RU2630293C2 - Method for x-ray controlling pipes and device for its implementation - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: control is performed at the time, when the pipe is in the radiation-protected premises, that has the input and output gates, oncoming supports adapted to take the top and bottom position and located in the pipe movement path, an x-ray source and receiver located in the same premises on the opposite sides of the controlled surface, one of these devices is mounted on the rod with the supporting wheels, which is inside the pipe at the time of the control, and the other one is near the pipe movement path. Before the control, the pipe is located on the transport device in front of the radiation-protected premises. The gates of the premises are open, the rod with the supporting wheels lies on the oncoming supports, then the front end of the pipe is led through the enlet gates to the first oncoming support supporting the rod, the support is lowered, allowing the tube to move further into the premises through the transport device, bumping the rod, the oncoming supports are consistently lowered at the pipe approach. The supporting wheels roll on the inner surface of the pipe, supporting thereon, while the pipe is further led by the transport device until the moment, when the rear end of the pipe passes the first support, the first support is raised, the gates are shut, the radiographic inspection of the pipe wall is performed, when the pipe moves inside the premises, after the control the pipe is led to the last oncoming support, the gates are open, the last oncoming support is lowered, the rod rolls on the supporting wheels on the inner pipe surface, and the oncoming supports are consistently raised, and they pick up the rod, as soon as the end of the pipe goes through the appropriate support, the pipe is removed from the premises by using the transport device.

EFFECT: providing ability to control the seams of the welded pipes, in which the control device is located on the path of the main process flow.

2 cl, 5 dwg

Description

Refers to the field of x-ray control and can be used, for example, to control the welds of welded pipes.

A known installation of x-ray inspection of pipes of the company General Electric (http://ndt.net/article/ecndt2010/reports/1_04_26.pdf), in which the pipe for control by means of a transport device is introduced into a radiation-protected room, control is carried out using a source and a receiver located on opposite sides of the pipe wall, one of the devices is mounted on a rod fixedly installed in the room, and the other on a stand located near the pipe's path of movement. For monitoring, the pipe is removed from the main process stream, introduced into the radiation-protected room and then removed from it and returned to the process stream.

A Yxlon pipe x-ray inspection device is also known as a prototype (http://www.yxlon.com/Resources/Products/Pipe/PipeInspector-Product-Sheet-eng-01-LR.pdf), which contains a radiation-protected room, having a gate, an X-ray source and a receiver located in the same room and located on opposite sides of the pipe wall to be monitored, one of these devices being mounted on a rod fixedly installed in the room, and the other is placed on a rack near the pipe moving path and a transport device moving control removable pipe. To control the pipe with the help of a transport device is introduced into the room and after control it is removed from it through the same gate.

Common to the structures of the rods of the known devices is the presence of a support connecting the rod with the floor of the radiation-protected room. This mechanical connection is adjustable or rigid, but it does not break. For control, the pipe enters the radiation-protected room through the gate, bumping into the bar on which the source or receiver is located. Control is carried out with the gates closed. After the end of control, the controlled pipe leaves the radiation-protected room through the same gate and returns to the process stream. To ensure control, the radiation-protected room is located away from the process stream, and an additional transport device is necessary for the delivery and installation of pipes for control. All this requires additional space and material investments in the design, construction and operation of the workshop.

The task is to develop a control method that allows you to position the control device in the path of the main process stream and create a device that implements the method.

The problem is solved as follows.

The control is carried out at the moment when the pipe is in a radiation-protected room, with input and output gates and input supports located in the path of the pipe, which can take an upper and lower position. X-ray source and receiver are placed in the same room on opposite sides of the pipe wall being monitored, one of these devices being mounted on a rod with support wheels, which is inside the pipe at the time of control, and the other is placed near the pipe movement path. Before control, the pipe on the transport device is in front of the radiation-protected room, the gates of the room are open, the bar with support wheels lies on the supplied supports. Then, the front end of the pipe through the entrance gate is brought to the first input support supporting the rod, the support is lowered, allowing the pipe to move further inside the room by means of a transport device, bumping into the rod, the input supports are successively lowered at the entrance to each of them, while the supporting the rod wheels roll on the inner surface of the pipe, resting on it, while the pipe moves through the transport device until the second end of the pipe passes the first support. The support is lifted, the gate is closed and X-rays of the pipe wall are translucent when the pipe moves indoors. After the end of the control, the pipe is brought to the last supply support, the gate is opened, the last supply support is lowered. With the further advancement of the pipe inside the room, the rod rolls on the support wheels along the inner surface of the pipe, and the supplied supports are successively lifted, and they pick up the rod, as soon as the rear end of the pipe passes the corresponding support, the pipe is taken out of the room by means of a transport device.

An apparatus for x-ray inspection of pipes for implementing the method comprises a radiation-protected room having an input and output gate, an X-ray source and receiver located in this room and located on different sides of the wall of the pipe being monitored, a rod and supported supports configured to receive the upper and the lower position, fixed on the floor of the room in the path of the pipe, and a transport device for moving the controlled pipe. The supports support the rod when they are in the upper position and allow the pipe to move above them when they are in the lower position by means of a transport device. The source and receiver are located: one of the devices on the rod, and the other near the path of the pipe. The rod is made with the possibility of rolling relative to the pipe inside it on the support wheels.

As a transport device, a system of roller or chain conveyors or a cart with transport and lifting-rotary rollers can be used. Each of the options for a transport device has its own advantages and disadvantages. For any variant of the transport device, the supplied supports can be lowered to a level that allows the transport device to continue to move with the pipe or pipe placed on it on the transport device above them.

The ability to change the height of the supports and the rolling of the rod relative to the pipe inside it on the support wheels allows you to break the rigid connection of the rod with the floor of the room. The rod can be supported by supporting wheels, either on the supplied supports, or on a pipe passing through the room, while the rod with the source or receiver retains its position relative to the room and, accordingly, the receiver or source. The pipe can pass through the radiation-protected room and exit through the exit gate. This provides the opportunity to place a radiation-protected room in the path of the main process stream.

The drawings show the state of the device during the implementation of the steps of a specific example of the method - X-ray inspection of welds of welded pipes. In this case, a cart was used as a transport device.

FIG. 1 - initial state of the device.

FIG. 2 - transportation of the pipe to a radiation-protected room.

FIG. 3 - start of control.

FIG. 4 - end of control.

FIG. 5 - withdrawal of the controlled pipe from the room.

A device for implementing the method comprises a radiation-protected room 1, an entrance gate 2 and an output gate 3, a radiation source 4 mounted on a rack 5, a radiation receiver 6 mounted on a rod 7 with support wheels 8, and input supports 9. The controlled pipe 10 lies on a cart 11.

When implementing the method, the following operations are performed.

The controlled pipe 10 on the cart 11 in the main process stream is led to the entrance gate 2 of the radiation-protected room 1.

Open the entrance gate 2 rooms.

The pipe 10 continues to move, passes into the room 1 with a control installation, consisting of a radiation source 4 and a receiver 6.

The front end of the pipe 10 is led to the first input support 9. At this point, the end of the rod 7 is already inside the pipe 10. The rod 7 with one support wheel 8 hangs over the inner surface of the pipe 10.

The support 9 is lowered.

The part of the rod 7 freed from the support bends, and the support wheel 8 rests on the inner surface of the pipe 10.

The pipe 10 continues to move to the next input support 9. Support 9 is lowered.

According to this algorithm, the front end of the controlled pipe 10 passes all the supplied supports 9.

After the rear end of the controlled pipe 10 enters the room 1, the entrance gate 2 of the room is closed.

After the rear end of the controlled pipe 10 passes the first supply support 9, it is raised, and it picks up the rod 7.

The pipe 10 is located in room 1, lies on the cart 11. The rod 7 with the receiver 6 is located inside the pipe 10, is supported by wheels 8 on the inner surface of the pipe. The protruding ends of the rod 7 are based on the input supports 9. Gate 2 and 3 are closed. The pipe is ready for inspection.

During the control, the radiation source 4 is turned on, the controlled pipe 10 moves on the cart 11. The controlled welding seam passes between the source 4 and the receiver 6. The image of the controlled seam from the receiver 6 is transmitted to a flaw detector monitor (not shown).

After the end of the control, the entrance gate 2 and the exit gate 3 are opened. The controlled pipe 10 continues to move on the cart 11 in the direction of the main process stream.

The front end of the pipe 10 is brought to the last input support 9.

The support 9 is lowered.

The part of the rod 7 freed from the support bends, and the wheel 8 rests on the inner surface of the pipe 10.

The pipe 10 continues to move from the room.

After the rear end of the controlled pipe 10 passes the supply support 9, it is raised, and it picks up the rod 7.

During the movement of the pipe 10 in the radiation-protected room 1, the supplied supports 9 rise and pick up the rod 7 after the rear end of the controlled pipe passes the corresponding supplied support.

After the controlled pipe 10 leaves the room 1, the rod remains lying on the supplied supports 9. The installation is ready to receive the next pipe for monitoring.

From the description of the operations of the method it can be seen that the length of the radiation-protected premises should exceed twice the length of the monitored pipes. The length of the rod should be no less than twice the maximum pipe length + the length of the extreme sections of the rod supported by the extreme supply supports.

Using the proposed method and device for its implementation will allow you to not occupy a place in the workshop away from the process stream to accommodate a radiation-protected room and transport system, not to design and manufacture an additional transport system for moving the controlled pipe from the main process stream to a radiation-protected room . This increases the productivity of the installation and eliminates the need to use additional space for its placement.

Claims (2)

1. The method of x-ray inspection of pipes, in which the control is carried out at the moment when the pipe is in a radiation-protected room, with input and output gates, input supports made with the ability to take the upper and lower position and located on the path of the pipe, source and receiver x-ray radiation located in the same room on opposite sides of the surface to be monitored, one of these devices is mounted on a rod with support wheels, which is inside the pipe at the time of control, and the other is near the pipe movement path, and before control, the pipe on the transport device is in front of the radiation-protected room, while the gates of the room are open, the bar with support wheels lies on the supported supports, then the front end of the pipe is brought through the entrance gate to the first supplied support, supporting the bar, the support is lowered, allowing the pipe to move further inside the room by means of the transport device, bumping into the bar, the supported supports are successively lowered at the entrance of the pipe, etc. and the supporting wheels of the rod roll along the inner surface of the pipe, resting on it, while the pipe is advanced by means of a transport device until the rear end of the pipe passes the first support, the first support is lifted, the gate is closed, the pipe wall is screened by x-rays when the movement of the pipe indoors, after control, the pipe is brought to the last supply support, the gate is opened, the last supply support is lowered, as the pipe moves, the bar rolls on the support wheels along the inside the lower surface of the pipe, and the supplied supports are successively lifted, and they pick up the rod, as soon as the end of the pipe passes the corresponding support, the pipe is taken out of the room using a transport device. 2. An X-ray inspection device for pipes containing a radiation-protected room having an input and output gate, an X-ray source and receiver located in this room and located on opposite sides of the pipe wall to be monitored, one of these devices being mounted on a rod made with the possibility of rolling relative to the pipe inside it on the support wheels, and another near the path of movement of the pipe, the supplied bearings, made with the ability to take the upper and lower position, fixed on p lu flat supporting post and located in the path of movement of the pipe, and the transporting device for controlled movement of the tube.

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