KR20120009120A - Link Type Pipe Stopper Head - Google Patents

Abstract

PURPOSE: A link-type pipe stopper head is provided to use a small fitting by minimizing diameter using a mechanical link system when entering or exiting a pipe. CONSTITUTION: A link-type pipe stopper head comprises first and second gear housings(110,210), foldable ribs(310), a blocking membrane(330), and first and second bevel-type gears. When entering or exiting a pipe, a small fitting is used and a boring diameter is minimized since the first and second gear housings are located in a straight line and the foldable ribs and the blocking member are folded. After the foldable rib and the blocking member enter the pipe in a folded state, the first and second gear housing rotate by 90° and the first and second bevel gears engage. While the second bevel-type gear rotates and the foldable rib is unfolded, the blocking membrane tightly closes the inside of the pipe.

Description

Link Type Pipe Stopper Head

The present invention relates to a gas stopper head for blocking a fluid (a comprehensive concept including various liquids such as water, various gases such as gas, steam, heat, etc.) by using a blocking film having a link. It is to seal the inside of the slide tube using an elastic barrier film that is unfolded into a link structure without using a fluid.

If repair and replacement work are needed due to branching of the fluid pipe, other fluid valve failure, or damage to the pipe itself, shut off the supply of gas to the specific section where the work is performed, and supply the fluid to supply the fluid normally to the remaining sections. Blocking certain sections of piping should be preceded.

In this case, the blocking of the fluid pipe used is as follows.

(1) The fittings are welded to both ends of the section where the fluid supply is to be cut off.

(2) A sandwich valve and a hole saw are mounted on the upper part of the fitting, and the hole saw is brought close to the outer wall of the pipe to drill the pipe. As used herein, the hole soo is configured to allow perforation while preventing fluid leakage to the outside.

(3) Remove the hole saw, remove the metal chip generated during the drilling process, and insert the airbag into the pipe through the drilled hole.

(4) As shown in Fig. 1, the air bag is filled with air to inflate the air bag, and the inside of the pipe is sealed by the inflated air bag and the fluid flowing inside the pipe is blocked.

In the case of the conventional gas blocking method as described above, in order to block the gas, air is injected into the air bag inserted into the pipe to expand the gas. There is a possibility of spillage, so there is always a risk that can lead to a catastrophic disaster.

In addition, the inconvenience that the need for a separate compressor to fill the air inside the air bag is accompanied.

In addition, when the pressure inside the pipe is higher than the medium pressure, the pipe with the same diameter as the pipe is installed in the pipe to perform the drilling and gas blocking work, which takes a long time and greatly reduces the pipe integrity due to the fitting remaining after the work is completed. There is also.

Technical problem of the present invention created to solve the above problems is as follows.

First, it is an object of the present invention to provide a pipe stopper head of a new method that can fundamentally solve the problem of the bursting phenomenon occurs when using the conventional air-filled air tube.

Secondly, another object of the present invention is to use a pipe stopper head to which a mechanical link system is applied, thereby minimizing the diameter of the slide in and out, so that fitting of a smaller size can be used.

Third, another object of the present invention is to provide a pipe stopper head of a new type that does not require a separate compressor and can perform a fluid blocking operation simply.

Technical composition of the present invention created to achieve the above object is as follows.

The present invention first gear housing (110); A shaft connecting member 120 rotatably coupled to the first gear housing 110 and having a shaft connecting groove 121 connected to the rotary shaft 22 at an upper end thereof; A first bevel gear 130 coupled to the lower end of the shaft connecting member 120 and installed inside the first gear housing 110; A second gear housing 210 rotatably coupled with the first gear housing 110; A holding rod 220 coupled to the second gear housing 210 so as to be slidably and provided with a thread 11 along one outer circumferential surface thereof; Mounted inside the second gear housing 210 is fastened to the screw thread 11 provided on one side outer circumferential surface of the holding rod 220, the second gear housing 210 is rotated to the first gear housing 110 A second bevel gear 230 which rotates in engagement with the first bevel gear 130 when the angle is 90 degrees with the first bevel gear 130; A first link housing 240 coupled to the other end of the holding rod 220; A second link housing 250 coupled to the second gear housing 210 and slidably passing through the support rod 220; One end portion is radially coupled to the first link housing 240, the plurality of spreading teeth 310 is rotated; A plurality of supporters 320 rotatably coupled to one end of the second link housing 250 to be radially coupled to the other end, and rotatably coupled to the other end of the spreader 310; And a blocking film 330 coupled to the spreading rod 310 and covering the entire spreading rod 310 while being unfolded in a circle in association with the spreading rod 310 when radially spreading. The holding rod 220 is moved through the second gear housing 210 and the second link housing 250 in accordance with the rotation of the second bevel-type gear 230 and the first The distance between the first link housing 240 and the second link housing 250 is changed and the blocking film 330 is expanded or folded by the operation of the pedestal 320 and the unfolded 310. .

Technical effects of the configuration of the present invention are as follows.

First, it is possible to fundamentally solve the problem of the burst phenomenon that occurs when using the conventional air-filled air tube (gas bag).

In other words, by sealing the inside of the slide tube using a mechanical link system and a barrier without using the air tube, it is possible to fundamentally solve the phenomenon of the air tube being broken by the welding spark or the debris generated during the grinding operation, which was a conventional problem.

Second, by using a pipe stopper head to which a mechanical link system is applied, it is possible to use a smaller size fitting by minimizing the diameter of the slide in and out.

In other words, the first gear housing (110) and the second gear housing (210) are straight in a straight line when the entrance and exit of the glide, and the spreading rods 310 and the barrier film 330 are folded to enable a small size fitting. The drilling diameter can be minimized.

Third, a separate compressor is not required and the fluid blocking operation can be easily performed.

In other words, since the air tube is not provided, the filling air is unnecessary, and the first gear housing 110 and the second gear housing 210 enter the inside of the bow tube in a state where the folds 310 and the blocking membrane 330 are folded. When rotated to achieve this 90 degrees, the first bevel-type gear 130 and the second bevel-type gear 230 meshes with each other, and the second bevel-type gear 230 rotates under the linkage of the rotating shaft to spread out teeth 310. This unfolding, the blocking film 330 is to seal the inside of the tube, it is possible to perform a simple and safe fluid blocking operation.

1 shows a gas shutoff apparatus using a conventional air tube (gas bag).
2 is a cross-sectional structure of a specific embodiment of the present invention shows a state in which the first gear housing 110 and the second gear housing 210 are in a straight line and positioned above the sandwich valve.
3 illustrates a state in which the first gear housing 110 and the second gear housing 210 enter the inside of the slide tube through the sandwich valve.
4 is a second bevel gear 230 engaged with the first bevel gear 130 after the first gear housing 110 and the second gear housing 210 are 90 degrees as a cross-sectional structure of a specific embodiment of the present invention. The rotation of the holding rod 220 is moved, and the blocking film 330 is opened by the link action of the spreading rod 310 and the base plate 320 to seal the fluid inside the bow tube.
5 is an enlarged view of the link pipe stopper head of the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The first gear housing 110 is coupled to the lower end of the shaft tube 33 through which the rotary shaft 22 passes and accommodates the shaft connecting member 120 and the first bevel type gear 130 therein.

The shaft connecting member 120 is rotatably coupled to an upper portion of the first gear housing 110, and a shaft connecting groove 121 connected to the rotating shaft 22 is provided at an upper end thereof so that the rotating shaft and the shaft connecting member ( When the rotating shaft 22 is rotated in a state in which the 120 is coupled, the shaft connecting member 120 rotates in conjunction with each other.

The shaft connecting groove 121 may simply be a groove portion of a polygonal shape (in this case, the lower end of the rotating shaft may have a polygonal end portion of a corresponding shape), or a female screw may be provided (in this case, The lower end of the rotating shaft shall be provided with a male end of the corresponding type.).

The first bevel gear 130 is coupled to the lower end of the shaft connecting member 120 is rotated integrally with the shaft connecting member 120.

The second gear housing 210 is rotatably coupled to the first gear housing 110 in the up and down direction, and a second bevel type gear 230 is mounted therein. That is, the second gear housing 210 may form a straight line with the first gear housing 110 as shown in FIG. 2 or 3, or may form a right angle with the first gear housing 110 as shown in FIG. 4. When the first gear housing 110 and the second gear housing 210 are in a straight line, the first bevel-type gear 130 and the second bevel-type gear 230 do not mesh with each other, so power transmission is not performed. When the second gear housing 210 rotates upward so that the housing 110 and the second gear housing 210 are at a right angle, the first bevel gear 130 and the second bevel gear 230 mesh with each other to transmit power. Is done.

The holding rod 220 is slidably coupled through the second gear housing 210. A thread 11 is provided along one outer circumferential surface and a first link housing 240 and a blocking film 330 are installed at the other end. do.

The second bevel gear 230, which is rotatably coupled to the inside of the second gear housing 210, has a hollow penetrating the center thereof, and a female screw is provided in the hollow to be provided at one side of the holding rod 220. To the screw thread 11. Therefore, when the second gear housing 210 rotates to form an angle of 90 degrees with the first gear housing 110 and meshes with the first bevel gear 130, the second bevel gear 230 rotates. The holding rod 220 screwed with the gear 230 is moved to the left or right in the drawing.

The first link housing 240 has a cylindrical shape as a whole and is fixedly coupled to the other end of the holding rod 220.

The second link housing 250 is coupled to the second gear housing 210, and a hollow is formed in the center of the second link housing 250 to allow the holding rod 220 to slide slidably.

One end portion of each of the applicators 310 is radially coupled to the first link housing 240 and rotates to form a structure similar to a parasol or an umbrella.

One end of each pedestal 320 is pivotally coupled to the second link housing 250 and the other end is rotatably coupled to each of the applicators 310.

The blocking film 330 is coupled to the spreading rod 310, and when the spreading rod 310 is radially unfolded, the blocking layer 330 expands in a circular shape to cover the entire area occupied by the spreading rod 310.

The barrier layer 330 is elastic and does not allow air or water to pass through, and may be made of a material having an appropriate thickness that is strong and is not limited to a specific material. In a specific embodiment of the present invention, a rubber material such as silicone or urethane is used, but other materials may be used.

When the holding rod 220 moves through the second gear housing 210 and the second link housing 250 in accordance with the rotation of the second bevel gear 230 (eg, clockwise rotation), it moves to the left in the drawing. The distance between the first link housing 240 and the second link housing 250 is approaching, and the blocking film 330 is unfolded by the operation of the pedestal 320 and the unfolding 310, and the second bevel type gear 230 When the holding rod 220 is moved to the right side in the drawing due to the rotation (for example, counterclockwise rotation), the distance between the first link housing 240 and the second link housing 250 is increased and the support plate 320 is rotated. And the blocking film 330 is folded by the operation of the extension rod 310.

The blocking film 330 may be coupled to the spreading plate 310 in various ways. FIG. 5 illustrates a structure using a plurality of clasps 340 and wires 350 as one embodiment.

That is, the clasp 340 is coupled along the edge of the blocking film 330, and one end is coupled to the clasp 340, and the other end passes through the second link housing 250 to be coupled to the first link housing 240. The wire 350 is used together to pull the unfolded blocking film 330 taut.

In addition, the blocking film 330 may be a structure in which the hollow is formed in the center as shown in Figure 5 through which the other end of the holding rod 220 protrudes, in which case the blocking film fixing cap 223 to maintain airtightness ) Is coupled to the other end of the holding rod (220). That is, the blocking film fixing cap 223 is tightly coupled to the first link housing 240 so that the airtightness is maintained between the first link housing 240 and the blocking film 330.

The other end of the holding rod 220 protruding through the center of the blocking film 330 is provided with a concave ball receiving portion 221 as shown in Figure 5, the ball receiving portion 221 is accommodated in the ball 222 The ball 222 is accommodated so that a part of the ball receiving portion 221 is exposed to rotate freely. Therefore, when the first gear housing 110 and the second gear housing 210 descend in a straight line and flow into the inside of the bow tube, the ball 222 at the other end of the holding rod 220 is easily in contact with the inside of the bow tube. As it slides, it induces upward rotation of the second gear housing 210.

The spring member 122 is inserted into the shaft connecting member 120 to elastically support the shaft connecting member 120, and the shaft connecting member 120 moves up and down within a predetermined range in a state of being elastically supported by the spring member 122. This is possible. As the upper and lower clearances are present in the shaft connecting member 120, the second gear housing 210 rotates upward to form a right angle with the first gear housing 110 and the first bevel gear 130 and the second bevel type. The process of engaging the gear 230 may be made more smoothly.

As described above, embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the scope of protection of the present invention is not necessarily limited to these embodiments, and various design changes and notifications are made within the scope of not changing the technical gist of the present invention. In the case of addition or deletion of technology, and simple numerical limitations, it is obvious that the scope of the present invention is included.

11: Screw thread
22: rotating shaft
33: shaft tube
110: first gear housing
120: shaft connecting member 121: shaft connecting groove 122: spring member
130: first bevel gear
210: second gear housing
220: holding rod
221: ball receiving portion 222: ball 223: blocking film fixing cap
230: Second Bevel Gear
240: the first link housing
250: second link housing
310: Spread
320: stand
330: blocking film
340: clasp
350: wire

Claims (6)

A first gear housing 110 mounted to the lower end of the shaft tube 33 through which the rotary shaft 22 passes;
A shaft connecting member 120 rotatably coupled to the first gear housing 110 and having a shaft connecting groove 121 connected to the rotary shaft 22 at an upper end thereof;
A first bevel gear 130 coupled to the lower end of the shaft connecting member 120 and installed inside the first gear housing 110;
A second gear housing (210) rotatably coupled to the first gear housing (110) in a vertical direction;
A holding rod 220 coupled to the second gear housing 210 so as to be slidably and provided with a thread 11 along one outer circumferential surface thereof;
It is rotatably mounted in the second gear housing 210 is fastened to the thread 11 provided on one side outer circumferential surface of the holding rod 220, the second gear housing 210 is rotated to the first gear housing A second bevel gear 230 which rotates in engagement with the first bevel gear 130 when it is at an angle of 90 with 110;
A first link housing 240 coupled to the other end of the holding rod 220;
A second link housing 250 coupled to the second gear housing 210 and slidably passing through the support rod 220;
One end portion is radially coupled to the first link housing 240, the plurality of spreading teeth 310 is rotated;
A plurality of supporters 320 rotatably coupled to one end of the second link housing 250 to be radially coupled to the other end, and rotatably coupled to the other end of the spreader 310; And,
A blocking film 330 coupled to the spreading rod 310 and covering the entire spreading rod 310 while being unfolded in a circle in connection with the spreading rod 310 in a radial manner;
It is configured to include,
As the second bevel gear 230 rotates, the support rod 220 moves through the second gear housing 210 and the second link housing 250 and the first link housing 240. And a distance between the second link housing and the second link housing 250 is changed, and the blocking film 330 is expanded or folded by the operation of the pedestal 320 and the unfolded meat 310. In claim 1,
A ball receiving portion 221 provided at the other end of the holding rod 220 protruding through the center of the blocking film 330; And,
A ball 222 that is accommodated so as to be partially exposed to the ball receiving part 221 and rotates freely;
Linked pipe stopper head further comprising. In claim 1,
A spring member 122 inserted into the shaft connecting member 120 to elastically support the shaft connecting member 120;
Linked pipe stopper head further comprises. In claim 1,
A plurality of clasps 340 coupled along an edge of the blocking film 330; And,
One end is coupled to the clasp 340, the other end is passed through the second link housing 250, the wire 350 is coupled to the first link housing 240;
Linked pipe stopper head further comprises. In claim 2,
Blocking membrane fixing cap 223 is coupled to the other end of the holding rod 220 protruding through the center of the blocking film 330 to close the blocking film 330 to the first link housing 240 to keep the airtight );
Linked pipe stopper head characterized in that it further comprises. The method according to any one of claims 1 to 5,
The blocking film 330 is a link pipe stopper head, characterized in that the elastic rubber material.

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