KR102331285B1 - Magnetizing electrode device for nondestructive inspecting equipment with adjustable spacing between electrodes - Google Patents

Abstract

Provided is a magnetizing electrode device for non-destructive inspecting equipment, capable of adjusting the space between electrodes. The magnetizing electrode device constituting equipment for inspecting surface defects of an inspected object made of ferromagnetic material comprises: a first insulating body electrically non-conductive and provided with a slide groove in a longitudinal direction, whose cross-section is non-circular; a second insulating body electrically non-conductive and slidably coupled to the first insulating body along the slide groove; a first electrode having one end coupled to the first insulating body and extending in a cantilever shape perpendicular to the longitudinal direction of the first insulating body; a second electrode having one end coupled to the second insulating body and disposed parallel to the first electrode; a screw shaft disposed along a central axis of the slide groove and installed in the first insulating body to be rotatable; a screw groove screwed to the screw shaft and formed along a central axis of the second insulating body; a space control motor installed in the first insulating body and rotating the screw shaft; a toggle switch installed on the first insulating body and configured to control driving of the space control motor; and an energization switch configured to control supply of electricity to the first electrode and the second electrode.

Description

Magnetizing electrode device for nondestructive inspecting equipment with adjustable spacing between electrodes

The present invention relates to a non-destructive testing device, and more particularly, to a magnetizing electrode device for magnetizing the surface of a welded portion of an iron plate, which is a ferromagnetic material.

Non-destructive inspection is a method of inspecting the integrity, surface condition, cracks, etc. without destroying the workpiece, member, or structure in the manufacturing field.

Examples of the non-destructive inspection method include a magnetic inspection method, a radiographic method, an ultrasonic inspection method, a penetrant inspection method, and the like.

Magnetic flaw detection is a method of inspecting product defects using ferromagnetic fine particles. First, a magnetic field is applied to the product by contacting the spaced electrodes on the product surface. In that state, the ferromagnetic particles are sprayed on the surface of the product either directly (dry) or mixed with water or oil (wet). Accordingly, it can be observed that the ejected ferromagnetic particles are gathered along the defects on the surface of the product. These aggregated particles generally represent the shape or size of the defect. Subsurface defects can also be found in this way if they are not deep in the surface. In the process of performing magnetic inspection, particles colored with dyes are sometimes used for clearer observation.

Radiography is a method of inspecting defects inside a product using X-rays or radioactive isotopes. In industrial sites, it is mainly used to inspect defects in welds.

The ultrasonic inspection method is a method of inspecting the internal defects of a product by using the property of reflection when the ultrasonic beam applied to the product encounters internal defects such as cracks. Ultrasound for inspection is transmitted to the test object through an intermediate medium such as water, oil, glycerin, or grease. Ultrasonic inspection has excellent permeability and sensitivity, and is used to inspect defects in large objects such as train wheels, pressure vessels, and molds from various directions.

Penetration inspection is a method of inspecting defects such as surface cracks, overlapping areas, and pores by applying a liquid to the surface of a product and examining the penetration into the interior through open gaps on the surface. Penetrants can seep into cracks as small as 0.1 micrometers in width. Commonly used penetrants are fluorescent penetrants that fluoresce in ultraviolet light and visible penetrants that show clear outlines on the surface using mainly red dye. In the penetrant inspection method, the surface to be inspected is first cleaned and dried, and then the penetrating solution is applied to the surface with a brush or sprayed. After waiting enough time for the liquid to seep into the open cracks on the surface, the liquid remaining on the surface is wiped off with water or solvent. Then, a developer is added so that the penetrating solution flows backwards to the surface and spreads over the edges of the open gaps on the surface. By irradiating the visible penetrating solution (directly) or ultraviolet light and observing the fluorescent penetrating solution, the location and size of the defect are inspected.

Among these non-destructive inspection methods, the magnetic flaw detection method is widely used to inspect the surface and subsurface integrity of the ferromagnetic steel structure. In general, equipment for performing magnetic flaw detection requires lighting for visually observing the surface of the product, a magnetizing electrode that generates a magnetic field to magnetize the surface of the product, and a spray nozzle for spraying magnetic particles on the surface of the product. Conventionally, in order to perform magnetic flaw detection, an operator holds each magnetizing electrode separated from each other and touches the surface of the ferromagnetic product to conduct a strong current to generate a circular magnetic field centered on the magnetizing electrode, thereby permanently magnetizing the surface of the ferromagnetic product, and then generating magnetic particles. The product surface was inspected for defects by spraying and observing the distribution of magnetic particles. However, since the conventional magnetizing electrode device cannot control the distance between the electrodes, it is necessary to draw a guide line for the examination on the surface of the subject, and then perform the examination along the guide line. Accordingly, there is a problem in that the inspection workability is deteriorated.

001 KR 20-2019-0002606 A (2019.10.18)

It is an object of the present invention to provide a magnetized electrode device for a non-destructive inspection device with remarkably improved workability by improving the structure of a magnetizing electrode device for performing a magnetic flaw detection method, which has been devised to solve the above problems. there is

In order to achieve the above object, a magnetizing electrode device for a non-destructive testing device capable of adjusting the inter-electrode spacing according to the present invention is a magnetizing electrode device constituting an equipment for inspecting surface defects of an object to be inspected made of a ferromagnetic material,

a first insulating body electrically non-conductive and provided with a slide groove of a non-circular cross-section in a longitudinal direction;

a second insulating body electrically non-conductive and slidably coupled to the insulating body along the slide groove;

a first electrode having one end coupled to the first insulating body and extending in a cantilever shape perpendicular to the longitudinal direction of the first insulating body;

a second electrode having one end coupled to the second insulating body and disposed parallel to the first electrode;

a screw shaft disposed along the central axis of the slide groove and rotatably installed on the first insulating body;

a screw groove portion screwed to the screw shaft and formed along a central axis of the second insulating body;

a gap adjusting motor installed on the first insulating body and rotating the screw shaft;

a toggle switch installed on the first insulating body and controlling the driving of the interval control motor; and

It is characterized in that it includes a energization switch for controlling the supply of electricity to the first electrode and the second electrode.

a first spray nozzle installed on the first insulating body to spray magnetic particles; and

a second spray nozzle installed on the second insulating body to spray magnetic particles;

The center line of the first injection nozzle and the center line of the second injection nozzle are respectively arranged to be closer to each other as the distance from the first insulating body and the second insulating body in the longitudinal direction of the first electrode increases,

Preferably, the first insulating body is provided with an injection switch for simultaneously controlling the opening and closing of the first injection nozzle and the second injection nozzle.

The first electrode is detachably coupled to the first insulating body,

Preferably, the second electrode is detachably coupled to the second insulating body.

It is preferable that a distance indicator for indicating the distance between the first electrode and the second electrode is provided on the surface of the second insulating body.

In the magnetizing electrode device for a non-destructive testing device capable of adjusting the inter-electrode spacing according to the present invention, the distance between the first and second electrodes can be automatically adjusted by the interval adjusting motor, so the spacing between the magnetizing electrodes according to the shape of the object to be inspected Since it can be easily changed, it provides the effect of remarkably improving workability when performing the magnetic flaw detection method.

1 is a cross-sectional view showing the structure of a magnetizing electrode device according to a preferred embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along line II-II shown in FIG. 1 .
FIG. 3 is a view showing a state in which the first electrode and the second electrode are maximally spaced apart from each other in FIG. 2 .
4 is a view showing a state in which the shapes of the first electrode and the second electrode are replaced with different structures according to another embodiment of the present invention.

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

1 is a cross-sectional view showing the structure of a magnetizing electrode device according to a preferred embodiment of the present invention. FIG. 2 is a cross-sectional view taken along line II-II shown in FIG. 1 . FIG. 3 is a view showing a state in which the first electrode and the second electrode are maximally spaced apart from each other in FIG. 2 . 4 is a view showing a state in which the shapes of the first electrode and the second electrode are replaced with different structures according to another embodiment of the present invention.

1 to 4 , the magnetizing electrode device 10 (hereinafter referred to as “magnetizing electrode device”) for a non-destructive testing device capable of adjusting the inter-electrode spacing according to a preferred embodiment of the present invention includes a first insulating body 20 ), a second insulating body 30, a first electrode 40, a second electrode 50, a screw shaft 24, a screw groove part 32, a spacing adjusting motor 26, It includes a toggle switch 70 , an energization switch 80 , a first injection nozzle 61 , a second injection nozzle 62 , and an interval indicator 100 .

The magnetizing electrode device 10 is a magnetizing electrode device constituting a device for inspecting a surface defect of an inspected object made of a ferromagnetic material.

The first insulating body 20 is made of an electrically non-conductive material. The first insulating body 20 may be a rod-shaped structure. The first insulating body 20 is provided with a slide groove portion 22 of a non-circular cross-section in the longitudinal direction. A cross-section of the slide groove portion 22 may be, for example, a rectangle. The first insulating body 20 may be provided with a handle.

The second insulating body 30 is made of an electrically non-conductive material. The second insulating body 30 is slidably coupled to the second insulating body 30 along the slide groove portion 22 .

One end of the first electrode 40 is coupled to the first insulating body 20 . For example, an upper end of the first electrode 40 may be coupled to a lower portion of the first insulating body 20 . The first electrode 40 extends in a cantilever shape perpendicular to the longitudinal direction of the first insulating body 20 . The first electrode 40 may be made of copper, which is an electrically good conductor.

One end of the second electrode 50 is coupled to the second insulating body 30 . The second electrode 50 may be disposed parallel to the first electrode 40 . The second electrode 50 may be made of the same material as the first electrode.

The screw shaft 24 is disposed along a central axis of the slide groove portion 22 . The screw shaft 24 is rotatably installed on the first insulating body 20 .

The screw groove portion 32 is formed along the central axis of the second insulating body 30 . The screw groove portion 32 is screwed to the screw shaft 24 . Accordingly, as the screw shaft 24 rotates, the second insulating body 30 moves forward or backward along the slide groove portion 22 .

The interval adjusting motor 26 is installed on the first insulating body 20 . For example, the distance adjusting motor 26 may be installed inside the first insulating body 20 . The output shaft of the interval control motor 26 may be directly connected to one end of the screw shaft 24 or via a speed reducer. Electrical energy for driving the spacing adjusting motor 26 is supplied from the outside of the magnetizing electrode device 10 through an electric wire. The interval adjusting motor 26 rotates the screw shaft 24 . The screw shaft 24 rotates forward or reverse in place.

The toggle switch 70 is installed on the first insulating body 20 . The toggle switch 70 is electrically connected to the interval control motor 26 to control driving of the interval control motor 26 .

The energization switch 80 is a switch for controlling the supply of electricity to the first electrode 40 and the second electrode 50 . The energization switch 80 may be a push button switch. The energization switch 80 is preferably operated so that the first electrode 40 and the second electrode 50 are energized in a state in which they are in uniform pressure contact with the surface of the subject. The electrical connection relationship between the energization switch 80 and the first electrode 40 and the second electrode 50 may employ a known structure, and thus a detailed description thereof will be omitted.

The first injection nozzle 61 is installed on the first insulating body 20 . The first spray nozzle 61 is a device for spraying magnetic particles supplied from an external magnetic particle tank (not shown) toward the surface of the subject. The first injection nozzle 61 and the magnetic particle tank are connected through a hose. The first injection nozzle 61 is preferably installed in a longitudinal direction and an inclined direction of the first electrode 40 .

The second injection nozzle 62 is installed on the second insulating body 30 . The second spray nozzle 62 is a device for spraying magnetic particles supplied from an external magnetic particle tank (not shown) toward the surface of the subject. The second injection nozzle 62 and the magnetic particle tank are connected through a hose. The second injection nozzle 62 is preferably installed in a longitudinal direction and an inclined direction of the second electrode 50 .

The center line of the first injection nozzle 61 and the center line of the second injection nozzle 62 are the lengths of the first electrode 40 from the first insulating body 20 and the second insulating body 30, respectively. They are arranged so that they become closer and closer as they move away from each other along the direction. That is, the magnetic particles injected from the first injection nozzle 61 and the second injection nozzle 62 travel in a direction converging to a predetermined area.

Preferably, the first insulating body 20 is provided with an injection switch 90 for simultaneously controlling the opening and closing of the first injection nozzle 61 and the second injection nozzle 62 . The injection switch 90 may be configured to control a solenoid valve (not shown) installed in a magnetic particle tank (not shown) connected to the first injection nozzle 61 and the second injection nozzle 62 .

Meanwhile, it is preferable that the first electrode 40 has a structure capable of spraying an inert gas or compressed air toward the surface of the product separately from the first spray nozzle 61 . In addition, it is preferable that the second electrode 50 has a structure capable of injecting an inert gas or compressed air toward the surface of the product separately from the second injection nozzle 62 . The inert gas or compressed air injected from the first electrode 40 and the second electrode 50 can significantly reduce the risk of fire due to arc generation by removing oil or foreign substances before magnetizing the product surface in wet operation. provides an effect.

The first electrode 40 may be detachably coupled to the first insulating body 20 . For example, the first electrode 40 may be provided with a rotation stopping protrusion, and the second insulating body 30 may be provided with a rotation stopping protrusion to engage the rotation stopping protrusion.

The second electrode 50 may be detachably coupled to the second insulating body 30 . The separable coupling structure of the second electrode 50 and the second insulating body 30 may be the same as that of the first electrode 40 and the first insulating body 20 .

It is preferable that an interval indicator 100 indicating the distance between the first electrode 40 and the second electrode 50 is provided on the surface of the second insulating body 30 .

Hereinafter, the operation and effects of the magnetized electrode device 10 including the above-described components will be described in detail by using the magnetized electrode device 10 as an example to perform a magnetic flaw inspection.

In order to inspect the surface defects of the welded portion made of the ferromagnetic iron plate, the operator adjusts the distance between the first electrode 40 and the second electrode 50 constituting the magnetizing electrode device 10 to a necessary degree. In this process, the operator causes the interval adjusting motor 26 to rotate forward or reverse through the toggle switch 70 . Accordingly, the screw shaft 24 rotates. Accordingly, the second insulating body 30 linearly moves along the slide groove portion 22 . Accordingly, the distance between the first electrode 40 and the second electrode 50 is changed. In this process, the operator can visually check the distance between the first electrode 40 and the second electrode 50 by using the interval indicator 100 in real time. After adjusting the distance between the first electrode 40 and the second electrode 50 through this process, the first electrode 40 and the second electrode 50 are moved by moving the toggle switch 70 to the OFF position. The adjustment of the distance between the two electrodes 50 is completed.

Now, the operator arranges the free ends of the first electrode 40 and the second electrode 50 to contact the surface of the structure to be inspected. In this process, it is preferable to spray an inert gas or compressed air on the surface of the product from the first electrode 40 and the second electrode 50 . In the working process, it is preferable that the injection pressure of the inert gas or air is initially strong and weakly maintained after magnetization. The inert gas or compressed air injected from the first electrode 40 and the second electrode 50 can significantly reduce the problem of a fire caused by an arc generated between the electrode and the product in wet work. . Now, the energization switch 80 is pressed. Accordingly, a magnetic force line is formed on the surface of the object to be inspected with a contact point between the first electrode 40 and the second electrode 50 as a pole. Then, the operator sprays magnetic particles on the surface of the subject by pressing the injection switch 90 . Accordingly, the magnetic particles sprayed on the surface of the subject are arranged along the magnetic field lines. In this process, if there is a defect on the surface of the subject, the magnetic pole is separated and the magnetic particles are concentrated in the defective area, thereby increasing the distribution density. Accordingly, it is possible to inspect the surface defects of the object by observing the distribution of magnetic particles sprayed on the surface of the object.

As described above, in the magnetizing electrode device for a non-destructive testing apparatus capable of adjusting the distance between electrodes according to the present invention, the distance between the first electrode and the second electrode can be automatically adjusted by the distance adjusting motor. Since the inter-interval can be easily changed, it provides the effect of remarkably improving the workability when performing the magnetic flaw detection method.

In addition, since the magnetizing electrode device according to the present invention is configured to apply a current through the energization switch in a state in which the first electrode and the second electrode are uniformly pressed to the surface of the subject, the non-uniformity of the first electrode and the second electrode It provides the effect of preventing sparks from occurring due to pressure.

As mentioned above, although the present invention has been described in detail with reference to a preferred embodiment, the present invention is not limited to the above embodiment, and various modifications are possible by those skilled in the art within the technical spirit of the present invention. is clear

10: Magnetizing electrode device for non-destructive testing devices capable of adjusting the inter-electrode spacing
20: first insulating body
22: slide groove
24: screw shaft
26: interval adjustment motor
30: second insulated body
32: screw groove
40: first electrode
50: second electrode
61: first injection nozzle
62: second injection nozzle
70: toggle switch
80: energization switch
90: injection switch
100: interval indicator

Claims (4)

A magnetizing electrode device constituting a device for inspecting surface defects of an inspected object made of a ferromagnetic material, comprising:
a first insulating body electrically non-conductive and provided with a slide groove of a non-circular cross-section in a longitudinal direction;
a second insulating body electrically non-conductive and slidably coupled to the first insulating body along the slide groove;
a first electrode having one end coupled to the first insulating body and extending in a cantilever shape perpendicular to the longitudinal direction of the first insulating body;
a second electrode having one end coupled to the second insulating body and disposed parallel to the first electrode;
a screw shaft disposed along the central axis of the slide groove and rotatably installed on the first insulating body;
a screw groove portion screwed to the screw shaft and formed along a central axis of the second insulating body;
a spacing adjusting motor installed on the first insulating body and rotating the screw shaft;
a toggle switch installed on the first insulating body and configured to control the driving of the interval control motor; and
A magnetizing electrode device for a non-destructive testing device capable of adjusting the distance between electrodes, characterized in that it includes a energization switch for controlling the supply of electricity to the first electrode and the second electrode. According to claim 1,
a first spray nozzle installed on the first insulating body to spray magnetic particles; and
a second spray nozzle installed on the second insulating body to spray magnetic particles;
The center line of the first injection nozzle and the center line of the second injection nozzle are respectively arranged to be closer to each other as the distance from the first insulating body and the second insulating body in the longitudinal direction of the first electrode increases,
A magnetizing electrode device for a non-destructive testing device capable of adjusting the distance between electrodes, characterized in that the first insulating body is provided with an injection switch for simultaneously controlling the opening and closing of the first injection nozzle and the second injection nozzle. According to claim 1,
The first electrode is detachably coupled to the first insulating body,
The second electrode is a magnetized electrode device for a non-destructive testing device capable of adjusting the inter-electrode spacing, characterized in that the second electrode is detachably coupled to the second insulating body. According to claim 1,
A magnetizing electrode device for a non-destructive testing device capable of adjusting the distance between electrodes, characterized in that a gap indicator for indicating the distance between the first electrode and the second electrode is provided on the surface of the second insulating body.

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