KR101820023B1 - Apparatus for Testing LM Guide - Google Patents

Abstract

The present invention relates to an apparatus for measuring a load applied to an LM guide to be tested, an application unit for applying a load to the LM guide to be tested, a measurement unit for measuring a load applied to the LM guide by the application unit, And a moving unit for moving the measuring unit to move the EL block of the EL guide,
According to the present invention, the overall size can be reduced by moving the EL block to perform the test on the EL guide, and the accuracy and reliability of the test result on the EL guide can be improved.

Description

[Apparatus for Testing LM Guide]

The present invention relates to an ELM guide test apparatus for testing the durability of an ELM guide.

The LM Guide is one of the mechanical parts, and is used in a configuration in which the linear movement is repeatedly performed in the equipment and the like. Such an LM guide guides the linear movement of the structure in a state of supporting the linear moving structure. Therefore, it is required that the LM guide has durability capable of stably supporting the linear moving structure. In order to test the durability of the LM guide as described above, an LM guide test apparatus is used.

FIG. 1 is a schematic front view of a conventional ELM guiding test apparatus, and FIG. 2 is a schematic side view of an ELM guiding test apparatus according to the related art.

Referring to FIGS. 1 and 2, an LM guiding test apparatus 100 according to the related art includes a hydraulic cylinder 110 for applying a load to an LM guide 200 to be tested, a load applied to the LM guide 200 And a mobile unit 130 for moving the LM guide 200. The measurement unit 120 measures the position of the mobile unit 200, The LM guide 200 includes an LM rail 210 and an LM block 220 movably coupled to the LM rail 210.

The hydraulic cylinder 110 applies a load to the LM guide 200 using the hydraulic pressure. The hydraulic cylinder 110 changes the load applied to the LM guide 200 by changing the magnitude of the hydraulic pressure. The hydraulic cylinder 110 is installed on the upper side of the LM guide 200.

The measuring unit 120 is installed between the hydraulic cylinder 110 and the LM guide 200. The load provided by the hydraulic cylinder 110 is transmitted to the LM guide 200 through the measurement unit 120. The measurement unit 120 measures a load applied to the LM guide 200 by measuring a load provided from the hydraulic cylinder 110. [ The EL block 220 is coupled to the measurement unit 120.

The mobile unit 130 is installed below the LM guide 200. The mobile unit 130 is coupled to the EL display unit 210. The mobile unit 130 moves the LM 210 to perform the test on the LM guide 200. In this state, The moving unit 130 includes a support mechanism 131 coupled to the EL display 210, a movement mechanism 132 for moving the support mechanism 131 to move the EL display 210, And a guide mechanism 133 to which the support mechanism 131 is movably coupled. The guide mechanism 133 guides the support mechanism 131 to move in a straight line so that the LM 210 moves linearly. The guide mechanism 133 includes an EL element 1331 and an EL block 1332 for guiding the support mechanism 131 to linearly move.

The above-described conventional EL guiding test apparatus 100 has the following problems.

First, the LM guiding test apparatus 100 according to the related art performs a test on the LM guide 200 by repeatedly moving the LM 200 in a state where the LM block 220 is fixed . Therefore, the conventional ELM guiding test apparatus 100 has a problem in that the overall size of the ELM guiding test apparatus 100 increases because the ELM guiding testing apparatus 100 requires a space for repeatedly moving the ELM. This problem is further exacerbated as the size of the EL element 210 increases.

Secondly, when the LM guide 200 is applied to an actual product, the LM block 220 is repeatedly moved while the LM 210 is fixed. However, since the ELM guiding test apparatus 100 according to the related art has a structure in which the ELM block 210 is moved while the ELM block 220 is fixed, The test is performed in a test condition with a large difference from the test condition. Therefore, there is a problem in that the accuracy of the test result of the LM guide test apparatus 100 according to the prior art is lowered.

Third, the LM Guide test apparatus 100 according to the prior art uses the hydraulic cylinder 110 to apply a load to the LM Guide 200 to be tested. Since the hydraulic cylinder 110 is an expensive product, there is a problem that the cost for testing the LM guide 200 increases in the LM guide test apparatus 100 according to the related art. In addition, in the conventional ELM guiding test apparatus 100, a separate guiding mechanism 133 is required to linearly move the ELM 210. Therefore, there is a problem in that the overall configuration of the LM guide test apparatus 100 according to the related art is complicated, and the cost of testing the LM guide 200 further increases.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an apparatus for testing an LM guide capable of improving the accuracy of a test result for an LM guide.

Another object of the present invention is to provide an EL guiding test apparatus which can reduce the cost required for testing the EL guiding guide and can reduce the overall size.

In order to achieve the above-mentioned object, the present invention can include the following configuration.

The apparatus for testing an LM guide according to the present invention includes: an application unit for applying a load to an LM guide to be tested; A measurement unit coupled to the application unit and configured to measure a load applied to the LM guide by the application unit; A mounting unit on which the El emulation of the LM Guide is installed; And a mobile unit for moving the measurement unit to move the EL block to which the one side is movably coupled to the EL display and the other side is connected to the application unit.

The apparatus for testing an LM guide according to the present invention comprises: a mounting unit in which a first LM and a second LM are installed; A first application unit coupled to a first EL block movably coupled to the first EL display unit and configured to apply a load to the first EL display unit; A second application unit coupled to a second EL block movably coupled to the second EL display and adapted to apply a load to the second EL display; A measurement unit having the first application unit coupled to one side and the second application unit coupled to the other side; And a mobile unit for moving the measurement unit to move the first EL block and the second EL block.

The apparatus for testing an LM guide according to the present invention includes: a mounting unit in which a plurality of LM guides are installed; A plurality of application units for applying a load to each of the ELM guides; A plurality of measurement units for measuring a load applied to each of the LM guides by the application units; And a mobile unit for moving the measurement units to move the EL blocks of each of the ELM guides. The mobile unit may include a plurality of coupling mechanisms to which the measurement units are coupled, a coupling mechanism to couple the coupling mechanisms, and a moving mechanism to move the coupling mechanism.

According to the present invention, the following effects can be obtained.

The present invention can reduce the overall size and improve the accuracy and reliability of the test results for the LM guide by performing the test on the LM guide by moving the LM block.

The present invention can simultaneously test a plurality of LM guides, thereby reducing the cost of testing a plurality of LM guides.

1 is a schematic front view of an LM guiding test apparatus according to the prior art;
FIG. 2 is a schematic side view of a prior art LM Guide test apparatus
3 is a schematic perspective view of an LM Guide test apparatus according to the present invention.
4 is a schematic front view of the LM guide test apparatus according to the present invention as viewed in the direction of the arrow A in Fig.
5 is a schematic plan view of an LM Guide test apparatus according to the present invention.
Figure 6 is a schematic perspective view of a measurement unit and an application unit according to the present invention;
7 is a schematic block diagram for explaining a control unit and a display unit according to the present invention.
8 is a schematic perspective view of an LM guiding test apparatus according to a modified embodiment of the present invention.
9 is a schematic front view of the LM guide test apparatus according to a modified embodiment of the present invention,
10 is a schematic plan view of an ELM guiding test apparatus according to a modified embodiment of the present invention
11 is a schematic perspective view of a measurement unit and an application unit according to a modified embodiment of the present invention;
12 is a schematic perspective view of an LM Guide test apparatus according to another modified embodiment of the present invention
13 is a schematic rear view of the ELM guide test apparatus according to another modified embodiment of the present invention,
14 is a schematic plan view of an ELM guide test apparatus according to another modified embodiment of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of an ELM guide test apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

3 to 5, the LM guiding test apparatus 1 according to the present invention is for testing the LM Guide 200. FIG. The LM guide 200 includes an LM rail 210 and an LM block 220. The El emule 210 guides the El block 220 to move linearly. The EL block 220 is movably coupled to the EL display unit 210. The LM guide test apparatus 1 according to the present invention is configured to repeatedly reciprocate the ELM block 220 so that the ELM block 220 linearly moves along the ELM 210, Can be tested for durability.

To this end, the LM guiding test apparatus 1 according to the present invention includes a mounting unit 2 on which the LM 210 is installed, an application unit 3 for applying a load to the LM guide 200, A measurement unit 4 for measuring a load applied to the linear motion guide 200 by the application unit 3 and a movement unit 5 for moving the measurement unit 4. [ One end of the application unit 3 is coupled to the EL block 220 and the other end is coupled to the measurement unit 4. [ The measuring unit (4) is coupled to the mobile unit (5). As the moving unit 5 moves the measuring unit 4, the applying unit 3 moves and as the applying unit 3 moves, the Elb block 220 moves to the El emule 210). Therefore, in the LM guiding test apparatus 1 according to the present invention, by repeatedly reciprocating the Elb block 220 so that the El block 220 linearly moves along the El emery 210, 200 can be tested for durability. Accordingly, the LM guide test apparatus 1 according to the present invention can achieve the following operational effects.

First, since the conventional ELM guiding test apparatus repeatedly moves the ELM block 210 in a state where the ELM block 220 is fixed, as shown in FIG. 2, the ELM module 210 ) Increases the overall size due to the space that must be secured to move repeatedly.

Alternatively, the LM guiding test apparatus 1 according to the present invention performs a test on the LM guide 200 by repeatedly moving the LM 220 in a state where the LM 210 is fixed do. Accordingly, the LM guide test apparatus 1 according to the present invention does not need to secure a space for moving the EL element 210, as compared with the conventional art, so that the overall size can be reduced.

Second, the LM guiding test apparatus 1 according to the present invention is configured such that the LM guide 200 is repeatedly reciprocated in the same manner as the LM guide 200 is applied to the actual product, Perform a test on. Accordingly, the LM guiding test apparatus 1 according to the present invention can improve the accuracy of the test results for the LM guide 200.

Third, in the ELM guiding test apparatus 1 according to the present invention, since the ELM block 220 is guided by the ELM 210 and linearly moves, in the prior art, The guide mechanism 133 of FIG. Therefore, the LM guide test apparatus 1 according to the present invention can simplify the overall configuration compared to the prior art, and reduce the cost of testing the LM guide 200. [

Hereinafter, the installation unit 2, the application unit 3, the measurement unit 4, and the mobile unit 5 will be described in detail with reference to the accompanying drawings.

Referring to FIGS. 3 to 5, the installation unit 2 supports the LM guide 200. The mounting unit (2) is provided with the above-described EL display (210). The mounting unit 2 supports the EL display 210 so that the EL display 210 is positioned at a position where it can guide the linear movement of the EL display unit 220 relative to the EL display unit 220.

The mounting unit 2 is provided with an EL element 210 formed in a horizontal direction (X-axis direction). Accordingly, the EL block 220 can be linearly moved along the EL element 210 in the horizontal direction (X-axis direction). In the installation unit 2, the EL display 210 may be installed upright in the vertical direction (Z-axis direction). The vertical direction (Z-axis direction) is a direction perpendicular to the horizontal direction (X-axis direction). 3, the horizontal direction (X-axis direction) is the horizontal direction, and the vertical direction (Z-axis direction) is the height direction. Accordingly, the EL block 220 can be moved along the EL element 210 while standing in the vertical direction (Z-axis direction). Therefore, the following effects can be obtained in the LM guide test apparatus 1 according to the present invention.

1 and 2, in the LM guiding test apparatus 100 according to the related art, the LM guide 200 is laid down in the horizontal direction (X-axis direction, as shown in FIG. 3) ≪ / RTI > Accordingly, in the LM guiding test apparatus 100 according to the related art, the measuring unit 120 is installed above the LM guide 200 to be tested, and the hydraulic cylinder 110 is installed above the measuring unit 120 do. Accordingly, the LM Guide test apparatus 100 according to the related art is further provided with a load applied to the LM Guide 200 by using the hydraulic pressure, and the hydraulic cylinder 110 and the measurement unit 120 Is applied to the LM guide 200 as a load. Accordingly, since the prior art LMP guide test apparatus 100 can not apply a load to the LMP guide 200 less than the weight of the hydraulic cylinder 110 and the measurement unit 120, 200) is limited.

3 to 5, the LM guiding test apparatus 1 according to the present invention is installed in the installation unit 2 with the LM guide 200 standing in the vertical direction (Z-axis direction) . Accordingly, in the LM guiding test apparatus 1 according to the present invention, the application unit 3 is installed next to the LM guide 200 to be tested, and the measurement unit 4 is installed next to the application unit 3 do. Therefore, since the weight of the application unit 3 and the measurement unit 4 is not applied to the LM guide 200 as a load, the LM guide test apparatus 1 according to the present invention can be applied to the LM guide 200, It is possible to increase the range of the load that can be applied to the load. Accordingly, the LM guide test apparatus 1 according to the present invention can apply loads of various sizes to the LM guide 200 as compared with the prior art, so that the LM guide 200 can be tested under various test conditions .

3 to 5, the installation unit 2 includes a first frame 21 to which the EL element 210 is coupled, a second frame 22 to which the first frame 21 is coupled, And a third frame 23 to which the second frame 22 is coupled.

The first frame 21 is installed in the vertical direction (Z-axis direction) so as to support the EL element 210 erected in the vertical direction (Z-axis direction) and is coupled to the second frame 22 . The first frame 21 may be formed as a rectangular plate as a whole.

The second frame 22 may be laid down in the horizontal direction (X-axis direction) and coupled to the third frame 23. The second frame 22 supports the first frame 21 to support the LM guide 200. The second frame 22 may be formed as a rectangular plate as a whole.

The third frame (23) supports the second frame (22). The second frame 22 may be coupled to the third frame 23 at a predetermined distance from the third frame 23. The mobile unit 5 may be positioned between the third frame 23 and the second frame 22. The third frame 23 may be formed as a rectangular plate as a whole.

Referring to FIGS. 3 to 6, the application unit 3 applies a load to the LM guide 200. The application unit 3 is located between the LM guide 200 and the measurement unit 4. [ One end of the application unit 3 is coupled to the measurement unit 4, and the other end is connected to the EL block 220. When the moving unit 5 moves the measuring unit 4, the applying unit 3 moves together with the measuring unit 4. [ As the application unit 3 moves, the EL block 220 can move along the EL display 210. [ One end of the EL block 220 is movably coupled to the EL display unit 210, and the other end thereof is coupled to the EL unit. The application unit 3 can apply a load to the EL block 220 and the EL element 210 by applying a force to the EL block 220. [ The EL block 220 may include an insertion groove 221 (shown in FIG. 6) in which the application unit 3 is inserted. The application unit 3 may be inserted into the insertion groove 221 to be coupled to the elb block 220.

The application unit 3 can change the magnitude of the load applied to the LM guide 200. [ The LM guide test apparatus 1 according to the present invention can test the durability of the LM guide 200 by moving the LM block 220 according to a set test condition. For example, the test conditions may include a magnitude of a load applied to the LM guide 200 by the application unit 3, a number of times the LM 220 moves back and forth along the LM 200, A cumulative distance at which the moving body 220 moves along the EL display 210, a moving speed of the EL display 220, and the like. After the LMP 200 is tested according to the test conditions as described above, it is determined whether or not the LMP 200 is applicable to equipment having environmental conditions corresponding to the test conditions.

The application unit (3) can be rotatably coupled to the measurement unit (4). The application unit 3 may be rotated in a first direction or a second direction in a state of being coupled to the measurement unit 4. [ The first direction and the second direction are directions opposite to each other. The application unit 3 can change the load applied to the LM guide 200 as it is rotated in the first direction or the second direction. When the application unit (3) is rotated in the first direction, the application unit (3) is fastened to the measurement unit (4). Accordingly, the application unit 3 can reduce the load applied to the LM guide 200. [ When the application unit (3) is rotated in the second direction, the application unit (3) is released from the measurement unit (4). Accordingly, the application unit 3 can increase the load applied to the LM guide 200. [ Therefore, since the expensive hydraulic cylinder for applying the load can be omitted in the conventional EL guide test apparatus 1 according to the present invention, the cost for testing the EL guide 200 can be reduced.

3 through 6, the application unit 3 includes a pressing mechanism 31 (shown in FIG. 6) inserted into the EL block 220, a fastening mechanism 32 fastened to the measuring unit 4 , And a rotation mechanism 33 for rotating the fastening mechanism 32. [

The pressing mechanism 31 is inserted into an insertion groove 221 (shown in FIG. 6) formed in the elbow block 220. As the pressing mechanism 31 is inserted into the insertion groove 221, the EL block 220 can move together as the applying unit 3 moves. The pressing mechanism 31 may be formed in a disk shape as a whole but is not limited thereto and may be a shape that can be inserted into the elb block 220 so that the elb block 220 and the applying unit 3 can move together. And may be formed in other shapes such as a rectangular plate shape. The insertion groove 221 may be formed in a shape corresponding to the pressing mechanism 31.

One side of the fastening mechanism (32) is engaged with the pressurizing mechanism (31), and the other side is fastened to the measurement unit (4). A screw thread is formed on the outer peripheral surface of the fastening mechanism (32). Although not shown, the measuring unit 4 is formed with a fastening groove for fastening the fastening mechanism 32. As the fastening mechanism 32 is fastened to the measuring unit 4 or the fastening is released from the measuring unit 4, the applying unit 3 can change the load applied to the LM guide 200 have. The fastening mechanism 32 may be formed in a cylindrical shape as a whole.

The rotating mechanism (33) is coupled to the fastening mechanism (32). The rotating mechanism 33 is coupled to the fastening mechanism 32 so as to be positioned between the measuring unit 4 and the pressing mechanism 31. The fastening mechanism 32 may be coupled to the pressurizing mechanism 31 and the measurement unit 4 through the rotation mechanism 33. To this end, the rotation mechanism 33 may be formed with a through hole (not shown) through which the fastening mechanism 32 passes. The rotation mechanism (33) is fixedly coupled to the fastening mechanism (32). Accordingly, the fastening mechanism 32 can rotate together with the rotation mechanism 33 as it rotates. The outer circumferential surface of the rotating mechanism 33 may have a polygonal structure. Accordingly, the user can easily rotate the rotating mechanism 33 using a predetermined tool, and accordingly, the load applied to the LM guide 200 can be changed by rotating the fastening mechanism 32 .

Although not shown, the LM guiding test apparatus 1 according to the present invention may include a driving mechanism for rotating the rotating mechanism 33. The drive mechanism can rotate the rotation mechanism 33 to rotate the fastening mechanism 32 so that the fastening mechanism 32 is fastened to the measurement unit 4 or the fastening is released from the measurement unit 4. [ Accordingly, the LM guide testing apparatus 1 according to the present invention can test the LM guide 200 under various test conditions by varying the load applied to the LM guide 200. [ The driving mechanism may include a motor for providing a turning force, and a connecting means for connecting the motor and the rotating mechanism 33. The connecting means may be a pulley and a belt, gear, chain or the like.

3 to 6, the measurement unit 4 measures a load applied to the LM guide 200 by the application unit 3. [ The measuring unit (4) is coupled to the mobile unit (5). The mobile unit 5 can move the application unit 3 and the EL block 220 by moving the measurement unit 3. [ The measuring unit 4 detects a load applied to the LM guide 200 by the application unit 3 by sensing the direction in which the application unit 3 is rotated and the degree to which the application unit 3 is rotated Can be measured. The measurement unit 4 may be a load cell.

The measuring unit 4 is coupled to the mobile unit 5 so as to be positioned on the opposite side of the elb block 220 with respect to the applying unit 3. The measurement unit 4 is coupled to the mobile unit 5 so as to be located next to the application unit 3. [ The application unit 3 is coupled to the measurement unit 4 so as to be positioned next to the elb block 220. In this case, the LM guide 200 may be installed upright in the vertical direction (Z-axis direction). Therefore, the LM guide test apparatus 1 according to the present invention prevents the weight of the measurement unit 4 and the application unit 3 from acting as a load on the LM guide 200, 200 can be increased. Accordingly, the LM guiding test apparatus 1 according to the present invention can test the LM guide 200 with a wider range of test conditions than the prior art.

Referring to Figs. 3 to 6, the mobile unit 5 moves the measurement unit 4. Fig. The mobile unit 5 repeatedly reciprocates the measuring unit 4 in the horizontal direction (X-axis direction) to move the EL block 220 in the horizontal direction X Axis direction). Therefore, the LM guide test apparatus 1 according to the present invention can perform the test on the LM guide 200. [ The mobile unit (5) is installed in the installation unit (2). The measuring unit (4) is coupled to the mobile unit (5).

3 to 6, the mobile unit 5 may include a coupling mechanism 51 to which the measurement unit 4 is coupled and a movement mechanism 52 to move the coupling mechanism 51 have.

The coupling mechanism (51) supports the measuring unit (4). The measuring unit 4 is coupled to the engaging mechanism 51 so that the measuring unit 4 can move together as the engaging mechanism 51 moves. The measuring unit 4 may be coupled to the coupling mechanism 51 using fastening means such as bolts.

The moving mechanism (52) can move the coupling mechanism (51). The moving mechanism (52) can move the measuring unit (4) by moving the engaging mechanism (51). Accordingly, the EL block 220 can be repeatedly reciprocated in the horizontal direction (X-axis direction) along the EL display unit 210. The moving mechanism 52 may include a motor 521, a ball screw 522, and a ball nut (not shown) fastened to the ball screw 522. The ball nut may be linearly coupled with the ball screw 522 by being fastened to the ball screw 522 or released from the ball screw 522 according to the direction in which the ball screw is rotated. The coupling mechanism 51 may be coupled to the ball nut. Accordingly, the coupling mechanism 51 can linearly move in the horizontal direction (X-axis direction) as the ball screw 522 is rotated by the motor 521. [ Although not shown, the moving mechanism 52 may be a cylinder type using a hydraulic cylinder or a pneumatic cylinder, a gear type using a motor, a rack gear and a pinion gear, a motor, a pulley and a belt The coupling mechanism 51 may be moved by a belt method or a method using a linear motor.

The moving mechanism 52 may be coupled to the third frame 23 so as to be positioned between the second frame 22 and the third frame 23. That is, the moving mechanism 52 is installed below the second frame 22. One side of the coupling mechanism 51 is coupled to the moving mechanism 52 between the second frame 22 and the third frame 23 and the other side is coupled to the measuring unit (4). Accordingly, the measurement unit 4, the application unit 3 and the EL block 220 can move in the horizontal direction (X-axis direction) from above the second frame 22. Therefore, in the LM guiding test apparatus 1 according to the present invention, the moving mechanism 52, the measuring unit 4, the applying unit 3 and the EL block 220 are all disposed on the second frame 22, It is possible to reduce the size of the second frame 22, as compared with that provided on the upper side. In this case, the coupling mechanism 51 may be coupled to the moving mechanism 52 and the measuring unit 4 through the second frame 22, respectively. The second frame 22 is formed with a through hole 24 through which the coupling mechanism 51 penetrates. The through holes 24 may be elongated in the horizontal direction (X-axis direction) so that the coupling mechanism 51 can move in the horizontal direction (X-axis direction). The through hole 24 may be formed to have a length corresponding to a length of the EL element 210 in the horizontal direction (X-axis direction).

3 to 7, the ELM guide test apparatus 1 according to the present invention may further include a control unit 6 (shown in Fig. 7) for controlling the mobile unit 5. [

The control unit 6 may control the mobile unit 5 to adjust the speed at which the measurement unit 4 moves. The control unit 6 may adjust the speed at which the EL block 220 moves along the EL display 210 by adjusting the speed at which the measuring unit 4 moves. Accordingly, the LM guide test apparatus 1 according to the present invention can change the moving speed of the LM guide 220 along the LM guide 210, You can test. The control unit 6 can control the moving speed of the coupling mechanism 51 by controlling the moving mechanism 52. [ The control unit 6 may be installed in the installation unit 2 or may be installed at a position apart from the installation unit 2. [

The control unit 6 may control the mobile unit 5 so that the EL block 220 moves at a different speed for each set interval. For example, the control unit 6 may move the first section A1 (shown in FIG. 5) at 300 mm / sec along the EL element 210 and the second section A2, shown in Fig. 5) at 500 mm / sec. Therefore, the ELM guide testing apparatus 1 according to the present invention allows the ELM block 220 to reciprocate along the ELM 210 while varying the speed thereof, .

3 to 7, the LM guiding test apparatus 1 according to the present invention may further include a display unit 7 (shown in FIG. 7) for displaying test conditions for the LM guide 200 have.

The display unit 7 may include a display device (not shown) for displaying test conditions for the LM guide 200. The display unit 7 can receive information on the magnitude of the load applied from the measuring unit 4 to the LM guide 200 by the application unit 3. The display unit 7 can display information on the received load on the display device. The user can check whether the load to be tested is being applied to the LM Guide 200 from the information displayed on the display device. The display unit 7 can receive information on the load from the measurement unit 4 via wire communication or wireless communication.

The display unit 7 can receive information on the speed at which the mobile unit 5 moves the Elb block 220 from the control unit 6 (shown in Fig. 7). The display unit 7 can display information on the received speed on the display device. The display unit 7 displays the number of times the EL display unit 220 reciprocates along the EL display unit 210 and the cumulative distance that the EL display unit 220 moves along the EL display unit 210 And may be displayed on the display device. In this case, the control unit 7 determines the number of times the Elblock 220 reciprocates along the El emule 210, the number of times the Elblock 220 moves along the El emule 210, Distance, and the like to the display unit 7. [0064] The display unit 7 can receive information from the control unit 7 via wired communication or wireless communication.

Although not shown, the LM guiding test apparatus 1 according to the present invention may include a plurality of the display units 7. The display unit 7 may display different information on the test condition. For example, the LM guiding test apparatus 1 according to the present invention may include a first display unit for displaying information about a load applied to the LM guide 200, and a second display unit for displaying information on the speed at which the LM block 220 moves And a second display unit for displaying the second display unit. The second display unit displays information on the number of times the EL display unit 220 reciprocates along the EL display unit 210, the accumulated distance traveled by the EL display unit 220 along the EL display unit 210, May be displayed.

Referring to FIGS. 8 to 10, the LM guiding test apparatus 1 according to the modified embodiment of the present invention can be implemented so as to simultaneously test two LM guides 200a and 200b (shown in FIG. 9) . Hereinafter, the LM guiding test apparatus 1 according to the modified embodiment of the present invention will be described. Hereinafter, configurations of the LM guiding test apparatus 1 according to a modified embodiment of the present invention will be described in detail with respect to configurations different from the LM guiding test apparatus 1 according to the present invention described above.

8 to 10, the mounting unit 2 supports a first LM guide 200a and a second LM guide 200b (shown in Fig. 9). The first ELM guide 200a includes a first ELM block 210a and a first ELM block 220a linearly movably coupled to the first ELM module 210a. The second ELM guide 200b includes a second ELM block 210b (shown in FIG. 9) and a second ELM block 220b linearly movably coupled to the second ELM module 210b . In the installation unit 2, the first and second EL elements 210a and 210b are spaced apart from each other by a predetermined distance.

The installation unit 2 is provided with a first elm emitter 210a and a second elm emitter 210b formed in the horizontal direction (X axis direction). Accordingly, the first ELM block 220a can be linearly moved in the horizontal direction (X-axis direction) along the first EL element 210a. The second EL block 220b may be linearly moved in the horizontal direction (X-axis direction) along the second EL element 210b. In the installation unit 2, the first EL element 210a and the second EL element 210b may be installed in the vertical direction (Z-axis direction). Accordingly, the first EL block 220a and the second EL block 220b are positioned in the vertical direction (Z-axis direction), respectively, so that the first EL block 210a and the second EL block 220b, Lt; RTI ID = 0.0 > 210b. ≪ / RTI > The first EL element 210a and the second EL element 210b are disposed to face each other. Accordingly, the first EL block 220a and the second EL block 220b are located between the first EL display 210a and the second EL display 210b.

8 to 10, the installation unit 2 includes two first frames 21a and 21b. The first frames 21a and 21b are coupled to the second frame 22. The first frames 21a and 21b are arranged in the vertical direction (Z-axis direction) so as to support the first EL element 210a and the second EL element 210b erected in the vertical direction Direction and can be coupled to the second frame 22. The first frames 21a and 21b are coupled to the second frame 22 at a predetermined distance from each other.

Referring to Figs. 8 to 11, the LM Guide test apparatus 1 according to the modified embodiment of the present invention includes a first application unit 3a and a second application unit 3b.

The first application unit 3a applies a load to the first LM guide 200a. The first application unit 3a is positioned between the first LM guide 200a and the measurement unit 4. [ One end of the first application unit 3a is coupled to the measurement unit 4 and the other end is coupled to the first ELM block 220a. When the moving unit 5 moves the measuring unit 4, the first applying unit 3a moves together with the measuring unit 4. [ As the first application unit 3a moves, the first ELM block 220a may move along the first ELMail 210a. One end of the first ELM block 220a is movably coupled to the first ELM 210a and the other end is coupled to the first application unit 3a. The first application unit 3a can apply a load to the first EL block 220a and the first EL block 210a by applying a force to the first EL block 220a. The first ELM block 220a may include a first insertion groove 221a (shown in FIG. 11) for inserting the first application unit 3a. The first application unit 3a may be coupled to the first ELM block 220a by being inserted into the first insertion groove 221a.

The first application unit 3a may vary the magnitude of the load applied to the first LM guide 200a. The first application unit 3a may be rotatably coupled to the measurement unit 4. The first application unit 3a may be rotated in the first direction or the second direction while being coupled to the measurement unit 4. [ The first application unit 3a can change a load applied to the first LM guide 200a as it is rotated in the first direction or the second direction. When the first application unit (3a) is rotated in the first direction, the first application unit (3a) is fastened to the measurement unit (4). Accordingly, the first application unit 3a can reduce the load applied to the first LM guide 200a. When the first application unit (3a) is rotated in the second direction, the first application unit (3a) is released from the measurement unit (4). Accordingly, the first application unit 3a can increase the load applied to the first LM guide 200a.

8 to 11, the first applying unit 3a includes a first pressing mechanism 31a inserted into the first ELM block 220a, a first pressing mechanism 31a fixed to the measuring unit 4, (32a), and a first rotating mechanism (33a) for rotating the first fastening mechanism (32a).

The first pressing mechanism 31a is inserted into a first insertion groove 221a (shown in FIG. 11) formed in the first EL block 220a. As the first pressing mechanism 31a is inserted into the first insertion groove 221a, the first ELM block 220a can move along with the movement of the first application unit 3a.

One side of the first fastening mechanism 32a is coupled to the first pressing mechanism 31a and the other side is fastened to the measurement unit 4. [ A thread is formed on the outer circumferential surface of the first fastening mechanism 32a. Although not shown, the measuring unit 4 is formed with a first fastening groove for fastening the first fastening mechanism 32a. As the first fastening mechanism 32a is fastened to the measuring unit 4 or fastening is released from the measuring unit 4, the first applying unit 3a is applied to the first LM guide 200a The load can be varied.

The first rotating mechanism (33a) is coupled to the first fastening mechanism (32a). The first rotating mechanism 33a is coupled to the first fastening mechanism 32a so as to be positioned between the measuring unit 4 and the first pressing mechanism 31a. The first fastening mechanism 32a may be coupled to the first pressing mechanism 31a and the measuring unit 4 through the first rotating mechanism 33a. To this end, the first rotation mechanism 33a may be provided with a first passage hole (not shown) through which the first fastening mechanism 32a passes. The first rotation mechanism 33a is fixedly coupled to the first fastening mechanism 32a. Accordingly, the first fastening mechanism 32a can rotate together as the first rotating mechanism 33a is rotated.

Referring to FIGS. 8 to 11, the second application unit 3b applies a load to the second LM guide 200b. The second application unit 3b is located between the second LM guide 200b and the measurement unit 4. [ The second application unit 3b has one side coupled to the measurement unit 4 and the other side coupled to the second EL block 220b. When the moving unit 5 moves the measuring unit 4, the second applying unit 3b moves together with the measuring unit 4. [ As the second application unit 3b moves, the second EL block 220b may move along the first EL element 210a. One end of the second ELM block 220b is movably coupled to the first ELM 210a and the other end thereof is coupled to the second application unit 3b. The second application unit 3b can apply a load to the second EL block 220b and the first EL element 210a by applying a force to the second EL block 220b. The second EL block 220b may include a second insertion groove (not shown) for inserting the second application unit 3b. The second application unit 3b may be inserted into the second insertion groove to be coupled to the second EL block 220b.

The second application unit 3b may vary the magnitude of the load applied to the second LM guide 200b. The second application unit (3b) can be rotatably coupled to the measurement unit (4). The second application unit 3b may be coupled to the measurement unit 4 so as to be positioned on the opposite side of the first application unit 3a with respect to the measurement unit 4. [ The second application unit 3b may be rotated in the first direction or the second direction while being coupled to the measurement unit 4. [ The second application unit 3b can change a load applied to the second LM guide 200b as it is rotated in the first direction or the second direction. When the second application unit 3b is rotated in the first direction, the second application unit 3b is fastened to the measurement unit 4. Accordingly, the second application unit 3b can reduce the load applied to the second LM guide 200b. When the second application unit 3b is rotated in the second direction, the second application unit 3b is released from the measurement unit 4. Accordingly, the second application unit 3b can increase the load applied to the second LM guide 200b.

8-11, the second applying unit 3b includes a second pressing mechanism 31b inserted into the second ELM block 220b, a second fastening mechanism 31b fastened to the measuring unit 4, (32b) for rotating the second fastening mechanism (32b), and a second rotating mechanism (33b) for rotating the second fastening mechanism (32b).

The second pressing mechanism 31b is inserted into the second insertion groove formed in the second EL block 220b. As the second pressing mechanism 31b is inserted into the second insertion groove, the second ELM block 220b can move together as the second applying unit 3b moves.

One end of the second fastening mechanism 32b is engaged with the second pressurizing mechanism 31b and the other end thereof is fastened to the measurement unit 4. A thread is formed on the outer circumferential surface of the second fastening mechanism 32b. Although not shown, the measuring unit 4 is formed with a second fastening groove for fastening the second fastening mechanism 32b. As the second fastening mechanism 32b is fastened to the measuring unit 4 or the fastening is released from the measuring unit 4, the second applying unit 3b is applied to the second LM guide 200b The load can be varied.

And the second rotating mechanism 33b is coupled to the second fastening mechanism 32b. The second rotating mechanism 33b is coupled to the second fastening mechanism 32b so as to be positioned between the measuring unit 4 and the second pressing mechanism 31b. The second fastening mechanism 32b may be coupled to the second pressing mechanism 31b and the measuring unit 4 through the second rotating mechanism 33b. To this end, the second rotation mechanism 33b may be provided with a second passage hole (not shown) through which the second fastening mechanism 32b passes. And the second rotating mechanism 33b is fixedly coupled to the second fastening mechanism 32b. Accordingly, the second fastening mechanism 32b can rotate together as the second rotating mechanism 33b is rotated.

8 to 11, the measurement unit 4 measures the load applied to the first LM guide 200a by the first application unit 3a. The measuring unit 4 senses the direction in which the first application unit 3a is rotated and the degree to which the first application unit 3a is rotated so that the first application unit 3a can move in the first direction, It is possible to measure a load to be applied to the load 200a. The measurement unit 4 measures a load applied to the second LM guide 200b by the second application unit 3b. The measurement unit 4 detects the direction in which the second application unit 3b is rotated and the degree to which the second application unit 3b is rotated so that the second application unit 3b can detect the direction of rotation of the second application unit 3b, The load to be applied to the electrode 200b can be measured. The first application unit 3a can apply a load having the same magnitude as the load applied to the second LMP guide 200b by the second application unit 3b to the first LMP guide 200a.

Referring to Figs. 8 to 11, the mobile unit 5 moves the measurement unit 4. Fig. The measurement unit 4 has the first application unit 3a coupled to one side and the second application unit 3b connected to the other side. The moving unit 5 repeatedly reciprocates the measuring unit 4 in the horizontal direction (X-axis direction) to move the first and second ELM blocks 220a and 220b in the horizontal direction (In the X-axis direction) repeatedly. Therefore, the LM guiding test apparatus 1 according to the modified embodiment of the present invention can simultaneously perform the tests on the first LM guide 200a and the second LM guide 200b. Accordingly, the ELM guide test apparatus 1 according to the modified embodiment of the present invention can achieve the following operational effects.

First, the LM guiding test apparatus 1 according to the modified embodiment of the present invention can simultaneously test two LM guides 200a and 200b using one measuring unit 4. [ Therefore, the LM guide test apparatus 1 according to the modified embodiment of the present invention can reduce the cost of performing the tests on the LM guides 200a and 200b, and the two LM guides 200a and 200b, It is possible to minimize the overall size increase due to testing.

Second, the LM guiding test apparatus 1 according to the modified embodiment of the present invention moves the first ELM block 220a and the second ELM block 220b simultaneously using one mobile unit 5 . Therefore, the LM guide test apparatus 1 according to the modified embodiment of the present invention can simplify the overall configuration and reduce the cost of performing the tests on the LM guides 200a and 200b .

Referring to FIGS. 12 to 14, the LM guiding test apparatus 1 according to another modified embodiment of the present invention includes 2N (N is an integer larger than 1) number of LM guides 200 (shown in FIG. 3) Can be implemented so that they can be tested simultaneously. In this case, two application units 3 (shown in FIG. 3) respectively coupled to two EL blocks 200 (two EL blocks 200 and two EL blocks 200 each having two EL blocks 200 shown in FIG. 3) , One measuring unit 4 (shown in Fig. 3) in which the two application units 3 are coupled, and a coupling mechanism 51 (shown in Fig. 3) in which the measuring unit 4 is coupled, . The LM guiding test apparatus 1 according to another modified embodiment of the present invention includes a plurality of sets and can simultaneously test a plurality of LM guides 200 using one moving mechanism 52 have.

To this end, the mobile unit 5 includes a connection mechanism 53 (shown in Fig. 13) for connecting the coupling mechanisms 51 of the sets. The connecting mechanism (53) is coupled to the moving mechanism (52). Therefore, the coupling mechanisms 51 of the sets can move together as the moving mechanism 52 moves the coupling mechanism 53. Accordingly, since the EL blocks 220 of the sets move along the EL elements 210, the EL element testing apparatus 1 according to another modified embodiment of the present invention can be applied to a plurality of EL elements 200 Can be performed at the same time. Therefore, the LM guide test apparatus 1 according to another modified embodiment of the present invention can perform a test on a plurality of LM guides 200 by using one movement mechanism 52, It is possible to simplify the configuration and reduce the cost of performing the test on the LM guides 200.

12 to 14, the connecting mechanism 53 (shown in FIG. 13) is coupled to the moving mechanism 52 so as to be positioned between the second frame 22 and the third frame 23 . When the moving mechanism 52 includes the motor 521 (shown in Fig. 12), the ball screw 522 (shown in Fig. 12), and the ball nut, Can be coupled to the nut. The coupling mechanism 51 (shown in FIG. 3) of the sets may be coupled to the coupling mechanism 53 between the second frame 22 and the third frame 23. The connection mechanism 53 may be formed as a rectangular plate as a whole. The second frame 22 may have a plurality of through holes 24 (shown in FIG. 3) for the coupling mechanism 51 (shown in FIG. 3) to pass through.

Referring to Figs. 12 to 14, the LM guide test apparatus 1 according to another modified embodiment of the present invention performs a test on four LM guides 200a, 200b, 200c, and 200d (shown in Fig. 13) Hereinafter, embodiments to be performed at the same time will be described in detail.

The installation unit 2 supports a first LM guide 200a, a second LM guide 200b, a third LM guide 200c and a fourth LM guide 200d. The first ELM guide 200a includes a first ELM block 210a and a first ELM block 220a linearly movably coupled to the first ELM module 210a. The second ELM guide 200b includes a second ELM block 210b and a second ELM block 220b linearly movably coupled to the second ELM module 210b. The third ELM guide 200c includes a third ELM block 210c and a third ELM block 220c linearly movably coupled to the third ELM module 210c. The fourth ELM guide 200d includes a fourth ELM block 210d and a fourth ELM block 220d linearly movably coupled to the fourth ELM module 210d.

The installation unit 2 is provided with the first El emerald 210a, the second El emre 210b, the third El emre 210c, and the fourth El emre 210d, It is installed at a distance. The first L emale 210a, the second L emre 210b, the third L emre 210c, and the fourth L emre 210d are arranged in the vertical direction (Z-axis direction) And can be installed in the installation unit 2. In this case, the first and second EL elements 210a and 210b are disposed to face each other. The third and the fourth E-mailers 210c and 210d are disposed to face each other. The installation unit 2 includes four first frames 21a, 21b, 21c, and 21d.

Referring to Figs. 12 to 14, the ELM guiding test apparatus 1 according to another modified embodiment of the present invention includes a first measuring unit 4a and a second measuring unit 4b.

The first measurement unit 4a is installed between the first and second LM guides 200a and 200b. The first measurement unit 4a has the first application unit 3a coupled to one side and the second application unit 3b connected to the other side. The first measurement unit 4a measures a load applied to the first LM guide 200a by the first application unit 3a. The first measurement unit 4a detects the direction in which the first application unit 3a is rotated and the degree to which the first application unit 3a is rotated so that the first application unit 3a The load applied to the LM guide 200a can be measured. The first measurement unit 4a measures a load applied to the second LM guide 200b by the second application unit 3b. The first measurement unit 4a detects the direction in which the second application unit 3b is rotated and the degree to which the second application unit 3b is rotated so that the second application unit 3b can detect the second The load applied to the LM guide 200b can be measured. The first application unit 3a can apply a load having the same magnitude as the load applied to the second LMP guide 200b by the second application unit 3b to the first LMP guide 200a.

The first application unit 3a applies a load to the first LM guide 200a. The first application unit 3a is positioned between the first LM guide 200a and the first measurement unit 4a. One end of the first application unit 3a is coupled to the first measurement unit 4a and the other end thereof is coupled to the first ELM block 220a. The first application unit 3a may vary the magnitude of the load applied to the first LM guide 200a. The first application unit 3a may be rotatably coupled to the first measurement unit 4a. The first application unit 3a may be rotated in the first direction or the second direction while being coupled to the first measurement unit 4a. The first application unit 3a can change a load applied to the first LM guide 200a as it is rotated in the first direction or the second direction. When the first application unit 3a is rotated in the first direction, the first application unit 3a is fastened to the first measurement unit 4a. Accordingly, the first application unit 3a can reduce the load applied to the first LM guide 200a. When the first application unit 3a is rotated in the second direction, the first application unit 3a is disengaged from the first measurement unit 4a. Accordingly, the first application unit 3a can increase the load applied to the first LM guide 200a.

The second application unit 3b applies a load to the second LM guide 200b. The second application unit 3b is located between the second LM guide 200b and the first measurement unit 4a. One end of the second application unit 3b is coupled to the first measurement unit 4a and the other end thereof is coupled to the second EL block 220b. The second application unit 3b may vary the magnitude of the load applied to the second LM guide 200b. The second application unit 3b may be rotatably coupled to the first measurement unit 4a. The second application unit 3b may be rotated in the first direction or the second direction while being coupled to the first measurement unit 4a. The second application unit 3b can change a load applied to the second LM guide 200b as it is rotated in the first direction or the second direction. When the second application unit 3b is rotated in the first direction, the second application unit 3b is fastened to the first measurement unit 4a. Accordingly, the second application unit 3b can reduce the load applied to the second LM guide 200b. When the second application unit 3b is rotated in the second direction, the second application unit 3b is released from the first measurement unit 4a. Accordingly, the second application unit 3b can increase the load applied to the second LM guide 200b.

Referring to FIGS. 12 to 14, the second measurement unit 4b is installed between the third LM guide 200c and the fourth LM guide 200d. The second measuring unit 4b has a third applying unit 3c coupled to one side and a fourth applying unit 3d coupled to the other side. The second measuring unit 4b measures a load applied to the third LM guide 200c by the third applying unit 3c. The second measuring unit 4b detects the direction in which the third applying unit 3c is rotated and the degree to which the third applying unit 3c is rotated so that the third applying unit 3c The load applied to the LM guide 200c can be measured. The second measurement unit 4b measures a load applied to the fourth LM guide 200d by the fourth application unit 3d. The second measurement unit 4b detects the direction in which the fourth application unit 3d is rotated and the degree to which the fourth application unit 3d is rotated so that the fourth application unit 3d can move in the fourth The load applied to the LM guide 200d can be measured. The third application unit 3c can apply a load having the same magnitude as the load applied to the fourth LM guide 200d by the fourth application unit 3d to the third LM guide 200c.

The third application unit 3c applies a load to the third ELM guide 200c. The third application unit 3c is located between the third ELM guide 200c and the second measurement unit 4b. One end of the third application unit 3c is coupled to the second measurement unit 4b and the other end thereof is coupled to the third EL block 220c. The third application unit 3c can vary the magnitude of the load applied to the third LM guide 200c. The third application unit 3c may be rotatably coupled to the second measurement unit 4b. The third application unit 3c may be rotated in the first direction or the second direction while being coupled to the second measurement unit 4b. The third application unit 3c can vary the load applied to the third LM guide 200c as it rotates in the first direction or the second direction. When the third application unit 3c is rotated in the first direction, the third application unit 3c is fastened to the second measurement unit 4b. Accordingly, the third application unit 3c can reduce a load applied to the third ELM guide 200c. When the third application unit 3c is rotated in the second direction, the third application unit 3c is released from the second measurement unit 4b. Accordingly, the third application unit 3c can increase the load applied to the third LM guide 200c.

The fourth application unit 3d applies a load to the fourth ELM guide 200d. The fourth application unit 3d is positioned between the fourth LM guide 200d and the second measurement unit 4b. One end of the fourth application unit 3d is coupled to the second measurement unit 4b and the other end thereof is coupled to the fourth EL block 220d. The fourth application unit 3d can vary the magnitude of the load applied to the fourth LM guide 200d. The fourth application unit 3d may be rotatably coupled to the second measurement unit 4b. The fourth application unit 3d may be rotated in the first direction or the second direction while being coupled to the second measurement unit 4b. The fourth application unit 3d can change a load applied to the fourth ELM guide 200d as it is rotated in the first direction or the second direction. When the fourth application unit 3d is rotated in the first direction, the fourth application unit 3d is fastened to the second measurement unit 4b. Accordingly, the fourth application unit 3d can reduce the load applied to the fourth ELM guide 200d. When the fourth application unit 3d is rotated in the second direction, the fourth application unit 3d is released from the second measurement unit 4b. Accordingly, the fourth application unit 3d can increase the load applied to the fourth ELM guide 200d.

12 to 14, the mobile unit 5 moves the first measurement unit 4a and the second measurement unit 4b. The mobile unit 5 includes a first coupling mechanism 51a (shown in FIG. 13) to which the first measurement unit 4a is coupled and a second coupling mechanism 51b , Shown in Fig. 13). The first coupling mechanism 51a and the second coupling mechanism 52b are coupled to the coupling mechanism 53. [ Accordingly, when the moving mechanism 52 moves the connection mechanism 53, the first measurement unit 4a and the second measurement unit 4b can move. Therefore, the LM guiding test apparatus 1 according to another modified embodiment of the present invention may include the first LM guide 200a, the second LM guide 200b, the third LM guide 200c, 4LM guide 200d at the same time.

In the above description, the LM guiding test apparatus 1 according to another modified embodiment of the present invention simultaneously performs the tests on the four LM guides 200. However, it should be understood that other modified embodiments An embodiment in which the LM guiding test apparatus 1 according to the embodiment performs the test for more than four LM guides 200 at the same time can be easily obtained.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Will be clear to those who have knowledge of.

1: ELM guide test apparatus 2: installation unit 3: authorization unit 4: measurement unit
5: mobile unit 6: control unit 7: display unit 21: first frame
22: second frame 23: third frame 24: through hole 31: pressing mechanism
32: fastening mechanism 33: rotating mechanism 51: engaging mechanism 52:
53: connection mechanism 200: LM Guide 210: El Emreil 220:

Claims (10)

An application unit for applying a load to an ELM guide to be tested;
A measurement unit coupled to the application unit and configured to measure a load applied to the LM guide by the application unit;
A mounting unit in which the EL elements of the ELM guide are installed in a horizontal direction; And
And a mobile unit for moving the measuring unit so as to move an EL block, one side of which is movably coupled to the EL emulsion and the other side of which is coupled to the application unit,
Wherein the mounting unit includes a first frame to which the EL display is coupled;
A second frame coupled to a lower side of the first frame; And
And a third frame spaced apart from the lower side of the second frame,
And the mobile unit is located between the second frame and the third frame. The method according to claim 1,
Wherein the measuring unit is rotatably coupled to the applying unit,
Wherein the application unit changes the load applied to the LM guide as it rotates in a first direction to be fastened to the measurement unit or in a second direction to release fastening from the measurement unit. The method according to claim 1,
The moving unit moves the measuring unit in the horizontal direction so that the EL block moves in the horizontal direction,
Wherein the mounting unit is provided with an el emhile formed in the horizontal direction so that the elb block is linearly moved in the horizontal direction,
Wherein the LM emulsion is installed in the installation unit in a vertical direction. The method according to claim 1,
And a control unit for controlling the mobile unit to adjust a speed at which the measurement unit moves;
Wherein the control unit controls the mobile unit so that the EL block moves at a different speed according to a set interval. A mounting unit in which a first el Emblem and a second el Emblem are installed;
A first application unit coupled to a first EL block movably coupled to the first EL display unit and configured to apply a load to the first EL display unit;
A second application unit coupled to a second EL block movably coupled to the second EL display and adapted to apply a load to the second EL display;
A measurement unit having the first application unit coupled to one side and the second application unit coupled to the other side; And
And a mobile unit for moving the measurement unit to move the first EL block and the second EL block,
The mounting unit may include a first frame to which the first EL display and the second EL display are coupled;
A second frame coupled to a lower side of the first frame; And
And a third frame spaced apart from the lower side of the second frame,
And the mobile unit is located between the second frame and the third frame. 6. The method of claim 5,
The first application unit and the second application unit are rotatably coupled to the measurement unit,
Wherein the first application unit changes a load applied to the first elm block and the first elm em line as it is rotated in a first direction to be fastened to the measurement unit or in a second direction to release fastening from the measurement unit ,
Wherein the second application unit changes a load applied to the second ELM block and the second ELM as the second application unit rotates in the first direction or the second direction. 6. The method of claim 5,
Wherein the moving unit moves the measuring unit in the horizontal direction so that the first and second ELM blocks move in a horizontal direction,
Wherein the first and second elbows are formed in the installation unit such that the first elbows and the second elbows are formed in the horizontal direction so that the first elbows and the second elbows move linearly in the horizontal direction,
Wherein the first and second elongated members are vertically installed and installed in the installation unit. 6. The method of claim 5,
And a control unit for controlling the mobile unit to adjust a speed at which the measurement unit moves;
Wherein the control unit controls the mobile unit so that the measurement unit moves at a different speed for each set interval. A mounting unit in which a plurality of LM guides are installed;
A plurality of application units for applying a load to each of the ELM guides;
A plurality of measurement units for measuring a load applied to each of the LM guides by the application units; And
And a mobile unit for moving the measurement units to move the EL blocks of each of the ELM guides,
The mounting unit includes a first frame to which a plurality of LM guides are coupled;
A second frame coupled to a lower side of the first frame; And
And a third frame spaced apart from the lower side of the second frame,
The moving unit includes a plurality of engaging mechanisms which are located between the second frame and the third frame and in which each of the measuring units is engaged, a connecting mechanism that connects the engaging mechanisms, and a moving mechanism that moves the connecting mechanism Wherein the test piece is a test piece. 10. The method of claim 9,
And a control unit for controlling the moving mechanism to adjust a speed at which the measuring units move;
Wherein the control unit controls the moving mechanism such that the measuring units move at different speeds for each set interval.

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