KR101505711B1 - Compression tester - Google Patents

Abstract

Disclosed is a compression test apparatus configured to measure an amount of plastic deformation of a cylindrical specimen such as a pipe by using an electromagnetic wave.
The compression testing apparatus according to one embodiment of the present invention includes a loading part 200 configured to apply a compressive load or a compressive displacement to a tubular specimen S; A measuring unit 300 provided in the loading part 200 and configured to measure the plastic deformation amount of the cylindrical sample S by the applied compressive load or the compressive displacement using an electromagnetic wave; A control unit (400) connected to the loading unit (200) and the measuring unit (300) to control the loading unit (200) and receive and store a signal from the measuring unit (300); And at least one specimen supporting unit (500) provided in the loading part (200) and configured so that the cylindrical specimen (S) does not deviate from its initial position without applying or applying a compressive load or a compressive displacement to the cylindrical specimen (S); Wherein the specimen supporting unit 500 includes a rod member 510 provided at one side and both sides of the lower base member 210 included in the loading member 200, 510 and the other side of which is provided with a support member 520 for supporting the cylindrical specimen S and a support member 520 provided between the rod member 510 and the support member 520 to elastically support the support member 520, And an elastic member 530 for supporting the elastic member 530.

Description

[0001] COMPRESSION TESTER [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a compression test apparatus for measuring a deformation amount of a specimen according to a compressive force applied to the specimen, and more particularly to a compression test apparatus configured to measure an amount of plastic deformation of a tubular specimen such as a pipe using electromagnetic waves.

The compression test apparatus is a device for measuring the deformation amount of a specimen according to a force applied to the specimen together with a tensile test apparatus. The double compression test system is a device for measuring the deformation of a specimen by applying a compressive load to the specimen and applying the applied compressive load.

On the other hand, a tubular structure such as a pipe is deformed when a compressive load is repeatedly applied for a short period or a long period of time, and is plastically deformed when the applied compressive load exceeds a predetermined size, and is broken if plastically deformed to a predetermined size or more. Therefore, it is necessary to measure the amount of plastic deformation of the cylindrical structure due to a short-term or repetitive compressive load.

Conventionally, a strain gauge was used for this purpose. That is, a strain gauge was attached to a cylindrical specimen, and a strain amount according to a compression load applied to the cylindrical specimen was measured by a strain gauge. However, since one strain gauge can measure only the amount of microdeformation of a local portion of a cylindrical specimen, there is a problem that a large number of strain gauges are required to measure the deformation amount of the entire cylindrical specimen.

Accordingly, a plurality of strain gauges must be installed in the cylindrical specimen, but it is not easy to install a plurality of strain gauges in the cylindrical specimen. Also, strain data from a number of strain gauges must be collected and analyzed, which is also time consuming and requires a lot of experience.

Therefore, when a plurality of strain gauges are used, it is not easy to measure the amount of deformation according to the compressive load of the cylindrical specimen, and it takes a lot of time and cost.

In addition, since the strain gauge is influenced by the type, use, and shape of the cylindrical specimen, there is a problem that the measurement result is also affected depending on the type, usage, and shape of the cylindrical specimen.

The strain gauge can only measure the amount of deformation according to the compressive load applied to the cylindrical specimen, and the plastic deformation amount due to the compressive load applied to the cylindrical specimen can not be measured.

On the other hand, conventionally, when a compressive load is applied to a cylindrical specimen, the cylindrical specimen is deformed and deviates from its initial position. When a part of the cylindrical specimen is fixed to prevent this, there is a problem that an external force other than a compressive load such as reaction force acts on the cylindrical specimen. Thus, there is a problem that the reliability of the measurement is deteriorated and the cylindrical specimen may be damaged when external forces other than the compressive load act largely.

The present invention is realized by recognizing at least any one of the above-mentioned conventional needs or problems.

One aspect of the object of the present invention is to more accurately and quickly measure the amount of plastic deformation of the cylindrical specimen due to the applied compressive load or compressive displacement.

Another aspect of the object of the present invention is to enable a compression test regardless of the type, application, and shape of the cylindrical specimen.

Another aspect of the object of the present invention is to prevent the cylindrical specimen from separating from its initial position during the compression test of the cylindrical specimen.

A compression test apparatus according to an embodiment for realizing at least one of the above problems may include the following features.

The present invention is basically based on that the plastic deformation amount of the cylindrical specimen is measured by using an electromagnetic wave.

A compression testing apparatus according to an embodiment of the present invention includes a loading section configured to apply a compression load or a compression displacement to a tubular specimen; A measuring unit provided at the loading portion and configured to measure the plastic deformation amount of the cylindrical specimen by the applied compressive load or compression displacement by using an electromagnetic wave; A control unit connected to the load unit and configured to control the load application unit and receive and store a signal from the measurement unit; And at least one specimen supporting unit provided at the loading portion and configured to prevent the tubular specimen from leaving the initial position without applying or applying a compressive load or a compressive displacement to the tubular specimen; Wherein the specimen supporting unit comprises a rod member provided on one side and both sides of the lower base member included in the loading part, a supporting member movably provided on one side of the rod member and the other side supporting the tubular specimen, And an elastic member provided between the rod member and the support member for elastically supporting the support member.

In this case, the load applying section may apply a compressive load or a compressive displacement to the cylindrical specimen once or repeatedly.

Further, the load imparting portion may be a load imparting member movable to apply a compressive load or a compressive displacement to the tubular specimen; . ≪ / RTI >

The load applying unit may include a lower base member on which the cylindrical specimen is mounted; A plurality of pillar members, one side of which is connected to the lower base member and to which the load imparting member is movably connected; An upper base member to which the other side of the pillar member is connected; And a driving unit provided on the upper base member to be connected to the load applying member and connected to the control unit to move the load applying member; As shown in FIG.

The measuring unit may include an electromagnetic wave irradiator provided at one side of the load unit and connected to the control unit and configured to irradiate the cylindrical specimen with electromagnetic waves; And an electromagnetic wave receiver which is provided on the other side of the loading part and is connected to the control part and is configured to receive electromagnetic waves irradiated from the electromagnetic wave irradiation part and passed through the cylindrical specimen; . ≪ / RTI >

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The other side of the supporting member may be at least partially inclined.

The controller may further include a first controller connected to the load portion to adjust a compression load or a compression displacement applied to the cylindrical specimen; A second controller connected to the measuring unit for controlling irradiation and reception of electromagnetic waves; An integrated controller connected to the first controller and the second controller; And a setting storage unit connected to the integrated control unit and configured to set test conditions and receive and store signals from the measurement unit; . ≪ / RTI >

The measurement unit irradiates the tubular specimen with electromagnetic waves of a predetermined width and applies a compressive load or compressive displacement to the tubular specimen and the width of the electromagnetic wave that has passed through the tubular specimen before applying the compressive load or the compressive displacement to the tubular specimen, The plastic deformation amount of the cylindrical specimen can be measured by measuring the difference between the width of the electromagnetic wave passing through the cylindrical specimen.

As described above, according to the embodiment of the present invention, the plastic deformation amount of the cylindrical specimen is measured using electromagnetic waves, and the plastic deformation amount of the cylindrical specimen due to the applied compression load or compression displacement can be measured more accurately and quickly .

Further, according to the embodiment of the present invention, the compression test of the cylindrical specimen can be performed irrespective of the type, application, and shape of the cylindrical specimen.

Further, according to the embodiment of the present invention, the cylindrical specimen may not be separated from the initial position during the compression test of the cylindrical specimen by the specimen supporting unit, so that the compression test of the cylindrical specimen can be accurately performed, It is possible to prevent the cylindrical specimen from being broken due to the external force of the screw.

1 is a perspective view of an embodiment of a compression testing apparatus according to the present invention.
2 is a configuration diagram of an embodiment of a compression test apparatus according to the present invention.
Figs. 3 to 5 are diagrams showing the measurement of the amount of plastic deformation of the cylindrical specimen using one embodiment of the compression testing apparatus according to the present invention. Fig.

In order to facilitate understanding of the features of the present invention as described above, a compression test apparatus according to an embodiment of the present invention will be described in more detail.

Hereinafter, exemplary embodiments will be described based on embodiments best suited for understanding the technical characteristics of the present invention, and the technical features of the present invention are not limited by the illustrated embodiments, It is to be understood that the present invention may be implemented as illustrated embodiments. Therefore, it is intended that the present invention covers the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents. In order to facilitate understanding of the embodiments to be described below, in the reference numerals shown in the accompanying drawings, among the constituent elements which perform the same function in each embodiment, the related constituent elements are indicated by the same or an extension line number.

Embodiments related to the present invention are based on basically configured to measure the amount of plastic deformation of a cylindrical specimen using an electromagnetic wave.

1 and 2, the compression testing apparatus 100 according to the present invention may include a loading unit 200, a measuring unit 300, and a control unit 400. As shown in FIG.

The loading part 200 may be configured to apply a compressive load or a compressive displacement to the tubular specimen S. When a compressive load is applied to the tubular specimen S, it is possible to simulate a case in which a cylindrical structure such as a pipe is exposed to the outside to receive a compressive load. When compressive displacement is applied to the tubular specimen S, it is possible to simulate a case in which a tubular structure such as a pipe is buried underground to receive a compressive load.

The loading part 200 may include a loading member 230 as in the embodiment shown in FIGS. The load applying member 230 may be movable as shown in FIGS. 4, the compressive load or the compressive displacement may be applied to the cylindrical specimen S or the compressive load or the compressive displacement may not be applied as shown in FIG. 5 depending on the movement of the load imparting member 230 .

For this purpose, the load applying member 230 is a horizontal plate as in the embodiment shown in FIGS. 1 and 2, and may be movable up and down. However, the shape and the moving direction of the load applying member 230 are not limited to this, and any shape can be used as long as it can apply a compressive load or a compressive displacement to the cylindrical specimen S, and can be movable in any direction.

2 and 3, the loading part 200 includes a lower base member 210, a plurality of pillar members 220, an upper base member 240, and a lower supporting member 240 in addition to the load applying member 230 described above. And may further include a driving unit 250.

The tubular specimen S may be installed on the lower base member 210 as shown in FIGS. For this purpose, the lower base member 210 may be a horizontal plate as in the embodiment shown in FIGS. However, the shape of the lower base member 210 is not limited thereto, and any shape can be used as long as the cylindrical specimen S can be installed.

As shown in FIGS. 1 and 2, the column member 220 may be connected to the lower base member 210 at one side. Then, the load applying member 230 may be movably connected. Accordingly, as shown in FIGS. 4 and 5, the load applying member 230 can move along the column member 220.

The other side of the pillar member 220 can be connected to the upper base member 240 as shown in the embodiment shown in Figs. The upper base member 240 may have a shape corresponding to the lower base member 210, as shown in the illustrated embodiment. That is, the upper base member 240 may also be a horizontal plate. However, the shape of the upper base member 240 is not limited to this, and any shape is possible.

The driving unit 250 may be provided on the upper base member 240 so as to be connected to the load applying member 230 as in the embodiment shown in FIGS. In addition, the driving unit 250 may be connected to the control unit 400. By the driving of the drive unit 250 under the control of the controller 400, the load applying member 230 can be moved as shown in FIGS.

To this end, the drive unit 250 may be, for example, a linear motor. However, the driving unit 250 is not limited to this, and may be any known one as long as it can be connected to the load applying member 230 and the control unit 400 to move the load applying member 230 under the control of the controller 400. [ It is also possible.

The driving unit 250 may include a load sensor 251 such as a load cell as shown in FIGS. 1 and 2. Thus, the magnitude of the compressive load applied to the cylindrical specimen S by the drive unit 250 can be measured. The load sensor 251 is not particularly limited, and any known sensor may be used as long as it can measure the magnitude of the compression load.

On the other hand, the loading part 200 can apply a compressive load or a compressive displacement to the cylindrical specimen S once or repeatedly.

The measuring unit 300 may be provided in the loading part 200 as in the embodiment shown in FIGS. 3 to 5, the plastic deformation amount of the cylindrical specimen S due to the compression load or the compression displacement applied to the cylindrical specimen S is measured using an electromagnetic wave such as visible light, infrared light or ultraviolet light .

Thus, since the plastic deformation amount of the cylindrical specimen S is measured using the electromagnetic wave, the plastic deformation amount of the cylindrical specimen due to the applied compressive load or the compression displacement can be measured more accurately and quickly than in the case of using the conventional strain gauge have. Since the cylindrical specimen is not affected by electromagnetic waves, it is possible to perform the compression test of the cylindrical specimen irrespective of the type, use, and shape of the cylindrical specimen.

To this end, the measuring unit 300 can irradiate the cylindrical sample S with electromagnetic waves with a predetermined width L. For example, as shown in Fig. 3, the electromagnetic wave can be irradiated at a predetermined width L larger than the radius of the tubular specimen S at the center of the tubular specimen S.

Accordingly, as shown in FIG. 3, a part of the electromagnetic wave does not pass through the cylindrical specimen S by the cylindrical specimen S, but a part of the electromagnetic wave passes through the cylindrical specimen S as shown in FIG.

3, the measuring unit 300 measures the width L0 of the electromagnetic wave that has passed through the cylindrical specimen S before applying the compressive load or the compression displacement to the cylindrical specimen S, The difference between the width L1 of the electromagnetic wave that has passed through the plastic specimen S subjected to the plastic deformation as shown in FIG. 5 can be measured by applying a compressive load or a compressive displacement to the cylindrical specimen S as shown in FIG. Thereby, the amount of plastic deformation of the cylindrical specimen S can be measured.

Therefore, the plastic deformation amount of the cylindrical specimen due to the applied compressive load or compression displacement can be measured more accurately and quickly as described above. Further, the compression test of the cylindrical specimen can be performed irrespective of the type, usage, and shape of the cylindrical specimen.

1 and 2, the measuring unit 300 may include an electromagnetic wave irradiating unit 310 and an electromagnetic wave receiving unit 320.

1 and 2, the electromagnetic wave irradiating unit 310 includes a lower base member 210 and a lower base member 210 on one side of the loading unit 200, that is, the lower loading unit 200 in the illustrated embodiment, (240). And may be connected to the control unit 400. Then, as shown in Figs. 3 and 5, the tubular specimen S may be configured to irradiate electromagnetic waves.

The electromagnetic wave irradiating unit 310 may be, for example, a laser, an LED, or an incandescent / fluorescent lamp. However, the electromagnetic wave irradiating unit 310 is not particularly limited, and any known electronic wave irradiating unit may be used as long as the electromagnetic wave irradiating unit 310 irradiates the cylindrical specimen S with electromagnetic waves.

1 and 2, the electromagnetic wave receiving unit 320 is disposed between the lower base member 210 and the upper base member 240 on the other side of the load member 200, that is, As shown in FIG. And may be connected to the control unit 400. As shown in FIGS. 3 and 5, the electromagnetic wave irradiating unit 310 may be configured to receive the electromagnetic wave that has been irradiated from the electromagnetic wave irradiating unit 310 and has passed through the cylindrical specimen S.

The electromagnetic wave receiving unit 320 may include a sensor capable of sensing an electromagnetic wave. However, the electromagnetic wave receiving unit 320 is not particularly limited, and any known electronic apparatus can be used as long as it is configured to receive electromagnetic waves.

The control unit 400 may be connected to the loading unit 200 and the measurement unit 300 as shown in FIG. Then, by controlling the loading part 200, a signal from the measuring part 300, for example, the magnitude of the compression load applied to the cylindrical specimen S, the magnitude of the compression displacement, the number of times the compression load is applied, Number of times, or the amount of plastic deformation of the cylindrical specimen S, and the like.

2, the control unit 400 may include a first control unit 410, a second control unit 420, an integrated control unit 430, and a setting storage unit 440.

2, the first control unit 410 may be connected to the drive unit 250 of the load unit 200, that is, the load unit 200 in the illustrated embodiment. The first control unit 410 can adjust the compression load or compression displacement applied to the tubular specimen S. In the illustrated embodiment, the force or displacement applied to the load applying member 230 connected to the drive unit 250 can be adjusted to adjust the compressive load or compression displacement applied to the cylindrical specimen S.

The second controller 420 may be connected to the measuring unit 300, that is, the electromagnetic wave irradiator 310 and the electromagnetic wave receiver 320 of the measuring unit 300 in the illustrated embodiment, as shown in FIG. The second control unit 420 can control the irradiation of the electromagnetic wave from the electromagnetic wave irradiating unit 310 and the reception of the electromagnetic wave from the electromagnetic wave receiving unit 320.

The integrated controller 430 may be connected to the first controller 410 and the second controller 420 as shown in FIG. The first control unit 410 and the second control unit 420 can be controlled by the integrated control unit 430.

The configuration storage unit 440 may be connected to the integrated controller 430 as shown in FIG. In addition, the setting storage unit 440 can set the test conditions of the cylindrical specimen S. And, it can be configured to receive and store signals from the measuring unit 300. The setting storage unit 440 may include a computer and a program embedded therein as shown in the illustrated embodiment.

However, the configuration storing unit 440 is not particularly limited, and any known configuration may be used as long as the configuration storing unit 440 is connected to the integrated controlling unit 430 and is configured to set test conditions and receive and store signals from the measuring unit 300. [

Meanwhile, the compression testing apparatus 100 according to the present invention may further include at least one of the specimen supporting units 500 as shown in FIGS. 1 and 2. In the illustrated embodiment, two pairs, i.e. four specimen support units 500 are provided. However, the number of the specimen supporting units 500 is not limited to this, and any number of specimen supporting units 500 can be used.

As in the embodiment shown in Figs. 1 and 2, the specimen supporting unit 500 may be provided on the lower part base member 210 of the loading part 200, i.e., the loading part 200 in the illustrated embodiment. have. Also, the specimen-holding unit 500 can be applied to the cylindrical specimen S even if the compressive load or the compressive displacement is applied as shown in Fig. 4 or the compressive load or the compressive displacement is not applied as shown in Figs. 3 and 5, (S) does not deviate from the initial position.

Therefore, it is possible to accurately perform the compression test of the cylindrical specimen and to prevent the cylindrical specimen from being damaged by external forces other than the compressive load during the compression test.

To this end, the specimen supporting unit 500 may include a rod member 510, a supporting member 520, and an elastic member 530. [

The rod member 510 may be provided on one side and on both sides of the lower base member 210 of the load member 200, as in the embodiment shown in Figs. One side of the support member 520 is movably provided to the rod member 510, and the other side thereof can support the cylindrical specimen S. The other side of the support member 520 may be at least partially inclined as shown in the illustrated embodiment. The elastic member 530 may be provided between the rod member 510 and the support member 520 to elastically support the support member 520.

3, the tubular specimen S is supported by the two pairs of specimen supporting units 500, that is, the two pairs of supporting members 520 to which the elastic force of the elastic members 530 is applied, as shown in Fig. So that it can be installed in the lower base member 210 of the loading part 200.

4, when the cylindrical specimen S is subjected to a compressive load or a compressive displacement, the cylindrical specimen S is deformed and the supporting member 520 is also deformed in accordance with the deformation of the cylindrical specimen S, (530). Thereby, even if a compressive load or a compression displacement is applied to the tubular specimen S, the tubular specimen S can be prevented from leaving the initial position.

5, if the compressive load or compressive displacement is no longer applied to the tubular specimen S, the tubular specimen S is returned to its original shape according to the magnitude of the applied compressive load or compressive displacement, It can be deformed. Even in this case, since the elastic force of the elastic member 530 is applied to the support member 520, the cylindrical specimen S can be prevented from leaving the initial position.

As described above, by using the compression test apparatus according to the present invention, it is possible to more accurately and quickly measure the plastic deformation amount of the cylindrical specimen due to the applied compressive load or compression displacement, The compression test of the cylindrical specimen can be carried out irrespective of the compression test of the cylindrical specimen, so that the compression test of the cylindrical specimen can be accurately performed, It is possible to prevent the cylindrical specimen from being damaged.

The above-described compression test apparatuses are not limited to the configurations of the above-described embodiments, but the embodiments may be configured by selectively combining all or some of the embodiments so that various modifications may be made .

100: Compression testing device 200: Load part
210: lower base member 220: pillar member
230: load imparting member 240: upper base member
250: drive unit 251: load sensor
300: Measuring section 310: Electromagnetic wave irradiating section
320: Electromagnetic wave receiving unit 400:
410: first control section 420: second control section
430: Integrated control unit 440:
500: specimen supporting unit 510: rod member
520: support member 530: elastic member
S: The Psalms

Claims (10)

(200) configured to apply a compressive load or a compressive displacement to the tubular specimen (S);
A measuring unit 300 provided in the loading part 200 and configured to measure the plastic deformation amount of the cylindrical sample S by the applied compressive load or the compressive displacement using an electromagnetic wave;
A control unit (400) connected to the loading unit (200) and the measuring unit (300) to control the loading unit (200) and receive and store a signal from the measuring unit (300); And
At least one specimen supporting unit (500) provided in the loading part (200) and configured so that the cylindrical specimen (S) does not separate from the initial position even if the cylindrical specimen (S) is not subjected to a compressive load or a compressive displacement; And,
The specimen supporting unit 500 includes a rod member 510 provided on one side and both sides of a lower base member 210 included in the loading member 200, And a supporting member 520 for supporting the tubular specimen S and an elastic member 530 provided between the rod member 510 and the supporting member 520 for elastically supporting the supporting member 520 ). ≪ / RTI > The compression test apparatus according to claim 1, wherein the loading part (200) applies a compression load or a compression displacement to the cylindrical specimen (S) once or repeatedly. The load carrying member (230) according to claim 1, wherein the loading part (200) is movable to apply a compressive load or a compressive load to the tubular specimen (S); And a compression test apparatus. 4. The method of claim 3, wherein the loading part (200)
A lower base member 210 on which the cylindrical specimen S is installed;
A plurality of pillar members 220 having one side connected to the lower base member 210 and the load imparting member 230 movably connected thereto;
An upper base member 240 to which the other side of the pillar member 220 is connected; And
A driving unit 250 provided on the upper base member 240 to be connected to the load applying member 230 and connected to the controller 400 to move the load applying member 230;
Further comprising: a pressure sensor for detecting the pressure of the fluid; The apparatus of claim 1, wherein the measuring unit (300)
An electromagnetic wave irradiating part 310 provided at one side of the loading part 200 and connected to the controller 400 and irradiating the tubular specimen S with electromagnetic waves; And
An electromagnetic wave receiver 320 provided on the other side of the loading part 200 and connected to the controller 400 and configured to receive electromagnetic waves irradiated from the electromagnetic wave irradiator 310 and passed through the tubular specimen S;
And a compression test apparatus. delete delete The compression test apparatus according to claim 1, wherein the other side of the support member (520) is at least partially inclined. The apparatus of claim 1, wherein the controller (400)
A first control part 410 connected to the loading part 200 to adjust a compression load or compression displacement applied to the cylindrical specimen S;
A second controller 420 connected to the measuring unit 300 to control irradiation and reception of electromagnetic waves;
An integrated controller 430 connected to the first controller 410 and the second controller 420; And
A setting storage unit (440) connected to the integrated control unit (430) and configured to set test conditions and receive and store signals from the measurement unit (300);
And a compression test apparatus. The method according to claim 1, wherein the measuring unit (300) irradiates the tubular specimen (S) with electromagnetic waves of a predetermined width (L)
The width LO of the electromagnetic wave that has passed through the cylindrical specimen S and the width of the cylindrical specimen S plastically deformed by applying a compressive load or a compressive displacement to the cylindrical specimen S before applying the compression load or the compression displacement to the cylindrical specimen S, And the width (L1) of the electromagnetic wave that has passed through the cylindrical sample (S) is measured to measure the plastic deformation amount of the cylindrical sample (S).

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