KR102017273B1 - Ultrasonic Inspector Assemble - Google Patents

Abstract

The present invention provides an ultrasonic probe assembly coupled to a slide groove formed in the gas of the ultrasonic flaw detector, a pair of first insertion portions formed on one side and inserted into the slide groove, a coupling portion formed on the other side, A body having an incision groove formed between the first insertion portion of the pair, a coupling female screw portion which is slidably coupled to the incision groove and formed along an axial direction from the top, and a second position positioned between the pair of first insertion portions A movable body having a movable body having an insertion portion, a fastening male screw portion penetrating the upper portion of the body to be fastened to the fastening female screw portion, a head portion formed at one end of the fastening male screw portion, a support frame coupled to the coupling portion, and a support frame A pair of support rings spaced apart from the inner circumferential surface, a coil spring provided between the pair of support rings, a holder installed at a lower end of the support frame, and a holder It is rotatably coupled and includes a wedge having a probe and a water supply pipe, and the pair of first insertion portions are formed with a first locking portion engaged with an inner side of the slide groove, and the second insertion portion has an inner inner side of the slide groove. It characterized in that the second locking portion is formed to be caught.

Description

Ultrasonic Transducer Assemblies {Ultrasonic Inspector Assemble}

The present invention relates to an ultrasonic probe assembly installed in an ultrasonic flaw detector.

In general, butt welding of a thick plate to which the high heat input single side welding is applied, solidification cracks are generated near the edge of the plate where the welding is completed, and then the non-destructive inspection is confirmed after the welding is completed.

At this time, the ultrasonic flaw detection method is most often used as a test method for checking the presence or absence of a weld defect.

Ultrasonic Examination is a non-destructive test that detects surface and internal defects by sending high frequency sound waves into the material to be inspected. By analyzing the energy amount of the ultrasonic wave reflected from the discontinuity, the running time of the ultrasonic wave, etc., the position and size of the discontinuity can be accurately determined.

Ultrasonic examination is a method to check the discontinuity existing inside the test specimen. It is most widely used with radiographic examination, but it can be easily inspected even if the thickness of the test specimen is thick. have.

In addition, the information that can be obtained during the ultrasonic examination is made through reflection, refraction, diffraction and interference due to the nature of the ultrasonic wave, reflection from the discontinuity in the test body, reflection at the interface between the solid and the gas, and at the interface between the solid and the liquid. The pulse-reflection method through the reflector of is mainly used.

Ultrasonic testing in industrial applications is used to detect laminations, cracks and inclusions in discontinuous parts of the base material as well as to detect pores, cracks, inclusions and fatigue cracks that may occur during processing (welding, casting, etc.) or during use. Used. In addition, it can be used in many fields ranging from steel as well as bridges made of non-steel materials, steel structures, shipbuilding, pressure vessels, and general mechanical parts.

According to the structure of a conventional ultrasonic flaw detector for inspecting weld defects on the hull, an ultrasonic probe is coupled to a gas that is capable of driving by a motor, and the transducer moves close to the surface of an inspected object when the gas is driven. Structures are known which allow inspection of weld defects.

In the conventional art of the structure, when the surface of the inspected object is uniform, the accuracy of inspection is high, but when the surface of the inspected object has a bend, irregularities, or stepped surface, the probe is lifted up and the defect cannot be detected properly. there was.

In addition, the method of coupling the ultrasonic transducer to the gas is inserted into the coupling portion provided on one side of the ultrasonic probe through the end of the slide groove formed in the gas and then moved along the slide groove to fix the ultrasonic transducer to a desired position. There is a problem that takes a long time when replacing.

In addition, when a part of the slide groove is damaged, there is a problem that the ultrasonic transducer cannot move along the slide groove so that the ultrasonic transducer cannot be positioned at a desired position.

An object of the present invention is to provide an ultrasonic transducer assembly that can improve the accuracy of the inspection by preventing the floating between the probe and the inspected object to solve the problems as described above.

In addition, an object of the present invention is to provide an ultrasonic probe assembly capable of simply and quickly coupling an ultrasonic probe assembly to a gas of an ultrasonic flaw detector, thereby improving workability.

It is also an object of the present invention to provide an ultrasonic probe assembly capable of detecting a defect present at right angles to the axial direction of a welded portion of an inspection object.

The ultrasonic probe assembly according to the embodiment is an ultrasonic probe assembly coupled to a slide groove formed in the gas of the ultrasonic flaw detector, and is formed on one side of the pair of first insertion portions inserted into the slide groove and formed on the other side Between the coupling portion, a body having a cutout groove formed between the pair of first insertion portions, the coupling female screw portion coupled to the cut groove to be slidably moved along the axial direction from the top, between the pair of first inserting portions A moving body having a second inserting portion positioned in the body, a fastening male screw portion penetrating the upper portion of the body to be fastened to the fastening female screw portion, a moving body adjusting device having a head portion formed at one end of the fastening male screw portion, and a supporting frame coupled to the coupling portion And a pair of support rings spaced apart from the inner circumferential surface of the support frame, a coil spring provided between the pair of support rings, and a lower portion of the support frame. A holder installed at the end and rotatably coupled to the holder, the wedge having a probe and a water supply pipe, wherein the pair of first insertion portions are formed with a first locking portion engaged with one side of the slide groove; The second insertion portion is characterized in that the second locking portion is formed on the other inner side of the slide groove is formed.

According to the embodiment, the coupling portion has rail guides formed with slide protrusions on both sides thereof, and slide grooves coupled to the slide protrusions are formed on both side surfaces of the support frame.

According to an embodiment the support frame is located between the rail guide and the holder in the axial direction.

According to the embodiment having the above-described configuration, it is possible to prevent the floating between the probe and the inspected object to improve the accuracy of the inspection.

In addition, the ultrasonic probe assembly can be easily and quickly coupled to the gas of the ultrasonic flaw detector, thereby improving the workability.

In addition, defects existing at right angles to the axial direction of the welded portion of the inspection object can be detected, thereby improving the reliability of the inspection.

1 is a perspective view showing an ultrasonic transducer assembly according to an embodiment of the present invention.
Figure 2 is an exploded perspective view of the ultrasonic transducer assembly according to an embodiment of the present invention.
3 is a perspective view showing a modified embodiment of the body shown in FIG.
Figure 4 is a perspective view showing a coupled state of the body and the moving body according to the embodiment of the present invention.
5 is an exploded perspective view of the body and the moving body shown in FIG.
6 is a view showing an operation in which the body and the moving body shown in FIGS.
7 is a side view showing a state of use of the ultrasonic transducer assembly according to an embodiment of the present invention.

Embodiments of the present invention will be described in more detail with reference to the accompanying drawings. In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of description.

In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to the intention or convention of a user or an operator. Therefore, definitions of these terms should be made based on the contents throughout the specification.

1 is a perspective view showing an ultrasonic transducer assembly according to an embodiment of the present invention, Figure 2 is an exploded perspective view showing an ultrasonic transducer assembly according to an embodiment of the present invention, Figure 3 is a modified embodiment of the body shown in Figure 2 4 is a perspective view illustrating a coupling state of a body and a moving body according to an embodiment of the present invention, FIG. 5 is an exploded perspective view of the body and the moving body shown in FIG. 4, and FIG. The drawing shows the operation of the body and the moving body being coupled to the gas.

Referring to this, the ultrasonic probe assembly 100 according to the embodiment is coupled to the slide groove 12 formed in the base 10 of the ultrasonic flaw detector (not shown), so that the ultrasonic flaw detector 2 is welded to the inspected object 1. As a test for defects in the welded part 2 when traveling in the axial direction of the body, the body 110, the moving body 120, the moving body adjusting device 130, the support frame 140, the support ring 142, coil spring 144, holder 150, and wedge 160.

The body 110 is coupled to the slide groove 12 formed in the base 10.

On one side of the body 110, a pair of first insertion parts 112 inserted into the slide grooves 12 are formed to be spaced apart, and on the other side, the coupling parts 114 are welded parts 2 of the inspected object 1. It is formed to face).

In addition, the coupling portion 114, as shown in Figure 3, one surface may be formed to be inclined at a predetermined angle.

The reason for forming the inclined surface of the coupling portion 114 as shown in FIG. 7 is that the support frame 140 coupled to the coupling portion 114 to be described later as shown in FIG. 7 is in the axial direction of the welded portion 2 of the inspection object 1. A defect in which the wedge 160 coupled to the lower end of the support frame 140 by the holder 150 to be inclined at a predetermined angle with respect to the axial direction of the welded portion 2 of the inspection object 1 exists at right angles. To be detected.

It is easily detected when the position of the defect in the welded portion 2 intersects the transmission direction of the ultrasonic wave at right angles due to the characteristics of the ultrasonic wave, but the position of the defect in the welded portion 2 is parallel to the transmission direction of the ultrasonic wave. If there is no detection, the coupling part 114 is inclined at a predetermined angle, so that a defect existing in the welding part 2 can be detected even if it exists at right angles to the axial direction of the welding part 2.

In addition, a cutting groove 116 having a predetermined length and a predetermined depth is formed between the pair of first insertion parts 112, and a guide groove 116a is formed inside the cutting groove 116.

The moving body 120 is coupled to the slide groove 116 to be moved. The fastening female screw 122 is formed in the center of the moving body 120 along the axial direction from the top, and is located between the pair of the first inserting portions 112 on one side thereof and has a pair of the first inserting portions ( A second inserting portion 124 is formed to be inserted into the slide groove 12 together with 112.

Here, the pair of first inserting portion 112 is formed with a first catching portion 112a that is caught on one side of the slide groove 12, and the second inserting portion 124 has an inner portion of the slide groove 12. The second locking portion 124a that is locked to the other side is formed.

That is, as shown in FIGS. 4 and 5, the first locking portion 112a and the second locking portion 124a are alternately formed with respect to the slide groove 12.

As described above, since the first catching portion 112a and the second catching portion 124a are formed in the first inserting portion 112 and the second inserting portion 124, respectively, staggered with respect to the slide groove 12. In the state where the insertion part 112 and the second insertion part 124 are inserted into the slide groove 12, as shown in FIG. 6, the moving part 120 slides through the moving part adjusting device 130 described later. The first locking portion 112a and the second locking portion 124a are respectively fixed to one side and the other side of the slide groove 12 while the body 110 is firmly coupled to the base 10.

The other side of the movable body 120 is formed with a guide protrusion (120a) coupled to the guide groove 116a formed inside the incision groove 116 so that the movable body 120 can be moved along the incision groove 116 .

In addition, one end of the spring is supported on one side of the inside of the incision groove 116, and the other end is supported on one side of the moving body 120 facing the inner one side of the incision groove 116. (S) may be provided (see FIG. 6).

This spring (S) as shown in Figure 6, by applying an elastic force in a direction away from the moving body adjusting device 130, which will be described later the moving body 120 is moved by the moving body control device 130 When moved in a direction away from the moving body control 130, it can be moved more easily.

The movable body adjusting device 130 allows the movable body 120 coupled to the incision groove 116 to slide along the incision groove 116 and passes through the upper portion of the body 110 to form a fastening female screw formed in the movable body 120. A fastening male screw portion 132 fastened to the portion 122 and a head 134 formed at one end of the fastening male screw portion 132.

The support frame 140 has a rectangular plate shape and is coupled to the coupling part 114.

In addition, the support frame 140 may be coupled to the coupling unit 114 so as to be slidably movable. In this case, the coupling unit 114 has a rail guide 118 having slide protrusions 118a formed at both sides thereof, and the bolt (B). Is installed through, the both sides of the support frame 140 is formed with a slide groove (140a) coupled to the slide projection (118a).

In addition, a pair of support rings 142 are spaced apart in the support frame 140 in the axial direction of the support frame 140, and a coil spring 144 is provided between the pair of support rings 142. It is possible.

At this time, any one of the pair of support rings 142 is located at the bottom of the rail guide 118, the other is located at the top of the holder 150 to be described later.

In addition, a protrusion 142a coupled to the slide groove 140a formed in the support frame 140 is formed on each inner circumferential surface of the pair of support rings 142.

A stopper 146 is installed at the top of the support frame 140 through a bolt B and a nut N. The stopper 146 moves the ultrasonic flaw detector installed with the ultrasonic probe assembly 100 to another place. For example, when moving, the support frame 140 is not separated from the rail guide 118 by its own weight.

Holder 150 is hinged through the bolt (B) and the nut (N) to be rotated in the axial direction of the support frame 140 to the bottom of the support frame 140, a pair of wings 152 on both sides It is formed to protrude in parallel.

Wedges 160 are hinged to the ends of the pair of wings 152 formed on both sides of the holder 150, respectively.

In addition, the wedge 160 includes a probe 162 for generating an ultrasonic wave to be delivered to the surface of the inspected object 1 and water, which is a medium for allowing the ultrasonic wave generated from the probe 162 to be transmitted to the inspected object 1. The water supply pipe 164 for supplying the inside of the wedge 160 is provided.

In addition, the bottom surface of the wedge 160 may be provided with a magnetic material 166, which is welded when the ultrasonic probe assembly according to the present invention is moved along the welded portion 2 of the inspected object 1 together with the ultrasonic flaw detector. If the surface of (2) is not uniform, the wedge 160 is not separated from the surface of the weld (2).

Although embodiments of the present invention have been described above with reference to the accompanying drawings, those skilled in the art may variously modify and change the present invention without departing from the spirit of the invention as set forth in the claims below. I can understand that.

110; Body 142a; spin
112; First inserting portion 144; Coil spring
112a; First catching portion 146; stopper
114; Coupling part 150; holder
116; Incision groove 152; A pair of wings
116a; Guide groove 160; Wedge
118; Rail guide 162; Transducer
118a; Slide protrusion 164; Water supply pipe
120; Mobile 166; Magnetic material
120a; Guide protrusion
122; Tightening female thread
124; 2nd insert
124a; Second catching part
130; Mobile control
132; Tightening Male Thread
134; Head
140; Support frame
140a; Slide groove
142; A pair of support rings

Claims (5)

An ultrasonic probe assembly coupled to a slide groove formed in the gas of the ultrasonic flaw detector,
A body having a pair of first insertion parts spaced apart from one side and inserted into the slide groove, a coupling part formed on the other side, and a cutout groove formed between the pair of first insertion parts;
A movable body coupled to the cutting groove so as to be slidably moved, the movable body having a fastening female screw portion formed along an axial direction from an upper portion thereof, and a second inserting portion positioned between the pair of first inserting portions;
A moving body adjusting mechanism having a fastening male screw portion which penetrates the upper portion of the body and fastened to the fastening female screw portion, and a head portion formed at one end of the fastening male screw portion;
A support frame coupled to the coupling part;
A pair of support rings spaced apart from an inner circumferential surface of the support frame;
A coil spring provided between the pair of support rings;
A holder installed at a lower end of the support frame; And,
A wedge rotatably coupled to the holder and having a probe and a water supply pipe;
The pair of first inserting portions may be formed with a first catching portion that is caught inside one side of the slide groove, and the second inserting portion may have a second catching portion that is caught inside the other side of the slide groove. Ultrasonic transducer assembly.
The method according to claim 1,
The coupling portion is provided with a rail guide formed with slide projections on both sides,
Ultrasonic transducer assembly, characterized in that the slide groove is formed on both sides of the support frame coupled to the slide projection.
The method according to claim 2,
And the support frame is positioned between the rail guide and the holder in an axial direction.
The method according to claim 1,
Ultrasonic transducer assembly, characterized in that the magnetic body is provided on the bottom surface of the wedge.
The method according to claim 1,
Ultrasonic transducer assembly, characterized in that the coupling portion is formed inclined one surface.

Images