KR100855869B1 - Large scale oedometer - Google Patents

Abstract

The present invention relates to a large-scale Odometer tester for testing the compressibility and permeability of the sample by loading the load through hydraulic pressure to sand, gravel or crushed stone material and measuring the penetration of water, so that the mobile bogie 110 is movable. A loading frame 100 having a plurality of columns 140 installed vertically on a base 130 on which the rails 120 are installed, and having a crosshead 150 attached to an upper end of the columns 140; A sample cell 200 which is placed on the moving trolley 110 of the loading frame 100 and into which the sample 600 is placed; A hydraulic servo actuator (300) installed at the crosshead (150) and having a pressure plate (320) attached to a lower end of the piston shaft (310) to load the sample (600) filled in the sample cell (200); A hydraulic servo control unit 400 for controlling the strength of the hydraulic pressure supplied to the hydraulic servo actuator 300; And a load cell 500 installed between the piston shaft 310 and the pressure plate 320 of the hydraulic servo actuator 300 to measure the compressive load.

Large, Odometer, Test, Loading, Constant Stress, Constant Strain, Compressibility, Permeability

Description

Large scale oedometer tester {Large scale oedometer}

1 is a perspective view of a large-scale odometer tester according to the present invention,

2 is a front view of a large-scale odometer tester according to the present invention,

3 is a side view of a large-scale odometer tester according to the present invention,

4A is a plan view of a sample cell,

4b is a cross-sectional view of a sample cell,

5 is a cross-sectional view showing a test state of the tester according to the present invention.

* Explanation of symbols for main parts of the drawings

100: loading frame 110: moving bogie

120: rail 130: base

140: column 150: crosshead

200: sample cell 210: porous plate

212: drain 220: catchment space

230: drainage line 240: filter paper

300: hydraulic servo actuator 310: piston shaft

320: pressure plate 322: water inlet

324: flow meter 326: water supply pipe

328: valve 400: hydraulic servo control unit

500: load cell 600: sample

The present invention relates to a large-scale Odometer tester, and in detail, it is possible to test the ground material such as gravel or rock material having a large particle size, and to apply a load using a hydraulic servo control system, so that the constant speed and static load test It is possible to supply and drain water inside the sample cell into which the sample is injected, so that the compression characteristics according to the submersion of the ground material and the permeation characteristics for each load stage can be easily and accurately analyzed.

In general, the Oidometer tester measures the amount of settlement over time for undisturbed clay samples or sands with small particle diameters in each load step (up to 12.8kg / cm ² ), resulting in compression coefficient, volume change coefficient, expansion index, and prior consolidation. It is a device to derive load and permeability coefficient. The size of the existing general consolidation test device is mainly 6cm in diameter and 2cm in height, and mainly adopts a constant stress method, which is a loading method using weights. Recently, Rowe consolidation cells with larger dimensions (maximum diameter 25 cm, height 9 cm) have been used to measure the transverse consolidation characteristics of the samples, but most of them have only been tested on clay and silt samples.

The present invention has been made in order to solve the above problems, the object of the present invention is to test the ground material such as gravel and rock material with a large particle diameter, and the load at each load step of the constant speed and static load test According to the present invention, it is possible to automatically make it possible, and also to provide the large-scale Odometer tester which can analyze the compression and permeability characteristics according to the submersion of ground material.

In order to achieve the above object, the present invention includes a loading frame in which a plurality of columns are vertically installed on a base on which a rail is movable and a crosshead is attached to an upper end of the columns; A sample cell placed on a moving trolley of the loading frame and into which a sample is placed; A hydraulic servo actuator installed at the crosshead and having a pressure plate attached to a lower end of a piston shaft to load a sample; A hydraulic servo control unit for controlling the strength of the hydraulic pressure supplied to the hydraulic servo actuator; It is provided between the piston shaft and the pressure plate of the hydraulic servo actuator to provide a large-scale odometer tester comprising a; load cell for measuring the compression load.

More preferably, the pressure plate is provided with a water supply port for supplying water to the sample inside the sample cell, and the water supply port is connected to a water supply pipe with a flow meter, and the water drained through the sample is discharged under the sample cell. Drainage is provided to enable easy and accurate analysis of the compression characteristics of the submerged ground material.

It is known that the large Odometer tester of the present invention is a device for reproducing the consolidation (compression) characteristics of a large granulated material such as a dam building material. In general, the maximum aggregate size of the test material is known to be about 1/6 of the cell size. In the case of this tester, the maximum aggregate size that can be tested in a 60 cm diameter cell is about 10 cm, and in the case of a 1 m diameter cell, a maximum aggregate size of about 16 cm may be used. Also, in the case of clay and fine grain material, it is difficult to grasp the crushing phenomenon according to the load because the sample particles are small, but in this case, the maximum consolidation load of the conventional general apparatus (12.8kg / cm ² ) by reproducing the maximum load to 200ton. It can automatically reproduce the consolidated load of 25kg / cm ^{2, which} is twice as large as the step, and also adopt the strain method that can control the constant displacement, so that the extruded and crushed the fill material with high loads such as dams There is an advantage that you can grasp various characteristics. In addition, it is possible to measure the permeability coefficient in each load step by injecting a constant flow rate for each load step and measuring the flow rate and time outflow from the time when the inflow amount and the outflow amount are the same.

Hereinafter, with reference to the accompanying drawings, preferred embodiments that do not limit the present invention will be described in detail.

1 to 3 are a perspective view, a front view, and a side view showing a large-scale odometer tester according to the present invention, and FIG. 4 is a plan view of a sample cell.

As shown in FIGS. 1 to 4, the large-scale odometer tester of the present invention includes a plurality of columns 140 installed vertically on the base 130 on which the rails 120 are installed so that the moving cart 110 is movable. A loading frame 100 having a crosshead 150 attached to an upper end of the column 140; A sample cell 200 which is placed on the moving trolley 110 of the loading frame 100 and into which a sample (not shown) is introduced; A hydraulic servo actuator (300) installed at the crosshead (150) and having a pressure plate (320) attached to a lower end of the piston shaft (310) to load the sample filled in the sample cell (200); A hydraulic servo control unit 400 for controlling the strength of the hydraulic pressure supplied to the hydraulic servo actuator 300; The load cell 500 is installed between the piston shaft 310 and the pressure plate 320 of the hydraulic servo actuator 300 to measure the compression load.

The moving cart 110 is lowered to allow the guide roller 112 to travel on the rail 120 during the movement so as to prevent the load from being caught by the guide roller 112 during the test, and the guide roller 112 during the test. In order to be able to lift the pneumatic cylinders 114 are respectively installed on the upper portion of the guide roller 112.

In addition, the sample cell 200 has a hollow cylindrical shape, as can be seen in the plan view of FIG. 4A and the cross-sectional view of FIG. 4B, an upper portion of the sample cell 200 is opened, and a plurality of drain holes 212 are drilled in the lower portion thereof. The plate 210 is installed so that the drained water is discharged through the sample filled therein, and the collecting plate 220 is formed at the lower portion of the porous plate 210 to collect the drained water. In addition, the drainage line 230 is connected to the outside of the collecting space 220, so that the amount of water drained from the sample can be collected and measured separately.

The hydraulic servo actuator 300 is installed vertically on the crosshead 150 and the pressure plate 320 is attached to the lower end of the piston shaft 310 to load the sample filled in the sample cell 200, which is a hydraulic pressure. The hydraulic pressure supplied by the servo control unit 400 is controlled to enable constant speed and constant stress loading tests.

In the present invention, the pressure plate 320 is provided with a plurality of water inlets 322 for supplying water to the sample filled in the sample cell 200 with a constant density, and the water inlet 322 has a flow meter 324. Is connected to the water supply pipe 326 is to be able to accurately measure the water supply amount, the water supply pipe 326 is attached to the on-off valve 328.

The load cell 500 is installed on the upper portion of the pressure plate 320 attached to the lower end of the piston shaft 310 of the hydraulic servo actuator 300 to measure the pressure at the time of pressurization.

Figure 5 is a cross-sectional view showing a state of testing the characteristics of the sample using the tester of the present invention, when explaining the process of the compression test and permeability test of the sample using the tester of the present invention are as follows.

[Compression test process]

1. Put the porous plate 210 and the filter paper 240 in the bottom in the sample cell 200 in order to put the sample 600 thereon.

2. After loading the sample cell 200 containing the sample 600 on the mobile trolley 110 by using a crane (not shown), along the rail 120 of the base 130 to the Odometer tester of the present invention Move it. At this time, the position of the sample cell is adjusted so that the cross section of the sample 600 in the sample cell 200 and the center of the pressing plate 320 exactly match.

3. Start loading after setting the sample. The load is loaded so that the load load of the load cell 500 increases step by step. At this time, after the deformation of the sample is completed in one load step, the next step load is applied. If necessary, water infiltrates (or saturates) into the sample 600 in the sample cell 200 through the water inlet 322 formed on the pressure plate 320 before loading or at a predetermined loading stage. You can observe the effect on.

4. Record the amount of deformation of the material at each loading stage and determine the compressibility of the material from the load-strain relationship.

[Permeability Test Course]

1. Put the porous plate 210 and the filter paper 240 in the bottom in the sample cell 200 in order to put the sample 600, and then compacted as necessary to prepare a sample. After completing the sample, place the filter paper (not shown) on the upper part of the sample.

2. Penetrate water into the sample and measure the amount of drained water after a certain amount of time.

3. The rate of water passing through the sample can be measured from its relationship to the flow rate drained over time.

In the large-scale Odometer tester of the present invention, the maximum aggregate size that can be tested in a 60 cm diameter cell is about 10 cm, and in the case of a 1 m diameter cell, an aggregate having a maximum diameter of about 16 cm may be used.

Also, in the case of clay and fine grain material, it is difficult to grasp the crushing phenomenon of the particle due to the small sample particle, but in this case, the maximum consolidation load of the conventional general device (12.8kg / cm) by reproducing the maximum load to 200ton ² ) It can automatically reproduce the consolidated load of 25kg / cm ^{2, which} is twice that of ² ), and also adopt the strain method that can control the constant displacement. There is an advantage in that it is possible to variously understand the exit and shredding characteristics.

In addition, it is possible to measure the permeability coefficient in each load step by injecting a constant flow rate for each load step and measuring the flow rate and time outflow from the time when the inflow amount and the outflow amount are the same.

As described above, the present invention is capable of testing ground materials such as gravel and rock material having a large particle diameter, and can be loaded using a hydraulic servo control system, so that a constant speed and static load load test is possible, and a sample is injected. Since the water supply and drainage are possible inside the sample cell, it has a useful effect such as the simple and accurate analysis of the compressive characteristics and the permeability coefficient for each load stage.

Claims (3)

A loading frame in which a plurality of columns 140 are vertically installed on the base 130 on which the rails 120 are movable so that the moving cart 110 is movable, and a crosshead 150 is attached to an upper end of the columns 140. 100; It is placed on the moving trolley 110 of the loading frame 100 and made of a hollow cylindrical shape so that the sample 600 is inserted therein, the upper part of which is open and the plurality of drainage holes 212 are perforated perforated plate ( 210 is installed, the lower portion of the porous plate 210 is formed with a collecting space 220 for collecting the drained water, the sample cell to which the drain line 230 is connected to the outside of the collecting space 220 200; A hydraulic servo actuator (300) installed at the crosshead (150) and having a pressure plate (320) attached to a lower end of the piston shaft (310) to load the sample (600) filled in the sample cell (200); A hydraulic servo control unit 400 for controlling the strength of the hydraulic pressure supplied to the hydraulic servo actuator 300; A load cell 500 installed between the piston shaft 310 and the pressure plate 320 of the hydraulic servo actuator 300 to measure a compressive load; It is made, including, the pressure plate 320 is formed with a water supply port 322 distributed to a certain density in order to supply water to the sample inside the sample cell 200, the water supply port 322 is a flow meter 324 Large odometer tester, characterized in that the water supply pipe 326 is attached. delete delete

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