KR20080057674A - Sand blast abrasion test apparatus - Google Patents

Abstract

A sand blast abrasion test apparatus is provided to prevent damage to a sensor as well as to increase in measurement accuracy by installing the sensor adjacent to a sample. A sand blast abrasion test apparatus includes a sample stage(140), a hopper, a nozzle(120), a sensor(200), and a controller. The hopper contains abrasive for abrading a sample loaded on the sample stage. The nozzle sprays the abrasive to the sample on the sample stage. The sensor detects abrasion of the sample abraded by the abrasive. The controller stops spraying the abrasive from the nozzle when the abrasion of the sample reaches a predetermined level.

Description

Sand blast abrasion test apparatus

1 is a schematic view of a sand blast wear test apparatus according to a first embodiment of the present invention;

FIG. 2 is an enlarged view of a portion A shown in FIG. 1. FIG.

Figure 3 is a schematic view of a sand blast wear test apparatus according to a second embodiment of the present invention.

4 is an enlarged view of a portion B shown in FIG. 3.

<Explanation of symbols for the main parts of the drawings>

100 sandblast wear test device 110 hopper

120: nozzle 130: air compressor

140: Psalm stage 141: Psalm

150: abrasive collector 160: the basket

170: load cell 180: control unit

200, 210: sensor

The present invention relates to a sand blast wear test apparatus.

Sand blast refers to a method of neatly finishing the surface of metal products such as castings by blowing sand. As a method of spraying such sand, there are a method using compressed air and a method using centrifugal force.

In general, the sandblast wear test as described above is carried out for the quality test for such a coating layer on a product in which an organic coating layer such as a polymer is disposed on a steel sheet. In such abrasion test, abrasion is continued until the surface of the steel sheet, which is the base layer, is exposed to the outside, and the abrasion coefficient is calculated. The wear factor is expressed as a coating layer thickness (μm) relative to the weight (g) of the abrasive used.

However, according to the conventional sand blast wear test apparatus, the equipment was directly stopped after the tester observed until the organic coating layer was completely worn, and the weight of the abrasive was directly measured. Therefore, the wear test is dependent on the naked eye of the tester, there is a disadvantage that the accuracy of the wear test falls. In addition, since the weight of the abrasive is directly measured and continuous observation of the tester is required during the test, the wear test is inconvenient to perform.

It is an object of the present invention to provide a sand blast wear test apparatus having a structure in which a wear test on a specimen can be automatically performed so that the accuracy and test convenience of the wear test can be improved.

Sandblast wear test apparatus according to the present invention is a device capable of performing a wear test on a specimen, the specimen stage is disposed; A hopper for accommodating an abrasive material to wear off the specimen disposed on the specimen stage; An injection device for injecting the abrasive contained in the hopper through a nozzle to the specimen disposed on the specimen stage; A sensor for detecting a degree of polishing of the specimen by the abrasive injected by the injection device; And a control unit which stops spraying of the abrasive from the spraying device when the degree of polishing of the specimen detected by the sensor reaches a predetermined level.

According to the sand blast wear test apparatus according to the present invention, a sensor for measuring the degree of polishing of a specimen which is a wear test target and a control unit for automatically controlling the operation of the wear test apparatus based on data of the sensor are provided. Therefore, since the operation of the sand blast wear test apparatus can be automatically controlled according to the degree of polishing of the specimen, the accuracy of the wear test results on the specimen can be improved, and the working convenience of such abrasion test can be improved.

Further, according to the sand blast wear test apparatus, a load cell capable of automatically measuring the amount of abrasive used in the wear test is provided. Thus, since the amount of abrasive for abrasion of the specimen in the load cell can be measured automatically, the accuracy of the abrasion test results for the specimen can be improved, and the working convenience of such abrasion test can be improved.

In addition, according to the sand blast wear test apparatus, the sensor is installed perpendicular to the distal end of the nozzle or the specimen stage. Therefore, it is possible to prevent the damage of the sensor by the abrasive injected from the nozzle while improving the measurement accuracy for the specimen by placing the sensor so as to be close to the specimen.

Hereinafter, a sandblast wear test apparatus according to embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a view schematically showing a sand blast wear test apparatus according to a first embodiment of the present invention, Figure 2 is an enlarged view of the portion A shown in FIG.

1 and 2 together, the sand blast wear test apparatus 100 according to this embodiment includes a hopper 110, a nozzle 120, an air compressor 130, and a specimen stage 140. ), An abrasive collector 150, a basket 160, a load cell 170, a controller 180, and a sensor 200.

The sand blast wear test apparatus 100 configured as described above performs a wear test on a specimen 141 disposed on the specimen stage 140.

The hopper 110 has an abrasive contained therein. The abrasive contained in the hopper 110 is sprayed onto the specimen 141 disposed on the specimen stage 140 through the nozzle 120 to wear the specimen 141.

The hopper 110 may be formed in a funnel shape, and a hole connected to the nozzle 120 may be formed at a lower portion of the center, and the abrasive may be supplied to the nozzle 120 through the hole.

The nozzle 120 is a portion through which the abrasive supplied from the hopper 110 passes. The nozzle 120 is supplied with air having a predetermined pressure generated by the air compressor 130. This supplied air increases the speed of the abrasive supplied in the nozzle 120. Then, the abrasive passing through the nozzle 120 may be strongly impacted on the specimen 141 of the specimen stage 140 disposed below the nozzle 120. Such a collision may cause the specimen 141 to be worn.

The nozzle 120 and the air compressor 130 are parts for supplying an abrasive to the specimen 141 and may be defined as injection devices.

Here, the air compressor 130 is connected to the nozzle 120, the sand blast wear test device 100 is presented as using the compressed air, but this is exemplary, the present invention is not limited thereto. . That is, the sand blast wear test apparatus 100 may be provided in a structure using a centrifugal force in addition to the method of injecting the compressed air.

The upper surface of the specimen stage 140 forms a shape inclined at a predetermined angle. The specimen 141 is installed on the inclined top surface. The specimen 141 is in a state in which an organic coating layer is formed. When formed as described above, after the abrasive injected from the nozzle 140 collides with the specimen 141, it may fall along the inclined surface of the specimen stage 140. Then, the collection of the abrasive after the impact on the specimen 141 can be facilitated.

The sensor 200 is a part for measuring the wear level of the specimen 141. As the sensor 200, a magnetic sensor may be used. When the magnetic sensor is used as the sensor 200, the base layer of the specimen 141 made of ferromagnetic steel is gradually exposed as the organic coating layer of the specimen 141 is removed by the abrasive, so that the sensor 200 is exposed. Intensity of the signal measured in the becomes stronger, the wear level of the specimen 141 can be determined by this signal strength. This determination may be performed by the controller 180 receiving the data measured by the sensor 200.

Here, it is shown that a magnetic sensor is used as the sensor 200, but this is exemplary, and the present invention is not limited thereto. That is, various sensors and structures corresponding to the wear level of the specimen 141 may be applied.

In this embodiment, the sensor 200 is disposed at the distal end of the nozzle 120. Then, the sensor 200 is disposed to be close to the specimen 141 to improve the measurement accuracy of the specimen 141 and to damage the sensor 200 by the abrasive sprayed from the nozzle 120. You can prevent it.

When the sensor 200 is a magnetic sensor, the nozzle 120 may be made of a nonmagnetic material such as glass having a higher hardness than the abrasive. Then, it is possible to minimize the influence on the sensor 200 of the nozzle 120 while preventing the wear of the nozzle 120 by the abrasive.

In addition, the specimen stage 140 may be made of nonmagnetic material for the same reason. Examples of such materials include austenitic stainless steel, plastics, and polymers.

After colliding with the specimen 141, the abrasive dropped along the top surface of the specimen stage 140 is dropped into the abrasive collector 150. The abrasive collector 150 is disposed below the specimen stage 140, and an opening of a portion facing the specimen stage 140 is larger than an opening of the lower side opposite to the specimen stage 140. That is, the abrasive collector 150 may be formed in a funnel shape. By achieving the shape as described above, the collection of the abrasive dropped to the abrasive collector 150 can be made smoothly.

The basket 160 is disposed below the abrasive collector 150 to accommodate abrasives that have passed through the abrasive collector 150.

The load cell 170 is disposed to contact the lower end of the basket 160 to measure the weight of the abrasive contained in the basket 160. The weight of the abrasive measured in the load cell 170 is data that can be converted into the amount of abrasive used in the wear test on the specimen 141 in the sand blast wear test apparatus 100.

When the degree of polishing of the specimen 141 detected by the sensor 200 reaches a predetermined level, the controller 180 stops spraying of the abrasive from the nozzle 120. The stopping of the abrasive injection may be performed by stopping the air compressor 130 or the like.

In the present embodiment, based on the data on the degree of polishing of the specimen 141 detected by the sensor 200, the control unit 180 may automatically stop the wear test on the specimen 141. Therefore, since the operation of the sand blast wear test apparatus 100 can be automatically controlled according to the degree of polishing of the specimen 141, the accuracy of the wear test results for the specimen 141 can be improved, The ease of operation of such abrasion tests can be improved.

In addition, since the amount of abrasive for abrasion of the specimen 141 in the load cell 170 can be automatically measured, the accuracy of the abrasion test results for the specimen 141 can be improved, and such abrasion test Work convenience can be improved.

Hereinafter, another embodiment of the present invention will be described with reference to the drawings. In carrying out this description, descriptions that overlap with those described in the above-described first embodiment will be replaced by the description thereof and will be omitted herein.

Figure 3 is a schematic view showing a sand blast wear test apparatus according to a second embodiment of the present invention, Figure 4 is an enlarged view of the portion B shown in FIG.

3 and 4 together, in the sand blast wear test apparatus 100 according to the present embodiment, the sensor 210 is installed perpendicular to the specimen stage 140.

When installed as described above, by placing the sensor 210 to be close to the specimen 141 to improve the measurement accuracy of the specimen 141, the sensor 210 by the abrasive injected from the nozzle 120 ) Can be prevented.

According to the sand blast wear test apparatus according to the present invention, a sensor for measuring the degree of polishing of a specimen which is a wear test target and a control unit for automatically controlling the operation of the wear test apparatus based on data of the sensor are provided. Therefore, since the operation of the sand blast abrasion test apparatus can be controlled automatically according to the degree of grinding of the specimen, the accuracy of the abrasion test result on the specimen can be improved, and the work convenience of such abrasion test can be improved. have.

Further, according to the sand blast wear test apparatus, a load cell capable of automatically measuring the amount of abrasive used in the wear test is provided. Therefore, since the amount of abrasive for the wear of the specimen in the load cell can be automatically measured, the accuracy of the wear test results on the specimen can be improved, and the work convenience of such abrasion test can be improved.

In addition, according to the sand blast wear test apparatus, the sensor is installed perpendicular to the distal end of the nozzle or the specimen stage. Therefore, while placing the sensor so as to be close to the specimen to improve the measurement accuracy for the specimen, there is an effect that can prevent the damage of the sensor by the abrasive injected from the nozzle.

While the invention has been shown and described with respect to specific embodiments thereof, those skilled in the art can variously modify the invention without departing from the spirit and scope of the invention as set forth in the claims below. And that it can be changed. Nevertheless, it will be clearly understood that all such modifications and variations are included within the scope of the present invention.

Claims (6)

In a sand blast wear test apparatus capable of performing a wear test on a specimen, A specimen stage in which the specimen is disposed; A hopper for accommodating an abrasive material to wear off the specimen disposed on the specimen stage; An injection device for injecting the abrasive contained in the hopper through a nozzle to the specimen disposed on the specimen stage; A sensor for detecting a degree of polishing of the specimen by the abrasive injected by the injection device; And And a control unit which stops spraying of the abrasive from the spraying apparatus when the degree of polishing of the specimen detected by the sensor reaches a predetermined level. The method of claim 1, Sand sensor wear test apparatus, characterized in that the magnetic sensor. The method of claim 2, And at least one of the nozzle and the specimen stage is made of a nonmagnetic material. The method of claim 1, Sand sensor wear test apparatus, characterized in that the sensor is installed on the end of the nozzle. The method of claim 1, Sand sensor wear test apparatus, characterized in that the sensor is installed perpendicular to the specimen stage. The method of claim 1, Sandblast wear test apparatus further comprises a load cell for measuring the amount of abrasive used in the test on the specimen.

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