KR100921501B1 - Water tank for ultrasonic reflectoscope - Google Patents

Abstract

The present invention relates to an ultrasonic flaw detector tank, a reaction tank in which pure water is stored, a collecting tank into which the pure water stored in the reaction tank flows, a filtering tank for filtering the pure water of the collection tank to be supplied to the reaction tank, and seated inside the reaction tank. There is provided an ultrasonic flaw detector comprising a leveling unit for adjusting the level of the specimen. Therefore, it is possible to quickly perform the ultrasonic flaw detection of the specimen by preventing a defect factor during the ultrasonic flaw detection of the specimen, there is an effect that can improve the reliability in the ultrasonic flaw detection results.

Specimen, Ultrasonic Testing, Inspection, Prevention

Description

Ultrasonic flaw detector {WATER TANK FOR ULTRASONIC REFLECTOSCOPE}

The present invention relates to an ultrasonic flaw detection tank, and more particularly, it is possible to quickly perform a quality inspection of a specimen by preventing defects generated when inspecting the quality of the specimen using ultrasonic waves, and improving the reliability of the inspection results. It relates to an ultrasonic flaw detector tank that can be made.

Ultrasonic flaw detectors are generally used to inspect the surface or internal quality of cast steel. Ultrasonic flaw detectors for quality testing of cast steels use the phenomenon that sound waves are reflected within the boundary of media with different characteristics (especially density). Device. 1 is a perspective view showing an ultrasonic flaw detector and a water tank.

Referring to the drawings, when the specimen 10 is cut to a certain size from the cast through the playing process, the specimen is seated in the open tank 20 and the pure water 30 in the tank 20 Will be saved. An ultrasonic transducer 40 for generating ultrasonic waves toward the specimen 10 is installed at the upper portion of the water tank 20, and the ultrasonic transducer 40 is installed in the manipulator 50. The ultrasonic transducer 40 scans the surface or the inside of the specimen 10 by the manipulator 50 freely moving along the surface of the specimen in the water tank 20 and outputs the result to confirm the quality of the specimen. do.

However, when the ultrasonic inspection of the specimen using the water tank as described above, the ultrasonic flaw detection of the specimen is caused by the following factors.

end. If a deviation occurs in the horizontality of the specimen seated in the bath, it affects the sensitivity of the ultrasonic return to the ultrasonic probe and is recognized as a defect in the specimen.

I. The machined surface of the specimen reacts with the oxygen of the pure water stored in the bath and is corroded and recognized as a defect.

All. The dissolved gas generated by the difference in the solubility of the pure water stored in the tank moves to the surface of the specimen, attracts foreign matter suspended in the pure water, attaches bubbles to the surface of the specimen, and recognizes the bubbles as defects generated on the surface of the specimen.

la. Since the pure water stored in the tank is also used for the ultrasonic inspection of other specimens, foreign matter suspended in the pure water increases with the ultrasonic inspection number of the specimen and contaminates the pure water.

Ultrasonic flaw detection of the specimen caused by the above factors lowers the reliability of the test result. Accordingly, the ultrasonic probe repeatedly scans the surface or the inside of the specimen to reduce the error of the ultrasonic test result. It takes a lot of time to detect. In addition, the surface corrosion and foreign matter adhesion of the specimen generated by the ultrasonic flaw as described above will adversely affect the inspection of the subsequent process.

The present invention is to solve the above problems, to prevent the ultrasonic flaw detection of the specimen to quickly perform the ultrasonic flaw detection of the specimen, to improve the level of reliability of the ultrasonic flaw detection tank to the horizontal degree of the tank It is an object of the present invention to provide an ultrasonic flaw tank that can adjust, and does not generate corrosion and bubbles on the surface of the specimen contained in pure water, and can reduce the pollution degree of pure water.

According to the technical idea of the present invention for achieving the above object, a reaction tank in which pure water is stored, a collecting tank into which the pure water stored in the reaction tank flows, a filtering tank for filtering the pure water of the collection tank and supplying it to the reaction tank, It is achieved by the ultrasonic flaw detection tank including a horizontal adjustment unit for adjusting the horizontal degree of the specimen seated inside the reactor.

Here, the separation plate is installed on the inner bottom surface of the reaction vessel, it is preferable to include a mounting plate is installed on the upper surface of the separation plate and the specimen is seated.

In addition, it is preferable that a flow path is formed in the separation plate and the seating plate so that the pure water stored in the reaction tank flows into the collection tank.

In addition, the observation window is preferably formed on the side wall of the reactor.

In addition, it is preferable that a shielding plate is installed in the reaction tank so as to be partitioned into a collection tank and a filtration tank.

In addition, the shielding plate installed between the reaction tank and the collection tank is preferably open to the bottom.

In addition, the shielding plate provided between the filtration tank and the reaction tank is preferably lower than the reaction vessel side wall.

In addition, it is preferable that a pump for forcibly draining pure water to the filtration tank is installed in the sump tank.

In addition, it is preferable that a filter for filtering pure water is provided on the inner upper portion of the filtration tank.

In addition, the material of the reaction tank, the collection tank and the filtration tank is preferably aluminum or aluminum alloy.

Moreover, it is preferable that the said pure water contains 0.06 to 0.08% of water-soluble rust inhibitors.

Ultrasonic flaw detection tank according to the present invention, the water-soluble rust preventive agent is contained in the pure water to prevent the surface corrosion of the specimen, the material is made of aluminum or aluminum alloy, the pure water is stable, the foreign matter contained in the pure water is filtered Since it is supplied, bubbles generated on the surface of the specimen can be reduced. In addition, since the pollution of the pure water can be reduced and used repeatedly, the loss of pure water can be reduced.

Accordingly, it is possible to quickly perform the ultrasonic flaw detection of the specimen by preventing a defect factor during the ultrasonic flaw detection of the specimen, there is an effect that can improve the reliability in the ultrasonic flaw detection results.

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

Figure 2 is a perspective view of the ultrasonic flaw detection tank according to the present invention, Figure 3 is an exploded perspective view of the ultrasonic flaw detection tank according to the present invention.

Referring to the drawings, the ultrasonic flaw detector 100 according to the present invention includes a reaction tank 110 in which a specimen cut into a predetermined size from a cast steel that has undergone a playing process is seated and pure water is stored therein, and the reaction tank 110. ) The water collecting tank 120 is partitioned inside and the pure water stored in the reaction tank 110 and the filtering tank 130 for filtering the pure water of the collecting tank 120 to supply to the reaction tank 110, and the reaction tank 110 Installed on the outer bottom surface is composed of a horizontal adjustment unit 140 for adjusting the horizontal degree of the specimen seated in the reaction tank (110). Here, the reaction tank 110, the sump tank 120, and the filtration tank 130 in which the pure water circulates are made of aluminum or an aluminum alloy material that does not react with oxygen contained in the pure water.

The reactor 110 has an area that allows the specimen to be ultrasonically inspected on a plane and has a box shape with an upper surface open so that pure water can be stored therein, and pure water is provided on the sidewall of the reactor 110. A drain 101 for supplying or draining water is provided. In addition, an observation window 102 made of a transparent material is formed on the sidewall of the reaction tank 110 so as to grasp the level of the specimen and the level of pure water located on the seating plate 104. At this time, the pure water stored in the reaction tank 110 preferably contains 0.06 to 0.08% of a water-soluble rust inhibitor to form an oxide film on the surface of the specimen to prevent corrosion of the pure oxygen reacts on the surface of the specimen.

In addition, a spacer plate 112 is installed on the inner bottom surface of the reaction tank 110, and a seating plate 114 on which a specimen is mounted is installed on an upper surface of the spacer plate 112. The separation plate 112 is formed with a groove 112a for guiding pure water to the sump tank 120 so that pure water flows into the sump tank 120, and the seating plate 114 has a specimen on the seating plate 114. When it is positioned to prevent the specimen from being in close contact with the seating plate 114, while the pure water stored in the reaction tank 110 can flow to the separation plate 112 through the through hole 114a of the seating plate 114. A plurality of through holes 114a are formed.

That is, a flow path is formed in the separation plate 112 and the seating plate 114 to allow the pure water stored in the reaction tank 110 to flow into the water collecting tank 120. The flow path is formed of the seating plate 114 described above. The groove 112a of the through hole 114a and the spacer plate 112 is not limited thereto, and may be variously implemented. For example, a gap is formed between the seating plate 114 and the side wall of the reactor 110, and a cylindrical spacer plate 112 having a predetermined height is mounted so that the seating plate 114 does not contact the bottom of the reactor. A flow path may be formed between the plate 114 and the reaction tank 110 through which pure water flows into the water collecting tank 120.

The first shielding plate 104, the second shielding plate 106, and the third shielding plate 108 are formed in the reaction tank 110 to be partitioned into the sump tank 120 and the filtration tank 130. The first shielding plate 104 is installed between the reaction tank 110 and the collecting tank 120, the lower portion of the first shielding plate 104 is opened so that the pure water of the separation plate 112 flows into the collecting tank 120.

In addition, a pump 122 is installed in the sump tank 120 to pull up the pure water into the filtration tank 130, and the pure water drawn up by the pump 122 from the sump tank 120 is lowered from the bottom of the filtration tank 130. A water supply pipe 124 is installed at a lower portion of the second shielding plate 106 provided between the sump tank 120 and the filtration tank 130 so as to rise, and the pump 122 and the second shielding plate (installed in the sump tank 120). The water supply pipe 124 installed at 106 is connected to the fluid line.

The filtration tank 130 is a filter 132 is installed on the inner upper portion of the filtration tank 130 to filter the foreign matter contained in the pure water, the filter 132 is a fixed plate partitioning the filtration tank 130 horizontally Seated at 134, the filter 132 is supported by a press plate 136 that presses the filter 132 with a predetermined weight so that it is not floated by the pure water rising from the bottom of the filtration tank 130.

Here, the filter 132 may be combined with a sponge, a loofah and a glass ball to filter out fine foreign matter contained in pure water. In addition, the fixing plate 134 and the press 2 plate 136 are formed with a plurality of through holes 138 to allow the pure water to pass therethrough. In addition, the third shielding plate 108 installed between the filtration tank 130 and the reaction tank 110 has an upper portion than the sidewall of the reaction tank 110 so that the pure water of the filtration tank 130 flows into the reaction tank 110. Formed low.

And, the lower portion of the reaction tank 110 is provided with a horizontal adjusting unit 140 to adjust the horizontal degree of the specimen located in the seating plate 114, the horizontal adjusting unit 140 is a support plate 142 installed on the ground The first post 144 having a predetermined height, a connection core 146 which does not deviate from the upper end of the first post 144, and is idling, and threads and bottoms formed in the inner diameter of the connection core 146. It is composed of a second post 148 that is engaged and the upper end is fixed to the outer bottom surface of the reactor (110).

The leveling unit 140 as described above is installed along the lower edge of the reaction tank 110, wherein the leveling unit 140 is not limited only by the above-described configuration, and also has an equivalent function It may be replaced with another configuration. For example, a cylinder lifted by hydraulic or pneumatic pressure may be installed along the lower edge of the reactor 110.

The operation of the ultrasonic flaw detector tank having the above configuration will be described based on FIG. 4. 4 is a cross-sectional view taken along the line A-A of FIG.

It will be described with reference to the drawings, when the specimen 10 cut to a certain size from the slab undergoing the playing process to the seating plate 114 of the reactor 110 is seated, the train 101 is installed on the side wall of the reactor 110 Pure water containing 0.06% to 0.08% of a water-soluble rust preventive agent is supplied to the reaction tank 110). The water-soluble rust preventive agent prevents surface corrosion of the specimen 10 by forming an oxide film on the surface of the specimen 10 located in the reaction tank 110.

When the specimen 10 is immersed in pure water, an ultrasonic flaw detector (not shown) generates ultrasonic waves toward the specimen 10 at the upper portion of the reaction tank 110. At this time, the ultrasonic wave generated by the ultrasonic flaw detector measures the horizontal deviation of the specimen located on the seating plate 114 and outputs it to the worker. When the horizontal deviation of the specimen is output to the operator, the operator adjusts the horizontal deviation of the measured specimen 10 through the horizontal adjustment unit 140 installed in the lower portion of the reaction tank.

That is, when the specimen 10 is inclined downward toward one side, the second core 148 is raised by rotating the connecting core 146 of the opposing horizontal adjustment unit 140 to raise the horizontal posture of the specimen 10. Will be adjusted. As such, when the horizontal deviation of the specimen 10 is adjusted, the ultrasonic sensitivity of returning to the ultrasonic probe from the specimen located in the reaction tank 110 is improved, thereby preventing the ultrasonic flaw detection due to the decrease in the ultrasonic sensitivity.

When the horizontal deviation of the specimen is adjusted as described above, the ultrasonic flaw detector moves along the surface of the specimen to scan the surface or the inside of the specimen and outputs the result to the operator to check the quality of the specimen.

When the quality of the specimen is confirmed as described above, the pump 122 installed in the collection tank 120 is operated. The pure water stored in the reaction tank 110 is connected to the through hole 114a of the seating plate 114 located at the bottom of the specimen. Along the groove 112a of the separation plate 112, the water is introduced into the collection tank 120 through the lower portion of the first shielding plate 104. The pure water introduced into the collection tank 120 is pulled up by the pump 122 and supplied to the filtration tank 130 through the water supply pipe 124 of the second shielding plate 106.

At this time, the pure water supplied from the water collecting tank 120 to the filtration tank 130 is pulled up from the bottom of the filtration tank 130 and passes through the filter 132 installed on the filtration tank 130 while filtering the foreign substances contained in the pure water. Will be filtered. The pure water filtered out of the foreign substance flows back to the reactor 110 through the upper portion of the third shielding plate 108 and is supplied again. When the pure water is re-supplied to the reaction tank in the filtered state in the filter tank 130 as described above, the dissolved gas of the pure water is moved to the surface of the specimen to prevent foreign substances from attracting foreign substances to reduce bubbles generated on the surface of the specimen. It will prevent flaw detection.

On the other hand, the present invention is not limited only to the embodiments described above, but can be modified and modified within the scope not departing from the gist of the present invention, it should be seen that such modifications and variations are included in the technical idea of the present invention. do.

For example, a cover (not shown) may be installed on the upper portion of the reaction tank to prevent foreign substances from flowing into the pure water of the reaction tank.

1 is a perspective view showing an ultrasonic flaw detector and a water tank.

Figure 2 is a perspective view of the ultrasonic flaw detector according to the present invention.

Figure 3 is an exploded perspective view of the ultrasonic flaw detector according to the present invention.

4 is a cross-sectional view taken along the line A-A of FIG.

<Description of Symbols for Main Parts of Drawing>

100: ultrasonic flaw detector 110: reaction tank

102: observation window 104: first shielding plate

106: second shielding plate 108: third shielding plate

112: separation plate 114: seating plate

120: sump 122: pump

130: filtration tank 132: filter

140: leveling unit 144: first post

146: connecting core 148: second post

Claims (11)

A reaction tank in which pure water is stored, A collection tank into which the pure water stored in the reactor flows, A filtration tank for filtering the pure water in the sump and feeding the reaction tank; A horizontal adjusting unit for adjusting a horizontal degree of the specimen seated inside the reactor; Ultrasonic flaw detection tank including a shield plate is installed so that the inside of the reaction tank is divided into a collection tank and a filtration tank. The method according to claim 1, A separation plate installed on the inner bottom surface of the reactor; Ultrasonic flaw detection tank including a seating plate is installed on the upper surface of the separation plate and the specimen is seated. The method according to claim 2, Ultrasonic flaw detection tank, characterized in that the flow path is formed in the separation plate and the seating plate so that the pure water stored in the reaction tank flows into the sump. The method according to claim 1, Ultrasonic flaw detection tank, characterized in that the observation window is formed on the side wall of the reaction tank. delete The method according to claim 1, Ultrasonic flaw detection tank characterized in that the shield plate is installed between the reaction tank and the sump tank. The method according to claim 1, The shielding plate installed between the filtration tank and the reaction tank has an upper portion of the flaw detection tank, characterized in that lower than the reaction vessel side wall. The method according to claim 1, Ultrasonic flaw detection tank, characterized in that the pump is installed to forcibly drain the pure water to the filter tank. The method according to claim 1, Ultrasonic flaw detection tank characterized in that a filter for filtering pure water is installed on the inner upper portion of the filtration tank. The method according to claim 1, Ultrasonic flaw detection tank, characterized in that the material of the reaction tank, the sump tank and the filtration tank is aluminum or aluminum alloy. The method according to claim 1, The pure water is an ultrasonic flaw detection tank comprising a water-soluble rust inhibitor 0.06 ~ 0.08%.

Images