KR102657106B1 - Probe connection device for pipe internal inspection system with distance control module - Google Patents

Abstract

The probe connection device of the piping internal inspection system according to the present invention includes a tubular connector formed to face one end of a tube that is to be inspected; a distance adjustment member installed through the connection pipe so that the distance between the connection pipe and the tube can be adjusted; a moving member that moves integrally with the distance adjustment member; a straight first rail member in which the moving member is installed to be movable and extends in a direction perpendicular to the longitudinal direction of the connection pipe; second rail members installed at both ends of the first rail member and coupled to the first rail member to be movable in a direction perpendicular to the longitudinal direction; and a sliding fixing member whose one end is coupled to the second rail member and whose other end is curved in a direction away from the second rail member and includes a wheel provided with magnetic force.

Description

Probe connection device for pipe internal inspection system with distance control module}

The present invention relates to non-destructive testing equipment, and more specifically, to a connection device that allows effective installation and connection of a probe that inspects the inside of a pipe.

Heat exchanger tubes in petrochemical complexes or power plants are parts through which high-temperature and high-pressure steam passes during operation. The heat exchanger is provided with a plurality of tubes in a bundle form. Heat exchanger tubes are often subject to damage such as wear, cracks, and tenting. Therefore, it is necessary to inspect whether defects occur in the heat exchanger tube. Inspection of heat exchanger tubes is performed periodically. Inspection of heat exchanger tubes is performed with the purpose of increasing efficiency and preventing accidents. For example, in pipe internal inspection, a non-destructive inspection probe is inserted into the inside of a pipe or tube and moves along the pipe to inspect pipe defects. Pipe internal inspection methods include the Internal Rotary Inspection System (IRIS) and Eddy Current Testing (ECT) using ultrasonic waves.

IRIS is a method of investigating pipe defects by filling the inside of a pipe with water and rotating and moving an ultrasonic probe. The IRIS method has the advantage of enabling precise inspection, but has the disadvantage of being time consuming.

ECT is a method of investigating pipe defects by moving a moving ECT probe along the inside of the pipe. ECT is difficult to conduct a detailed investigation, but has the advantage of requiring a short period of time.

Generally, a heat exchanger is composed of a plurality of tube structures installed in a bundle form inside a cylindrical piping frame.

An example of a device for installing non-destructive testing equipment in a heat exchanger is disclosed in Korean Patent Publication No. 10-2018-0115553. However, the conventional device does not have any major problems when inspecting pipes located in the center, but when inspecting pipes located at the edges, there is a problem in that it is difficult to install inspection equipment. If the inspection equipment is not installed properly, IRIS has the problem that the reliability of the inspection results is reduced due to leakage in the pipe when applying the probe. In the ECT test, there is a problem that the reliability of the test results is reduced due to damage to the probe due to vibration when the probe is inserted and withdrawn.

001 KR 10-2018-0115553 A (2018.10.23)

The purpose of the present invention was to solve the problems described above, and by improving the structure of the device for connecting the probe for internal piping inspection, the probe connection device for the piping internal inspection system is convenient to install regardless of the location of the pipe. is to provide.

In order to achieve the above object, the probe connection device of the piping internal inspection system according to the present invention includes a tubular connector formed to face one end of a tube that is to be inspected;

a distance adjustment member installed through the connection pipe so that the distance between the connection pipe and the tube can be adjusted;

a moving member that moves integrally with the distance adjustment member;

a straight first rail member in which the moving member is installed to be movable and extends in a direction perpendicular to the longitudinal direction of the connection pipe;

second rail members installed at both ends of the first rail member and coupled to the first rail member to be movable in a direction perpendicular to the longitudinal direction; and

It is characterized in that it includes a sliding type fixing member, one end of which is coupled to the second rail member and the other end of which is curved in a direction away from the second rail member, and which includes a wheel provided with magnetic force.

A male screw portion may be provided on an outer peripheral surface of the connection pipe and a female thread portion may be provided on an inner peripheral surface of the distance adjustment member, so that the connection pipe may be configured to approach or move away from the tube as the distance adjustment member rotates.

The first rail member includes a first screw member that moves the moving member, and the moving member is screw-coupled with the first screw member, so that as the first screw member rotates, the moving member moves the first screw member. It can be installed to be movable along the longitudinal direction of the rail member.

A second screw member installed along the longitudinal direction of the second rail member is provided,

Both ends of the first rail member are screw-coupled with the second screw member, so that the first rail member can be installed to be movable along the second rail member.

The sliding fixing member may include a support arm whose one end is rotatably connected to the second rail member about a pivot axis.

One end is supported by the second rail member, and the other end is supported by the support arm, and the other end of the support arm may include an elastic member that generates an elastic restoring force in a direction away from the second rail member.

The wheel may include a wheel made of an electromagnet and a tire made of rubber surrounding the outer circumference of the wheel.

a first motor that rotates the distance adjustment member;

a second motor that provides power to move the moving member;

a third motor that provides power to move the first rail member; and

It may include a position controller that integratedly controls the first motor, the second motor, and the third motor.

The second rail member may be installed to be movable in the longitudinal direction of the first rail member.

In the probe connection device of the piping internal inspection system according to the present invention, the second rail member is fixed as the sliding fixing member is fixed by magnetic force along the outer peripheral surface of the heat exchanger tube frame, and the second rail member is movably connected to the second rail member. Since the position of the connector can be changed, installed, and separated by the distance control member installed on the moving member installed on the first rail member, it provides the effect of installing the probe of the non-destructive testing equipment very easily and efficiently compared to the conventional structure. This provides the effect of significantly shortening the inspection time.

Figure 1 is a diagram showing a state in which the probe connection device of the piping internal inspection system according to a preferred embodiment of the present invention is installed on the heat exchanger tube.
FIG. 2 is a cross-sectional view taken along line II-II shown in FIG. 1.
Figure 3 is a cross-sectional view taken along line III-III shown in Figure 1.
FIG. 4 is a cross-sectional view taken along line IV - IV shown in FIG. 1.
Figure 5 is a diagram showing a state in which a probe is installed in a tube at a different position in Figure 1.

Hereinafter, preferred embodiments according to the present invention will be described in more detail with reference to the attached drawings.

Figure 1 is a diagram showing a state in which the probe connection device of the piping internal inspection system according to a preferred embodiment of the present invention is installed on the heat exchanger tube. FIG. 2 is a cross-sectional view taken along line II-II shown in FIG. 1. Figure 3 is a cross-sectional view taken along line III-III shown in Figure 1. FIG. 4 is a cross-sectional view taken along line IV - IV shown in FIG. 1. Figure 5 is a diagram showing a state in which a probe is installed in a tube at a different position in Figure 1.

1 to 5, the probe connection device 10 (hereinafter referred to as “probe connection device”) of the piping internal inspection system according to a preferred embodiment of the present invention includes a connector 20 and a distance adjustment member ( 30), a moving member 40, a first rail member 50, a second rail member 60, and a sliding fixing member 70.

The connection pipe 20 is a tubular member arranged to face one end of the tube 200, which is the object to be inspected. The inner diameter of the connection pipe 20 preferably matches or has a size close to the inner diameter of the tube 200. The connection pipe 20 is arranged to extend the tube 200 outward. A male thread portion is provided on the outer peripheral surface of the connection pipe 20. The front end of the connector 20 may be provided with rubber packing to prevent water leakage.

The distance adjustment member 30 is a screw-shaped member. A female thread portion is provided on the inner peripheral surface of the distance adjustment member 30. The connection pipe 20 is installed to penetrate the distance adjustment member 30 in a screwed manner. The distance adjustment member 30 is installed so that the distance between the connection pipe 20 and the tube 200 can be adjusted. That is, the connection pipe 20 may be installed to move forward or backward as the distance adjustment member 30 rotates clockwise or counterclockwise in place. As the distance adjustment member 30 rotates, the connection pipe 20 may approach or move away from the tube 200.

The moving member 40 rotatably supports the distance adjusting member 30. A bearing may be installed between the moving member 40 and the distance adjusting member 30. The moving member 40 can move integrally with the distance adjusting member 30 along the first rail member 50, which will be described later. A first motor (not shown) that rotates the distance adjustment member 30 may be installed on the moving member 40. The first motor is mechanically connected to the distance adjustment member 30 and rotates the distance adjustment member 30. A reducer may be installed between the first motor and the distance adjustment member 30.

The first rail member 50 is a straight member disposed in a direction parallel to the radial direction of the circular cylindrical frame 100 accommodating the plurality of tubes 200. More specifically, the first rail member 50 may extend in a direction perpendicular to the longitudinal direction of the connection pipe 20.

The moving member 40 is installed to be movable along the first rail member 50. The first rail member 50 may be provided with a first screw member 52 that moves the moving member 40. The first rail member 50 may be equipped with a second motor (not shown) that rotates the first screw member 52. That is, the second motor provides power to move the moving member 40. The moving member 40 is screw-coupled with the first screw member 52. As the first screw member 52 rotates, the moving member 40 is installed to be movable along the longitudinal direction of the first rail member 50.

The second rail member 60 is installed at both ends of the first rail member 50, respectively. The second rail member 60 is disposed in a direction perpendicular to the longitudinal direction of the first rail member 50. Additionally, the second rail member 60 is disposed in a direction perpendicular to the longitudinal direction of the connection pipe 20. The first rail member 50 is movably coupled to the second rail member 60. That is, the first rail member 50 is coupled to be movable in a direction perpendicular to the longitudinal direction of the first rail member 50 along the second rail member 60. A second screw member 62 installed along the longitudinal direction of the second rail member 60 is provided. The second rail member 60 may be equipped with a third motor (not shown) that rotates the second screw member 62. That is, the third motor provides power to move the first rail member 50. Both ends of the first rail member 50 may be coupled to the second screw member 62 in a ball screw structure. Accordingly, the first rail member 50 is installed to be movable along the second rail member 60. Meanwhile, the second rail member 60 may be installed to be movable in the longitudinal direction of the first rail member 50. The second rail member 60 may be fixed to the first rail member 50 at a specific position using means such as fixing screws.

One end of the sliding fixing member 70 is coupled to the second rail member 60. The other end of the sliding fixing member 70 is curved in a direction away from the second rail member 60. The sliding fixing member 70 includes a wheel 72 equipped with magnetic force. The wheel 72 may include, for example, an electromagnet that selectively generates a strong magnetic force. The wheel 72 may include a wheel made of an electromagnet and a tire made of rubber surrounding the outer circumference of the wheel. The sliding fixing member 70 is fixed to the outer peripheral surface of the frame 100 by magnetic force. Additionally, the sliding fixing member 70 can slide and move along the outer peripheral surface of the frame 100. The sliding fixing member 70 may be provided with a fourth motor (not shown) that rotates the wheel 72. For example, the sliding fixing member 70 includes a support arm 74. One end of the support arm 74 is rotatably connected to the second rail member 60 about the pivot axis. The other end of the support arm 74 is curved in a direction away from the second rail member 60. The wheel 72 is rotatably installed on the support arm 74. Two support arms 74 may be provided on each of the second rail members 60.

The second rail member 60 and the support arm 74 may be connected by an elastic member 76. One end of the elastic member 76 is supported by the second rail member 60. The other end of the elastic member 76 is supported by the support arm 74. The elastic member 76 generates an elastic restoring force in a direction where the other end of the support arm 74 moves away from the second rail member 60. The elastic member 76 may be a coil spring. Meanwhile, a pneumatic cylinder or a hydraulic cylinder may be employed as the elastic member 76. The elastic member 76 functions to press the sliding fixing member 70 to better adhere to the frame 100.

It may include a position controller (not shown) that integratedly controls the first motor, the second motor, and the third motor. The position controller is electrically connected to the first motor, the second motor, and the third motor. The position controller can also integratedly control a fourth motor (not shown) that moves the sliding fixing member 70.

Hereinafter, the operational effects of the probe connection device 10 including the above-described components will be described in detail by taking the process of installing a UT (Ultrasonic Testing) probe or an ECT probe in the tube 200 as an example.

Before installing the UT probe 300 or the ECT probe on the tube 200, first, the probe connection device 10 is installed on the frame 100. In order to install the connection device on the frame 100, work can be started in a state where the connection pipe 20 is not coupled to the distance adjustment member 30. The gap between the pair of second rail members 60 is adjusted to approximate the outer diameter of the frame 100 to be installed. And the sliding fixing member 70 connected to the second rail member 60 is attached to the outer peripheral surface of the frame 100. In this process, the wheel 72 including the electromagnet is firmly attached and fixed to the outer peripheral surface of the frame 100. Additionally, in this process, the elastic member 76 serves to press the wheel 72 toward the frame 100 so that the sliding fixing member 70 is firmly adhered to the frame 100.

Now, the first rail member 50 and the moving member 40 are moved so that the distance adjustment member 30 corresponds to the position of the tube 200 to be measured. Since the first rail member 50 and the moving member 40 can be moved in directions perpendicular to each other, they correspond to a process of moving on a kind of plane coordinate. When the distance adjustment member 30 corresponds to the position of the tube 200 to be measured, the connector 20 is coupled to the distance adjustment member 30. The distance adjustment member 30 rotates. The connector 20 moves in a direction approaching the tube 200. With the connector 20 and the tube 200 in contact with each other, the UT probe 300 or the ECT probe enters the tube 200 through the connector 20 to perform non-destructive testing. In this process, when the UT probe 300 is applied, the tube 200 may be filled with water. Meanwhile, when applying an ECT probe, the tube 200 does not need to be filled with water. When the inspection of one tube 200 is completed, the probe 300 is separated from the tube 200 in order to inspect the tube 200 at another location. Then, the distance adjustment member 30 rotates in the reverse direction to separate the connector 20 from the tube. Now, the moving member 40 and the first rail member 50 move so that the distance adjusting member 30 corresponds to the tube 200 at the next position. In this process, depending on the position of the tube 200 to be inspected, the sliding fixing member 70 may be fixed to the outer circumference of the frame 100 while rotating along the outer circumference of the frame 100. Then, the inspection process described above is repeatedly performed. In this process, the distance adjustment member 30, the moving member 40, and the first rail member 50 can be automatically operated by the first motor, second motor, and third motor, so workability is remarkable. There are advantages to improving it. In this process, if a location confirmation camera is installed in front of the connector 20, the worker has the advantage of being able to work remotely from a distance without directly approaching the site.

As described above, in the probe connection device of the piping internal inspection system according to the present invention, the second rail member is fixed as the sliding fixing member is fixed by magnetic force along the outer peripheral surface of the heat exchanger tube frame, and the second rail member is connected to the second rail member. Since the position of the connector can be changed, installed, and separated by the distance control member installed on the moving member installed on the movably connected first rail member, the probe of the non-destructive testing equipment can be installed very easily and efficiently compared to the conventional structure. to provide. This provides the effect of significantly shortening the inspection time.

The probe connection device according to the present invention provides the effect of improving the versatility of the equipment because it can selectively apply a UT probe or an ECT probe when performing non-destructive testing on multiple tubes, such as a heat exchanger.

Above, the present invention has been described with reference to preferred embodiments, but the present invention is not limited to these examples, and various forms of embodiments may be embodied without departing from the technical spirit of the present invention.

10: Probe connection device
20: connector
30: Distance control member
40: moving member
50: First rail member
52: First screw member
60: Second rail member
62: Second screw member
70: sliding fixing member
72: wheels
74: Jijiam
76: elastic member
100: frame
200: tube
300: Probe

Claims (1)

A tubular connection tube formed to face one end of the tube that is the object to be inspected;
a distance adjustment member installed through the connection pipe so that the distance between the connection pipe and the tube can be adjusted;
a moving member that moves integrally with the distance adjustment member;
a straight first rail member in which the moving member is installed to be movable and extends in a direction perpendicular to the longitudinal direction of the connection pipe;
second rail members installed at both ends of the first rail member and coupled to the first rail member to be movable in a direction perpendicular to the longitudinal direction; and
It includes a sliding type fixing member, one end of which is coupled to the second rail member and the other end of which is curved in a direction away from the second rail member, and including a wheel provided with magnetic force,
The sliding fixing member includes a support arm whose one end is rotatably connected to the second rail member about a pivot axis and is curved in a direction away from the second rail member; and
One end is supported by the second rail member, the other end is supported by the support arm, and the other end of the support arm includes an elastic member that generates an elastic restoring force in a direction away from the second rail member,
A male thread is provided on the outer peripheral surface of the connection pipe and a female thread is provided on the inner peripheral surface of the distance adjustment member, so that the connection pipe approaches or moves away from the tube as the distance adjustment member rotates,
A second screw member installed along the longitudinal direction of the second rail member is provided,
Both ends of the first rail member are screwed together with the second screw member, so that the first rail member is movable along the second rail member. Probe connection device.