KR102461201B1 - Yoke type magnetic tester - Google Patents

Abstract

The present invention relates to a magnetic particle tester which performs a magnetic particle test by making contact with a test object that is a metal material, and more particularly, to a magnetic particle tester which has a switch for turning on/off power at the lower end of an electrode and can spray magnetic particles according to a user's selection or can adjust the amount of sprayed magnetic particles during a test. The magnetic particle tester can magnetize a test object by contact with the test object without a separate operation and can selectively spray magnetic particles according to a user's selection, thereby improving convenience of use.

Description

Magnetic particle flaw detector {Yoke type magnetic tester}

The present invention relates to a magnetic particle flaw detector that performs a magnetic particle inspection in contact with a subject made of a metal material, and more particularly, a switch for turning on/off the power is provided at the lower end of the electrode, and according to the user's selection when performing the inspection It relates to a magnetic particle flaw detector capable of spraying magnetic particles or controlling the amount of sprayed magnetic particles.

In general magnetic particle inspection, when a test object is magnetized, if there is a defect blocking the magnetic flux on the surface or on the surface, the magnetic field leaks from there, and magnetic poles are formed on both sides of the defect. Creates a magnetic field in space. If you spray magnetic powder in the space, the magnetic powder will become magnetized and stick to the defective area with stimulation. It is a non-destructive testing method that measures the defect area and size of a specimen by looking at the shape of the magnetic particles in it.

Compared to other non-destructive testing methods, magnetic particle inspection is suitable for surface crack inspection, is simple, and is not limited by the size and shape of the subject. On the other hand, it is limited to ferromagnetic materials, and internal inspection is impossible, and there are several disadvantages such as the position of the discontinuity must be perpendicular to the magnetic flux direction.

Magnetic particle inspection can be divided into continuous method and residual method. Magnetic particle inspection uses a magnetic particle flaw detector that conducts magnetizing current or excitation current through the subject to magnetize the subject.

For magnetic particle flaw detectors, stationary equipment, portable, prod, yoke, etc. are used depending on the type of test equipment. , the coil method, the Freud method, the yoke method (interpole method), and the magnetic flux penetration method.

The conventional magnetic particle flaw detector has a considerable weight, so that the user can easily feel fatigue while holding it. In particular, it provided a great inconvenience to the user because the switch for supplying power had to be kept pressed continuously, and it was troublesome to carry a separate barrel containing magnetic particles to spray the magnetic particles on the subject. did.

1. Registered Patent Publication No. 10-1002435 'Fluorescent Magnetic Particle Detector' (Registration Date: 2010.12.13) 2. Registered Patent Publication No. 10-0775968 'Variable magnetic particle flaw detector' (Registration date 2007.11.06)

The present invention has been devised to solve the above problem, and power is applied depending on whether the subject is in contact with the subject without a separate operation, so that the subject can be magnetized. An object of the present invention is to provide a magnetic particle flaw detector that can improve

The magnetic particle flaw detector of the present invention is coupled to the main body 100 and the main body 100 including a coil 110 to which power is applied so as to be in contact with a subject to perform a magnetic particle inspection, and from the coil 110 an electrode 200 that receives a current and contacts the subject S; is formed at the lower end of the electrode 200 and is applied to the coil 110 by whether the main body 100 is pressurized to bring the electrode 200 and the subject S into contact with each other. The first switch 300 for controlling the supply of; characterized in that it further comprises.

In addition, the first switch 300 of the present invention is composed of a 1-1 switch 310 and a 1-2 switch 320, the 1-1 switch 310 and the 1-2 switch ( Power is supplied to the coil 110 only when all of the 320 are operated.

The main body 100 of the present invention further includes a spraying unit 400 for spraying magnetic particles in the direction of the subject S, and between the electrode 200 and the main body 100, the first switch ( A second switch for controlling the operation of the injection unit 400 so that the injection unit 400 is operated when the main body 100 is further pressed more than the pressing force for pressing the main body 100 for the operation of 300) ( 500); characterized in that it is further provided.

On the other hand, the injection unit 400 of the present invention is a nozzle 410 formed on one side of the main body 100; Receiving tank 420 in which magnetic powder is accommodated; A pump 430 that receives magnetic particles from the receiving tank 420 and discharges them to the outside of the nozzle 410 by applying a predetermined pressure to the received magnetic particles depending on whether the second switch 500 operates or not; may include

And the second switch 500 of the present invention includes a first terminal 510 fixed to the inside of the body 100; and a second terminal 520 fixed to the upper end of the electrode 200; an elastic member 530 provided between the upper end of the electrode 200 and the body 100 to elastically support the electrode 200; Installed to slide in the vertical direction on the body 100, the lower end is supported or spaced apart from the side of the electrode 200 according to the vertical movement to control the contact between the first terminal 210 and the second terminal 520 It characterized in that it includes; a stopper (540).

Thereafter, a seating portion 210 is further formed on the side surface of the electrode 200 of the present invention to be inclined at a predetermined angle, and the lower end of the stopper 540 is seated, and the lower end of the stopper 540 is the seating portion ( 210) and is characterized in that it is formed to form a corresponding inclined surface.

The present invention provides convenience to the user because a separate switch operation is unnecessary by magnetizing the subject as a terminal is in contact with the subject, and magnetic particles or fluorescent magnetic particles can be sprayed onto the subject according to the user's selection, and spray There is an advantage in that the accuracy and reliability of inspection can be secured by controlling the amount of spraying.

1 is a perspective view showing the overall appearance of the present invention.
Figure 2 is a schematic diagram showing the main configuration of the present invention.
3 is a partial cross-sectional view showing an embodiment and an operation embodiment of the first switch of the present invention.
4 and 5 are partial cross-sectional views showing an embodiment of the operation of the second switch and the injection unit of the present invention.
Figure 6 is a perspective view showing an embodiment of the stopper of the present invention.

Hereinafter, an embodiment of the magnetic particle flaw detector of the present invention will be described in detail with reference to the drawings.

1 and 2 , the present invention includes a body 100 , an electrode 200 , and a first switch 300 .

The body 100 is formed in a 'c' shape with an open portion facing downward, and a coil 110 formed along the shape of the body 100 is provided inside the body 100 . The body 100 is formed to surround the outside of the coil 110 . When power is applied to the coil 110 , the electrode 200 may come into contact with the subject S to perform a magnetic particle inspection.

A power cord 111 for applying power to the coil 110 is further provided on one side of the main body 100 , and the power cord 111 may be detachably attached to the main body 100 .

The electrodes 200 are provided in pairs so as to be respectively formed on both ends of the body 100 , and one side is connected to the coil 110 to receive current from the coil 110 . That is, when power is applied to the coil 110 , a magnetizing current may be generated in the coil 110 , and the generated current may be transmitted to the electrode 200 . A magnetic particle inspection may be performed by emitting current received while the lower end of the electrode 200 is in contact with the subject S to the subject S.

The first switch 300 is respectively formed at the lower end of the pair of electrodes 200 . The first switch 300 controls the supply of power applied to the coil 110 . That is, it is possible to turn ON/OFF the supply of current delivered to the electrode 200 by the operation of the first switch 300 .

The first switch 300 is formed at the lower end of the electrode 200 and when the user presses the main body 100 with a predetermined pressing force while holding the main body 100, the first switch 300 is compressed and the ON state is changed. At the same time, the electrode 200 is in contact with the subject S, so that a current can flow to the subject S.

Conversely, when the pressing force for pressing the main body 100 is released, the first switch 300 is turned off, and the power supply applied to the coil 110 is cut off at the same time.

The user may press the main body 100 to operate the first switch 300 , and the first switch 300 may be turned on while the first switch 300 is pressed by the weight of the main body 100 .

Referring to FIG. 2 , the first switch 300 includes a pressing plate 301 , an elastic member 302 , and first and second terminals 303 and 304 . The pressing plate 301 is inserted into the fastening groove 201 formed at the lower end of the electrode 200 , and may be guided to the fastening groove 201 to slide up and down.

The elastic member 302 is formed between the inner surface of the pressing plate 301 and the fastening groove 201 to elastically support the pressing plate 301 . The first terminal 303 is provided on the inner surface of the fastening groove 201 , and the second terminal 304 is provided on the upper end of the pressing plate 301 . The first terminal 303 and the second terminal 304 may be in contact with each other according to the vertical movement of the pressure plate 301 , and the first switch 300 may be in an ON or OFF state depending on whether the pressure plate 301 is in contact.

In addition, the first switch 300 is provided with the elastic member 302 while pressing the main body 100 with a predetermined pressing force so that the pressing plate 301 can be inserted into the fastening groove 201 , and thereby the first and second The two terminals 303 and 304 may be in contact with each other and the first switch 300 may be in an ON state.

Referring to FIG. 3 , the first switch 300 may include a 1-1 switch 310 and a 1-2 th switch 320 . When the 1-1 switch 310 and the 1-2 switch 320 have the same structure as each other, and both the 1-1 switch 310 and the 1-2 switch 320 are operated in an ON state Power may be supplied to only the coil 110 . Accordingly, it is possible to prevent a cause of malfunction.

Referring to FIGS. 1, 2 and 4 , the main body 100 transmits a current to the subject S, and when the subject S is magnetized, a spraying unit that sprays magnetic particles in the direction of the subject S ( 400) may be further provided. The injection unit 400 may be formed at both ends of the body 100 as a pair, respectively, and not only magnetic particles but also liquid fluorescent magnetic particles, cleaning liquid, etc. may be accommodated and sprayed.

In addition, a second switch 500 for controlling the operation of the injection unit 400 is further provided between the electrode 200 and the body 100 . The second switch 500 is in an ON state when the main body 100 is pressed with a predetermined pressing force, and becomes an OFF state when the pressing force is released.

The second switch 500 can be operated only when the user who performs the magnetic particle inspection wants. That is, when the second switch 500 further presses the main body 100 more than the pressing force applied when pressing the main body 100 with a predetermined pressing force for the operation of the first switch 300 , the second switch 500 . may be operated to inject magnetic particles from the injection unit 400 .

Referring to FIGS. 4 and 5 , the injection unit 400 includes a nozzle 410 , an accommodation tank 420 , and a pump 430 . The nozzle 410 is formed on one side of the main body 100, and a spray hole through which magnetic particles are sprayed may be formed in the center.

The accommodating tank 420 may accommodate magnetic particles therein, and although not shown in the drawings, may be formed in a structure capable of receiving magnetic particles from the outside. The receiving tank 420 is connected to the nozzle 410 to supply magnetic particles accommodated in the nozzle 410 .

The pump 430 delivers the magnetic particles accommodated in the receiving tank 420 to the nozzle 410 , and provides a predetermined discharge pressure so that the magnetic particles can be discharged from the nozzle 410 at a predetermined pressure. That is, the pump 430 is located between the receiving tank 420 and the nozzle 410 and may be turned on/off depending on whether the second switch 500 is operated.

4 and 5 , the second switch 500 includes first and second terminals 510 and 520 , an elastic member 530 and a stopper 540 . The second switch 500 is formed at a portion where the body 100 and the electrode 200 are connected. At this time, a portion of the upper end of the electrode 200 may be slid in the vertical direction by the second switch 500 in a state in which it is inserted into the electrode insertion groove 101 formed in the body 100 .

The first terminal 510 is fixed to the inside of the body 100 , and the second terminal 520 is fixed to the upper end of the electrode 200 . As the electrode 200 moves in the vertical direction, the first terminal 510 and the second terminal 520 are in contact with each other, and the second switch 500 is turned on according to whether the first and second terminals 510 and 520 are in contact. /may be OFF.

The elastic member 530 is located inside the electrode insertion groove 101 and is provided between the upper end of the electrode 200 and the body 100 to elastically support the electrode 200 . It is preferable that the elastic modulus of the elastic member 530 provided in the second switch 500 is formed to have a larger elastic modulus than the elastic modulus of the elastic member 302 provided in the first switch 500 .

Accordingly, when the main body 100 is pressed, the elastic member 302 of the first switch 500 may be compressed first, and then the elastic member 530 of the second switch 500 may be compressed.

The stopper 540 surrounds the electrode 200 and the body 100 and is installed to slide in the vertical direction. The stopper 540 is provided to control that the elastic member 530 is compressed so that the first and second terminals 510 and 520 come into contact with each other.

That is, as the stopper 540 moves up and down, the lower end may be supported or spaced apart from the side of the electrode 200 , and when supported, the compression of the elastic member 530 is limited. Accordingly, the user can control whether the magnetic powder is injected by manipulating the stopper 250 .

Meanwhile, a seating portion 210 inclined at a predetermined angle may be formed on a side surface of the electrode 200 on which the lower end of the stopper 540 is seated. In addition, the lower end of the stopper 540 may be inclined at a predetermined angle to form an inclined surface corresponding to the seating portion 210 .

When the body 100 is pressed in a state where the lower end of the stopper 540 is seated on the seat 210 due to the formation of the seating portion 210, the lower end of the stopper 540 is widened and the lower end of the stopper 540 is narrowed at the same time. It is possible to improve the fixing force of the stopper 540 as it becomes. Accordingly, even when the body 100 is forcibly pressed while the lower end of the stopper 540 is supported by the electrode 200 , it is possible to prevent the second switch 500 from being operated.

Referring to FIG. 6 , on both sides of the stopper 540 so that the gap between the lower end and the upper end of the stopper 540 can be widened or narrowed, a pair of incision grooves 541 for cutting the upper and lower portions of the stopper 540, respectively. This can be further formed.

The magnetic particle flaw detector of the present invention with such a configuration does not require a separate switch operation to magnetize the subject S, and can easily spray magnetic particles or fluorescent magnetic particles onto the subject S according to the user's selection. It can provide convenience.

100: body 200: electrode
300: first switch 400: injection unit
500: second switch

Claims (6)

A body 100 including a coil 110 to which power is applied so as to be in contact with a subject to perform a magnetic particle inspection, and the main body 100 are coupled to the body 100, and receive current from the coil 110 to perform a magnetic particle inspection. electrode 200 in contact with (S); includes,
It is formed at the lower end of the electrode 200 and controls the supply of power applied to the coil 110 by whether or not the main body 100 is pressurized to bring the electrode 200 and the subject S into contact with each other. a first switch 300 to;
The main body 100 has a spraying unit 400 for spraying magnetic particles in the direction of the subject (S); further provided,
Between the electrode 200 and the main body 100, when the main body 100 is further pressed by more than the pressing force for pressing the main body 100 for the operation of the first switch 300, the injection unit 400 A magnetic particle flaw detector, characterized in that it further comprises; a second switch (500) for controlling the operation of the injection unit (400) to operate. The method of claim 1,
The first switch 300 is composed of a 1-1 switch 310 and a 1-2 switch 320,
The magnetic particle flaw detector, characterized in that power is supplied to the coil (110) only when the 1-1 switch (310) and the 1-2 switch (320) are both operated. delete The method of claim 1,
The spray unit 400 includes a nozzle 410 formed on one side of the body 100;
Receiving tank 420 in which magnetic powder is accommodated;
a pump 430 for receiving magnetic particles from the receiving tank 420 and discharging the magnetic particles to the outside of the nozzle 410 by applying a predetermined pressure to the received magnetic particles depending on whether the second switch 500 operates;
Magnetic particle flaw detector comprising a. 5. The method of claim 4,
The second switch 500 includes a first terminal 510 fixed to the inside of the main body 100 ; and a second terminal 520 fixed to an upper end of the electrode 200 ;
an elastic member 530 provided between the upper end of the electrode 200 and the body 100 to elastically support the electrode 200;
Installed to slide in the vertical direction on the body 100, the lower end is supported or spaced apart from the side of the electrode 200 according to the vertical movement to control the contact between the first terminal 510 and the second terminal 520 a stopper 540;
Magnetic particle flaw detector comprising a. 6. The method of claim 5,
A seating portion 210 is further formed on the side surface of the electrode 200, which is inclined at a predetermined angle and on which the lower end of the stopper 540 is seated,
A magnetic particle flaw detector, characterized in that the lower end of the stopper (540) is formed to form an inclined surface corresponding to the seating portion (210).

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