KR20220035008A - Supporting device for pipe - Google Patents

Abstract

The present invention provides a supporting device for a pipe, which comprises: a housing which has a barrel structure with an internal space; a connecting rod which is connected to the housing to be slidably moved in a vertical direction, which is provided with a sliding plate disposed inside the housing at the upper end, and which has a hanger connection part arranged outside the housing to connect the pipe at the lower end; an elastic member which is inserted and installed inside the housing and which elastically supports the connecting rod; an elastic adjustment part which is installed in the housing to be connected to the sliding plate and which adjusts the movable range of the sliding plate in the vertical direction inside the housing; and a pipe condition check part which is installed to be connected to the housing and which measures the load received from the pipe while supporting the pipe to determine the change or vibration of the pipe.

Description

Supporting device for pipe

The present invention relates to a pipe support device for supporting various pipes installed in ships or offshore structures.

In general, large structures such as ships or offshore structures use pipes for various purposes. In particular, the pipe used for such a large structure uses a large-diameter pipe having a large weight or size.

Vibration occurs in the pipe by receiving movement generated from the structure itself in which the pipe is installed, or by the flow of a fluid flowing through the pipe. In addition, the pipe expands or contracts depending on the temperature of the fluid flowing along the pipe.

In this case, the pipe causes damage or breakage of the pipe due to the displacement of the horizontal component or the vertical component, and thus connects and supports the pipe using a pipe support device for preventing this.

However, the conventional pipe support device simply connects and supports the pipe and cannot grasp the change or vibration state of the pipe in real time, so there is a limit in preventing damage or damage to the pipe in advance.

The related technology related to the supporting device for piping is presented in Korean Patent Laid-Open No. 10-2019-0050161 (2019.05.10).

An object of the present invention is to provide a support device for a pipe that stably supports the pipe and enables to grasp the change or vibration state of the pipe in real time.

The present invention provides a housing having a cylindrical structure provided with an internal space, connected and installed to be slidably movable in the vertical direction to the housing, a sliding plate disposed inside the housing is coupled to the upper end of the housing, and a pipe is connected to the lower end of the housing A connecting rod coupled to a hanger connecting part disposed on the outside, an elastic member inserted and installed inside the housing, elastically supporting the connecting rod, installed in the housing to be connected to the sliding plate, the sliding plate in the vertical direction from the inside of the housing A pipe including an elastic control unit for adjusting the movable range, a pipe condition check unit installed to be connected to the housing, and configured to measure the load received from the pipe while supporting the pipe to determine the change or vibration state of the pipe A support device is provided for

In addition, a lifting guide groove is formed in the side portion of the housing to extend from the upper side to the lower side of the housing, and it protrudes outward from the outer edge of the sliding plate so as to be inserted and disposed to be slidably moved in the vertical direction in the lifting guide groove. and an adjustment connection end having an adjustment connection groove formed therethrough to penetrate in the vertical direction, wherein the elastic adjustment unit is inserted into the adjustment connection groove so as to be connected to the adjustment connection end, and the upper end of the adjustment rod is fixedly coupled to the upper side of the housing , It may include a pair of locking stoppers inserted and installed on the outside of the control rod so as to be respectively disposed on the upper side and the lower side of the control connecting rod.

In addition, the pipe state check unit is installed in the bottom of the housing in an inserted state inside the housing, the piston rod is a hydraulic cylinder connected to the bottom surface of the sliding plate in a state that is arranged in parallel with the connecting rod, the hydraulic cylinder A pressure sensor that measures the hydraulic pressure in the hydraulic cylinder as the sliding plate moves in the vertical direction, is connected to the pressure sensor, receives the hydraulic pressure value measured from the pressure sensor, and the hydraulic cylinder according to the vertical movement of the sliding plate. After calculating the stress value applied from the pipe through the pressure difference, it may include a stress calculation output means for outputting the calculated stress value to determine the fluctuation or vibration state of the pipe.

In addition, the stress calculation output means sets and stores a safety stress value for maintaining a stable fluctuation or vibration state of the pipe, and the pipe condition check unit is connected to the stress calculation output means, and the stress value calculated by the stress calculation output means When the ratio exceeds the set ratio compared to the safety stress value, an emergency notification means for receiving a signal from the stress calculation output means and generating a notification may be further provided.

The support device for piping according to the present invention, when elastically supporting the pipe connected to the connecting rod with an elastic member, allows the pipe condition check unit to grasp the change or vibration state of the pipe through the load received from the pipe, so that the operator can control the pipe Enables you to respond before damage occurs. And, the elastic control unit allows the elastic member to maintain an elastic support state capable of stably supporting the pipe while adjusting the elastic operating range of the elastic member.

1 is a configuration diagram of an installation state of a support device for piping according to an embodiment of the present invention.
FIG. 2 is an enlarged perspective view of part A of FIG. 1 .
FIG. 3 is a cross-sectional view of a part A shown in FIG. 1 .

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

1 is an installation state configuration diagram of a support device for piping according to an embodiment of the present invention, FIG. 2 is an enlarged perspective view of part A shown in FIG. 1 , and FIG. 3 is a cross-sectional view of part A shown in FIG. 1 . 1 to 3 , the support device for piping according to an embodiment includes a housing 100 , a connecting rod 200 , an elastic member 300 , an elastic control unit 400 , and a piping condition check unit 500 . In the provided state, the pipe 20 installed spaced apart from the support structure 10 is supported in a connected state.

The housing 100 is a part that connects and supports the connecting rod 200 to be described later so as to be slidably movable in the vertical direction, and also connects and supports the elastic adjustment unit 400 . The housing 100 is formed to have a tubular structure having an inner space, so that the elastic member 300 can be disposed to be inserted therein. Here, after the housing 100 is formed in a cylindrical structure with an openable upper side, the fastening member 102 composed of bolts and nuts in a state where the cover plate 101 is disposed on the upper side of the opened housing 100 By allowing the coupling to seal the upper side of the housing 100 through the coupling rod 200 and the elastic member 300, it is possible to easily insert or detach the connecting rod 200 and the elastic member 300 to the inside of the housing 100. In addition, a rod insertion hole 100a is formed through the center of the bottom surface of the housing 100 so that the connecting rod 200 can be connected and disposed in a vertically slidable state. At this time, a bearing member that enables the connecting rod 200 to be stably slidably connected in the vertical direction may be coupled to the portion in which the rod insertion hole 100a of the housing 100 is formed.

In addition, the upper end of the housing 100, more specifically, the upper surface of the cover 101, a fastening hole 104a to be coupled to the support structure 10 through a fastening member 11 composed of a bolt and a nut in a connected state. ) is provided with a coupling lug 104 is formed.

In addition, at least a pair of lifting guide grooves 103 are formed in the housing 100 to face each other on the side surface. The elevating guide groove 103 is formed to extend from the upper side to the lower side of the housing 100 so as to be arranged in parallel with the longitudinal direction of the housing 100 , that is, the axial direction of the connection rod 200 . In this way, the elevating guide groove 103 guides the sliding plate 210 of the connecting rod 200 to be connected to the housing 100 and enables stable sliding movement in the vertical direction, and the sliding plate 210 is provided. The outer edge of the sliding plate 210 is protruded to the outside of the housing 100 so as to be connected to the elastic control unit 400 .

The connecting rod 200 is a linear shaft member connected and installed to the housing 100 so as to be slidably movable in the vertical direction. A sliding plate 210 , which is slidably inserted and disposed inside the housing 100 , is coupled to the upper end of the connecting rod 200 . Here, the sliding plate 210 may be formed in a plate shape corresponding to the inner cross-sectional shape of the housing 100 , and serves to transmit the elastic force of the elastic member 300 to the connecting rod 200 .

And, the outer edge of the sliding plate 210 is provided with a coupling adjustment connection end 211 to protrude outward. The adjustment connection end 211 is inserted and disposed to slide vertically in the elevation guide groove 103 of the housing 100 , and the sliding plate 210 moves stably in the vertical direction inside the housing 100 . In addition to making it possible, it serves to connect the elastic control unit 400 to the sliding plate 210 . Here, an adjustment connection groove 212 is formed in the adjustment connection end 211 to penetrate in the vertical direction so that the adjustment rod 410 of the elastic adjustment unit 400 can be connected in an inserted state.

In addition, a hanger connection part 220 disposed on the outside of the housing 100 to connect the pipe 20 is coupled to the lower end of the connection rod 200 . The hanger connection hole 220a is provided in the hanger connection part 220 so that the hanger 30 composed of a pair of hanger plates having a pair of semicircular cross-sectional structures can be fastened with the fastening member 31 composed of a bolt and a nut. through is formed.

The elastic member 300 is an elastic member that elastically supports the connecting rod 200 . That is, the elastic member 300 can absorb the shock or vibration of the pipe 20 connected to the connecting rod 200 . The elastic member 300 is inserted and installed inside the housing 100 , and more specifically, the elastic member 300 is inserted and installed on the outside of the connecting rod 200 to be located inside the housing 100 . At this time, the lower end of the elastic member 300 is disposed to be seated inside the bottom surface of the housing 100 , and the upper end of the elastic member 300 is disposed to be connected to the lower surface of the sliding plate 210 , the elastic member 300 . allows the connecting rod 200 to move elastically in the vertical direction on the housing 100 while elastically supporting the sliding plate 210 . Here, the elastic member 300 may be selectively applied as a coil spring, but the present invention is not limited thereto.

The elastic control unit 400 is a part that adjusts the degree of movement in the vertical direction of the sliding plate 210 inside the housing 100 . That is, the elastic control unit 400 controls the elastic operating range of the elastic member 300 by adjusting the vertical movement range of the sliding plate 210 , the pipe 20 connected to and supported by the connecting rod 200 is Allows control of the range that can be changed in the vertical direction. The elastic adjustment unit 400 is installed in the housing 100 so as to be connected to the sliding plate 210 of the connecting rod 200 . In addition, the elastic adjustment unit 400 includes an adjustment rod 410 and a stopper 420 .

The adjustment rod 410 is a straight shaft-shaped member that supports the sliding plate 210 of the connecting rod 200 in a connected state to be slidably movable in the vertical direction. The adjustment rod 410 is installed to be inserted into the adjustment connection groove 212 to be connected to the adjustment connection end 211 of the sliding plate 210, and the upper end of the adjustment rod 410 is the upper side of the housing 100, In more detail, it is fixedly coupled to the cover plate 101 through a fastening member such as a bolt and a nut. In addition, a screw portion may be formed on the outer surface of the control rod 410 to allow the locking stopper 420 to be coupled in a screw state.

The locking stopper 420 is a member that is arranged to be connected to the control rod 410 in a mutually spaced apart state, and sets a range in which the sliding plate 210 of the connection rod 200 can move on the control rod 410 . That is, the locking stopper 420 is inserted into the control rod 410 and installed, and the locking stopper 420 disposed on the upper side of the sliding plate 210 moves the sliding plate 210 upward on the control rod 410 no longer. The locking stopper 420 disposed on the lower side of the sliding plate 210 is locked so as not to move, and the sliding plate 210 is caught on the control rod 410 so as not to move downward any longer. This, the locking stopper 420 has a nut structure in which a thread is formed on the inside so that the fastening is made in a state where the position can be adjusted on the adjustment rod 410 . And, on one side of the locking stopper 420, a fixing pin (not shown) is screwed through the inside and outside of the locking stopper 420 so that it can be fixed at a predetermined position on the control rod 410 of the locking stopper 420. It can be very well equipped. That is, when the fixing pin is rotated so that one end of the fixing pin is arranged to be pressed against the outer surface of the control rod 410 , the locking stopper 420 maintains a stable fixed state on the control rod 410 while maintaining the sliding plate 210 . ) to make a sliding movement within a stable fixed range up and down on the control rod 410 .

In addition, one side of the locking stopper 420 of the elastic control unit 400 , more specifically, a surface portion facing the sliding plate 210 , absorbs shock when it collides with the sliding plate 210 to absorb the impact force. A member (not shown) may be coupled. Of course, the shock absorbing member may be formed in a ring shape made of rubber or synthetic resin having ductility, or a coil spring may be selectively applied.

The pipe condition check unit 500 is a part that measures the load received from the pipe 20 in a state in which the pipe 20 is supported to determine the fluctuation or vibration state of the pipe 20 . That is, the pipe state check unit 500 makes it possible to know the state of the elastic member 300 in a state in which the load of the pipe 20 is elastically supported through the elastic member 300 . The pipe condition check unit 500 is connected and installed to the housing 100 , and in more detail, it is installed to be connected to the sliding plate 100 of the housing 100 so as to measure the load received from the pipe 20 . . Here, the pipe state check unit 500 includes a hydraulic cylinder 510 , a pressure sensor 520 , and a stress calculation output means 530 .

The hydraulic cylinder 510 is a cylinder in which the length of the piston rod 511 is adjusted according to the vertical movement of the sliding plate 210 . That is, the piston rod 511 of the hydraulic cylinder 510 is connected to the bottom surface of the sliding plate 210 in a state that is arranged in parallel with the connection rod 200 , and the piston rod 511 is the upper and lower portions of the sliding plate 210 . It moves according to the movement. Here, the hydraulic cylinder 510 is inserted and installed inside the housing 100 so as to be disposed between the lower portion of the sliding plate 210 and the bottom of the housing 100 , and the body portion of the inlet cylinder 510 is the housing 100 . ) to be coupled to the bottom of the At this time, as the hydraulic cylinder 510, a pneumatic cylinder is selectively used, but is not limited thereto. As such, the piston rod 511 of the hydraulic cylinder 510 is installed to connect and support the sliding plate 210 in a state that is arranged in parallel with the connection rod 200, and serves to additionally support the load of the pipe 20 can be done

The pressure sensor 520 is a sensor that measures the hydraulic pressure in the inlet cylinder 510 as the piston rod 511 moves correspondingly according to the vertical movement of the sliding plate 210 . The pressure sensor 520 is installed to be connected to the inside of the hydraulic cylinder 510 so as to measure the hydraulic pressure of the hydraulic cylinder 510 . More preferably, the pressure sensor 520 may be installed at the upper end and the lower end of the inner body of the hydraulic cylinder 510, respectively.

The stress calculation output means 530 receives the hydraulic pressure value measured from the pressure sensor 520 and is applied from the pipe 20 through the pressure difference of the hydraulic cylinder 510 according to the vertical movement of the sliding plate 210 . After calculating the stress value, the calculated stress value is output so that the fluctuation or vibration state of the pipe 20 can be grasped. The stress calculation output means 530 is connected to the pressure sensor 520 by wire, such as a cable, or wirelessly, such as Wi-Fi, Bluetooth, or infrared communication, to receive a hydraulic pressure value measured from the pressure sensor 520 . . Here, the stress calculation output means 530 receives the hydraulic pressure value measured from the pressure sensor 520, and then through the pressure difference of the hydraulic cylinder 510 according to the vertical movement of the sliding plate 210, the pipe 20 It may include a computer server 531 provided with a program for calculating the stress value applied from the , and an output device 532 for outputting the stress value calculated from the computer server 531 on a display.

In addition, the computer server 531 of the stress calculation output means 530 sets and stores a safety stress value for maintaining a stable fluctuation or vibration state of the pipe 20 . At this time, the safety stress value stored in the computer server 531 is based on a value of less than 80% based on the elastic limit value of the elastic member 300 .

In addition, the pipe state check unit 500 is connected to the computer server 531 of the stress calculation output means 530, and the stress value calculated by the computer server 531 of the stress calculation output means 530 is a safety stress. When the ratio exceeds the set ratio compared to the numerical value, that is, when the calculated stress value based on the elastic limit value of the elastic member 300 is 80% or more, a signal is transmitted from the computer server 531 of the stress calculation output means 530. An emergency notification means 540 for generating a notification such as a warning light or a warning sound or a warning message on the output device 532 may be provided.

As described above, in the support device for piping according to an embodiment, when the pipe 20 connected to the connecting rod 200 is elastically supported by the elastic member 300 , the pipe state check unit 500 is configured to perform the pipe 20 . It is possible to grasp the fluctuation or vibration state of the pipe 20 through the load received from the operator, so that the operator can respond before the pipe 20 is damaged. And, the elastic adjustment unit 400 allows the elastic member 300 to maintain an elastic support state that can stably support the pipe 20 while adjusting the elastic operating range of the elastic member 300 .

Although the present invention has been described with reference to the embodiment shown in the drawings, which is merely exemplary, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Accordingly, the true technical protection scope of the present invention should be defined by the technical spirit of the appended claims.

100: housing 200: connecting rod
210: sliding plate 220: hanger connection part
300: elastic member 400: elastic control unit
410: adjustment rod 420: jam stopper
500: pipe condition check unit 510: hydraulic cylinder
520: pressure sensor 530: stress calculation output means
540: emergency notification means

Claims (4)

a housing having a tubular structure provided with an internal space;
a connecting rod connected to the housing to be slidably moved in the vertical direction, a sliding plate disposed inside the housing is coupled to an upper end thereof, and a hanger connector disposed outside the housing to connect a pipe to a lower end coupled to the connecting rod;
an elastic member inserted and installed inside the housing and elastically supporting the connecting rod;
an elastic adjustment unit installed in the housing to be connected to the sliding plate and configured to adjust a movable range of the sliding plate in the vertical direction inside the housing; and
A piping support device including a; a piping condition check unit installed to be connected to the housing and configured to measure the load received from the piping in a state in which the piping is supported to determine the fluctuation or vibration state of the piping. The method according to claim 1,
A lifting guide groove is formed in the side portion of the housing to extend from the upper side to the lower side of the housing,
It is provided to protrude outwardly from the outer edge of the sliding plate so as to be inserted and disposed to be slidably moved in the vertical direction in the elevating guide groove, and includes an adjustment connection end formed with an adjustment connection groove to penetrate in the vertical direction;
The elastic control unit,
an adjustment rod having an upper end fixedly coupled to the upper side of the housing while being inserted into the adjustment connection groove so as to be connected to the adjustment connection end;
A support device for piping including a pair of locking stoppers inserted and installed on the outside of the control rod so as to be respectively disposed on the upper side and the lower side of the control connecting rod. The method according to claim 1,
The pipe condition check unit,
A hydraulic cylinder coupled to the bottom of the housing in a state of being inserted into the housing and connected to the bottom of the sliding plate in a state in which the piston rod is arranged in parallel with the connecting rod;
a pressure sensor installed in the hydraulic cylinder and measuring the hydraulic pressure in the hydraulic cylinder as the sliding plate moves in the vertical direction;
It is connected to the pressure sensor, receives the hydraulic pressure value measured from the pressure sensor, calculates the stress value applied from the pipe through the pressure difference of the hydraulic cylinder according to the vertical movement of the sliding plate, and outputs the calculated stress value. A support device for piping including a stress calculation output means that enables to grasp the fluctuation or vibration state of the piping. 4. The method according to claim 3,
The stress calculation output means sets and stores a safety stress value that maintains a stable fluctuation or vibration state of the pipe,
The pipe condition check unit is connected to the stress calculation output means, and when the stress value calculated by the stress calculation output means exceeds a set ratio compared to the safety stress value, an emergency that receives a signal from the stress calculation output means and generates a notification Supporting device for piping further comprising a notification means.

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