KR102132195B1 - A device to check for radioactive contamination of steel pipe scaffold used in nuclear facilities - Google Patents

Abstract

The present invention relates to a radioactive contamination inspection apparatus of a steel pipe scaffold used in a nuclear facility, which comprises: a work table; a plurality of steel pipe scaffolding guides; a first transfer roller; a first drive motor; a second transfer roller; a second drive motor; a detection unit holder for outer surface inspection; a radiation meter main body holder for the outer surface inspection; a radiation meter for the outer surface inspection; a detection unit holder for inner surface inspection; a radiation meter main body holder for the inner surface inspection; a radiation meter for the inner surface inspection; and a motor control panel.

Description

A device to check for radioactive contamination of steel pipe scaffold used in nuclear facilities}

The present invention relates to an apparatus for inspecting radioactive contamination of steel pipe scaffolding used in nuclear facilities, and more specifically, repair work of a containment building liner plate in a radiation management area of a nuclear power plant and a reactor steam generator. Generator installed in the replacement work of the steel pipe scaffold used in nuclear facilities to have a structure capable of accurately and quickly performing the radioactive contamination inspection on the inner and outer surfaces of each steel pipe scaffold removed after being used. It is about.

In general, various maintenance work is carried out in the radiation management area of a nuclear power plant that is a nuclear facility, and during such maintenance work, safe and accurate work is performed during maintenance work of the containment building line plate and replacement of the reactor steam generator. In order to be carried out, a scaffold assembly structure for work is installed at a required installation location in the radiation management area, and then maintenance work is carried out.

As such, in order to install the scaffold assembly structure, a steel pipe scaffold, which is a metal pipe, is used in a large amount in the radiation management area of a nuclear power plant, and the used steel pipe scaffold is a target for export after decontamination. Inspection is carried out for each steel pipe scaffolding used, and this radioactive contamination inspection is performed manually by a worker using a radiation measuring instrument.

Radioactive contamination inspection of these conventional steel pipe scaffolding, especially radiation contamination inspection of the inner and outer sides of the steel pipe scaffolding, using cutting equipment, cut each steel pipe scaffold into two equal parts along the longitudinal direction, and then press the cut steel pipe scaffold. After flattening to flatten, the flattened steel pipe scaffolding is carried out, and the details are published in the registered patent publication of Korean Patent No. 10-1900708 (Registration on September 14, 2018).

However, the radioactive contamination inspection method of the steel pipe scaffolding used in the conventional nuclear power facility having the above-described configuration requires a preliminary work to cut and flatten the steel pipe scaffolding, which results in a very low work productivity as well as cost associated with the travel expenses. Of course, there is a problem that the worker is exposed to radiation for a long time.

The present invention has been devised in consideration of the above-described conventional problems, and its purpose is to minimize radioactive contamination inspection on the inside and outside sides of the steel pipe scaffold without preliminary work for cutting and flattening the steel pipe scaffold used in the nuclear power facility. The steel pipe scaffolding used in the nuclear facility to minimize the exposure time to the radiation of the worker and to significantly reduce the inspection cost, as well as to perform the temporary storage of the nuclear power plant more efficiently. It is to provide a radioactive contamination inspection device.

The object of the present invention is a work table having a top plate and a leg portion supporting the top plate; A plurality of steel pipe scaffold guides, which are mounted at regular intervals on a straight line so as to be left and right concentric with respect to the work table, and guide the steel pipe scaffold in the longitudinal direction; The steel pipe is installed rotatably and reversely to form an angle with the steel scaffolding scaffolding on one of the steel pipe scaffolding guides located on the right side of the middle line of the work table so as to contact the outer circumferential surface of the steel mine scaffold mounted on the steel pipe scaffolding guide. A first transfer roller for rotating and moving the steel pipe scaffold on the scaffold guide; A first drive motor mounted on the work table and connected to a rotation axis of the first transfer roller to rotate the first transfer roller forward and backward; The first transfer roller is parallel to the first transfer roller and is installed to be rotatable in the normal and reverse rotation, so as to contact the outer circumferential surface of the steel mine scaffold mounted on the steel pipe scaffold guide, A second transfer roller for rotating and moving the steel pipe scaffold on the steel pipe scaffold guide; A second drive motor mounted on the work table and connected to a rotation axis of the second transfer roller to rotate the second transfer roller forward and backward; It is mounted on the position of the middle line of the work table, and the detection unit holder for the outer surface inspection for placing the detection section of the radiation measuring instrument on the upper side of the steel pipe scaffold conveyed on the steel pipe scaffold guide; A radiation measuring instrument main body holder for outer surface inspection mounted on the work table and on which a radiation measuring instrument body is disposed; It is disposed on the detection surface holder for the outer surface inspection and detects radiation on the outer surface of the steel pipe scaffold, and is disposed on the body surface holder for the radiation surface inspection for external inspection and is electrically connected to the detection unit to be received by the detection unit A radiation measuring instrument for inspecting an outer surface composed of a radiation measuring instrument body for calculating and displaying a detection signal; Of the steel pipe scaffold guides located on the left side of the middle line of the work table, on a straight line of the steel pipe scaffold guides mounted at the most distant from the middle line, it is mounted on a work table spaced apart in the distant direction of the middle line, and A detection unit holder for inspecting an inner surface for placing the detection unit above the middle line of the work table; A radiation measuring instrument body holder for inspecting an inner surface mounted on the work table and on which the radiation measuring instrument body is disposed; The detection unit is disposed on the inner surface inspection detection unit holder to detect radiation on the inner surface of the steel pipe scaffold, and is disposed on the inner surface inspection radiation meter body holder and electrically connected to the detection unit to be received by the detection unit A radiation measuring instrument for inspecting an inner surface composed of a radiation measuring instrument body for calculating and displaying a detection signal; The first and second driving motors are electrically connected to each other, mounted on the work table, and composed of a motor control control panel that controls ON/OFF, forward/reverse rotation and speed of the first and second driving motors. This can be achieved by the radioactive contamination inspection device for steel pipe scaffolding used in nuclear facilities.

The apparatus for inspecting radioactive contamination of steel pipe scaffolding used in a nuclear power facility according to the present invention enables rapid inspection of radioactive contamination on the inside and outside of the steel pipe scaffolding used in a nuclear power facility without cutting and flattening work. It has the effect of significantly reducing the cost of radioactive contamination inspection, enabling rapid inspection, and minimizing exposure time for radioactivity of workers, while also significantly improving self-employment productivity.

1 is a plan view showing a radioactive contamination inspection device of a steel pipe scaffold used in a nuclear power facility according to the present invention,
Figure 2 is an operational state diagram showing the configuration and operation state of the working table among the radioactive contamination inspection device of the steel pipe scaffold used in the nuclear power facility according to the present invention,
Figure 3a is a front view showing a steel pipe scaffold mounted on the steel pipe scaffold guide of the radioactive contamination inspection device of the steel pipe scaffold used in a nuclear power facility according to the present invention,
Figure 3b is an operational state diagram showing a state in which the steel pipe scaffold is mounted on the steel pipe scaffold guide shown in Figure 3a is rotated and transported,
Figure 4 is a steel pipe scaffold mounted on the steel pipe scaffold guide of the radioactive contamination inspection device of the steel pipe scaffold used in a nuclear power facility according to the present invention is rotated in a spiral by a first or second transfer roller operation It is a plan view of the operating state showing the state,
5 is a block diagram illustrating the mutually organic correlation of the motor control operation panel and the first and second driving motors among the radioactive contamination inspection devices of the steel pipe scaffolding used in the nuclear power facility according to the present invention,
6 is a perspective view showing a working table among radioactive contamination inspection devices of steel pipe scaffolding used in a nuclear power facility according to the present invention,
7 is a perspective view showing a detector holder for inspecting the outer surface of a radioactive contamination inspection device of a steel pipe scaffold used in a nuclear power facility according to the present invention.

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

Prior to this, the terms or words used in the present specification and claims should not be construed as being limited to ordinary or lexical meanings, and the inventor appropriately explains the concept of terms to explain his or her invention in the best way. Based on the principle that it can be defined, it should be interpreted as meanings and concepts consistent with the technical spirit of the present invention.

Therefore, the embodiments shown in the embodiments and the drawings described in this specification are only the most preferred embodiments of the present invention, and do not represent all of the technical spirit of the present invention, and at the time of this application, they can be replaced. It should be understood that there may be various equivalents and variations.

The lead blanket for radiation shielding according to the present invention will be described in detail with reference to FIGS. 1 to 5 of the accompanying drawings.

1 to 7, the radioactive contamination inspection apparatus 10 of a steel pipe scaffold used in a nuclear power facility according to the present invention includes a work table 20, a plurality of light pipe scaffold guides 30, first and A second transfer roller (40) (60), a first and second drive motor (50) (70), an outer surface inspection detection unit holder (80), an outer surface inspection radiation measuring instrument body holder (90) and , Radiation measuring device 100 for inspecting the outer surface, detecting part holder 110 for inspecting the inner surface, radiation measuring instrument main body 120 for inspecting the inner surface, radiation measuring device 130 for inspecting the inner surface, and motor control operation panel It consists of 140.

The work table 20 is a table having a top plate and a leg portion supporting the top plate, a wheel member 21 mounted on the lower surface of each leg for easy movement, and an auxiliary top plate foldably hinged to both ends ( 22).

The plurality of steel pipe scaffold guides 30 are mounted on the worktable 20 at regular intervals on a straight line to the left and right, relative to the middle line M, and transport the steel pipe scaffold 200 in the longitudinal direction By guiding as much as possible, it consists of a guide body 31 and three ball transfer units 32.

The guiding body 31 is a flat shape, and both ends are bent vertically upward, so that the middle portion is fired by going out on the self-supporting table 20.

When the steel pipe scaffold 200 is mounted on the ball transfer unit 32, the ball comes into contact with the outer circumferential surface of the steel pipe scaffold 200 and the steel pipe scaffold is operated in a spiral shape while the ball rotates according to the operating force of the steel pipe scaffold 200 ( 200) in the longitudinal direction.

The first transport roller 40 is a steel pipe scaffold guide 30 located on the right side of the middle line of the work table 20 so as to contact the outer circumferential surface of the steel mine scaffold 200 mounted on the steel pipe scaffold guide 30 ) Is installed rotatably in the reverse direction to form an angle with the steel scaffolding 200 on one side, and rotates and transfers the steel pipe scaffolding 200 on the steel pipe scaffold guide 30.

The first drive motor 50 is mounted on the work table 30, is connected to the rotating shaft of the first transfer roller 40 to rotate the first transfer roller 40 forward and backward.

The second transfer roller 60 is a steel pipe scaffold guide 30 located on the left side of the middle line of the work table 20 so as to contact the outer circumferential surface of the steel mine scaffold 200 mounted on the steel pipe scaffold guide 30 ) Is installed on the upper side of one of the first transfer roller 40 in parallel and reverse rotation, and rotates and transfers the steel pipe scaffold 200 on the steel pipe scaffold guide 30.

The second drive motor 70 is mounted on the work table 20, is connected to the rotating shaft of the second transfer roller 60 to rotate the second transfer roller 60 forward and backward.

The detection unit holder 80 for the outer surface inspection is mounted at the midline position of the work table 20, and the detection unit of the radiation measuring instrument is placed on the upper side of the steel pipe scaffold 200 transferred on the steel pipe scaffold guide 30 , Consisting of a holder 81 and a leg portion 82.

The holder 81 has a rectangular frame shape, and horizontally supports a lower edge of the detection unit 101 for inspecting the outer surface.

The leg portion 82 is vertically provided at each corner portion of the lower surface of the mounting frame 81, and fixes the mounting base body 81 on the work table 20.

The radiation measuring instrument body holder 90 for inspecting the outer surface is mounted on the work table 20 and the radiation measuring instrument body is disposed.

The radiation measuring device 100 for inspecting the outer surface is disposed on the detection unit holder 80 for inspecting the outer surface, and the detection unit 101 for detecting radiation on the outer surface of the steel pipe scaffold 200, and for inspecting the outer surface It is arranged on the radiation measuring instrument main body 90 and is electrically connected to the detection unit 101 and is composed of a radiation measuring instrument body 102 that calculates and displays a detection signal received from the detection unit 101.

The inner surface inspection detector holder 110 is a steel pipe scaffold guide 30, which is mounted at a position farthest from the middle of the steel pipe scaffold guides 30 located on the left side of the middle line of the work table 20. It is mounted on the work table 20 spaced apart in the distant direction of the midline on a straight job, and the detector of the radiation measuring instrument is disposed above the midline of the work table 20, the support 111 and the detector mount 112 ).

The support 111 has a bolt assembly hole (111a) at the upper end is fixedly installed on the work table (20).

The detector mount 112 is a round bar, one end of which is detachably detached and coupled to the bolt assembly hole 111a of the support 111 to be horizontally disposed, and the mid-line of the detection section for inspecting the inner surface is a work line 20 On the upper surface of the work table 20, it is maintained in a spaced upward direction, and is provided with a screw portion 112a and a detector assembly portion 112b.

The screw portion 112a is detachably screwed to the bolt assembly hole 111a of the support 111 at one end of the detector mount 112.

The detector assembly section 112b is a tube at the other end of the detector mounting table 112, has a cable assembly groove formed in the side section, and a detector for inspecting the inner surface is detachably assembled.

The radiation measuring instrument body holder 120 for inspecting the inner surface is mounted on the work table 20 and the radiation measuring instrument body is disposed.

The radiation measuring device 130 for inspecting the inner surface is disposed on the detecting unit holder 120 for inspecting the inner surface, and the detecting unit 131 for detecting radiation on the inner surface of the steel pipe scaffold 200, and for inspecting the inner surface It is arranged on the radiation measuring instrument main body 120 and is electrically connected to the detection unit 131 and is composed of a radiation measuring instrument main body 132 that calculates and displays a detection signal received by the detection unit 131.

The motor control operation panel 140 is electrically connected to the first and second driving motors 50 and 70, and is mounted on the work table 20, and the first and second driving motors 50 are (70) ON/OFF, forward/reverse rotation and speed control.

The radioactive contamination test for the steel pipe scaffold 200 used in a nuclear power facility is carried out as follows using the radioactive contamination test device 10 for the steel pipe scaffold used in a nuclear power facility according to the present invention having the above-described configuration.

First, the steel pipe scaffolding 200 to be inspected is mounted on the steel pipe scaffold guide 30 located on the right side (based on the drawing) of the middle line M on the work table 20. At this time, the outer circumferential surface of the left end of the steel pipe scaffold 200 is set to abut against the first transfer roller 40.

When the steel pipe scaffolding 200 is set as described above, the operator operates the motor control operator panel 140 to drive the first and second driving motors 50 and 70 in the forward direction, at an angle with the steel pipe scaffolding 200. As the installed first and second transfer rollers 40 and 60 are rotated in the clockwise direction, the steel pipe scaffold 200 is rotated while drawing a spiral in a counterclockwise direction and is transferred in the longitudinal direction. At this time, each of the steel pipe scaffold guides 30 on which the steel pipe scaffold 200 is mounted is provided with three ball transfer units 32 for supporting the steel pipe scaffold 200 by balls rotated freely. The scaffold 200 is smoothly rotated in a spiral on the steel pipe scaffold guide 30 and can be transferred in the left (based on the drawing) longitudinal direction.

As described above, the outer surface of the steel pipe scaffold 200 that is helically rotated and transported on the steel pipe scaffold guide 30 is a detection unit 101 of the radiation measuring instrument 100 for inspecting the outer surface disposed on the upper side of the steel pipe scaffold 200 By radioactive contamination inspection of the outer surface of the steel pipe scaffold (200), the inside surface disposed inside the steel pipe scaffold (200) by the detector mounting table (112) of the detection unit holder (120) for the inside surface inspection The radioactive contamination test is performed on the inner surface of the steel pipe scaffold 200 by the detection unit 131 of the dragon radiation measuring instrument 130.

When the primary radiation contamination test for the inner and outer surfaces of the steel pipe scaffold 200 is transferred while the steel pipe scaffold 200 is spirally rotated in the left longitudinal direction as described above, the operator operates the motor control operation panel 140 to The first and second driving motors 50 and 70 are driven in the reverse direction, and accordingly, the steel pipe scaffold 200 is spirally rotated counterclockwise while being transported in the longitudinal direction to the right (based on the drawing), thereby Secondary radioactive contamination test is performed on the inner and outer sides, and the secondary radioactive contamination test is completed. The worker classifies and processes the steel pipe scaffold 200 as polluted or non-contaminated according to the primary and secondary radioactive contamination test results. You can do it.

As can be seen from the above, the radioactive contamination inspection apparatus 10 of a steel pipe scaffold used in a nuclear power facility according to the present invention includes a work table 20, a plurality of steel pipe scaffold guides 30, first and A second transfer roller (40) (60), a first and second drive motor (50) (70), an outer surface inspection detection unit holder (80), an outer surface inspection radiation measuring instrument body holder (90) and , Radiation measuring device 100 for inspecting the outer surface, detecting part holder 110 for inspecting the inner surface, radiation measuring instrument main body 120 for inspecting the inner surface, radiation measuring device 130 for inspecting the inner surface, and motor control operation panel Consisting of (140), it is possible to carry out a radioactive contamination test on the inner and outer sides of the steel pipe scaffold without performing a separate preliminary work to perform a radioactive contamination test on the steel pipe scaffolding 200 used in a nuclear facility. By making it possible, work productivity is significantly improved, work costs are greatly reduced, and inspection work can be performed quickly and accurately, minimizing the risk of radiation exposure to workers while operating forest storage in nuclear facilities more efficiently. There is this.

As described above, in the present invention, specific matters such as specific components and the like have been described by limited embodiments and drawings, but these are provided only to help a more comprehensive understanding of the present invention, and the present invention is not limited to the above embodiments , Anyone having ordinary knowledge in the field to which the present invention pertains can make various modifications and variations from these descriptions.

Accordingly, the spirit of the present invention should not be limited to the described embodiments, and it will be said that not only the claims to be described later, but also all those with equivalent or equivalent modifications to the claims are included in the scope of the spirit of the present invention. .

10: Radioactive contamination inspection device for steel pipe scaffolding used in nuclear facilities
20: Worktable 30: Steel pipe scaffolding guide
40: first transfer roller 50: first drive motor
60: second transfer roller 70: second drive motor
80: detector for external surface inspection
90: body of the radiation measuring instrument for outer surface inspection
100: radiation meter for outer surface inspection
110: detector for the inner surface inspection
120: Radiation measuring instrument main body for inner surface inspection
130: radiation measuring instrument for inner surface inspection 200: steel pipe scaffolding

Claims (5)

A work table 20 having a top plate and a leg portion supporting the top plate;
A plurality of steel pipe scaffold guides 30, which are mounted at regular intervals on a straight line to be left and right opposite to the middle line M on the work table 20, and guide the steel pipe scaffold 200 in the longitudinal direction;
Steel scaffold scaffolding on one side of the steel pipe scaffold guide 30 located on the right side of the middle line of the work table 20 so as to contact the outer circumferential surface of the steel mine scaffold 200 mounted on the steel pipe scaffold guide 30 200) is installed rotatably in a forward and reverse direction to form an angle, and the first transfer roller 40 for rotating and moving the steel pipe scaffold 200 on the steel pipe scaffold guide 30;
A first drive motor 50 mounted on the work table 20 and connected to a rotation axis of the first transfer roller 40 to rotate the first transfer roller 40 forward and backward;
The upper side of one of the steel pipe scaffold guides 30 located on the left side of the middle line M of the work table 20 so as to contact the outer circumferential surface of the steel mine scaffold 200 mounted on the steel pipe scaffold guides 30 A second conveying roller 60 installed parallel to the first conveying roller 40 and rotatable in a forward and reverse direction, and rotating and forward conveying the steel pipe scaffold 200 on the steel pipe scaffold guide 30;
A second drive motor (70) mounted on the work table (20) and connected to a rotation axis of the second conveying roller (60) to rotate the second conveying roller (60) forward and backward;
A detector holder 80 for inspecting an outer surface that is mounted at a position of the midline of the work table 20 and places the detector of the radiation measuring instrument on an upper side of the steel pipe scaffold 200 conveyed on the steel pipe scaffold guide 30;
It is mounted on the work table 20, the radiation measuring instrument main body 90 for outer surface inspection where the radiation measuring instrument body is disposed;
The detection unit 101 is disposed on the outer surface inspection detection unit holder 80 to detect radiation on the outer surface of the steel pipe scaffold 200, and is disposed on the outer surface inspection radiation meter body holder 90 A radiation measuring instrument 100 for inspecting an outer surface composed of a radiation measuring instrument main body 102 that is electrically connected to the detection unit 101 and calculates and displays a detection signal received from the detection unit 101;
Of the steel pipe scaffold guides 30 located on the left side of the middle line M of the work table 20, the middle of the straight line of the steel pipe scaffold guides 30 mounted at the position farthest from the middle line M It is mounted on the work table 20 spaced apart in the distal direction of the line M, and the detection unit holder 110 for inspecting the inner surface for placing the detector of the radiation measuring instrument above the middle line M of the work table 20 ;
A radiation meter body holder 120 for inspecting an inner surface on which the radiation meter body is disposed on the work table 20;
The detection unit 131 is disposed on the inner surface inspection detection unit holder 120 to detect radiation on the inner surface of the steel pipe scaffold 200, and is disposed on the inner surface inspection radiometer body holder 120 A radiation measuring instrument (130) for inspecting an inner surface composed of a radiation measuring instrument body (132) that is electrically connected to the detection unit (131) and calculates and displays a detection signal received by the detection unit (131);
The first and second driving motors 50 and 70 are electrically connected to each other and mounted on the work table 20, and ON/OFF of the first and second driving motors 50 and 70, Radioactive contamination inspection device of a steel pipe scaffold used in a nuclear power facility, characterized in that it consists of a motor control operation panel (140) that controls forward and reverse rotation and speed.
According to claim 1,
The work table 20,
Wheel members (21) mounted on the lower surface of each leg,
An apparatus for inspecting radioactive contamination of a steel pipe scaffold used in a nuclear power facility, characterized by having an auxiliary top plate (22) that is hinged and foldable at both ends.
According to claim 1,
The steel pipe scaffolding guide 30,
The plate-like guide body 31 having both ends vertically bent upward,
It consists of three ball transfer units 32 mounted opposite to the inner bottom surface and both inner surfaces;
Steel pipe scaffolding 200 is disposed between the three ball transfer unit 32, the radioactive contamination inspection device of the steel pipe scaffold used in a nuclear facility, characterized in that the transfer.
According to claim 1,
The detector holder 80 for the outer surface inspection,
A square frame-shaped mounting frame 81 for horizontally supporting the lower edge of the outer surface inspection detecting unit 101.
A steel pipe used in a nuclear power facility, characterized in that it is vertically provided at each corner of the holder 81 and comprises a leg 82 that fixes the holder body 81 on the work table 20. Scaffold radioactive contamination tester.
According to claim 1,
The detector holder 110 for inspecting the inner surface,
A support 111 having a bolt assembly hole 111a at the upper end and fixedly installed on the work table 20,
As a round bar, one end is detachably connected to the bolt assembly hole 111a of the support 111 and is horizontally disposed, and the inner surface inspection detection section of the work table 20 is placed on the middle line of the work table 20. It is composed of a detector mounting table 112 to keep the upper surface and spaced upward;
The detector mount 112,
A screw part 112a detachably screwed to the bolt assembly hole 111a of the support 111 at one end and a cable assembly groove cut in the side part as a tube on the other end, and a detector for inspecting the inner surface is detachable Radioactive contamination inspection device of a steel pipe scaffold used in a nuclear facility, characterized in that it has a detector assembly (112b) that is assembled.

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