KR200466924Y1 - Resonant column test apparatus with positioning device for driving plate - Google Patents

Abstract

The present invention is to fix the specimen (S) in the inner bottom in a standing manner, to install a fixing plate 13 through the upper outer peripheral surface of the specimen (S) with a margin and to seal the inner space with the top plate 11 ( 10); A support plate 20 having a coil 41 which is supported on the fixing plate 13 so that height adjustment is possible and is supplied with electricity; A drive plate 30 fixed to the upper end of the specimen S and provided with a magnet 42 that electronically interacts with the coil 41 to transmit the torsional excitation force to the specimen S; In the resonant column tester comprising a; sensing means 50 for measuring the displacement of the drive plate 30, the guide rod which is supported by the fixed plate 13 to guide the vertical movement of the support plate 20 The support plate 20 is supported by a plate support means 200 including a compression spring 210 interposed between the fixing plate 13 and the support plate 20, and a chamber ( The rod 110 penetrating the upper plate 11 of the 10 to press the upper surface of the support plate 20, and the pressurizer 130 is installed on the upper surface of the upper plate 11 to elevate the rod 110 The level adjusting means 100 is included, and the height of the support plate 20 is adjusted by the lifting and lowering of the rod 110.

Description

RESONANT COLUMN TEST APPARATUS WITH POSITIONING DEVICE FOR DRIVING PLATE}

The present invention relates to a resonant column tester that can adjust the height of the support plate, and more particularly, even if the height change of the specimen occurs during the torsional shear test, it is possible to change the shrinkage of the specimen without dismantling and resetting. It is related with the resonant column tester which can adjust the height of the support plate which can be adjusted to the exact test environment conditions.

The resonant column tester is a non-destructive type tester that calculates the shear modulus, the Young's modulus, the shear damping ratio, or the damping ratio of the rod to soil samples. In order to adapt to the environment, the strain is measured by applying an ambient stress and applying a vibration excitation device or a vibration excitation using a longitudinal excitation device to the specimen, and based on the measured strain The shear modulus, Young's modulus, shear damping ratio, or rod damping ratio of the specimen were calculated.

Here, the torsional shear test in which the torsional vibration excitation is applied to the specimen is measured after measuring the torque and the torsional displacement caused by the resistance of the specimen when the specimen is subjected to the torsional excitation at various frequencies. Shear stress and shear strain are calculated by applying the specimen size (section area and length) to the data values, and the shear modulus and damping constant based on the correlation between the calculated shear stress and shear strain Is a test to obtain.

Conventional technologies for such a resonant column tester have been disclosed in Korea Patent Publication No. 10-2009-0011204, Korean Patent No. 10-0994424, and the like, and the resonator column tester manufactured and used based on these prior arts has an internal space. It is constructed as shown in FIG.

Referring to FIG. 1, the conventional resonant column tester includes a chamber 10, a support plate 20, a drive plate 30, an excitation means 40, a sensing means 50, a controller (not shown), and a characteristic calculation device ( 60). The chamber 10 fixes the specimen fixing end plates 14 and 15 to the upper and lower ends of the specimen S, respectively, and fixes the specimen fixing end plate 14 of the lower end to the inner bottom surface, and the inner space with the upper plate 11. It is possible to seal the, it is made in a state fixed to the upper end of the support 12 placed in the bottom surface of the annular fixing plate 13 wrapped around the upper end of the specimen (S) at a distance. The support plate 20 is fixed to the upper side of the fixing plate 13 so that the height can be adjusted, it is formed in the form of an annular shape penetrating through the upper end of the specimen (S). The drive plate 30 is fixed to the upper surface of the specimen fixed end plate 15 fixed to the upper end of the specimen (S). The excitation means 40 is fixed to the coil 41 which is installed on the support plate 20, and to extend to the outer peripheral surface of the drive plate 30 to electronically interact with the coil 41 specimen (S) It consists of a magnet 42 which transmits the excitation force to it. The sensing means 50 is a configuration for measuring the displacement and acceleration of the drive plate 30 fixed to the upper portion of the specimen (S) via the upper specimen fixed end plate 15, the vertical of the drive plate 30 The linear displacement measuring unit 51 (LVDT) for detecting the displacement, the proxy meter 52 for measuring the rotational displacement of the drive plate 30 and the accelerometer 53 for measuring the rotational acceleration of the drive plate 30 is included. The controller (not shown) controls the ambient pressure in the chamber 10 and the supply of electricity to the coil 41. The characteristic calculation device 60 calculates the shear modulus and the damping constant based on the data measured by the sensing means 50.

The conventional resonant column tester configured as described above is based on data measured by the sensing means 50 when the electric frequency and power supplied to the coil 41 in the state set as shown in FIG. 1 are changed. Calculate physical properties.

However, in the conventional resonant column tester, when the vertical displacement of the specimen (S) is generated by supplying electricity to the coil 41 and performing the torsional shear test, the ambient pressure applied to the inside of the chamber 10 for the accuracy of the measurement data. The operation of removing the cover 11 and disassembling the cover 11 and the cylindrical body 11 ′ and adjusting the height of the support plate 20 had to be performed and again set to the test preparation state of FIG. 1. In other words, when the torsional shear test is performed, the specimen S is contracted to change the vertical length, and accordingly, the height of the drive plate 30 is also changed, so that the relative position of the magnet 42 with respect to the coil 41 is also changed. Since the excitation force in the excitation means 40 cannot be transmitted to the drive plate 30 accurately, in order to ensure the accuracy of the measurement data, the coil 41 and the magnet 42 are in accordance with the data measured by the linear displacement measuring instrument 51. When the relative position of the was increased, the test was stopped and the height of the support plate 20 was adjusted to accurately match the relative positions of the coil 41 and the magnet 42.

Furthermore, in the conventional resonant column tester, when the support plate 20 to which the coil 41 is fixed to the fixing plate 13 is fastened, a plurality of long bolts 21 are fastened along the circumference, so that each bolt 21 is fixed. It was very cumbersome to adjust the height by matching them with each other, and nuts (not shown) may be fastened to the upper and lower surfaces of the plates 20 and 13 to which the bolts 21 are fastened for the firm fixing of the support plate 20. In the case, more cumbersome and accurate height adjustment was also difficult.

In addition, the torsional shear test is performed repeatedly by changing the frequency and power of the electricity supplied to the coil 41 to a variety of values, the height adjustment operation of the support plate 20 also has to be repeated, the time required for the torsional shear test Lengthened

KR 10-2009-0011204 A 2009.02.02. KR 10-0994424 B1 2010.11.16.

Therefore, the object of the present invention is that the relative position of the drive plate and the support plate can be adjusted in accordance with the change in the length of the specimen without dismantling and resetting even when the upper and lower lengths of the specimen are changed during the torsional shear test. It is to provide a resonant column tester that can adjust the height of the support plate.

In order to achieve the above object, the present invention, the specimen (S) is fixed to the inner bottom in a standing manner, and the fixing plate (13) is installed to the upper outer peripheral surface of the specimen (S) with a margin to the top plate (11) A chamber 10 which seals the internal space; A support plate 20 having a coil 41 which is supported on the fixing plate 13 so that height adjustment is possible and is supplied with electricity; A drive plate 30 fixed to the upper end of the specimen S and provided with a magnet 42 that electronically interacts with the coil 41 to transmit the torsional excitation force to the specimen S; In the resonant column tester comprising a; sensing means 50 for measuring the displacement of the drive plate 30, the guide rod which is supported by the fixed plate 13 to guide the vertical movement of the support plate 20 The support plate 20 is supported by a plate support means 200 including a compression spring 210 interposed between the fixing plate 13 and the support plate 20, and a chamber ( The rod 110 penetrating the upper plate 11 of the 10 to press the upper surface of the support plate 20, and the pressurizer 130 is installed on the upper surface of the upper plate 11 to elevate the rod 110 It is characterized in that it comprises a level adjusting means 100 including, to adjust the height of the support plate 20 by the lifting of the rod 110.

On the upper surface of the upper plate 11, it is characterized in that the elevating level measuring unit 140 for measuring the elevating change of the rod 110.

The rod 110 is provided in plural numbers to press the support plate 20 at multiple points, and fix the upper end protruding from the upper plate 11 to the plate-shaped lifting plate 120. It characterized in that the steel plate 120 is pressed.

The guide rod 220 passes through the fixing plate 13 and the support plate 20, and passes through the compression spring 210 at a portion passing between the fixing plate 13 and the support plate 20. It is characterized by.

The pressurizer 130 may include: a bolt 132 installed in the center of the upper plate 11 so as to pass through the center of the elevating plate 120; It is characterized in that it comprises a; rotating plate 131 is screwed to the upper end of the bolt 132 protruding to the upper portion of the elevating plate 120 to rotate.

The elevating level measuring unit 140 is an LVDT measuring a linear distance between a fixed point and a fixed point on the rod 110 protruding to the upper surface of the upper plate 11. differential transformer).

The present invention configured as described above is to elastically support the support plate 20 to the fixed plate 13 by using the compression spring 210 and to press the support plate 20 with the level adjusting means 100, In addition, since the level adjusting means 100 is operated externally, even if shrinkage of the specimen S during the torsional shear test, the height of the support plate 20 can be easily adjusted without manual dismantling and reassembly to perform the torsional shear test. You can resume. Accordingly, the present invention significantly shortens the time required for the torsional shear test, and accurately obtains the result obtained in the torsional shear test, and also damages the specimen and the resonant column tester, which was involved in the manual dismantling and reassembly. Can be significantly reduced.

In addition, the present invention is precisely adjusted according to the measured value of the lifting level meter 140 when adjusting the height of the support plate 20, it is possible to precisely adjust the height of the support plate 20 by the contraction length of the specimen (S). have. Accordingly, the present invention can further improve the reliability of the result obtained in the torsional shear test.

1 is a perspective view of a conventional resonant column tester.
Figure 2 is a perspective view of the inside of the resonator column tester that can adjust the height of the support plate according to an embodiment of the present invention.
Figure 3 is an enlarged perspective view of the upper side of the level adjusting means 100 in the embodiment of the present invention.
4 is an enlarged perspective view of the rod support 110 and the plate support means 200 of the level adjusting means 100 in the embodiment of the present invention.
Figure 5 is a perspective view showing the assembly process of the resonator column tester that can adjust the height of the support plate according to an embodiment of the present invention.
6 is a perspective view showing the installation process of the level adjusting means 100 in an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described to be easily carried out by those of ordinary skill in the art.

2 to 6 are views for explaining the resonator column tester that can adjust the height of the support plate according to an embodiment of the present invention, Figure 2 is a perspective view of the inside, Figure 3 is a level adjusting means 100 4 is a partially enlarged perspective view of an upper side of the upper side, and FIG. 4 is a partially enlarged perspective view of a lower portion of the rod 110 and a plate supporting means 200 of the level adjusting means 100, and FIG. 6 is a perspective view showing the installation process of the level adjusting means 100.

2 to 6, the resonator column tester that can adjust the height of the support plate according to an embodiment of the present invention, the specimen fixed end plate (top and bottom) in the same way as the conventional resonator column shown in FIG. 14 and 15, the chamber 10 is configured to accommodate the specimen (S) in a closed space, the support plate 20 is installed in the chamber 10, and the fixed to the upper end of the specimen (S) A drive plate 30 fixed to the specimen fixed end plate 15, an excitation means 40 for applying a torsional vibration excitation to the drive plate 30, and a displacement and acceleration of the drive plate 30 for measuring Sensing means 50 and a characteristic calculation device 60 for calculating the physical property value of the specimen based on the value measured by the sensing means (50).

The chamber 10, the support plate 20, the drive plate 30, the excitation means 40, the sensing means 50 and the characteristic calculation device 60 are generally known components and the background of the present invention Since described in the technology, it will be briefly described at a level that helps to understand the embodiments of the present invention.

The specimen S to be placed inside the chamber 10 is a cylindrical sample chopped soil collected from the ground into the cylindrical membrane, and thus it is difficult to directly fix the chamber 10 directly to the bottom surface of the chamber 10 and the drive plate 30. Fix the specimen fixing end plates 14 and 15 to the top and bottom, respectively.

The chamber 10, the specimen (S) to which the specimen fixed end plate (14, 15) is fixed to the bottom surface in a standing manner, the support plate 20, the drive plate 30, the excitation means 40 and the sensing After the means 50 is also installed inside, it is surrounded by a hollow cylindrical body (11 ') and covers the upper opening of the cylindrical body (11') with a top plate (11) to seal the structure of the specimen (S) Thereafter, after the plurality of struts 12 are placed in place, the support plate 20 is supported by fixing an annular fixing plate 13 to the struts 12 to surround the upper outer circumferential surface of the specimen S. Although not shown in the drawing, in order to create an environment corresponding to the actual ground in the specimen S, the specimen is prepared by pressurizing the internal space of the chamber 10 (for example, by increasing the internal pressure defined in the case of pneumatic). Means for applying ambient pressure to (S) are also provided.

The support plate 20 is formed of an annular frame surrounding the upper portion of the specimen (S) to be installed to be supported on the fixing plate 13, but to adjust the height upward based on the fixing plate (13) Supported. In the related art, as shown in FIG. 1, a bolt fastened to the support plate 20 and a fixing plate 13 is adjusted to adjust the height of the screw to the support plate 20.

The drive plate 30 is fixed to the upper surface of the specimen fixed end plate 15 fixed to the upper end of the specimen (S), is formed close to the disk shape and provided with a plurality of protrusions along the edge to extend later described Magnet 42 can be provided in each projection. Here, the height of the support plate 20 and the height of the drive plate 30 is matched for accurate electronic coupling between the coil 41 and the magnet 42 of the excitation means 40 to be described later.

The excitation means 40, the magnet 42 is fixed to the projection of the drive plate 30, and the coil 41 is installed on the upper surface of the support plate 20 in accordance with the position of the magnet 42 It is configured by. Accordingly, when electricity is supplied to the coil 41, a rotational excitation force may be applied to the drive plate 30 by the electromagnet interaction between the coil 41 and the magnet 42. S) is delivered.

The sensing means 50 is a component that measures the displacement of the drive plate 30 generated by applying the rotational excitation force by the excitation means 40, and detects the vertical displacement of the drive plate 30. The linear displacement measuring instrument 51 (LVDT) includes a proxy meter 52 measuring rotational displacement of the drive plate 30 and an accelerometer 53 measuring rotational acceleration of the drive plate 30.

The characteristic calculation device 60 is a device for obtaining a result of the torsional shear test. The sensing means 50 measures the amount of torque and torsional displacement generated in the specimen and applies the cross-sectional area and length of the specimen to shear stress. ) And shear strain are calculated, and the shear modulus and damping constant are calculated from the relationship between shear stress and shear strain.

However, the resonator column tester according to the present invention supports the support plate 20 on the fixed plate 13 in a manner different from that of the conventional resonator column tester, and in addition, the support plate 20 does not need to be disassembled. It is configured to adjust the height of the.

Resonant column tester according to the present invention for this purpose, the plate support means 200 for holding the support plate 20 to the fixed plate 13, and the level adjusting means provided to adjust the height of the support plate 20 from the outside 110.

The plate supporting means 200 includes a guide rod 220 vertically penetrating the support plate 20 and the fixing plate 13 arranged up and down; And a compression spring 210 interposed between the fixing plate 13 and the support plate 20. In order to prevent the compression spring 210 from being separated, the support plate is provided in the embodiment of the present invention. The compression spring 210 passes through the guide rod 220 passing between the 20 and the fixing plate 13.

Here, since the compression spring 210 has an elastic force to be extended again to the pressing in the longitudinal direction to restore to the original state, pressing the support plate 20 from the upper side to exert a force to push the support plate 20 upward again. do. The compression spring 210 is to use a high stiffness spring to minimize the elastic means, even if the pressing means (rod 110, which will be described later in the present invention) does not move and a weak vibration is applied in a fixed state desirable.

Referring to FIG. 5, in the embodiment of the present invention, the guide rod 220 is constituted by a bolt so that the bolt head is caught by the upper surface of the support plate 20 and protrudes downward from the fixing plate 13. Screw the nut 221. This is to prevent the support plate 20 from being bounced by the compression spring 210 when the support plate 20 is supported on the fixed plate 13 by using the plate support means 200. However, the method of preventing the support plate 20 from being bounced need not be limited to the form shown in FIG. 20) and the fixing plate 13 is firmly fixed to one end and the other end is penetrated through the other end, and the method of fastening the nut to the other end protruding through it is also possible. In other words, the guide rod 220 may be supported by the fixing plate 13 to guide the vertical movement of the support plate 20 by any method.

The level adjusting means 100 is a rod 110 that penetrates the upper plate 11 of the chamber 10 so as to protrude to the upper portion of the upper plate 11 and the lower end of the upper plate 11 to contact the upper surface of the support plate 20. ; A pressurizer 130 installed on an upper surface of the upper plate 11 to elevate the rod 110; And an elevating level measuring unit 140 installed on an upper surface of the upper plate 11 to measure an elevating height of the rod 110.

Hereinafter, the level composition means 100 will be described in detail with reference to FIGS. 2 to 6 to describe an embodiment of the present invention.

The rod 110 is made of a long rod that penetrates the upper plate 11 and forms a lower end in the form of a hemisphere to press the upper surface of the support plate 20 to the apex of the hemisphere, and is mounted in a plurality of annular support plates. It is mounted so as to be disposed at an equiangular position in a circle according to the position of (20) to evenly press the upper surface of the support plate 20 at multiple points. As such, the pressing of the support plate 20 at multiple points corresponding to the positions of the rods 110 is to prevent the support plate 20 from tilting when the rod 110 is pressed. The plurality of rods 110 protruding to the upper portion of the upper plate 11 are fixed to one lifting plate 120 formed in a plate shape, and the bushing 112 is formed when the rod 110 is penetrated through the upper plate 11. Even if the rod 110 is elevated by installing the chamber 10 maintains the sealed state inside.

The pressurizer 130 is configured to press the elevating plate 120, and adjusts the height of the support plate 20 by adjusting the pressing depth of the elevating plate 120. The pressurizer 130 for this purpose is installed in the form of fixing the bolt head to the center of the upper surface of the upper plate 11, the bolt 132 and penetrating the center of the elevating plate 120, and the elevating plate 120 It comprises a rotation disk 131 having a nut 133 is screwed to the upper end of the bolt 132 protruding upwards, the rotation disk 131 is raised or lowered in accordance with the rotation direction. Accordingly, the rotation disk 131 is to press the lifting plate 120 when rotating in the downward direction. If the rotation disk 131 is rotated in a rising direction, the rod 110 is raised by the elastic force of the compression spring 210, so that the contact state between the rotation disk 131 and the lifting plate 120 is maintained. do. The rotating disc 131 may be provided with a handle 134 as shown, and although not shown in the drawing, it is preferable to install a locking means for stopping the rotation of the rotating disc 131.

The lifting level measuring unit 140 is fixed to the end of the bracket 141 in a vertical direction after fixing the plate-shaped bracket 141 in the horizontal direction to any one of the plurality of rods 110 Installed, the linear distance between the bracket 141 fixed to the rod 110 and the upper surface of the upper plate 11 is measured. In the embodiment of the present invention, the cutting groove 142 is formed at the end of the bracket 141 to fit the lifting level measuring unit 140, the bolt 143 in the direction of narrowing the width of the cutting groove 142 By tightening, the lifting level measuring unit 140 is firmly fixed. The lifting level measuring unit 140 provided as described above makes it possible to know the lifting degree of the rod 110 when lifting the rod 110 using the pressurizer 130, and thus the lifting level measuring unit 140 is measured. It is possible to precisely adjust the lifting height of the rod 110 while viewing the value. In other words, when performing the torsional shear test on the actual specimen, the change in the length of the specimen is so small that it must be accurately matched while looking at the measured value of the lifting level measuring unit 140.

On the other hand, the lifting level measuring unit 140 does not need to be limited to the above-described manner, and as another example, may be installed on the lifting plate 120, but the rod 110 with the top plate 11 as a reference point If configured to detect the change in elevation of is satisfied. The lifting level measuring unit 140 may be configured as the linear variable differential transformer (LVDT) used for linear distance measurement.

The present invention having the level adjusting means 100 and the plate supporting means 200 as described above, the process of fixing the lower end of the specimen (S) to the bottom surface of the chamber 10, as shown in FIG. The support plate 20 and the drive plate 30 on which the excitation means 40 and the sensing means 50 are installed are installed, but the support plate 20 is supported on the fixed plate 13 by using the plate support means 200. And a process of fixing the drive plate 30 to the upper end of the specimen S, a process of fixing the cylindrical body 11 'of the chamber 10, and an upper plate 11 on which the level adjusting means 100 is installed. Through the process of closing the upper opening of the cylindrical body (11 ') is assembled as shown in FIG. Then, while supplying electricity to the coil 41 of the excitation means 40 in a state in which the pressure of the internal space of the chamber 10 is set to a predetermined pressure, it is measured while varying the frequency and power of the electricity to be supplied. Based on the measured value of the sensing means 50, the torsional shear test to obtain the physical properties of the specimen.

In addition, if the vertical length change of the specimen S measured by the linear displacement measuring device 51 of the sensing means 50 during the torsional shear test exceeds a preset threshold, the torsional shear test is paused and the level adjusting means is performed. The height of the rod 110 is adjusted according to the vertical length change amount of the specimen S by using the 100. At this time, the height of the rod 110 can be precisely adjusted by manipulating the level adjusting means 100 while checking the value measured by the elevating level measuring unit 140, so as to accommodate the change in length according to the shrinkage of the specimen S. By adjusting the height of the support plate 20, the relative position between the coil 41 and the magnet 42 of the excitation means 40 can be precisely adjusted, and after that, the torsion shear test can be restarted again.

As such, the resonant column tester according to the present invention adjusts the height of the support plate 20 without the disassembly and reassembly even when the specimen S is contracted during the torsional shear test. The relative position between the magnet 41 and the magnet 42 can be accurately and easily matched, thereby not only accurately obtaining the result obtained in the torsional shear test but also reducing the time required for the torsional shear test.

In the above described and illustrated to specific embodiments to illustrate the technical idea of the present invention, the present invention is not limited to the same configuration and operation as the specific embodiment as described above, as long as various modifications do not depart from the scope of the present invention. It can be carried out in. Therefore, such modifications should also be considered to be within the scope of the present invention, the scope of the present invention should be determined by the claims below.

S: specimen
10 chamber 11 upper plate 12 prop
13: fixing plate 14, 15: specimen fixing end plate
20: support plate 21: bolt 30: drive plate
40: excitation means 41: coil 42: magnet
50: sensing means 51: linear displacement measuring instrument 52: proxy meter
53: accelerometer 60: characteristic calculation device
100: level adjusting means 110: rod 112: bushing
120: lifting plate 130: pressurizer 131: rotating disk
132: bolt 133: female thread 134: handle
140: lifting level measuring instrument 141: bracket
200: plate support means 210: compression spring 220: guide rod
221 nut

Claims (6)

A chamber 10 which fixes the specimen S on the inner bottom in a standing manner, installs a fixing plate 13 penetrated to the upper outer circumferential surface of the specimen S, and seals the inner space with the upper plate 11; A support plate 20 having a coil 41 configured to be supported by a height and to be supplied with electricity at an upper side of the fixing plate 13; A drive plate 30 fixed to the upper end of the specimen S and provided with a magnet 42 that electronically interacts with the coil 41 to transmit the torsional excitation force to the specimen S; In the resonant column tester comprising a; sensing means 50 for measuring the displacement of the drive plate 30,
A guide rod 220 supported by the fixing plate 13 to guide the vertical movement of the support plate 20, and a compression spring 210 interposed between the fixing plate 13 and the support plate 20. Support the support plate 20 with a plate support means 200 comprising a,
The rod 110 penetrating the upper plate 11 of the chamber 10 to press the upper surface of the support plate 20, and the pressurizer 130 installed on the upper surface of the upper plate 11 to elevate the rod 110. And a level adjusting means (100) including a height of the support plate (20) to adjust the height of the support plate (20) by lifting the rod (110). The method of claim 1,
On the upper surface of the upper plate 11,
Resonance column tester that can adjust the height of the support plate, characterized in that the lifting level measuring unit 140 to measure the lifting change of the rod 110. 3. The method according to claim 1 or 2,
The rod 110 is provided in plurality, pressurizes the support plate 20 at multiple points, and fixes the upper end projecting to the upper plate 11 to the plate-shaped lifting plate 120,
Resonator column tester that can adjust the height of the support plate, characterized in that for pressing the lifting plate (120) with the pressurizer (130). The method of claim 3, wherein
The guide rod 220,
The height of the support plate, characterized in that penetrates through the compression spring 210 at a portion passing through the fixing plate 13 and the support plate 20, passing between the fixing plate 13 and the support plate 20. Resonant column tester can be adjusted. The method of claim 3, wherein
The pressurizer 130,
A bolt 132 installed in the center of the upper plate 11 to penetrate the center of the elevating plate 120; Revolving column tester capable of adjusting the height of the support plate, characterized in that it comprises a; rotating plate 131 is screwed to the upper end of the bolt 132 protruding to the upper portion of the elevating plate (120). The method of claim 3, wherein
The lifting level measuring unit 140,
The support plate, characterized in that the linear variable differential transformer (LVDT) for measuring the linear distance between the fixed point and the fixed point to the rod 110 protruding to the top surface of the top plate 11 Resonant column tester with adjustable height.

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