a pressing bar 140 formed in a arc of a predetermined length. And the pressing pad 140 is formed in an arc shape corresponding to the curvature of the contact portion 112. [ The pressing bar 140 selectively pushes the contact portion 112 while moving back and forth. And pushes the contact portion 112 forward. When the backward movement is performed, the pushing force is removed and the contact portion 112 returns to the original position.

When a plurality of pressing devices are formed as described above, the pressing bars 140 having a predetermined length may be formed adjacent to each other. It is formed at a close position as follows. This configuration is configured to press the compression pedestal 140 finely according to the deformation state of the channel. When any one of the compression pedestals 140 or the plurality of compression pedestals 140 is selectively operated, It is possible to press the pressing member 140 of the pressing member.

 The pressing device includes a rack 142 extending from the center of the blocking plate 100 to the pushing plate 140 and a pinion 143 engaged with the rack 142, . The rack 142 is formed to engage with the pinion 143 so that when the rack 142 is moved forward and backward by the rotation of the pinion 143, the pushing bar 140 is moved forward and backward.

The rack 142 and the pinion 143 can be installed in the receiving space formed in the shape of the rack 142 and the pinion 143 on one side of the shield plate 100 so that the rack 142 and the pinion 143 are not projected to the outside, It is possible to operate stably.

FIG. 3 is an exemplary view showing another side of the fluid pipe cut-off device according to the present invention, and FIG. 4 is an exemplary view showing the operation of the pressing device according to the present invention.

As described above, the pinion 143 is installed on the rotating shaft 144 and rotates to operate the rack 142. At this time, the rotating shaft 144 is rotated in the opposite direction to the other surface of the blocking plate 100 as shown in FIG. So that it penetrates through the blocking plate 100. The rotation shaft 144 thus formed is separately provided and can be rotated by the handle 160 that is detachably attached to the rotation shaft 144. The pressing rod 140 can be moved forward or backward by rotating the rotary shaft 144 from the other surface of the blocking plate 100 to the handle 160 to move the rack 142 forward or backward.

A ratchet 146 is installed on the rotating shaft 144. The ratchet 146 is configured to limit rotation in one direction by a pawl 147 as is well known in the art, such that the rack 142 is rotated in one direction (e.g., clockwise) The rotation shaft 144 can not be rotated in the other direction in a state in which the pushing bar 140 pushes the contact portion 112. Therefore, the pressing pad 140 can maintain the state of pushing the contact portion 112 as it is.

On the other hand, when the pushing piece 140 pushing the contact portion 112 is to be returned to the original position, the pawl 147 restraining the ratchet 146 is released, and then the rotary shaft 144 is rotated in the opposite direction do.

FIGS. 5 and 6 are views illustrating a process of injecting a fluid pipe cut-off device according to the present invention into a pipe. The blocking plate 100 is composed of the base 120 and the rotary plate 130 as an example.

The fluid pipe cut-off device according to the present invention punctures the pipe and inserts it into the pipe. In this process, first, a single pipe is connected to the periphery of the pipe at both positions outside the area where the work is performed, that is, the area where the cutting work or the branch pipe connection work is performed. A first valve is provided in each of these end pipes. The first valve is typically a gate valve.

And a perforation device is inserted through the first valve in the direction of the outer circumferential surface of the conduit to puncture the conduit. Then, the punching device is pulled out to switch the first valve to a closed state, and both ends of the bypass pipe are connected to the first valve.

Next, a pair of second valves are provided at the periphery of the pipeline so as to be located at two positions inside the both end sides of the bypass pipe. Then, the perforation device is inserted through the second valve to puncture the perimeter of the pipe at the positions on both side ends of the bypass pipe in the pipe, and through the hole, The device shutoff plate 100 is turned on. Thus, the fluid pipe cut-off device of the present invention is disposed inside the pipe at both positions of the channel area where the work is performed. In this state, the second valve is closed.

Thereafter, a hole is drilled in the channel between the pair of second valves to discharge the fluid. Then, the rotary plate 130 is unfolded due to the pressure difference of the fluid pipe cutoff device blocking plate 100 according to the present invention. As a result, both ends of the working area are blocked inside the pipe. Since the first valve connected to the bypass pipe is opened at this time, the fluid is supplied to the place of use without interrupting the flow through the bypass pipe. Therefore, .

3 and 4, when the handle 160 is connected to the rotary shaft 144 to rotate the rotary shaft 144, the pinion (not shown) 143 are rotated to move the rack 142 forward. As a result, the pushing piece 140 advances and the contact portion 112 of the packing 110 is pushed against the inner wall of the pipe to prevent the fluid from leaking. In particular, since the base 120 is arranged in the vertical direction inside the pipe by puncturing a hole in the upper part of the channel and the blocking plate 100 is inserted, and the pressing device according to the present invention is installed on the rotary plate 130, As described above, when the pressing bar 140 is advanced, the left and right inner walls are strongly pressed by the contact portion 112 in the pipe. Therefore, it is possible to effectively seal the ducts whose deformation is greater than the diameters of the upper and lower directions by the earth pressure.

100: blocking plate, 110: packing,
112: contact portion, 120: base,
130: rotary plate, 140: compression stand,
142: rack, 143: pinion,
144: rotation shaft, 146: ratchet,
147: Paul, 160: Handle,
180: stretching bar.

Claims (5)

A packing (110) is formed along the edges in a disc shape as a whole, and the packing (110) includes a blocking plate (100) having a contact portion (112) formed at an inclination in a direction in which fluid flows,
The blocking plate 100 is inserted into the conduit and arranged in a direction intersecting the longitudinal direction of the conduit so that the contact portion 112 is in contact with the inner wall surface of the conduit,
The pressing plate 140 is moved forward by pushing the contact portion 112 so that the pressure plate 140 is moved forward and backward, Wherein the fluid conduit is adapted to be pressed against the inner wall. The method according to claim 1,
The blocking plate 100 includes a base 120 having a predetermined length and a rotary plate 130 rotatably connected to both sides of the base 120. The base 120 is vertically Disposed to block the flow of fluid,
Wherein the pressing device is formed on the rotary plate (130) so that the abutting portion (112) can press the left and right inner walls of the duct. The method according to claim 1,
Wherein a plurality of the pressing devices are provided so that the pushing bars (140) are connected to each other or separated from each other. The method according to claim 1,
The pressing device includes a rack 142 that is connected to the push rod 140 and is installed outward from the center of the shutoff plate 100 and a pinion 143 that engages with the rack 142. The pinion 143 The rack 142 is moved forward and backward to rotate the pressing bar 140 forward and backward,
A rotating shaft 144 passing through the blocking plate 100 from the other surface of the blocking plate 100 to the pinion 143 and a ratchet 146 mounted on the rotating shaft 144,
The rotating shaft 144 is rotated on the other surface of the blocking plate 100 so that the pinion 143 is operated while the rotation of the rotating shaft 144 is selectively restricted by the ratchet.
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