KR101602905B1 - Belt type scanner apparatus for non-destructive inspection - Google Patents

Abstract

The present invention relates to a belt type scanner for a non-destructive test. The belt type scanner for a non-destructive test includes: a scanner scanning an object to be tested; a linear moving unit having a scanner holder on which the scanner is mounted and moving in an axial direction of the object; a belt wherein a front end is fixed to one side of the linear moving unit to fix the linear moving unit to the object and a base end encloses the circumference of the object to be clamped to the other side of the linear moving unit; and a tension control unit controlling tension of a belt by being arranged along the belt enclosing the circumference of the object. If the belt is clamped by a control unit of a clamp after the bent encloses the circumference of the object, the belt is fixed by a locking unit not to be untied. Therefore, a preparing process for inspecting the object is simple, and a whole weight of the scanner is light. So, the scanner can be easily carried and moved.

Description

[0001] The present invention relates to a belt scanner for non-destructive inspection,

The present invention relates to a non-destructive inspection belt scanner, and more particularly, to a non-destructive inspection belt scanner capable of quickly fixing a scanner for inspecting an internal crack of an object to be inspected.

In general, non-destructive Testing (NDT) is conducted to ensure uniformity of products through quality control and maintenance inspection of industrial products such as welded products, castings, and rolled materials and to ensure reliability from customers.

Nondestructive inspection is a method of inspecting the exterior of a product without defects such as pores, cracks, and internal defects of the product, without changing the shape or function of the product. Radiographic testing (Radiograpic Testing, Ultrasonic Testing (UT), Magnetic Particle Testing (MT), Liquid Penetrant Testing (PT), Eddy Current Testing (ECT), Leak Test Testing, LT) and Acoustic Emisson Testing (AET).

Among such non-destructive inspection methods, the non-destructive inspection method for inspecting the welding site mainly uses a radiation inspection method. Since such a radiation inspection method has a great risk of exposure to radiation, and because of the deterioration of inspection efficiency due to night work and inconvenience The process control is difficult due to inevitable avoidance in the corresponding industry, and the reliability of the test results is deteriorated particularly in the case of crack defects.

Therefore, in recent years, it is possible to detect minute cracks more easily than a radiation examination method in which the ability such as fine welding cracking and stress cracking is difficult, besides the above problems, and it is possible to improve the efficiency of examination, Ultrasonic flaw detection method is used to obtain various effects such as shortening the entire process period and preventing the radiation exposure accident at the night work.

Ultrasonic inspection is a method to determine the position and size of defects by analyzing energy amount and time of ultrasonic waves reflected from internal defects by transmitting ultrasonic waves to the specimen. It is a method of detecting high pressure steam, In the case of oil or gas-receiving pipes, defects in the welds can cause a great problem, so defect inspection for the welds is important. Accordingly, nondestructive inspection is required for such pipes and ultrasonic inspection is required.

As a prior art of a conventional ultrasonic inspection apparatus, there is a "scanner for automatic nondestructive inspection of piping welds" in Korean Patent Registration No. 10-0961283. The scanner for nondestructive inspection according to this prior art is installed in a linear movement guide means having a probe holder and a probe holder of a linear movement guide means and is electrically connected to a manager computer to inspect the welding portion of the pipe and send the inspection value to the manager computer And a fixing means for fixing the linear movement guiding means and the rotary movement guiding means around the pipe, for rotating the probe along the circumference of the pipe through the probe and the linear movement guiding means.

At this time, the fixing means is composed of a chain, one side of which is fixed to one side of the base block of the rotational movement guide means and the other free end is fixed to the pipe by being fixed to the other side of the base block by winding the pipe.

However, in the scanner for automatic nondestructive inspection of piping welds according to the prior art as described above, the structure is very complicated because the chain is constituted by the fixing means for fixing the linear movement guiding means and the rotational movement guiding means around the pipe, There is difficulty in carrying.

That is, in order to inspect the pipe, the scanner for non-destructive inspection according to the prior art should first fix the linear movement guide means and the rotation movement guide means around the pipe. In this case, the chain must be fixed so as to adhere closely to the circumference of the pipe, so that the linear movement guide means and the rotation movement guide means can move safely. Since the chain has a structure in which unit objects composed of a straight line portion and a joint portion are continuously connected It is difficult to completely close the chain around the pipe.

In addition, even if the chain is brought into close contact with the periphery of the pipe, the scanner for non-destructive inspection according to the prior art has to be adjusted so that the chain and the sprocket wheel installed in the rotation movement guide means are correctly engaged with each other. .

In the scanner for non-destructive inspection according to the prior art, since the chain is required to support the loads of the linear movement guide means and the rotation movement guide means, the chain is made of a metal material of high strength, which is significant in weight and inconvenient for carrying and transporting.

KR 10-0961283 B (2013.01.23)

It is an object of the present invention to provide a belt scanner for nondestructive inspection which can be installed on a test object with a simple structure and can be easily disassembled if necessary.

According to an aspect of the present invention, there is provided a scanner comprising: a scanner for scanning an object to be inspected; a linear movement unit having a scanner holder on which the scanner is mounted and moving in the axial direction of the object to be inspected; A belt whose tip is fixed to one side of the linear movement unit to fix the unit to the object to be inspected and whose base end is clamped to the other side of the linear movement unit by wrapping the periphery of the object to be inspected and a belt surrounding the periphery of the object to be inspected, And a tension adjusting unit for adjusting the tension of the non-destructive inspection belt.

Here, the linear movement unit includes a rail fixed in the axial direction of the object to be inspected and a fastener for linearly moving along the rail and fixing the tip of the belt to the one side, and a clamp for clamping the base of the belt is provided on the other side It is preferable to include a moving block.

The clamp includes a pair of brackets spaced apart from each other by a width of the belt on the other side of the moving block, a rotating shaft provided between the pair of brackets and fixed to the base end of the belt, And a control unit provided at a base end of the rotation shaft and adapted to adjust a rotation angle of the rotation shaft by a user.

The ratchet lever is hinged to a bracket adjacent to the ratchet wheel and has one end engaged with the ratchet wheel to interlock rotation of the rotation shaft in the forward direction. And a torsion spring for returning the ratchet lever in a reverse direction by providing an elastic force to the ratchet lever.

The control unit may include an adjusting lever formed integrally with a base end of the rotating shaft and rotated by a user to rotate the rotating shaft and a stopper formed on the bracket adjacent to the adjusting lever to limit a rotation angle of the adjusting lever desirable.

In addition, the belt is preferably provided with a plurality of steel wires therein.

The tension adjusting unit may include a base plate positioned between the object to be inspected and the belt, a pressing plate facing the base plate so that the belt is interposed therebetween, and a pressing plate provided at the rear of the pressing plate, And a roller provided at both ends of the base plate for rolling contact with the object to be inspected.

Preferably, the pressing plate has a pressing protrusion formed on the surface facing the belt.

Preferably, the roller is provided with a brake pad on a surface in rolling contact with the object to be inspected.

According to the non-destructive inspection belt scanner according to the present invention, when the belt is tightened through the adjusting portion of the clamp after the belt is wound around the object to be inspected, the belt is fixed by the locking portion so as not to be loosened, Simple.

Further, unlike a conventional chain, a belt for fixing a moving block to an object to be inspected is made of a belt, so that the entire weight of the scanner is light, which makes it convenient to carry and move.

1 is a perspective view showing a non-destructive inspection belt scanner according to the present invention.
2 is a side view of a non-destructive inspection belt scanner according to the present invention.
3 is a cross-sectional view showing the line AA in Fig.
4 is a cross-sectional view showing the BB line in Fig.
5 is a cross-sectional perspective view of Fig.
6 is an enlarged perspective view showing a locking part and an adjusting part of a non-destructive inspection belt scanner according to the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor may properly define the concept of the term to describe its invention in the best possible way And should be construed in accordance with the principles and meanings and concepts consistent with the technical idea of the present invention.

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

FIG. 1 is a perspective view showing a non-destructive inspection belt scanner according to the present invention, FIG. 2 is a side view showing a non-destructive inspection belt scanner according to the present invention, and FIG. 3 is a sectional view taken along line A-A of FIG.

The non-destructive inspection belt scanner according to the present invention includes a scanner (not shown) for scanning an object to be inspected T extending in an axial direction such as a bar, a tube, etc., a scanner (not shown) A belt 200 for fixing the linear movement unit 100 to the object to be inspected and a tension adjusting unit 300 for adjusting the tension of the belt 200 wound around the object to be inspected .

In order to check the internal state of the object to be inspected, the scanner irradiates the wavelength energy of the ultrasonic wave or the radiation toward the object to be inspected, receives the wavelength energy reflected therefrom, and detects pores, cracks Lt; RTI ID = 0.0 > defects. ≪ / RTI > For example, the scanner may be an ultrasonic probe, a radiation probe, or the like.

The scanner is mounted on the linear movement unit 100 provided with the scanner holder 150, and the scanner is separated or assembled from the scanner holder 150 as required. The linear moving unit 100 includes a rail 110 and a moving block 120. The rail 110 is provided with an adhesive fixture such as a magnet to fix the rail 110 in the axial direction of the object to be inspected, (T).

The guide groove 112 is formed in the rail 110 so that the movable block 120 can move stably along the rail and the protrusion 122 3) is formed so that the moving block 120 is guided in the guide groove 112 and stably moves along the rail 110 in the axial direction of the object to be inspected.

The moving block 120 is provided with the scanner holder 150 on which the scanner is mounted so that the moving block 120 moves along the rail 110 to inspect the inspection target T. The moving block 120 includes the scanner holder 150, The moving block 120 is moved along the rail 110 in a state where the moving block 120 is separated from the object to be inspected T by providing a wheel 124 on the object to be inspected T, Axis direction.

The moving block 120 moving the scanner in the axial direction of the inspection object T is provided with the fastener 140 and the clamp 130 for fixing the belt 200. [

A clamp 130 for clamping the base end of the belt 200 is provided at one side of the moving block 120 and a fastener 140 for fixing the end of the belt 200 is provided at the other side. When the fastener 140 and the clamp 130 are fixed to the fastener 140 and the clamp 130, respectively, a space is formed between the belt 200 and the moving block 120,

A fastener 140 is disposed at one side of the moving block 120. The fastener 140 includes an insertion groove 142 into which the tip of the belt 200 is inserted and a plate 144 And a fastening hole 146 which is screwed into the insertion groove 142 through the plate 144 and the belt 200 so that the tip of the belt 200 can be fixed to one side of the moving block 120 do.

A clamp 130 is provided on the other side of the moving block 120. The bracket 131 formed on the other side of the moving block 120 is supported by the bracket 131 and rotated, A locking part 133 for interrupting the rotation of the rotary shaft 132 and an adjusting part 134 for controlling the degree of rotation of the rotary shaft 132 by the user. Such a clamp 130 will be described with reference to Figs. 4 to 6. Fig.

FIG. 4 is a cross-sectional view taken along line B-B of FIG. 2, FIG. 5 is a perspective view of FIG. 4, and FIG. 6 is an enlarged perspective view of a lock part and a control part of a non-destructive inspection belt scanner according to the present invention.

The brackets 131 are integrally formed on the other side of the moving block 120 and are formed as a pair spaced apart from each other by a width of the belt 200. The pair of brackets 131 And the rotation shaft 132 is rotatably supported by the bracket 131. The rotation shaft 132 is rotatably supported by the bracket 131. [

The base end of the belt 200 is fixed to the rotation shaft 132 and the belt 200 is wound on the rotation shaft 132 as the rotation shaft 132 rotates to rotate the belt 200 from the fastener 140 to the rotation shaft 132 200).

A locking portion 133 for blocking the rotation of the rotation shaft 132 is provided at the tip of the rotation shaft 132. A base end of the rotation shaft 132 is connected to a control portion 134 Is installed.

The ratchet wheel 133a is provided with a ratchet wheel 133a and a ratchet lever 133b and a torsion spring 133c. The ratchet wheel 133a is integrally formed with the tip of the rotation shaft 132, And teeth are formed on the outer diameter thereof to rotate in the same direction as the rotation of the rotation shaft 132. [

The ratchet lever 133b is hinged to the bracket 131 adjacent to the ratchet wheel 133a so that the ratchet lever 133b is pivoted about the hinge and one end of the ratchet lever 133b is rotated by the ratchet wheel 133b 133a to rotate the rotation shaft 132 in the forward direction.

That is, when the ratchet wheel 133a is engaged with the ratchet lever 133b, the rotation shaft 132 rotates only in the forward direction. When the ratchet wheel 133a and the ratchet lever 133b are disengaged, As shown in FIG.

The ratchet lever 133b, which is engaged with the ratchet wheel 133a and interlocks with the rotation direction of the rotation shaft 133b, is provided with a torsion spring 133c and is provided with an elastic force for returning the ratchet lever 133b in the reverse direction.

That is, the torsion spring 133c is interposed in the hinge of the ratchet lever 133b, one end of the torsion spring 133c is fixed to the ratchet lever 133b, and the other end is fixed to the bracket 131, The one end of the ratchet lever 133b is held in meshing engagement with the teeth of the ratchet wheel 133a by the elastic force provided by the torsion spring 133c.

On the other hand, at the base end of the rotation shaft 132, an adjustment unit 134 is provided to adjust the rotation angle of the rotation shaft 132 by a user's operation.

The adjusting portion 134 is formed integrally with the base end of the rotating shaft 132 and is formed in the bracket 131 adjacent to the adjusting lever 134a and the adjusting lever 134a that is rotated by the user to rotate the rotating shaft 132. [ And a stopper 134b for limiting the rotation angle of the control lever 134a. When the user rotates the control lever 134a, the rotation shaft 132 rotates in the same manner.

The movable block 120 is moved along the rail 110 in the axial direction of the object to be inspected T and then the movable block 120 is moved in the axial direction of the object to be inspected T, The user first releases the locking part 133 of the clamp 130 so that the rotation shaft 132 can be rotated in the forward or reverse direction and then the control lever 134a So that the rotating shaft 132 winds the belt 200 to closely contact the belt 200 around the object to be inspected.

The ratchet lever 133b is engaged with the teeth of the ratchet wheel 133a by the elastic force provided by the torsion spring 133c of the lock portion 133 so that the rotation axis 132 is not arbitrarily rotated, And is fixed to the object T to be inspected.

Conversely, after the scanning of the object to be inspected by the scanner is completed, the ratchet wheel 133a is operated by operating the ratchet lever 133b of the locking part 133 to move the mobile block 120 for inspection at another point, The control lever 134a of the regulating portion 134 is operated by a user to loosen the belt 200. [

After moving the moving block 120 along the rail 110 and positioning the moving block 120 at a position to be inspected, the user moves the adjusting block 134 to fasten the moving block 120 by tightening the belt 200 .

Such a clamp 130 is operated by a user to move the movable block 120 along the rail in the axial direction of the object to be held in a stopped state at a certain portion. At this time, Since the belt 200 is tightly adhered to the periphery of the object to be inspected or loosened by only the operation of the belt 134, the movement block 120 can be quickly fixed and the preparation time for inspection can be shortened.

Meanwhile, the belt 200, which surrounds the inspection object T and fixes the moving block 120 to the object to be inspected, is provided with a plurality of steel wires therein, so that when the belt 200 is fastened to the object to be inspected, .

In the non-destructive inspection belt scanner of the present invention, the tension adjusting unit 300 is disposed along the belt 200 so as to control the tension of the belt 200 surrounding the periphery of the inspection object T so that an excessive tension is not generated .

3, the tension adjusting unit 300 includes a base plate 310, a pressing plate 320, an elastic member 330, and a roller 340 as shown in the enlarged view of FIG. The base plate 310 is disposed between the object to be inspected T and the belt 200 and is provided with rollers 340 that are in rolling contact with the object to be tested on both sides of the base plate 310.

At this time, on the outer circumferential surface of the roller 340, a brake pad 341 having a high coefficient of friction such as urethane and exhibiting an elastic restoring force is formed. When the brake pad 341 is formed on the outer circumferential surface of the roller 340 as described above, it is possible to prevent the friction between the roller 340 and the object to be inspected when sliding the movable block 120 to the object to be inspected, T, the brake pad 341 is resiliently deformed when the belt 200 is tightened with an excessive pressure, thereby preventing the inspection object T from being damaged.

The pressing plate 320 faces the base plate 310 and the belt 200 is positioned between the base plate 310 and the pressing plate 320. An elastic member 330 is provided at the rear of the pressing plate 320 to provide an elastic force so that the pressing plate 320 can be pressed toward the base plate 310. An elastic member 330 is provided at the rear of the elastic member 330, A cover 350 is provided to support the pressing plate 330 so as to provide an elastic force toward the pressing plate 320.

When the pressing plate 320 presses the belt 200 by means of the elastic member 330, the pressing plate 320 presses the elastic member 330 against the belt 200, The pressing force exerted on the pressing protrusion 321 is concentrated on the pressing protrusion 321 so that the belt 200 can be more stably fixed.

When the tension adjusting unit 300 includes the base plate 310, the pressing plate 320, the elastic member 330 and the roller 340 as described above, the belt 200 is wound on the object to be inspected and is clamped by the clamp 130 The pressing plate 320 presses the belt 200 by the elastic member 330 of the tension adjusting unit 300 to prevent the tension adjusting unit 300 from moving arbitrarily on the belt 200 .

Since the belt 200 at the portion where the tension adjusting unit 300 is installed is spaced apart from the outer circumferential surface of the object to be inspected T so that the contact surface between the belt 200 and the object to be inspected is minimized, (120) can be fixed to the object to be inspected (T).

Therefore, when the tension is excessively applied to the belt 200, the brake pad 341 provided on the roller 340 is fully buffered to properly buffer the tension of the belt 200, so that the belt 200 is damaged .

According to the nondestructive inspection belt scanner of the present invention having the above configuration, after the belt 200 is wound around the object to be inspected T, the belt 200 is tightened through the adjusting portion 134 of the clamp 130 The belt 200 is fixed by the locking part 133 so as not to be loosened, so that the preparation process and the disassembly for inspecting the inspection object T are simple.

Unlike a conventional chain, the belt 200 for fixing the moving block 120 to an object to be inspected is made of a belt 200 such as a fabric, so that the entire weight of the scanner is light and the conveying and moving is convenient.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. .

100: linear movement unit 110: rail
120: moving block 130: clamp
131: Bracket 132:
133: locking portion 133a: ratchet wheel
133b: ratchet lever 133c: torsion spring
134: adjusting part 134a: adjusting lever
134b: stopper 140: fastener
200: Belt 300: Tension control unit
310: base plate 320: pressure plate
321: pressing projection 330: elastic member
340: roller 341: brake pad

Claims (9)

A scanner for scanning the object to be inspected;
A linear moving unit having a scanner holder on which the scanner is mounted and moving in the axial direction of the object to be inspected;
A belt whose tip is fixed to one side of the linear movement unit so as to fix the linear movement unit to the object to be inspected and whose base end is wrapped around the object to be inspected and clamped to the other side of the linear movement unit; And
And a tension adjusting unit disposed along a belt surrounding the periphery of the object to be inspected and controlling the tension of the belt to rotate or stop the linear motion unit about the periphery of the object to be inspected,
The tension adjusting unit includes:
A base plate positioned between the object to be inspected and the belt; A pressing plate facing the base plate with the belt interposed therebetween; An elastic member provided on the rear side of the pressing plate to provide an elastic force so that the pressing plate presses the belt; And a roller provided at both ends of the base plate and in rolling contact with an object to be inspected, wherein the pressing plate has a pressing protrusion formed on a surface facing the belt, A pad is provided,
The linear movement unit includes:
A rail fixed in the axial direction of the object to be inspected; And a moving block provided with a fastener for linearly moving along the rail and fixing the tip of the belt to one side and a clamp for clamping a base end of the belt on the other side of the rail, A guide groove is formed so as to be movable, and a protrusion is formed in the moving block in conformity with the guide groove,
Wherein the tension adjusting unit is provided with a plurality of spaced apart portions along the periphery of the inspected object,
When the diameter of the object to be inspected changes, the length of use of the belt surrounding the object to be inspected changes, and the number of the tension adjusting units disposed along the belt is increased or decreased, or the interval between the tension adjusting units is adjusted Wherein the belt scanner is a belt scanner for non-destructive inspection.
delete The method according to claim 1,
The clamp
A pair of brackets spaced apart from each other by a width of the belt on the other side of the moving block;
A rotating shaft installed between the pair of brackets and fixing a base end of the belt;
A locking portion provided at a tip of the rotary shaft for controlling the rotation of the rotary shaft; And
And an adjusting unit installed at a base end of the rotating shaft to adjust a rotation angle of the rotating shaft by a user.
The method of claim 3,
The locking portion
A ratchet wheel integrally formed with a tip of the rotary shaft;
A ratchet lever hinged to the bracket adjacent to the ratchet wheel and having one end engaged with the ratchet wheel to interlock rotation of the rotation shaft in the forward direction;
And a torsion spring for applying an elastic force to the ratchet lever and returning the ratchet lever in a reverse direction.
The method of claim 3,
The control unit includes:
An adjustment lever formed integrally with a base end of the rotation shaft and rotated by a user to rotate the rotation shaft; And
And a stopper formed on the bracket adjacent to the adjustment lever to limit a rotation angle of the adjustment lever.
The method according to claim 1,
Wherein the belt is provided with a plurality of steel wires therein.
delete delete delete

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