KR102031197B1 - Instrumented Indentation Tester - Google Patents

Abstract

An instrumented indentation tester according to the present embodiments comprises a main body supported on a support frame and sliding up and down by a driving part, a load sensor provided at a lower end of the main body, an indenter shaft having an upper end coupled to the load sensor and an indenter coupled to the lower end, and a displacement sensor part including a scale bar coupled to any one of the main body and the support frame and a sensor coupled to the another one. An objective of the present invention is to measure, by the displacement sensor, an indentation depth without slipping even if a surface of the test object has a curvature when an indentation test is performed by being installed in the test object, and in addition, can be easily installed in a chamber providing a high-temperature environment to a specimen and improve an accuracy and precision of the displacement sensor.

Description

Instrumented Indentation Tester

The present embodiments relate to an instrumentation press-fit tester, and more particularly, the displacement sensor may properly measure the press-in depth even if the surface of the test object has a curvature when it is installed on the test object and performs the press-fit test. The present invention relates to an instrumentation indentation tester that can be easily installed in a chamber providing a high temperature environment and improves the accuracy and precision of a displacement sensor.

In general, a tester such as an indentation tester for measuring the physical properties of the test object has been installed inside the test room because of its large volume and weight. It is possible to install and test directly on the test object in the field.

In addition, various parts and structures installed in industrial fields such as machinery, construction, and chemistry are large in volume and weight, but may be installed in a state in which physical properties are changed or shapes or structures are deformed during the installation process. Therefore, in order to confirm the final safety of the installation structure, it is necessary to test with the structure installed.

Therefore, the miniaturized tester is installed directly on the installation structure in an industrial site to perform the test. In particular, when the indentation tester performs the indentation test, the conventional indentation tester is provided with a displacement sensor on the indenter shaft to measure the indentation depth of the indenter. The rod part forms a different axis from the indenter and is simultaneously supported by the indenter on the surface of the installation structure. As the indenter is pressed, the rod part slides in the axial direction and the displacement sensor measures the indentation depth.

However, when the surface of the installation structure has a curvature, when the indenter is press-fitted, the rod part has a different axis from that of the indenter, so that the rod slides due to the curvature so that the displacement sensor cannot properly measure the indentation depth.

In addition, most materials or components used in modern society such as power generation facilities such as nuclear power and thermal power, chemical facilities, and gas piping are exposed to high temperature as well as room temperature, and high reliability considering the change of physical properties of these materials from the design stage In order to be equipped, it is necessary to measure the material properties at high temperatures.

Therefore, the tester performs a test by providing a high temperature environment to the specimen and having a chamber inside to maintain a vacuum for thermal insulation. In particular, when the indentation tester performs the indentation test, when the indenter is pressed into the specimen, Indentation tester as well as the indenter, the displacement sensor provided on the indenter shaft likewise has to be provided inside the chamber, it is difficult to install the indentation tester in the chamber, there is a problem that the accuracy and precision of the displacement sensor in a high temperature environment may be degraded.

The present embodiments are devised in the above-described background, even when the surface of the test object has a curvature when it is installed on the test object and the surface of the test object has a curvature, the displacement sensor does not slip and can measure the indentation depth. It is an object of the present invention to provide an instrumentation indentation tester which can be easily installed in a chamber in which the inside is maintained in a vacuum and improves the accuracy and precision of the displacement sensor.

In addition, the object of the present invention is not limited thereto, and other objects not mentioned will be clearly understood by those skilled in the art from the following description.

According to the present embodiments, the main body is supported on the support frame and slid up and down by the driving unit, the load sensor provided at the lower end of the main body, the indenter shaft coupled to the load sensor and the indenter is coupled to the lower end of the main body, the main body and the support frame Instrumentation indentation tester including a displacement sensor unit including a scale bar coupled to any one of the sensor coupled to the other may be provided.

According to the present embodiments, even when the test object has a curvature when installed on the test object and the surface of the test object has a curvature, the displacement sensor can measure the indentation depth without slipping, and is also easy for a chamber that provides a high temperature environment to the specimen. It is possible to provide an instrumentation indentation tester which can be installed easily and improves the accuracy and precision of the displacement sensor.

1 is a perspective view showing an example in which the instrumentation indentation tester according to the present embodiment is installed.
2 is a perspective view of an instrumentation indentation tester according to the present embodiments.
3 to 4 are cross-sectional views of FIG. 2.
5 to 7 are exploded perspective views of FIG.

Some embodiments of the present embodiments will now be described in detail with reference to the accompanying drawings. In adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are assigned to the same components as much as possible even though they are shown in different drawings. In addition, in describing the present embodiments, when it is determined that a detailed description of a related known configuration or function may obscure the gist of the present embodiments, the detailed description thereof will be omitted.

In addition, in describing the components of the present embodiments, terms such as first, second, A, B, (a), and (b) may be used. These terms are only for distinguishing the components from other components, and the nature, order or order of the components are not limited by the terms. If a component is described as being "connected", "coupled" or "connected" to another component, that component may be directly connected to or connected to that other component, but there may be another configuration between each component. It is to be understood that the elements may be "connected", "coupled" or "connected".

1 is a perspective view showing an example of the instrumentation indentation tester according to the present embodiment, Figure 2 is a perspective view of the instrumentation indentation tester according to the present embodiment, Figures 3 to 4 is a cross-sectional view of Figure 2, Figure 5 7 is an exploded perspective view of FIG. 2.

Instrumentation press-fit tester 100 according to the present embodiment, the main body 230, which is supported by the support frame 220 and slid up and down by the drive unit 210, the load sensor provided in the lower end of the main body 230 ( 250, an indenter shaft 260 having an upper end coupled to the load sensor 250 and an indenter 261 coupled to the lower end, a scale bar 242 coupled to any one of the main body 230 and the support frame 220. And a displacement sensor unit including a sensor 241 coupled to the other one.

Referring to Figure 1, the instrumentation indentation tester 100 according to the present embodiment is coupled to the portable fixed device 120 is fixed to the test object, such as turbine rotor 110 in the industrial field to perform the indentation test The portable fixing device 120 may be formed at an inclination angle between a portion supported by the shaft 111 and a portion where the indentation tester is coupled to form a connection portion of the blade 113 formed perpendicular to the shaft 111 ( Although the surface of the test object has a curvature as shown in (115), unlike the conventional indentation tester, the displacement sensor 241 is not directly supported by the test object and does not slip due to curvature, so that the indentation depth can be properly measured.

In addition, although not shown in the drawings, even when coupled to a chamber that provides a high-temperature environment to the specimen and maintains the interior in a vacuum for thermal insulation, the displacement sensor 241 is not coupled to the indenter shaft even when the indentation test is performed. It is easy to combine and the displacement sensor is not affected by the high temperature environment.

Hereinafter, referring to FIGS. 2 to 3, in order to clearly display the components of the present embodiments, bolts for coupling the components are omitted.

The main body 230 is supported by the support frame 220 and slides up and down by the driving unit 210. The lower end of the main body 230 is provided with a load sensor 250 to test when the driving unit 210 applies a load. Measure the load applied to the object.

The indenter shaft 260 has an upper end coupled to the load sensor 250 and an indenter 261 coupled to the lower end, so that the indenter 261 is subjected to the test object when the driving unit 210 applies a load to the main body 230. Is pressed into the surface of the substrate.

As such indenter 261, indenters, such as a Vickers and a Bulko beach, can be selected suitably and used.

In addition, the displacement sensor unit 240 is provided to measure the displacement generated on the surface of the test object due to the load, that is, the indentation depth of the indenter 261.

The displacement sensor unit 240 includes a scale bar 242 coupled to any one of the main body 230 and the support frame 220 and a sensor 241 coupled to the other body. 230 is measured displacement.

That is, since the lower frame 223 to be described later is coupled to the portable fixing device 120 and the like, the support frame 220 is fixed, and the displacement sensor unit 240 adjusts the displacement of the main body 230 with respect to the support frame 220. By measuring, the indentation depth of the indenter 261 is measured.

Therefore, as in the conventional indentation tester, the displacement sensor is coupled to the indenter shaft, and the indentation depth is not measured by measuring the displacement of the rod supported on the test object and sliding in the axial direction during the indentation. In the instrumentation press-fit tester 100, the displacement sensor unit 240 measures the displacement of the main body 230 with respect to the support frame 220, so that only the indenter 261 is supported on the test object, and the indenter 261 is Even if supported on the curved surface of the test object, the indentation depth of the indenter 261 can be properly measured without the risk of the displacement sensor unit slipping by the curvature.

On the other hand, the support frame 220 is a pair of the stop frame 222 facing each other with the body 230 therebetween, the upper frame 221 and the stop frame 222 coupled to the upper end of the stop frame 222 The lower frame 223 is coupled to the lower end, the lower frame 223 is coupled to the portable fixing device 120, the chamber, etc. Instrumentation indentation tester 100 is fixed, the stop frame 222 is approximately a square pillar It is formed in the shape of the main body 230 is provided between and supports the vertical sliding movement of the main body 230, the upper frame 221 is provided with a drive unit 210 to apply a load to the main body 230.

That is, the driving unit 210 is coupled to the upper frame 221, the connecting shaft 231 connected to the driving unit 210 is coupled to the upper end of the main body 230, the driving unit 210 by the connecting shaft 231. The power of is to be transmitted to the body 230.

A motor may be used as the driving unit 210, and the connecting shaft 231 is provided to penetrate the upper frame 221 so that the lower end is coupled to the main body 230, and the upper end is connected to the motor shaft through the hollow shaft 310. Can be connected.

Hollow shaft 310 is the upper end is coupled to the motor shaft and the lower end is coupled via the connecting shaft 231 and the ball screw, the rotation of the motor shaft is converted to the vertical movement of the connecting shaft by the ball screw, thus the main body 230 ) Can be slid up and down so that the driving unit 210 can apply a load to the body (230).

The indenter shaft 260 is provided to protrude downward through the lower frame 223, and the indenter 261 is coupled to the lower end of the indenter shaft 260.

Therefore, when performing the indentation test in the vacuum chamber, etc., since the displacement sensor unit 240 is not coupled to the indenter shaft 260, the installation becomes easy, and the displacement sensor unit 240 is not affected by the high temperature environment. Can be.

Meanwhile, in order for the main body 230 supported by the middle frame 222 to smoothly slide up and down, a sliding support member 433 may be provided between the middle frame 222 and the main body 230.

That is, the sliding support member 433 is provided between the inner surface of the middle frame 222 and the main body 230, the first groove 431 is formed in the axial direction on the inner surface of the middle frame 222 The main body 230 may have a second groove 435 facing the first groove 431, and the sliding support member 433 may be provided in the first groove 431 and the second groove 435. .

A cross roller slide may be used as the sliding support member 433. The cross roller slide has a pair of rails having grooves formed in a longitudinal direction, and a roller or a ball is provided between the rails so that both rails slide. It is suitable for supporting the axial sliding movement as in the present embodiments.

Accordingly, both rails of the cross roller slide are inserted into and coupled to the first groove 431 and the second groove 435, so that the main body 230 is supported by the stopping frame 222 when the main body 230 receives the load by the driving unit 210. And it can do sliding movement smoothly.

Meanwhile, as described above, the scale bar 242 and the sensor 241 of the displacement sensor unit 240 are coupled to the support frame 220 and the main body 230, hereinafter, the sensor 241 is connected to the stop frame 222. An embodiment in which the scale bar 242 is coupled to the main body 230 will be described. However, the present invention is not limited thereto, but the scale bar 242 is coupled to the stop frame 222 and the sensor 241 is connected to the main body 230. It may be coupled to the 230, it is obvious that it may be coupled to the upper frame 221 or the lower frame 223 instead of the stop frame 222.

The displacement sensor unit 240 includes a first bracket 243 and a second bracket 244, the sensor 241 is coupled to the support frame 220 via the first bracket 243 and the scale bar 242. ) Is coupled to the body 230 via the second bracket 244.

The first bracket 243 includes two or more first wings 411 and 412 supported by the support frame 220, and two or more second wings 413 and 414 supported by the sensor 241.

That is, the first wing parts 411 and 412 and the second wing parts 413 and 414 are supported by the support frame 220 and the sensor 241 at two or more surfaces, thereby minimizing shaking when the main body 230 is slid. Therefore, error occurrence is suppressed.

In the drawing, an exemplary embodiment in which two first wing parts 411 and 412 and two second wing parts 413 and 414 are provided is shown. Thus, the first bracket 243 may have a cross shape.

In addition, a coupling hole is formed in at least one of the first wing portions 411 and 412 and at least one of the second wing portions 413 and 414, and the first wing portions 411 and 412 in the support frame 220 and the sensor 241. A coupling hole communicating with the coupling hole of the second wing parts 413 and 414 is formed, such that the sensor 241, the first bracket 243, and the support frame 220 may be coupled by a coupling member, for example, a bolt.

The second bracket 244 may include a first coupling part 421 coupled to the main body 230 and a second coupling part 422 coupled to the scale bar 242.

As described above, since the scale bar 242 is supported by the sensor 241, the second coupling part 422 may be formed to protrude laterally from the first coupling part 421, and the scale bar 242 may be The side of the sensor 241 will be supported on the side that is not supported by the second wing (413,414).

Like the first wing portions 411 and 412 and the second wing portions 413 and 414, coupling holes are formed in the first coupling portion 421 and the second coupling portion 422, and the coupling holes are formed in the main body 230 and the scale bar 242. The coupling hole is formed in communication with the scale bar 242, the second bracket 244 and the main body 230 may be coupled by a coupling member, for example, a bolt.

In addition, one of the main body 230 and the first coupling portion 421 is formed with a first coupling groove 511 and the other is formed with a first coupling protrusion 512 inserted into the first coupling groove 511. Can be.

The first coupling groove 511 and the first coupling protrusion 512 may be formed in a direction perpendicular to the axial direction. Therefore, when the main body 230 slides up and down, the first coupling protrusion 512 is firstly formed. It is supported up and down in the coupling groove 511 and the second bracket 244 is fixed to the main body 230 in the vertical direction to minimize the shake and thus the occurrence of errors is suppressed.

In addition, any one of the scale bar 242 and the second coupling portion 422 is formed with a second coupling groove 521 and the other is a second coupling protrusion 522 inserted into the second coupling groove 521 Can be formed.

The second coupling groove 521 and the second coupling protrusion 522 may be formed in the axial direction. Therefore, the scale bar 242 coupled to the second bracket 244 when the main body 230 slides up and down. Is aligned in the axial direction, so that the occurrence of errors is suppressed when the sensor 241 measures the displacement of the scale bar 242.

According to the instrumentation press-fit tester having such a shape, the displacement sensor is coupled to the indenter shaft and not directly supported by the test object, but the scale bar and the sensor are coupled to the support frame and the body to measure the indentation depth of the indenter. Even if the surface of curvature has a curvature, the indentation depth can be measured properly without the risk of slipping of the displacement sensor. Also, when the indentation test is carried out on the test object provided in the vacuum chamber, the indentation tester can be easily installed in the chamber. Displacement sensor is not affected and accuracy and precision can be improved.

In the above description, it is understood that all the components constituting the embodiments of the embodiments are described as being combined or operating in combination, but the embodiments are not necessarily limited to the embodiments. That is, as long as it is within the scope of the present embodiments, all of the components may be selectively operated in one or more combinations.

In addition, the terms "comprise", "comprise" or "having" described above mean that the corresponding component may be included, unless otherwise stated, and thus excludes other components. It should be construed that it may further include other components instead. All terms, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the embodiments belong, unless otherwise defined. Terms commonly used, such as terms defined in the dictionary, should be interpreted to coincide with the contextual meaning of the related art, and shall not be construed in an ideal or overly formal sense unless explicitly defined in the present embodiments.

The above description is merely illustrative of the technical spirit of the present embodiments, and those skilled in the art to which the present embodiments belong may make various modifications and changes without departing from the essential characteristics of the present embodiments. will be. Therefore, the embodiments disclosed in the present embodiments are not intended to limit the technical spirit of the present embodiments, but to explain, and the scope of the technical spirit of the present embodiments is not limited by these embodiments. The scope of protection of the present embodiments should be interpreted by the following claims, and all technical ideas falling within the scope of equivalents thereof should be construed as being included in the scope of the present embodiments.

100: instrumentation indentation tester 210: drive unit
220: support frame 222: stop frame
230: main body 240: displacement sensor
241: sensor 242: scale bar
243: first bracket 244: second bracket
250: load sensor 260: indenter shaft
261: indenter 411,412: first wing portion
413, 414: second wing portion 421: first coupling portion
422: second coupling portion 433: sliding support member
511: first coupling groove 512: first coupling protrusion
521: second coupling groove 522: second coupling protrusion

Claims (13)

A main body supported by the support frame and slid up and down by the driving unit;
A load sensor coupled to the bottom surface of the main body;
An indenter shaft having an upper end coupled to the load sensor and an indenter coupled to the lower end;
A displacement sensor unit including a scale bar coupled to any one of the main body and the support frame and a sensor coupled to the other one;
Including,
The displacement sensor unit includes a first bracket and a second bracket, wherein the sensor is coupled to the support frame via the first bracket and the scale bar is coupled to the main body via the second bracket. Instrumentation press-fit tester. The method of claim 1,
The support frame includes a pair of stop frames facing each other with the main body therebetween, an upper frame coupled to an upper end of the stop frame, and a lower frame coupled to a lower end of the stop frame. Indentation tester. The method of claim 2,
The driving unit is coupled to the upper frame, the instrumentation and indentation tester, characterized in that the coupling via the connecting shaft passing through the upper frame. The method of claim 2,
Instrumentation indentation tester, characterized in that the indenter shaft is provided to protrude downward through the lower frame. The method of claim 2,
Instrumentation press-fit tester, characterized in that the sliding support member is provided between the stop frame and the main body. The method of claim 5,
A first groove formed in an axial direction is formed on an inner surface of the middle frame, and a second groove facing the first groove is formed in the main body, and the sliding support member is provided in the first groove and the second groove. Instrumentation indentation tester, characterized in that. delete The method of claim 1,
Instrumentation indentation tester, characterized in that the first bracket is provided with at least two first wings supported by the support frame, and at least two second wings supported by the sensor. The method of claim 1,
Instrumentation indentation tester, characterized in that the second bracket is provided with a first coupling portion coupled to the main body, and a second coupling portion coupled to the scale bar. The method of claim 9,
Instrumentation indentation tester, characterized in that the first coupling groove is formed in any one of the main body and the first coupling portion, the first coupling projection is inserted into the first coupling groove. The method of claim 10,
Instrumentation indentation tester, characterized in that the first coupling groove and the first coupling protrusion is formed in a direction perpendicular to the axial direction. The method of claim 9,
Instrumentation indentation tester, characterized in that the second coupling groove is formed in one of the scale bar and the second coupling portion, the second coupling protrusion is inserted into the second coupling groove. The method of claim 12,
Instrumentation indentation tester, characterized in that the second coupling groove and the second coupling protrusion is formed in the axial direction.

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