KR102525200B1 - Magnetization device for non-destructive testing provided with concave-convex structure - Google Patents

Abstract

A non-destructive inspection magnetization device having a concave-convex structure according to the present invention comprises: a core which is electrically connected to each of a pair of magnetized electrodes and is formed in a "∩" shape; induction coils which are wound around both ends of the core, respectively; an insulation cover which is formed to embed the core and the induction coils; a switch which is installed on the insulation cover to control the electrical supply to the induction coils; and a connector part to which an external power source supplying electricity to the induction coils is connected. A heat dissipation groove part which has a "∪" shaped cross-sectional structure and has both ends opened to the outside in the longitudinal direction is provided on the top of the insulation cover. In the heat dissipation groove part, a heat dissipation fan is installed to discharge heat transferred from the core to the outside of the insulating cover. Therefore, the magnetization device can prevent deformation of the insulating cover due to heat.

Description

Magnetization device for non-destructive testing provided with concave-convex structure}

The present invention relates to a magnetization device for non-destructive testing, and relates to equipment for inspecting the surface integrity of a welded part by partially magnetizing the surface of a sample in contact with a ferromagnetic sample.

Non-destructive testing is a method of inspecting workpieces, members, structures, etc. in the field of manufacturing for integrity, surface condition, cracks, etc. without destroying them.

Examples of non-destructive testing methods include magnetic testing, radiographic testing, ultrasonic testing, penetrant testing, and the like.

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

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

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

Penetration testing is a method of inspecting defects such as surface cracks, overlapping areas, and pores by applying liquid to the surface of a product and examining penetration into the inside through open cracks on the surface. The penetrating liquid can seep into cracks as small as 0.1 micrometer in width. Commonly used penetrants include fluorescent penetrants that fluoresce under 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 penetrant is applied to the surface with a brush or sprayed. After waiting enough time for the liquid to seep into the open crevices of the surface, wipe off any liquid remaining on the surface with water or solvent. Then, a developer is added to allow the penetrant to flow backwards to the surface and spread over the edges of open cracks in the surface. The location and size of the defect are inspected by observing the fluorescent penetrant by illuminating the visible penetrant (directly) or ultraviolet light.

Among these nondestructive inspection methods, magnetic inspection is widely used to inspect the surface and subsurface integrity of welded parts of ferromagnetic steel structures. In general, equipment for performing magnetic flaw detection requires a magnetization device that instantaneously magnetizes the surface of a ferromagnetic sample. Magnetic powder is sprayed on the surface of the magnetized sample to observe the distribution of magnetic powder to inspect the surface of the product for defects. In general, a magnetization device has an iron core inside an insulating coating made of synthetic resin, and an induction coil is wound around the end of the core, so that when AC power is applied to the induction coil, the electrode forms an electromagnet to magnetize the surface of the sample. configured to do However, the insulation coating made of an injection-molded synthetic resin to electrically insulate the core constituting the magnetization device and the user is thermally cured by heat generated in the process of electromagnetic interaction between the induction coil and the core. When the insulation coating is thermally cured, thermal deformation occurs, and wet magnetic particles penetrate into gaps caused by the thermal deformation, thereby increasing the risk of fire or electric shock.

001 KR 20-2019-0002606 A (2019.10.18)

An object of the present invention has been made to solve the above-mentioned problems, by improving the structure of a magnetization device for performing a magnetic flaw detection method, to effectively dissipate heat generated during operation of the magnetization device to the outside of the insulation coating. It is an object of the present invention to provide a magnetization device for non-destructive testing equipped with a heat deformation preventing structure.

In order to achieve the above object, a magnetization device for non-destructive inspection having a concave-convex structure according to the present invention includes a pair of magnetizing electrodes,

a core electrically connected to each magnetizing electrode and having a “∩” shape;

induction coils wound on both ends of the core, respectively;

an insulating sheath formed to bury the core and the induction coil;

a switch installed on the insulating sheath to control supply of electricity to the induction coil; and

In the magnetization device for non-destructive testing having a; connector to which an external power source for supplying electricity to the induction coil is connected,

A heat dissipation groove having a “∪”-shaped cross-sectional structure and having both ends in the longitudinal direction open to the outside is provided on the upper part of the insulation cover,

A heat dissipation fan is installed in the heat dissipation groove to dissipate the heat transferred from the core to the outside of the insulation cover,

A heat transfer member made of a material having higher thermal conductivity than that of the core is installed in the heat dissipation groove,

A plurality of concave-convex structures are formed on the heat transfer member to increase a contact area with air,

The heat transfer member is made of aluminum alloy or copper alloy,

The heat dissipation fan is characterized in that it is fixed to the insulation cover.

The magnetization device for non-destructive testing having a concavo-convex structure according to the present invention provides an effect of preventing the insulation coating from being deformed by heat by rapidly discharging heat generated in the magnetization device to the outside through a heat dissipation fan along a heat dissipation groove. do.

In addition, when the heat transfer member is provided in the heat dissipation groove part as in the preferred embodiment of the present invention, heat transfer between the heat transferred from the core and the air is accelerated to achieve faster heat dissipation, so that the heat dissipation efficiency is further improved.

In addition, since the heat dissipation fan can be selectively fixed to the heat transfer member or the insulating cover as needed, productivity of the device can be improved.

1 is a perspective view of a magnetization device according to a preferred embodiment of the present invention.
FIG. 2 is a cross-sectional view along line II-II shown in FIG. 1 .
FIG. 3 is a view showing a state in which the heat transfer member and the heat dissipation fan are separated from each other in FIG. 1 .
4 is a view showing a three-dimensional structure of a core according to the present invention.
5 is a view showing a three-dimensional shape of a heat transfer member according to another embodiment.
6 is a view showing an installation structure of a heat dissipation fan according to another embodiment.
7 is a view showing an installation structure of a heat dissipation fan according to another embodiment.
8 is a view showing air flow when heat is discharged to the outside through a heat dissipation groove in the magnetization device according to the present invention.

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

1 is a perspective view of a magnetization device according to a preferred embodiment of the present invention. FIG. 2 is a cross-sectional view along line II-II shown in FIG. 1 . FIG. 3 is a view showing a state in which the heat transfer member and the heat dissipation fan are separated from each other in FIG. 1 . 4 is a view showing a three-dimensional structure of a core according to the present invention. 5 is a view showing a three-dimensional shape of a heat transfer member according to another embodiment. 6 is a view showing an installation structure of a heat dissipation fan according to another embodiment. 7 is a view showing an installation structure of a heat dissipation fan according to another embodiment. 8 is a view showing air flow when heat is discharged to the outside through a heat dissipation groove in the magnetization device according to the present invention.

1 to 8, a magnetization device for non-destructive testing (hereinafter referred to as "magnetization device for non-destructive testing") having a concavo-convex structure according to the present invention includes a pair of magnetizing electrodes 20, a core ( 30), an induction coil 40, an insulating coating 50, a switch 60, a heat dissipation groove 52, a heat transfer member 54, and a heat dissipation fan 80.

The magnetizing electrode 20 is an electrode that physically contacts a sample. The magnetizing electrode 20 may be made of a material having good electrical conductivity, such as copper alloy. A pair of the magnetizing electrodes 20 is provided to be disposed at positions spaced apart from each other. The magnetizing electrode 20 may be rotatably installed at an end of a core 30 to be described later so that a contact angle may be changed.

The core 30 is electrically connected to each of the magnetizing electrodes 20 and is a “∩” shaped structure. The core 30 may be made of ferromagnetic carbon steel. The core 30 may be manufactured by cutting a thin steel plate into a shape and stacking and combining a plurality of them. It is preferable that a “∪” shaped groove portion is provided on the upper portion of the core 30 to correspond to a heat dissipation groove portion 52 to be described later.

The induction coil 40 is wound on both ends of the core 30, respectively. The induction coil 40 is a component that forms a magnetic field by supplying an alternating current. The induction coil 40 is wound along the end surface of the core 30 with the surface covered with an insulating material. The induction coil 40 and the core 30 remain electrically insulated. The induction coil 40 forms a magnetic field by an AC current supplied from the outside through a connector part 70 to be described later. A switch 60 is installed between the induction coil 40 and the connector part 70 . The switch 60 may be installed to be able to emerge and descend from the insulating sheath 50 to be described later. The switch 60 serves to open and close the flow of current between the connector part 70 and the induction coil 40 .

The insulation coating body 50 is a structure formed so that the core 30 and the induction coil 40 are buried. The insulating sheath 50 may be formed by insert injection molding to surround the outside of the core 30 and the induction coil 40 . The insulating cover 50 may be made of synthetic resin, which is an electrically non-conductive material.

The switch 60 is installed on the insulating sheath 50 . The switch 60 controls the supply of electricity to the induction coil 40 . The switch 60 may be a push button type switch. In addition, the switch 60 is applied with a digital off-delay timer that performs an instantaneous operation time-limited return function, so that when the operator presses the push button and removes the pressure, for example, after a time of about 5 seconds has elapsed It is preferable to be configured so that the power is turned off. In this way, when the switch 60 is equipped with a timer function, work efficiency is further improved.

The connector part 70 is a device to which an external power source for supplying electricity to the induction coil is connected. The connector part 70 may include two electrode terminals and one ground terminal.

The heat dissipation groove part 52 is provided on the upper part of the insulating coating body 50 . The heat dissipation groove part 52 has a "∪" shape longitudinal section structure. Both ends of the heat dissipation groove 52 in the longitudinal direction are formed in a structure open to the outside.

The heat dissipation fan 80 is installed in the heat dissipation groove 52 . The heat dissipation fan 80 is provided to quickly dissipate the heat transferred from the core 30 to the outside of the insulation cover 50 . The heat dissipation fan 80 may be, for example, an axial flow fan.

Preferably, a heat transfer member 54 is installed in the heat dissipation groove 52 . The heat transfer member 54 is provided to more effectively dissipate the heat of the insulating sheath 50 to the outside. The heat transfer member 54 is preferably made of a material having higher thermal conductivity than the core 30 . For example, an aluminum alloy or a copper alloy may be employed as the heat transfer member 54 . The heat transfer member 54 may be fixed to the heat dissipation groove 52 by an interference fit or a fastening means such as a screw. Preferably, the heat transfer member 54 has a plurality of concavo-convex structures to increase a contact area with air.

The heat dissipation fan 80 may be fixed to the heat transfer member 54 . When the heat dissipation fan 80 is fixed to the heat transfer member 54 , a frame of the heat dissipation fan 80 may be formed to engage with the concave-convex structure of the heat transfer member 54 . Meanwhile, the heat dissipation fan 80 may be fixed to the bottom or side surface of the heat transfer member 54 by a fastening means such as a screw.

Meanwhile, the heat dissipation fan 80 may be fixed to the insulation cover 50 . The heat dissipation fan 80 is preferably installed in a form buried in the heat dissipation groove 52 . The frame of the heat dissipation fan 80 is provided with a flange in which an assembly hole is formed, so that the flange can be fixed to the top or side surface of the insulation cover 50 .

Hereinafter, the operation and effect of the present invention will be described in detail by taking an operation process of the magnetization device 10 for non-destructive inspection including the above-described components as an example.

In order to inspect whether a welded portion made of ferromagnetic material has surface defects, a worker connects a power line supplied from the outside to the connector part 70 . In addition, the distance between the pair of electrodes 20 constituting the non-destructive test magnetizer 10 is adjusted to a necessary level. The operator now places the pair of electrodes 20 in contact with the surface of the structure to be inspected. Now, the switch 60 is pressed. Accordingly, AC current is supplied from the connector part 70 to the induction coil 40 . The alternating current supplied to the induction coil 40 forms a magnetic field around and inside the induction coil 40, and the core 30 further increases the strength of the magnetic field. Accordingly, lines of magnetic force having a contact point with a pair of electrodes 20 as poles are formed on the surface of the inspected object. In that state, the operator sprays magnetic powder on the surface of the subject. The magnetic particles sprayed on the surface of the test subject are arranged along the lines of magnetic force. In this process, when there is a defect on the surface of the object to be inspected, the magnetic poles are separated and the magnetic particles are concentrated on the defect area to increase the distribution density. Accordingly, surface defects of the object to be inspected may be inspected by observing the distribution of magnetic particles sprayed on the surface of the object to be inspected. In this process, the alternating current supplied to the induction coil 40 generates heat due to resistance of the induction coil 40, hysteresis and eddy current of the core 30. The heat generated in the operating process is transferred to the insulating sheath 50 in this way. The heat transferred to the insulating sheath 50 is cooled and dissipated through heat exchange with air. In this process, the heat dissipation grooves 52 and the heat dissipation fans 80 installed at both ends of the heat dissipation grooves 52 quickly discharge the heat transferred to the heat dissipation grooves 52 to the outside. In addition, when the heat transfer member 54 is installed in the heat dissipation groove 52, heat exchange and heat dissipation efficiency can be further improved through the heat dissipation groove 52.

As described above, the magnetizer for non-destructive inspection having a concavo-convex structure according to the present invention quickly dissipates heat generated in the magnetizer to the outside through a heat dissipation fan along the heat dissipation groove, thereby preventing deformation of the insulation cover due to heat. provides a preventive effect.

In addition, when the heat transfer member is provided in the heat dissipation groove part as in the preferred embodiment of the present invention, heat transfer between the heat transferred from the core and the air is accelerated to achieve faster heat dissipation, so that the heat dissipation efficiency is further improved.

In addition, since the heat dissipation fan can be selectively fixed to the heat transfer member or the insulating cover as needed, productivity of the device can be improved.

In the above, the present invention has been described in detail with preferred embodiments, but the present invention is not limited to the above embodiments, and many variations are possible within the technical spirit of the present invention by those skilled in the art. is clear

10: Magnetizer for non-destructive testing
20: electrode
30: core
40: induction coil
50: insulation sheath
52: heat dissipation groove
54: heat transfer member
60: switch
70: connector part
80: heat dissipation fan

Claims (1)

A pair of magnetizing electrodes are provided,
a core electrically connected to each magnetizing electrode and having a “∩” shape;
induction coils wound on both ends of the core, respectively;
an insulating sheath formed to bury the core and the induction coil;
a switch installed on the insulating sheath to control supply of electricity to the induction coil; and
In the magnetization device for non-destructive testing having a; connector to which an external power source for supplying electricity to the induction coil is connected,
A heat dissipation groove having a “∪”-shaped cross-sectional structure and having both ends in the longitudinal direction open to the outside is provided on the top of the insulation cover,
A heat dissipation fan is installed in the heat dissipation groove to dissipate the heat transferred from the core to the outside of the insulation cover,
A heat transfer member made of a material having higher thermal conductivity than the thermal conductivity of the core is installed in the heat dissipation groove,
A plurality of concave-convex structures are formed on the heat transfer member to increase a contact area with air,
The heat transfer member is made of aluminum alloy or copper alloy,
The heat dissipation fan is a magnetizer for non-destructive testing having a concave-convex structure, characterized in that fixed to the insulating coating.

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