KR100728766B1 - The fluid-crossing gate for pipeline - Google Patents

Abstract

A fluid-crossing gate for a pipeline is provided to install a rotation shaft of a joint unit to be spaced apart from a central axis of the fluid-crossing gate so that the joint unit is easily bent and the fluid-crossing gate is easily placed in the pipeline. A fluid-crossing gate for a pipeline includes an intercepting unit(70) connected to a valve body(110) of a pipeline(100) for intercepting fluid in the pipeline, a driving unit(10) installed in the upper side of a cylindrical body(90) of the fluid-crossing gate having a joint unit(60) for placing the intercepting unit in the pipeline, an actuating shaft(40) for receiving a driving force from the driving unit to move up and down, the joint unit disposed in the lower side of the actuating shaft, and the intercepting unit installed in the lower side of the joint unit for intercepting the fluid in the pipeline by an actuating fluid supplied to an actuating fluid supplying pipe(50). The actuating shaft has a female thread formed inside thereof and the female thread is engaged with a male thread formed around a rotation shaft(30) for receiving the driving force from a power transmission(20) for transmitting the driving force of the driving unit.

Description

The fluid-crossing gate for pipeline

1 is an installation state of the fluid circuit breaker for the pipe according to the embodiment of the present invention.

2 is a cross-sectional view of a fluidic circuit breaker for an embodiment of the present invention.

Figure 3 is a detailed view of the blocking device of the fluid circuit breaker for the pipe according to the embodiment of the present invention.

4 is a side cross-sectional view of FIG. 3

Figure 5 is a detailed view of the joint portion of the fluidic circuit breaker for piping according to an embodiment of the present invention.

Figure 6 is a detailed view of the head body of the fluid circuit breaker for piping according to an embodiment of the present invention.

Figure 7 is a detailed view of the head cover of the fluid circuit breaker for piping according to an embodiment of the present invention.

8 is a detailed view of the lever of the fluid circuit breaker for the pipe according to the embodiment of the present invention.

9 is a detailed view of the wing of the fluid circuit breaker for piping according to the embodiment of the present invention.

10 is a detailed view of the wing and the pad of the fluid circuit breaker for the pipe according to the embodiment of the present invention.

Figure 11a is a state diagram of the fluid circuit breaker operating in accordance with an embodiment of the present invention.

Figure 11b is a state diagram of the fluid circuit breaker operating in accordance with an embodiment of the present invention.

Figure 11c is a state of operation of the fluid circuit breaker for piping according to an embodiment of the present invention.

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

10: power unit 20: power transmission unit

30: rotating shaft 40: operating shaft

50: working fluid supply pipe 60: joint

70: blocking device 71: cylinder body

72: cylinder axis 73: cam

74: head body 75: lever

76: head cover 77: wings

78: pad 80: roller

100: pipe 110: valve body

According to the present invention, when relocating or repairing a pipe through which a fluid such as water flows, when a flow of fluid is required such as installing a valve and a branch pipe, a hole is drilled at a desired pipe position, and through the pipe through the hole. It relates to a fluid circuit breaker for piping to block the flowing fluid.

The pipe fluid circuit breaker is mainly used for maintenance, reinforcement, replacement, and relocation of the fluid pipe for maintenance, and at a certain point of the existing fluid pipe, instead of blocking the fluid by the valve at the desired position on the bar pipe. It is a method that can block the flow of fluid, minimize the blocking section and time, and reduce the damage of other users. In other words, when there are many existing accommodations such as city gas pipes or water supply pipes, when the pipes are moved for new accommodations or when the fluid is blocked for maintenance, such as maintenance of the drainage pipes, many existing accommodations may be inconvenient. Therefore, the pipe can be moved, repaired, and reinforced while continuously supplying fluid, thereby minimizing damage to the receiving place.

The prior art of the fluidic circuit breaker proposed for this purpose is shown in US Patent 4,458,721.

The prior art is mainly applied to a small pipe such as a city gas pipe, and is formed to supply air to an expansion part installed at the front end to block the fluid with the expanded tube, and the expansion part is jointed by the length of the expansion part. It includes a cylinder so as to include or stretchable, the spring is installed to solve the inconvenience of rotation of the joint is installed on the outside of the expansion portion, when inserting the expansion portion in the pipe smoothly inserted by the length of the expansion portion. The disadvantage of not being able to, and the high pressure of the fluid in the pipe, the air pressure supplied to the expansion portion is increased, the fastening of the expansion tube can be dismantled, there is a disadvantage that the expanded tube is damaged by the scale in the pipe.

In order to solve the above disadvantages, the present invention has been devised, the present invention can be easily installed in the pipe by installing the power unit, and the roller is installed at the end of the blocker to easily bend the joint In addition, the rotation axis of the joint is not installed on the central axis line, so that it is spaced apart to facilitate the bending of the joint, so that the blocking device can be easily inserted into the pipe, and the end of the deployed wing is closely adhered to the inside of the pipe. The purpose is to block the flow of fluid.

In order to achieve the above object, the fluid blocker for a pipe of the present invention is speeched to the valve body 110 of the pipe 100 to block the fluid in the pipe 10, and the blocker 70 is connected to the pipe. In the fluid blocker for the pipe formed with the joint portion 60 to be placed in (100),

A power unit 10 installed above the cylindrical body 90;

An operating shaft 40 configured to move up and down by receiving power from the power unit 10;

A joint part 60 formed below the operating shaft 40;

It is configured to include a blocking device 70 installed below the joint part 60 to block the fluid in the pipe 100 by the working fluid supplied to the working fluid supply pipe 50.

A female screw portion 41 is formed inside the operating shaft 40, and the female screw portion 41 rotates by receiving power from a power transmission device 20 that transmits power of the power plant 10. Speech with the male thread part 31 formed in ().

The rotation axis 62 of the joint portion 60 is formed to be spaced apart from the line along the central axis (C).

The roller 80 may be further installed below the blocking device 70.

The roller 80 is formed of the first roller 81 and the second roller 82, so that the first roller 81 installed in the rotational direction of the joint portion 60 protrudes more than the second roller 82. Is installed.

The blocking device 70 includes a cylinder portion consisting of a cylinder body 71 and a cylinder shaft 72 operated by a working fluid supplied to the working fluid supply pipe 50;

A head body 74 having a plurality of grooves 74a formed at equal intervals in the circumferential direction provided in the cylinder body 71 of the cylinder part; A cam (73) formed in the cylinder shaft (72) inside the head body (74) and having a groove (73a) formed on a circumferential surface moving up and down; A plurality of levers 75 installed on one side of the groove 73a of the cam 73 and the other side of the cam body 73 to rotate in the groove 74a of the head body 74; An actuating part including a head cover 76 that fixes the lever 75 to the head body 74;

A plurality of wings 77 are installed on the lever 75 so that the lever 75 is extended or contracted radially by the movement of the lever 75 which is operated by the movement of the cylinder shaft 72 of the operating portion, and at the end of the wing 77 The inclined surface 77a is formed to be in close contact with the inner circumferential surface of the 100, and the side inclined surface 77b is formed at the side so that the plurality of wings 77 may be in close contact with each other, so that the plurality of wings 77 may have fluid. It is formed of a blocking portion made to block.

The blocking device 70 moves the cylinder shaft 72 in which the cam 73 is installed to the working fluid supplied to the working fluid supply pipe 50, and moves the cam shaft 72 by the movement of the cylinder shaft 72. And a lever 75 installed between the head body 74 is operated, and the wing 77 installed on the lever 75 is unfolded in a radial manner by the operation of the lever 75, and the wing 77 Unfolding will block the fluid.

The blocking portion may be further provided with a pad 78 on the plurality of wings 77 in order to increase the blocking efficiency of the fluid.

Two working fluid tubes formed to supply the working fluid to the cylinder part are formed in the cylinder body 71 so as not to protrude outward.

The shaft 77 'formed on the blade 77 is rotatably installed in the hole 75a formed in the lever 75 of the operating unit.

Hereinafter, with reference to the drawings showing an embodiment of the present invention will be described in detail.

1 and 2, the body 90 of the present invention has a cylindrical upper portion 91 and a cylindrical lower portion of the cylindrical portion formed with a fastening portion in the valve body 110 of the pipe 100 in a flange connection method on the lower side. Body 92.

The upper portion of the cylindrical upper body 91 is provided with a power unit 10 for generating power, and a power transmission device 20 for transferring the power generated from the power unit 10 is installed.

The power unit 10 usually uses an electric motor, and the power transmission unit 20 uses a power transmission member such as a bevel gear that can change the power direction as shown in the accompanying drawings.

The power transmission device 20 may be removed by installing the shaft of the electric motor, which is the power device 10, to coincide with the central axis C.

The power transmission device 20 has a rotating shaft 30 installed so as to be rotatable inwardly of the upper body 91, the rotating shaft 30 is rotated by the rotation shaft 30 in the upper and lower sides of the upper body 91. The working shaft 40 moving to is spoken.

A male screw portion 31 is formed on the rotating shaft 30, and a female screw portion 41 is formed on the working shaft 40, so that the male screw portion 31 of the rotating shaft 30 and the female screw portion of the working shaft 40 are formed. Rotation of the rotary shaft 30 using the 41 allows the operating shaft 40 to be movable.

The lower housing inside the upper body 91 is provided with a guide housing 42 for guiding the operating shaft 40 in order to reduce the flow, such as the simultaneous shaking of the operating shaft 40.

The lower body 92 connected to the upper body 91 is provided with a connecting shaft 45 which is spoken with the operating shaft 40 and moves up and down within the lower body 92, and below the connecting shaft 45. Joint portion 60 is formed.

The connecting shaft 45 installed below the operating shaft 40 is usually formed integrally with the operating shaft 40, and the connecting shaft 45 has an end portion having an outer diameter similar to the inner diameter of the lower body 92. It is also possible to prevent the shaking of the operating shaft 40 by forming 46.

The joint part 60 is formed of an upper concave-convex portion 60a having a curved portion 61 formed on one side thereof, and a lower concave-convex portion 60b that is coupled to the upper concave-convex portion 60a to rotate in one direction. The rotating shaft 62 of the part 60a and the lower uneven part 60b is formed so that it may be spaced apart from the linear line of the central axis C. As shown in FIG.

Since the rotation shaft 62 is spaced apart from the central axis C, the blocking device 70 to be described later may smoothly bend the joint part 60 by its own weight.

The connecting shaft 45 and the joint part 60 are provided with a supply hole for supplying a working fluid supplied to the working fluid supply pipe 50 to a cylinder to be described later, as shown in FIGS. 4 and 5. The supply hole formed in the 60 is formed so that the working fluid can be supplied when the articulation part 60 operates so that the blocking device 70 to be described later is placed in the pipe 100.

In more detail, the supply hole is formed in the upper uneven portion 60a and the lower uneven portion 60b of the joint portion 60 and the supply hole formed in the upper uneven portion 60a and the lower uneven portion 60b is rotated on the shaft. In order to communicate with the supply hole formed in the 62, the inlet and outlet of the supply hole formed in the rotating shaft 62, when the blocking device 70 is placed in the pipe 100, the upper uneven portion 60a and the lower uneven portion 60b What is necessary is just to form the supply hole formed in the (circle) and to communicate with the supply hole formed in the rotating shaft 62. Usually it is possible to form an inlet and an outlet about 90 degrees apart.

The blocking device 70 is spoken to the lower uneven portion 60b of the joint part 60, and the blocking device 70 includes a cylinder body 71, a cylinder shaft 72 provided with the cylinder body 71, and The head body 74 formed at the end of the cylinder body 71 is formed, the grooves 74a are formed at equal intervals in the circumferential direction of the head body 74, the grooves of the head body 74 ( The lever 75 is radially installed between the 74a and the cam 73 formed at the end of the cylinder shaft 72, and is formed in the lever 75 in the coupling groove 74b formed in the groove 74a. The shaft 75a is placed so that the lever 75 is rotated about the shaft 75b, and the shaft 77a of the blade 77 is formed in the hole 75a formed in the lever 75. It is inserted so that the wings 77 are expanded or contracted by the operation of the lever 75.

The wing 77 installed in the hole 75a formed in the lever 75 is rotatably installed about the axis 77 ', which is the wing 77 when the wing 77 is extended or retracted. This is to prevent them from interfering with each other.

An inclined surface 77a is formed on the wing 77 to be in close contact with the inner circumferential surface of the pipe 100, and a side slope surface 77b is formed to be in close contact with each other in the unfolded state. When the wing 77 is deployed by the inclined surface 77a and the side inclined surface 77b, the wing 77 blocks the fluid. That is, it is in close contact with the inner surface of the pipe 100 by the inclined surface 77a formed on the blade 77, so that the wings 77 are in close contact with each other when the wing 77 is deployed by the side inclined surface 77b.

The lever 75 placed in the groove 74a of the head body 74 is installed to be rotatable by the head cover 76.

The head cover 76 also has a groove 76a formed to correspond to the groove 74a of the head body 74.

The head body 74 and the head cover 76 can be seen with reference to FIGS. 6 and 7.

The blade 77 may be installed so that the disk pad 78 in the form of a disk can be expanded or contracted by the operation of the blade 77 in order to completely block the fluid. That is, the disc-shaped pad 78 is inserted into the groove 76b of the head cover 76 formed as shown in FIG. 7 and installed as shown in FIG. 3, so that the blade 77 can move together according to the wing 77. The fastening member is fixed as shown in FIG. 10 to operate as shown in FIG. 11C.

The pad 78 is made of a material having a predetermined elastic material, and is usually made of rubber or synthetic resin.

The blocking device 70 configured as described above is a working fluid inlet formed in the cylinder body 71 through a supply hole formed in the working fluid supply pipe 50 consisting of two pipes, the connecting shaft 45, and the joint part 60. The working fluid supplied through the 71a and 71b is operated by moving the cylinder shaft 72, and the working fluid inlet 71a is located above the cylinder body 71, which is a portion projected from the lower uneven portion 60b. It is formed, the working fluid injection port 71b is formed in the lower side of the cylinder body 71 through a hole formed in the side portion of the cylinder body 71.

The blocking device 70 configured as described above moves the cylinder shaft 72 in which the cam 73 is installed to the working fluid supplied to the working fluid supply pipe 50, and moves the cam by the movement of the cylinder shaft 72. The lever 75 provided between the 73 and the head body 74 is operated, and the wing 77 installed on the lever 75 is unfolded in a radial manner by the operation of the lever 75 to release the fluid. Will be blocked. When the pad 78 is installed on the wing 77, the pad 78 is unfolded by the spreading wing 77 and is supported by the wing 77 to block the fluid.

The head cover 76 is provided with a roller 80 so as to protrude more than the wing 77.

The roller 80 is composed of a second roller 82 in the opposite direction to the first roller 81 installed in the rotational direction of the joint portion 60, the first roller 81 is more than the second roller 82 It is installed to protrude further.

That is, the first roller 81 is installed below the second roller 82 to allow the first roller 81 to contact the inner surface of the pipe 100 before the second roller 82.

This is to allow the joint portion 60 to be easily bent by the roller 80.

Referring to Figure 11 attached to the operating state of the present invention configured as described above,

As shown in FIG. 11A, the operating shaft 40 moves downward by the power of the power unit 10, and the blocking device 70 is inserted through a hole formed in the pipe 10, and operated in the state as illustrated in FIG. 11A. When the shaft 40 is further moved downward, the joint unit 60 is bent as shown in FIG. 11B, and the blocking device 70 is placed inside the pipe 100, and the blocking device 70 is connected to the pipe 100 as shown in FIG. 11B. The shutoff device 70 is installed to block the fluid as shown in FIG. 11C by supplying the working fluid to the working fluid supply pipe 50 in the state of being placed therein, and moving the cylinder shaft 72 forward to spread the wings 77. .

According to the present invention configured as described above, when the rotation axis of the joint part is installed to be spaced apart from the central axis of the fluid circuit breaker, the joint part is easily rotated by placing the blocking device through a hole formed in the pipe by rotating the joint part by its own weight. A shutoff device can be easily placed in the pipe.

In addition, when the blocking device is inserted into the pipe by a roller installed at the tip of the blocking device, the roller slides and moves in the pipe, thereby placing the blocking device without placing an impact on the inside of the pipe.

In addition, the end portion is in close contact with the inside of the pipe in the radially unfolded state to support the pad to block the high pressure fluid.

Claims (10)

A shutoff device 70 is provided to the valve body 110 of the pipe 100 to block the fluid in the pipe 100, and the joint part 60 is disposed so that the shutoff device 70 can be placed in the pipe 100. In the formed fluidic circuit breaker, A power unit 10 installed above the cylindrical body 90; An operating shaft 40 configured to move up and down by receiving power from the power unit 10; A joint part 60 formed below the operating shaft 40; And a shutoff device (70) formed below the joint part (60) to block a fluid in the pipe (100) by the working fluid supplied to the working fluid supply pipe (50). The method of claim 1, The fluid blocker for piping, characterized in that the roller 80 is further installed to the lower side of the blocking device (70). The method of claim 1, A female screw portion 41 is formed inside the operating shaft 40, and the female screw portion 41 rotates by receiving power from a power transmission device 20 that transmits power of the power plant 10. A fluidic circuit breaker for the pipe, characterized in that the speaker (31) formed in the speech. The method of claim 2, The roller 80 is formed of the first roller 81 and the second roller 82, so that the first roller 81 installed in the rotational direction of the joint portion 60 protrudes more than the second roller 82. A fluid circuit breaker for piping, characterized in that it is installed. The method according to claim 1 or 2, The blocking device 70 includes a cylinder portion consisting of a cylinder body 71 and a cylinder shaft 72 operated by a working fluid supplied to the working fluid supply pipe 50; A head body 74 having a plurality of grooves 74a formed at equal intervals in the circumferential direction provided in the cylinder body 71 of the cylinder part; A cam (73) formed in the cylinder shaft (72) inside the head body (74) and having a groove (73a) formed on a circumferential surface moving up and down; A plurality of levers 75 installed on one side of the groove 73a of the cam 73 and the other side of the cam body 73 to rotate in the groove 74a of the head body 74; An actuating part including a head cover 76 that fixes the lever 75 to the head body 74; A plurality of wings 77 are installed in the lever 75 so that the lever 75 is extended or contracted radially by the movement of the lever 75 actuated by the movement of the cylinder shaft 72 of the operating part, and at the end of the wing 77 a pipe The inclined surface 77a is formed to be in close contact with the inner circumferential surface of the 100, and the side inclined surface 77b is formed at the side so that the plurality of wings 77 may be in close contact with each other, so that the plurality of wings 77 may have fluid. A fluid circuit breaker for pipe, characterized in that formed with a blocking portion made to block. The method of claim 5, The blocking device 70 moves the cylinder shaft 72 in which the cam 73 is installed to the working fluid supplied to the working fluid supply pipe 50, and moves the cam shaft 72 by the movement of the cylinder shaft 72. And a lever 75 installed between the head body 74 is operated, and the wing 77 installed on the lever 75 is unfolded in a radial manner by the operation of the lever 75, and the wing 77 The fluid blocker for piping, characterized in that formed to block the fluid by the expansion. The method of claim 5, The blocking unit is characterized in that the pad 78 is further provided with a plurality of blades (77) in order to increase the blocking efficiency of the fluid. The method according to claim 1 or 2, The rotation shaft 62 of the joint portion 60 is formed to be spaced apart from the line on the central axis (C) for the fluid circuit breaker. The method of claim 5, Two working fluid pipes formed to supply the working fluid in the cylinder portion is formed in the cylinder body 71 so as not to protrude outwards. The method of claim 5, And a shaft (77 ') formed in the blade (77) so as to be rotatable in a hole (75a) formed in the lever (75) of the operating portion.

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