KR102509485B1 - UV irradiation device for non-destructive testing - Google Patents

Abstract

According to an aspect of the present invention, an ultraviolet (UV) irradiation device for non-destructive inspection may comprise: a mounting part to which a spray bottle is mounted; a handle part extended from the mounting part and grasped by the operator's hand; a spraying part coupled to the mounting part and pressing a head part of the spray bottle by the operator to spray the contents contained in the spray bottle; an irradiation part located at the top of the head part of the spray bottle and irradiating light and ultraviolet rays; and a connecting part coupled to the irradiation part to connect the irradiation part to the handle part.

Description

UV irradiation device for non-destructive testing}

The present invention relates to an ultraviolet irradiation device for non-destructive inspection, and more particularly, to an ultraviolet irradiation device for non-destructive inspection capable of securing a defect detection capability.

In general, the non-destructive testing method is a method of inspecting defects such as pores or cracks inside the article to be tested, internal defects of welds, etc. without destroying the article. It refers to an inspection method that detects the extent of tissue abnormalities or defects by applying phosphorus sunlight, heat, radiation, sound waves, electricity, and electrical energy to measure the change in the characteristics of energy caused by tissue abnormalities and defects.

This non-destructive inspection method is more useful than the destructive inspection method that destroys the test object to check for defects, and is applied to various fields such as safety inspection of various facilities. inspection method is being used.

Non-destructive inspection methods include visual inspection, radiographic testing (RT), ultrasonic testing (UT), magnetic particle testing (MT), liquid penetrant testing (PT), There are Eddy current Testing (ET) and Acoustic Emission Testing.

Here, the flaw detection method using a spray gun, which is a kind of magnetic particle testing (MT), uses a spray gun for spraying a penetrant containing a fluorescent material on an object to be inspected and an LED lighting device used for penetrant inspection.

It is used for the purpose of examining the defects of the inspection subject by irradiating ultraviolet LED after spraying on the inspection subject using a spray.

At this time, the UV LED requires a distance of 38 m or more and an ultraviolet intensity of 800 μW/cm 2 or more, but it is not easy to measure a range that substantially satisfies the standards.

Due to this, there is a problem in that the uniformity of the defect detection capability is insufficient and the reliability of the quality inspection is lowered.

Republic of Korea Patent Registration No. 10-1334628 (2013.12.05)

The present invention has been made to solve the above problems, and an object of the present invention is to provide an ultraviolet irradiation device for non-destructive inspection that ensures distance and strength satisfying required standards.

In addition, it is to provide an ultraviolet irradiation device for non-destructive inspection that can prevent the reliability of quality inspection from deteriorating due to lack of uniformity in defect detection capability.

An ultraviolet irradiation device for non-destructive inspection according to an embodiment of the present invention for achieving the above object includes a mounting portion to which a spray can is mounted, a handle portion extended from the mounting portion and grasped by a worker's hand, and the A spraying part coupled to the mounting part and pressing the head of the spray can by an operator to spray the contents contained in the spray can, and an irradiation part located on the top of the head of the spray can and irradiating light and ultraviolet rays; A connection portion coupled to the irradiation portion and connecting the irradiation portion to the handle portion may be provided.

A display portion connected to the irradiation portion and displaying the distance of light reflected from the irradiation portion and the intensity of ultraviolet rays after being irradiated from the irradiation portion is further provided, and the irradiation portion includes a first irradiation portion for irradiating light to the test body and A second irradiation unit for irradiating ultraviolet rays, a light receiving unit for receiving light reflected after irradiation from the first irradiation unit, and a measurement unit for measuring intensity of ultraviolet rays reflected after irradiation from the second irradiation unit, The display unit may include a first display unit that displays the distance of the reflected light in association with the light receiving unit, and a second display unit that displays the intensity of the reflected ultraviolet light in association with the measurement unit.

A movable bracket coupled to the display portion to allow the display portion to move, the movable bracket having a thin plate shape and having a base plate provided between the irradiation portion and the display portion, and a width of the base plate A pair of swing plates positioned at both ends in the direction and provided in an upright shape, a curved inclined surface formed at the upper end of the swing plate, and a guide groove formed on the swing plate and provided in a curved shape along the inclined surface. can be provided.

The display portion is provided at both ends in the width direction and includes a guide protrusion fastened to the guide groove and moving along the guide groove, and the guide protrusion includes a slider positioned in the guide groove and extending from the slider to the guide protrusion. A protrusion body protruding from the groove, a first screw thread formed on an outer surface of the protrusion body, and a second screw thread engaged with the first screw thread on the guide protrusion to position the guide protrusion through a screw coupling method. It may be provided with a fixing cap that allows it to be fixed.

A control device provided on the movable bracket and linked to the irradiation part and the display part is further provided, wherein the control device includes a calculation unit for calculating a distance received through the light receiving unit and an intensity of ultraviolet rays measured through the measurement unit. An analysis unit for analysis, a first display unit for displaying different colors on the first display unit according to the calculated distance in connection with the calculation unit, and a first display unit for displaying different colors on the first display unit according to the calculated distance, and the second display unit according to the intensity of the analyzed ultraviolet rays in connection with the analysis unit. A second display unit for displaying different colors on the display unit may be provided.

According to the ultraviolet irradiation device for non-destructive inspection according to the present invention, it is possible to secure a distance and strength that satisfy the required standards.

In addition, it is possible to prevent reliability of quality inspection from deteriorating due to lack of uniformity in defect detection capability.

1 is a view showing an ultraviolet irradiation device for non-destructive inspection according to an embodiment of the present invention.
Figure 2 is a block diagram showing the ultraviolet irradiation device for non-destructive inspection shown in Figure 1;
Figure 3 is a view showing a state in which the ultraviolet irradiation device for non-destructive inspection shown in Figure 1 is used.
4 is a view showing a state in which a movable bracket is provided in the ultraviolet irradiation device for non-destructive inspection shown in FIG. 1;
Figure 5 is a view showing the movable bracket shown in Figure 4;
Figure 6 is a view showing the operation of the movable bracket shown in Figure 5;
7 is a block diagram showing a state in which a control device is provided in the ultraviolet irradiation device for non-destructive inspection shown in FIG. 4;
8 is a view showing a display portion displayed by the control device shown in FIG. 7;

Hereinafter, an ultraviolet irradiation device for non-destructive inspection according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing an ultraviolet irradiation device for non-destructive inspection according to an embodiment of the present invention.

As shown in FIG. 1, the ultraviolet irradiation device 10 for non-destructive inspection according to an embodiment of the present invention extends from the mounting portion 100 to which the spray bottle 20 is mounted, and the mounting portion 100, so that the operator A spray that combines the handle part 200 grasped by the hand and the mounting part 100 and presses the head part 21 of the spray bottle 20 by the operator to spray the contents contained in the spray bottle 20 The portion 300, the irradiation portion 400 located at the top of the head 21 of the spray bottle 20 to irradiate light and ultraviolet rays, and the irradiation portion 400 combined with the irradiation portion 400 to the handle portion It may be provided with a connection portion 500 connected to (200).

The contents contained in the spray bottle 20 are sprayed by pressing one end of the spraying portion 300 with the handle portion 200 while the operator is holding the handle portion 200 so that the other end is attached to the spray bottle 20 with the mounting portion 100 as an axis. ) It can be sprayed by being rotated to the head 21 and the head 21 being pressed.

After the contents are sprayed, the test object 40 can be inspected by setting the magnetic inspection device 30 to the test object 40.

Here, fluorescence magnetic inspection and liquid inspection should be conducted in a dark place with an illumination intensity of 20 lx or less due to the nature of the inspection application. is difficult to measure.

Next, the irradiation part 400 and the display part 600 to solve the above problems will be described. In the following description, only parts different from those of the above-described embodiment are described in detail, and detailed descriptions of the same or extremely similar parts are omitted.

2 is a block diagram showing the ultraviolet irradiation device for non-destructive inspection shown in FIG. 1, and FIG. 3 is a view showing how the ultraviolet irradiation device for non-destructive inspection shown in FIG. 1 is used.

1 to 3, the non-destructive inspection ultraviolet irradiation device 10 according to an embodiment of the present invention is connected to the irradiation part 400, and the distance of the light reflected after irradiation from the irradiation part 400 And a display portion 600 for displaying the intensity of ultraviolet light may be further provided.

In addition, the irradiation part 400 includes a first irradiation unit 410 for irradiating light to the test body 40, a second irradiation unit 420 for irradiating ultraviolet rays to the test body 40, and a first irradiation unit 410 for irradiating light. A light receiving unit 430 that receives the light that has been reflected after being irradiated and a measuring unit 440 that measures the intensity of the reflected ultraviolet light after being irradiated by the second irradiator 420 can be obtained.

The light irradiated from the first irradiation unit 410 is reflected from the specimen 40, and the reflected light may be received by the light receiving unit 430.

The ultraviolet rays irradiated from the second irradiation unit 420 are reflected from the test body 40, and the intensity of the reflected ultraviolet rays reflected from the measuring unit 440 can be measured.

Meanwhile, the display unit 600 includes a first display unit 610 that displays the distance of reflected light in association with the light receiving unit 430, and a second display unit 610 that displays the intensity of reflected ultraviolet rays in association with the measurement unit 440. A display unit 620 may be provided.

In this way, since it is possible to intuitively check the distance of the reflected light with the first display unit 610 and intuitively check the intensity of the reflected ultraviolet light with the second display unit 620, the distance required by the standard is provided. It can be easily confirmed whether or not the range of 38 cm or more and UV intensity of 800 μW/cm 2 or more is satisfied.

Accordingly, it is possible to exert an effect of preventing reliability of quality inspection from deteriorating due to lack of uniformity in defect detection capability.

Next, the movable bracket 700 provided in the ultraviolet irradiation device 10 for non-destructive inspection according to an embodiment of the present invention will be described. In the following description, only parts different from those of the above-described embodiment are described in detail, and detailed descriptions of the same or extremely similar parts are omitted.

4 is a view showing a state in which a movable bracket is provided in the ultraviolet irradiation device for non-destructive inspection shown in FIG. 1, FIG. 5 is a view showing the movable bracket shown in FIG. 4, and FIG. 6 is a view showing the movable bracket shown in FIG. This is a diagram showing how the bracket works.

1 to 6, the non-destructive inspection ultraviolet irradiation device 10 according to an embodiment of the present invention includes a movable bracket 700 coupled to the display portion 600 to allow the display portion 600 to move. more can be provided.

Looking in detail at the movable bracket 700, the movable bracket 700 is provided in the shape of a thin plate and includes a base plate 710 provided between the irradiation part 400 and the display part 600, and the base plate 710. A pair of swing plates 720 each located at both ends in the width direction and provided in an upright form, a curved inclined surface 730 formed at the top of the swing plate 720, and formed on the swing plate 720 A guide groove 740 provided in a curved shape along the inclined surface 730 may be provided.

The movable bracket 700 is provided in a 'U' shape by a base plate 710 and a pair of swing plates 720, and the swing plate 720 has one side higher than the other side by an inclined surface 730, and , The guide groove 740 may be provided long from one side to the other side along the inclined surface 730 .

The display part 600 can move on the movable bracket 700 by being combined with the movable bracket 700 .

To this end, the display portion 600 is provided at both ends in the width direction and has guide projections 630 that are fastened to the guide grooves 740 and move along the guide grooves 740, and the guide projections 630 are guide grooves. A slider 631 positioned at 740, a protruding body 632 extending from the slider 631 and protruding from the guide groove 740, and a first screw thread 633 formed on an outer surface of the protruding body 632 And, the guide protrusion 630 is provided with a second screw thread 810 engaged with the first screw thread 633 so that the position of the guide protrusion 630 is fixed through a screw coupling method. can be provided

The display portion 600 is provided to correspond to the base plate 710 in the inner space formed by the base plate 710 and the pair of swing plates 720, and the slider 631 is located in the guide groove 740, , The protruding body 632 may be provided in a form protruding to the outside of the movable bracket 700.

The fixing cap 800 is coupled to the protruding body 632 protruding out of the movable bracket 700, and the protruding body 632 and the fixing cap 800 are provided with a first screw thread 633 and a second screw thread, respectively. It can be coupled through the screw coupling method of (810).

In normal times, the slider 631 is positioned at the lowermost end of the swing plate 720 so that the display portion 600 corresponds to the base plate 710, and the position of the display portion 600 is fixed by tightening the fixing cap 800. can

When it is necessary to verify the distance and UV intensity, the fixing cap 800 is first unscrewed, and then the operator pushes the fixing cap 800 by hand so that the slider 631 moves along the guide groove 740 and swings the plate 720. It is possible to fix the position of the display portion 600 located at the top of the swing plate 720 by positioning it at the top of and tightening the fixing cap 800 .

Here, the display portion 600 is tilted toward the operator's line of sight at a certain angle by the swing plate 720, so that the area that the operator can see can be widened.

Accordingly, since the movable bracket 700 can be combined with the display portion 600 to easily check the distance and UV intensity, the effect of increasing work efficiency can be exhibited.

Next, the control device 900 provided in the ultraviolet irradiation device 10 for non-destructive inspection according to an embodiment of the present invention will be described. In the following description, only parts different from those of the above-described embodiment are described in detail, and detailed descriptions of the same or extremely similar parts are omitted.

FIG. 7 is a block diagram showing a state in which a control device is provided in the ultraviolet irradiation device for non-destructive inspection shown in FIG. 4 , and FIG. 8 is a view showing a display portion displayed by the control device shown in FIG. 7 .

1 to 8, the non-destructive inspection ultraviolet irradiation device 10 according to an embodiment of the present invention is provided on a movable bracket 700 and is controlled in conjunction with the irradiation part 400 and the display part 600. Device 900 may be further provided.

Looking in detail at the control device 900, the control device 900 includes a calculation unit 910 that calculates the distance received through the light receiving unit 430, and an analysis unit that analyzes the intensity of ultraviolet rays measured through the measurement unit 440. 920, the first display unit 930 that displays different colors on the first display unit 610 according to the calculated distance in connection with the calculation unit 910, and the analysis unit 920 to display the analyzed A second display unit 940 may be provided so that different colors are displayed on the second display unit 620 according to the intensity of ultraviolet rays.

A reference value of 38 cm is set in the calculation unit 910, and a calculation operation of comparing the distance of light received through the light receiving unit 430 with the reference value is performed, and the distance of light received through the light receiving unit 430 is shorter than the reference value. When the distance of the light received through the light receiving unit 430 is longer than the reference value or equal to each other, the first display unit 930 displays a green background through the first display unit 930. The received distance can be displayed on .

On the other hand, a reference value of 800 ㎼ / cm 2 is set in the analysis unit 920, and an analysis operation of comparing the ultraviolet intensity measured through the measurement unit 440 with the reference value is performed, and the value measured through the measurement unit 440 is higher than the reference value. When the intensity of ultraviolet rays is weak, the intensity measured through the second display unit 940 is displayed on a red background, and when the intensity measured through the measurement unit 440 is higher than the reference value or equal to each other, the second display unit 940 is displayed. Through this, the measured intensity can be displayed on a green background.

In this way, it is possible to easily determine whether or not the range is satisfied by distinguishing whether or not the range is satisfied by using the distance and UV intensity required by the standard as reference values, thereby increasing work efficiency.

In an embodiment of the present invention, it has been described that red and green are displayed on the first and second display units 930 and 940, but the first display unit 930 and the second display unit 940 do not have a field Depending on circumstances or preferences, various colors may be used and displayed.

In the above, the ultraviolet irradiation device for non-destructive inspection according to an embodiment of the present invention has been described, but the spirit of the present invention is not limited to the embodiments presented herein. And those skilled in the art who understand the spirit of the present invention may easily suggest other embodiments by adding, changing, deleting, adding, etc. of elements within the scope of the same spirit, but this is also within the spirit of the present invention. will be.

10: UV irradiation device for non-destructive inspection
20: spray bottle 21: head
30: magnetic inspection device 40: test specimen
100: mounting part 200: handle part
300: injection part 400: irradiation part
410: first investigation unit 420: second investigation unit
430: light receiving unit 440: measuring unit
500: connection part 600: display part
610: first display unit 620: second display unit
630: guide protrusion 631: slider
632: projection body 633: first screw thread
700: movable bracket 710: base plate
720: swing plate 730: slope
740: guide groove 800: fixed cap
810: second thread 900: control device
910: calculation unit 920: analysis unit
930: first outlet 940: second outlet

Claims (5)

A mounting part to which the spray bottle is mounted;
A handle part extended from the mounting part and grasped by the operator's hand;
A spraying portion coupled to the mounting portion and pushing the head of the spray bottle by an operator to spray the contents contained in the spray bottle;
An irradiation part located at the top of the head of the spray can and irradiating visible and ultraviolet rays;
A connection portion coupled to the irradiation portion and connecting the irradiation portion to the handle portion;
A display portion connected to the irradiation portion and displaying the distance of the visible light rays reflected from the irradiation portion and the intensity of ultraviolet rays after being irradiated by the irradiation portion is further provided, and the irradiation portion includes a first irradiation portion for irradiating visible rays to the test body; A second irradiation unit for irradiating ultraviolet rays, a light receiving unit for receiving visible light reflected after irradiation from the first irradiation unit, and a measurement unit for measuring the intensity of ultraviolet rays reflected after irradiation from the second irradiation unit, , Non-destructive inspection characterized in that the display portion comprises a first display unit displaying the distance of the reflected visible light in association with the light receiving unit, and a second display unit displaying the intensity of reflected ultraviolet rays in association with the measurement unit. UV irradiation device for
delete According to claim 1,
Further comprising a movable bracket coupled to the display portion so that the display portion is movable;
The movable bracket includes a base plate provided in the shape of a thin plate and provided between the irradiation part and the display part, a pair of swing plates positioned at both ends of the base plate in the width direction and provided in an upright form; An ultraviolet irradiation device for non-destructive inspection, characterized in that it comprises a curved inclined surface formed on the upper end of the swing plate and a guide groove formed on the swing plate and provided in a curved shape along the inclined surface.
According to claim 3,
The display portion is provided at both ends in the width direction and has guide protrusions fastened to the guide groove and moving along the guide groove,
The guide protrusion includes a slider positioned in the guide groove, a protrusion body extending from the slider and protruding from the guide groove, and a first screw thread formed on an outer surface of the protrusion body,
The guide protrusion is provided with a second screw thread engaged with the first screw thread, and a fixing cap for fixing the position of the guide protrusion through a screw coupling method.
According to claim 4,
A control device provided on the movable bracket and linked to the irradiation part and the display part is further provided,
The control device includes a calculation unit for calculating a distance received through the light receiving unit;
An analysis unit for analyzing the intensity of ultraviolet rays measured through the measurement unit;
A first display unit for displaying different colors on the first display unit according to the calculated distance in connection with the operation unit;
An ultraviolet irradiation device for non-destructive inspection, characterized in that it has a second display unit for displaying different colors on the second display unit according to the intensity of the analyzed ultraviolet rays in connection with the analysis unit.

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