KR20040045136A - Triaxial compressive tester - Google Patents

Abstract

PURPOSE: A triaxial compressive tester is provided to significantly improve reliability of a triaxial compressive test by completely and easily discharging air from a pressure chamber. CONSTITUTION: A triaxial compressive tester includes a base(10) having a sample table(12) for loading a construction member(1) thereon. A casing(20) is vertically installed on an upper portion of the base(10) in order to form a pressure chamber(22) on the base(10). First and second passages(14a,14b) are formed at both sides of a bottom of the base(10), respectively, in such a manner that the first and second passages(14a,14b) are communicated with the pressure chamber(22) of the casing(20). A third passage(14c) is formed at the center of the sample table(12). A packing(16) is interposed between the base(10) and the casing(20).

Description

Triaxial Compression Tester {TRIAXIAL COMPRESSIVE TESTER}

The present invention relates to a triaxial compression tester, and more particularly to a triaxial compression tester that can improve the reliability of the triaxial compression test by completely exhausting the air in the pressure chamber.

As is well known, the triaxial compressive test is a test for determining the shear strength of the soil, so that the stress and drainage conditions can be arbitrarily adjusted to reproduce the restraint pressure or consolidation pressure of the ground. Highly reliable test results can be obtained. Triaxial compression test can be divided into non-consolidation ratio drainage test, consolidation ratio drainage test and consolidation drainage test according to the consolidation method and drainage method.

In the triaxial compression tester for the triaxial compression test, the specimen of soil sample is wrapped in a rubber membrane and placed in a pressure chamber and then restrained by hydraulic pressure. The shear strength of the soil is obtained by shearing the soil sample. Pore water, also called pore water, is drained to measure volume change and pore water pressure due to reloading. In addition, the soil sample may be tested in a fully saturated state by applying back pressure.

On the other hand, it is important to completely discharge the air present in the pressure chamber in order to increase the reliability of the triaxial compression test. However, in the conventional triaxial compression tester, since the liquid film is formed while the lower surface of the cap is in contact with the liquid level of the pressure chamber, air is not smoothly discharged from the pressure chamber and bubbles remain in the pressure chamber. Bubbles remaining in the pressure chamber involve stress conditions and reduce the reliability of triaxial compression tests.

The present invention has been made in order to solve the various problems of the prior art as described above, the object of the present invention is a triaxial compression test by smoothly and completely discharge the air from the pressure chamber by a simple structure to prevent the remaining of bubbles To provide a triaxial compression tester that can greatly improve the reliability of the.

A feature of the present invention for achieving the above object, the base having a sample stand to put the specimen of the soil sample; An upright cylindrical casing installed to form a pressure chamber on an upper portion of the base; An encapsulation means placed in the pressure chamber of the casing and having a cylindrical rubber membrane for accommodating the specimen on the sample stage of the base and an upper perforated plate and a lower perforated plate disposed above and below the specimen; It is equipped to open and close the pressure chamber of the casing, has a discharge hole formed to discharge water and air from the pressure chamber of the casing, and has an annular fluid passage communicating with the discharge hole in the lower surface to induce the discharge of air A formed cap; A water supply device for supplying water to the pressure chamber of the casing to generate water pressure; A triaxial compression tester comprising a loading device having a ram for loading a specimen enclosed in a sealing means.

1 is a cross-sectional view showing the configuration of a triaxial compression tester according to the present invention,

Figure 2 is a cross-sectional view showing the configuration of the cap in the triaxial compression tester according to the present invention,

3 is a bottom view of FIG. 2.

♣ Explanation of symbols for the main parts of the drawing ♣

1: Test specimen of soil sample 10: Base

12: sample stand 20: casing

22: pressure chamber 30: sealing means

32: rubber film 34: upper perforated plate

36: lower perforated plate 38a, 38b: thread

40: cap 42: discharge hole

44: fluid passage 50: water supply device

56: pump 60: loading device

62: ram 70: first air pore pressure gauge

80: second air pore pressure measuring instrument 90: volume change measuring instrument

Hereinafter, a preferred embodiment of a triaxial compression tester according to the present invention will be described in detail with reference to the accompanying drawings.

First, referring to FIG. 1, the triaxial compression tester of the present invention has a base 10 having a columnar sample stage 12 on which a specimen 1 of an earth sample can be placed, and a pressure on the base 10. The upstanding cylindrical casing 20 provided so that the seal | sticker 22 may be provided is provided. The specimen 1 is produced with a diameter of 35 mm, 50 mm, 100 mm, or the like, with a diameter of 2 to 2.5 times the height, and generally 35 mm in diameter.

The first passage 14a and the second passage 14b are respectively formed at both bottoms of the base 10 so as to communicate with the pressure chamber 22 of the casing 20, and in the center of the sample table 12, a third passage 3 is formed. The passage 14c is formed. The packing 16 which keeps airtightness is interposed between the base 10 and the casing 20. In the present embodiment, the lower end of the casing 20 may be welded to maintain the airtightness on the upper surface of the base 10.

In addition, the triaxial compression tester of the present invention includes a sealing means 30 for enclosing the specimen (1) and placed in the pressure chamber 22 of the casing (20). The encapsulation means 30 includes a cylindrical rubber membrane 32 accommodating the specimen 1, an upper perforated plate 34 and a lower perforated plate disposed above and below the specimen 1 accommodated in the rubber membrane 32. It consists of 36. The lower portion of the rubber membrane 32 is coupled to the sample stage 12 of the base 10, and a plurality of seals 38a for maintaining airtightness are mounted between the sample stage 12 and the rubber membrane 32. It is.

1 to 3, a threaded cap 40 is mounted on the casing 20 to open and close the pressure chamber 22, and one side of the casing 20 is provided with a casing 20. A discharge hole 42 is formed to discharge the fluid, that is, water and air from the pressure chamber 22. An annular fluid passage 44 is formed in the lower surface of the cap 40 so as to communicate with the discharge hole 42 to induce the discharge of air.

As shown in detail in FIG. 2, the fluid passage 44 of the cap 40 is formed as a groove in which the radially inward first inclined surface 44a and the radially outward second inclined surface 44b are triangular in shape. The discharge hole 42 communicates with the apex of the triangular groove. The discharge hole 42 is formed at the highest point H ₁ of the fluid passage 44, and the fluid passage 44 located at the opposite side of the discharge hole 42 is formed at the lowest point H ₂ . The highest point H ₁ and the lowest point H ₂ of the fluid passage 44 are connected obliquely. The inclination angle θ ₁ of the second inclined surface is formed larger than the inclination angle θ ₂ of the first inclined surface 44a with respect to the central axis S of the discharge hole 42. Therefore, the air in the pressure chamber 22 is smoothly guided and discharged to the discharge hole 42 along the first and second second inclined surfaces 44a and 44b of the fluid passage 44. The discharge pipe 46 communicating with the discharge hole 42 of the cap 40 is equipped with a valve 46a for controlling the flow of the fluid, and a through hole 48 is formed in the center of the cap 40. .

Referring again to FIG. 1, a water supply pipe 52 of a water supply device 50 for supplying water to the pressure chamber 22 of the casing 20 to generate water pressure is provided in the first passage 14a of the base 10. The water supply pipe 52 is equipped with the valve 54 which controls the flow of water. The pump 56 for pumping water from the water source is connected to the water supply pipe 52 of the water supply device 50.

Triaxial compression tester of the present invention is provided with a loading device 60 for applying a load to the specimen (1) enclosed in the sealing means (30). The loading device 60 includes a ram 62 coupled to an upper portion of the rubber membrane 32 so as to press the specimen 1 through the upper perforated plate 34 of the sealing means 30, and a cap ( It consists of the loading rod 64 connected to the ram 62 via the through-hole 48 of 40. As shown in FIG. A passage 62a is formed in the ram 62 of the loading device 60, and a plurality of seals 38b for maintaining airtightness are mounted between the outer surface of the ram 62 and the rubber film 32. The guide bush 66 for guiding the loading rod 64 is attached to the through hole 48 of the cap 40. The loading rod 64 of the loading device 60 is connected to a pneumatic actuator or a hydraulic actuator which is well known as an operation means, and the loading of the loading rod 64 can be measured by a well-known load cell.

On the other hand, the third passage 14c of the sample stage 12 is connected to the pore drain pipe 72 of the first pore water pressure gauge 70 for measuring the pore water pressure generated in the specimen 1, and the pore drain pipe 72 ) Is equipped with a valve 74 for controlling the flow of void water. The second passage 14b of the base 10 is connected to a pore drain pipe 82 of a second pore water pressure gauge 80 for measuring the pore water pressure generated in the specimen 1, and the pore water drain pipe 82 is connected to the pore water drain pipe 82. The valve 84 which controls the flow of this is mounted. The second passage 14b of the base 10 and the passage 62a of the ram 62 are connected by a hose 86 having flexibility to communicate the pore drain pipe 82 of the second pore pressure gauge 80. have. In addition, the water supply pipe 52 of the water supply device 50 is connected to the water discharge pipe 92 of the volume change measuring instrument 90 which can measure the amount of water discharge when the water is loaded in the drained state.

The following describes the operation of the triaxial compression tester according to the present invention having such a configuration.

Referring to FIG. 1, in order to place the specimen 1 of the soil sample in the pressure chamber 22 of the casing 20, first, the specimen 1 is accommodated in the rubber membrane 32 of the sealing means 30. The upper and lower perforated plates 34 and 36 are disposed above and below the specimen 1. The lower portion of the rubber membrane 32 is coupled to the sample stage 12 so that the lower porous plate 36 is placed on the sample stage 12 of the base 10, and the loading device 60 is placed on the upper portion of the rubber membrane 32. Of the ram 62. Between the sample stage 12, the rubber membrane 32, the rubber membrane 32, and the ram 62 of the base 10, the airtightness is maintained by seals 38a and 38b, respectively. The cap 40 is coupled to close the pressure chamber 22.

Next, the valve 46a of the discharge pipe 46 and the valve 54 of the water supply device 50 are opened, and water is pumped by driving the pump 56 to supply water to the pressure chamber 22 of the casing 20. On the other hand, the air floating by the water filled in the pressure chamber 22 is discharged through the discharge hole 42 of the cap 40 and at the same time generates water pressure. When the water fills the pressure chamber 22 and the liquid level reaches the lower surface of the cap 40, the buoyant air is led to the low pressure fluid passage 44, and flows along the fluid passage 44 to discharge holes. Discharge through 42. Therefore, the air can be completely discharged from the pressure chamber 22 of the casing 20, and in particular, the residual of bubbles can be effectively eliminated. As a result, the change of the stress condition by the bubble remaining in the pressure chamber 22 can be prevented, and the reliability of a triaxial compression test can be improved significantly.

On the other hand, in the state in which the pressure of the pressure chamber 22, ie, the water pressure is kept constant, the specimen 1 is gradually pressurized by the ram 62 of the loading device 60 to compress and destroy it. At this time, in order to dissipate excess pore water pressure in the pressure chamber 22, a drainage test performed in a drainage state and a nondrainage test performed in a state of preventing drainage may be performed. In the non-consolidation ratio drainage test, the specimen (1) is accommodated in the rubber film (32), and then the specimen is applied in the undrained state without consolidation and loaded in the axial direction to destroy the specimen. In the consolidation ratio drainage test, the specimen 1 is consolidated and then destroyed in the undrained state. In the consolidation drainage test, the specimen (1) is consolidated and then axially loaded in the drained state to destroy the specimen. Through this triaxial compression test, the shear strength of the soil sample can be obtained, the pore water pressure can be measured by the first and second pore water pressure measuring instruments 70 and 80, and the specimen by the volume change measuring instrument 90. The volume change of (1) can be measured.

The embodiments described above are merely to describe preferred embodiments of the present invention, the scope of the present invention is not limited to the described embodiments, those skilled in the art within the spirit and claims of the present invention It will be understood that various changes, modifications, or substitutions may be made thereto, and such embodiments are to be understood as being within the scope of the present invention.

As described above, the triaxial compression tester according to the present invention smoothly and completely discharges air from the pressure chamber by a simple structure that can smoothly maintain the flow of air discharged through the discharge hole of the cap. By preventing the residue, the reliability of the triaxial compression test can be greatly improved.

Claims (5)

A base having a sample stand on which soil specimens can be placed; An upright cylindrical casing installed to form a pressure chamber on an upper portion of the base; An encapsulation means placed in the pressure chamber of the casing and having a cylindrical rubber membrane accommodating the specimen on the sample stage of the base and upper and lower plates disposed above and below the specimen; It is mounted to open and close the pressure chamber of the casing, and has a discharge hole formed to discharge water and air from the pressure chamber of the casing, the lower surface is in communication with the discharge hole to induce the discharge of air A cap having a fluid passage formed therein; A water supply device for supplying water to the pressure chamber of the casing to generate water pressure; A triaxial compression tester comprising a loading device having a ram for applying a load to the specimen enclosed in the sealing means. The triaxial compression tester according to claim 1, wherein the fluid passage of the cap is formed with a triangular groove having a first inclined surface in the radial direction and a second inclined surface in the radial direction. The triaxial compression tester according to claim 2, wherein the inclination angle of the second inclined surface is greater than the inclination angle of the first inclined surface with respect to the fluid passage of the cap with respect to the central axis of the discharge hole. The triaxial compression tester according to claim 2 or 3, wherein the discharge hole of the cap is formed at the height of the highest point of the fluid passage. The method of claim 1, wherein the sample stage of the base is connected to a first pore pressure measuring device for measuring the pore water pressure generated in the specimen, the ram of the loading device is a second air gap for measuring the pore water pressure generated in the specimen Triaxial compression tester connected to the hydraulic pressure meter.