LU501584B1 - Vacuum negative pressure soft bottom consolidation analyzer and sealing structure - Google Patents

Abstract

The invention relates to the technical field of consolidation analyzer, in particular a vacuum negative pressure soft bottom consolidation analyzer, which includes a base, a body, a top cover, a pressure plate, a tracking rod, a gas tube, an air chamber in the middle of the tracking rod, and the air chamber is connected to a through-hole in the pressure plate, and a pressure head is provided at the top of the tracking rod, and the pressure head is connected to a percentage meter for measuring the settlement. The gas tube is connected to the inner cavity of the tracking rod through the pressure head, and the other end of the gas tube is connected to the negative pressure charging device. A vacuum negative pressure soft bottom consolidation analyzer consisting of a base, a body, a top cover , a pressure plate, a tracking rod and a gas tube, is installed. The lower and upper permeable stones are located in the internal cavity of the body, and there is a water drainage tank at the bottom of the body to drain the water from the sample in the body under negative pressure.

Description

Vacuum negative pressure soft bottom consolidation analyzer and SEH sealing structure

Technical part

The invention relates to the technical field of consolidation analyzers, particularly to a vacuum-negative pressure soft bottom consolidation analyzer and a sealing structure.

technology in the background

The compressive properties of soils are mainly studied in indoor tests using conventional consolidation equipment, mostly on transformed low moisture content soils or naturally deposited soft clay soils that are essentially shaped and have some strength and the first stage pressure of 12.5 kPa in conventional able to withstand consolidation attempts.

However, soft soils with high water content are generally in a liquid state, and testing with traditional consolidation equipment often results in sample extrusion, affecting the accuracy of the test.

At present, a lightweight consolidation test rig capable of operating from 0.5 kPa has been developed, a lightweight consolidation test method has been proposed for extending traditional consolidation testing, and some non-linear pressure test data for high water content dredging mud has been obtained to evaluate the consolidation properties

1 softer soil better understand. However, current light weight consolidation tests focus on the consolidation of dredging mud under heap load and do not address the compressive properties of dredging mud under negative pressure. The conventional vacuum negative pressure soft bottom consolidation analyzer uses a gasket to seal the tracking rod and measurement hole during the pumping process. If the seal is too tight, the frictional resistance between the tracking rod and the measuring hole will be high, and it will be difficult or even impossible to move in the measuring hole, resulting in a large error in the vertical deformation measurement, especially in the state of low vacuum negative pressure, the vertical deformation is difficult to determine. To this end, the invention proposes a vacuum negative pressure soft bottom consolidation analyzer and sealing structure to solve the above problems.

SUMMARY OF THE INVENTION The object of the invention is to provide a vacuum-negative pressure soft bottom consolidation analyzer and a sealing structure to solve the problems raised in the above-mentioned background technology.

In order to achieve the above purpose, the present invention provides the following technical solution: a vacuum negative pressure 2 soft bottom consolidation analyzer, the vacuum negative pressure soft bottom consolidation analyzer comprising: base.

Body, wherein the body is a cylindrical structure and has a closed lower end of the cylinder and the sample to be tested is placed in the body, the body having a seepage pressure drain at the lower side wall, the seepage pressure drain being provided with a valve structure.

A top cover, wherein the top cover is attached to the opening position of the body, and the top cover includes a combination of a cover body and a case.

Pressure plate, wherein the pressure plate is movably inserted into the internal cavity of the body, the pressure plate being provided with a through hole at the center.

Tracking rod, where the tracking rod has an air chamber in the middle, and the air chamber is connected to the through hole in the pressure plate, and the tracking rod has a pressure head at its upper end, the pressure head with a percentage meter for measurement associated with the setting.

Gas tube, where the gas tube is connected to the internal cavity of the tracking rod through the printhead, and the other end of the 3rd

Gas pipe is connected to a vacuum charging device.

Preferably, the lower permeable stone is provided at the lower end of the internal cavity of the body and the upper permeable stone is provided at the upper end of the internal cavity, and the sample to be sampled is placed between the lower permeable stone and the upper permeable stone, with the diameter of the lower permeable stone stone and the upper permeable stone matches the diameter of the inner chamber of the body.

Preferably, the bottom surface of the body is provided with a drainage channel, the water bypass tank is arranged at regular intervals on the bottom surface of the body, the plurality of water bypass tanks are connected to each other, and the openings of the water bypass tank correspond to the seepage drainage pipe.

An umbrella-shaped slot is preferably provided on the underside of the pressure plate at the edge of the through-hole.

Preferably, the top cover is integrally formed between the top cover body and the case, and a ball slot is provided in the inner cavity side wall of the case, the ball slot is provided uniformly in a plurality of groups in the inner cavity side wall of the case, and a ball is in embedded in each of the ball slots, with the ball 4 mounted against the outer side wall of the tracking rod. SEH The sealing structure is provided on the above vacuum-negative pressure soft bottom consolidation analyzer, wherein the sealing structure comprises a combination of an insulating sealing membrane and a positioning spring.

Preferably, the tracking rod has an upper fixed flange securely welded to the outer side wall and the tracking rod is provided with an upper movable flange, the housing has a lower fixed flange securely welded to the side wall , and the housing is movably provided with a lower movable flange.

Preferably, the insulating sealant membrane has a cylindrical shape with the upper end of the sealant being clamped by an upper fixed flange and an upper movable flange and the lower end of the sealant being clamped by a lower fixed flange and a lower movable flange.

Preferably, the positioning spring is provided in the inner cavity of the isolation-seal membrane, and the positioning spring is firmly bonded to the inner side wall of the isolation-seal membrane, and the isolation-seal membrane is in an erected state when the positioning spring is in a retracted state.

Compared to the prior art, the present invention SEH has the following advantageous effects: I. A vacuum negative pressure soft soil consolidation analyzer consisting of a base, a body, a top cover, a pressure plate, a tracking rod and a gas tube, is being installed. The lower and upper permeable stones are located in the internal cavity of the body, and there is a water drainage tank at the bottom of the body to drain the water from the sample in the body under negative pressure.

2. By uniformly opening a plurality of ball slots on the inner side wall of the upper case of the top cover and providing balls embedded in the ball slots, thereby increasing the stability of the tracking rod during up and down movement by the action of the balls.

3. By providing a sealing structure consisting of an insulating sealing membrane and a positioning spring, the gap between the tie rod and the housing is sealed by the sealing structure to prevent gas leakage at its connection position, ensuring the accuracy of the final test results.

Description of the accompanying drawings FIG. 1 is a schematic view of the structure of the present 6

Invention.

FIG. 2 is a half-sectional view of the present invention.

FIG. 3 shows a schematic representation of the position of the flange adjustment in accordance with the present invention.

FIG. 4 shows a half-section view of the tracking rod.

FIG. Figure 5 shows a half sectional view of the top cover of the present invention.

FIG. Figure 6 shows a bottom view of the body of the present invention.

FIG. 7 shows a schematic representation of the sealing structure of the present invention.

In the figure: base 1, body 2, top cover 3, pressure plate 4, tracking rod 5, pressure head 6, gas pipe 7, lower permeable stone 8, upper permeable stone 9, air chamber 10, umbrella-shaped slot 11, water diversion tank 12, upper cover body 14 , housing 15, ball 16, upper fixed flange 17, lower fixed flange 18, upper movable flange 19, lower movable flange 20, sealing structure 21, isolation sealing membrane 22, positioning spring 23. Particular embodiments The technical solutions in the embodiments of the invention are presented in the The embodiments of the invention are described in a clear and complete manner below in connection with the accompanying drawings, 7 it being understood that the embodiments described represent only a part SEH of the embodiments of the invention and not all. Starting from the embodiments of the present invention, all other embodiments achieved by a person skilled in the art without any creative work fall within the scope of the present invention.

Referring to Figures 1-7, the invention provides a technical solution: a vacuum negative pressure soft bottom consolidation analyzer, the vacuum negative pressure soft bottom consolidation analyzer comprising: base 1.

Body 2, the body 2 being a cylindrical structure and having a closed lower end of the cylinder and the sample to be tested is placed in the body 2, the body 2 having a seepage pressure drain 13 on the lower side wall, the seepage pressure drain 13 having a Valve structure is provided.

Top cover 3, wherein the top cover 3 is attached to the opening position of the body 2, and the top cover 3 comprises a combination of a cover body 14 and a case 15.

Pressure plate 4, the pressure plate 4 being movably inserted into the internal cavity of the body 2, the pressure plate 4 being provided with a through hole at the center.

8th

Tracking rod 5, wherein the tracking rod 5 has an air chamber 10 in the middle, and the air chamber 10 is connected to the through hole in the pressure plate 4, and the tracking rod has a print head 6 at its upper end, the print head 6 associated with a percentage meter for measuring settlement.

Gas tube 7, where the gas tube 7 is connected to the inner cavity of the tracking rod 5 through the pressure head 6, and the other end of the gas tube 7 is connected to a vacuum charging device.

The lower permeable stone 8 is provided at the lower end of the internal cavity of the body 2 and the upper permeable stone 9 is provided at the upper end of the internal cavity, and the sample to be tested is set to the lower permeable stone 8 and the upper permeable stone 9, and the diameter of the lower permeable stone 8 and the upper permeable stone 9 coincides with the diameter of the internal cavity of the body.

The bottom surface of the body 2 is provided with a bypass water tank 12, the bypass water tank 12 is arranged at an equal pitch on the bottom surface of the body 2, and the plurality of bypass water tanks 12 are connected to each other, and the openings of the bypass water tank 12 correspond to the seepage drainage pipe 13 .The seepage drainage pipe 13 is used to monitor the 9th

pore water pressure and to connect the infiltration device by constructing SEH a vacuum negative pressure soft soil consolidation analyzer consisting of the base 1, the body 2, the top cover 3, the pressure plate 4, the tracking rod 5 and the gas tube 7. And by providing a lower permeable stone 8 and an upper permeable stone 9 in the internal cavity of the body 2 and a water drainage slit 12 in the bottom surface of the body 2 to drain the water body from the sample in the body 2 under the action of a lower vacuum pressure.

An umbrella-shaped slit 11 is provided on the lower surface of the pressure plate 4 at the edge of the through hole.

The top cover 3 is integrally formed between the cover body 14 and the case 15, and the inner cavity side wall of the case 15 is opened with ball grooves, the ball grooves being equally provided in a plurality of groups in the inner cavity side wall of the case 15 and the ball grooves are embedded with a ball 16, the ball 16 is provided against the outer side wall of the tracking rod 16 into the ball slots, the stability of the tracking rod 5 during up and down movement is improved by the action of the ball 16.

A sealing structure is provided on the vacuum-negative pressure soft SEH soil consolidation analyzer, the sealing structure 21 comprising a combination of an insulating sealing membrane 22 and a positioning spring 23 .

The outer side wall of the tracking rod 5 is welded with an upper fixed flange 17, which is fixedly welded to the outer side wall, and the tracking rod 5 is provided with an upper movable flange 19, the side wall of the housing 15 is fixed with a lower fixed flange 18 is welded, and the housing 15 is movably provided with a lower movable flange 20.

The insulation sealing membrane 22 is in the shape of a cylinder, the upper end of which is fixedly clamped by means of an upper fixed flange 17 and an upper movable flange 19, and the lower end of which is fixedly clamped by means of a lower fixed flange 18 and a lower movable flange 20. By providing a Sealing structure 21 composed of the isolation sealing membrane 22 and the positioning spring 23, the gap between the tracking rod 5 and the housing 15 is sealed by the sealing structure 21, so that gas leakage at the connection position of the two is avoided, thereby improving the accuracy of the final detection results is guaranteed.

The positioning spring 23 is provided in the inner cavity of the isolation 11 sealing membrane 22, and the positioning spring 23 is firmly SEH bonded to the inner side wall of the sealing membrane 22, and the isolation sealing membrane 22 is in an erected state when the positioning spring 23 is in the restoring state .

Working Principle: By constructing a vacuum negative pressure soft soil consolidation analyzer consisting of base 1, body 2, top cover 3, pressure plate 4, tracking rod 5 and 7, and by constructing a lower permeable stone 8 and an upper permeable stone 9 in the inner cavity of the body 2, and by opening a water drainage container 12 on the bottom surface of the body 2, the water in the sample in the body 2 is drained under the action of the negative vacuum pressure. The inner wall of the housing 15 of the top cover 3 is equally divided into ball slots, and the ball 16 is embedded in the ball slots to improve the stability of the tie rod 5 during up and down movement by the action of the ball 16. The sealing structure 21, which consists of the insulating sealing membrane 22 and the positioning spring 23, serves to seal the gap between the tracking rod 5 and the housing 15 to prevent gas leakage at the junction of the two, thus improving the accuracy of the final detection - to ensure results. In practice, the worker inserts the sample 12 into the body 2 between the lower permeable stone 8 and the upper permeable SEH stone 9, and then fixes the insulation sealing membrane 22 by attaching the upper cover 3 and passing it through the upper fixed flange 17, the upper movable flange 19, the lower fixed flange 18 and the lower movable flange 20 before driving the soft soil consolidation analysis apparatus.

While embodiments of the invention have been shown and described, it will be understood by those skilled in the art that numerous variations, modifications, substitutions and variations of these embodiments can be made without departing from the principles and spirit of the invention, the scope of which is determined by the appended claims and their equivalents is limited.

13

Claims (9)

NLU501584 CLAIMS I. Fin vacuum negative pressure soft bottom consolidation analyzer, characterized in that the vacuum negative pressure soft bottom consolidation analyzer comprises: Basıs (1). Body (2), wherein the body (2) is a cylindrical structure and has a closed lower end of the cylinder and the sample to be tested is placed in the body (2), the body (2) having a seepage pressure drain (13) at the lower side wall, wherein the seepage pressure drain (13) is provided with a valve structure. A top cover (3), wherein the top cover (3) is attached to the opening position of the body (2), and the top cover (3) comprises a combination of a cover body (14) and a case (15). Pressure plate (4), wherein the pressure plate (4) is movably inserted into the internal cavity of the body (2), the pressure plate (4) being provided with a through hole at the center. Tracking rod (5), wherein the tracking rod (5) has an air chamber (10) in the middle, and the air chamber (10) is connected to the through hole in the pressure plate (4), and the tracking rod at its upper end has a print head (6), the print head (6) having a percentage meter for measuring the 14th setting is connected. Gas tube (7), wherein the gas tube (7) is connected to the internal cavity of the tracking rod (5) through the pressure head (6), and the other end of the gas tube (7) is connected to a vacuum charging device. 2. A vacuum negative pressure soft soil consolidation analyzer according to claim 1, characterized in that: the lower permeable stone (8) is provided at the lower end of the internal cavity of the body (2) and the upper permeable stone (9) is provided at the upper end of the inner cavity is provided, and the sample to be tested is provided between the lower permeable stone (8) and the upper permeable stone (9), and the diameter of the lower permeable stone (8) and the upper permeable stone (9) with the diameter of the internal cavity of the body (2). 3. A vacuum negative pressure soft bottom consolidation analyzer according to claim 1, characterized in that the bottom surface of the body (2) is provided with a water bypass tank (12), the water bypass tank (12) is spaced evenly on the bottom surface of the body (2) is arranged, and the plurality of water bypass tanks (12) are connected to each other, and the openings of the water bypass tank (12) correspond to the seepage drainage pipe (13). 4. A vacuum negative pressure soft bottom consolidation analyzer according to claim 1, characterized in that an umbrella-shaped slit (11) is provided on the lower surface of the pressure plate (4) at the edge of the through hole. 5. A vacuum negative pressure soft bottom consolidation analyzer according to claim 1, characterized in that the top cover (3) is integrally formed between the top cover body (14) and the case (15) and the inner cavity side wall of the case (15) with Ball grooves are opened, the ball grooves are uniformly provided in a plurality of groups in the inner cavity side wall of the housing (15), and the ball grooves are embedded with a ball (16), the ball (16) being on the outer side wall of the tracking -Bar (5) attached. A sealing structure, characterized in that the sealing structure is provided on the vacuum-negative-pressure soft-bottom consolidation analyzer according to any one of the preceding claims 1 to 10, wherein the sealing structure (21) is a combination of an insulating sealing membrane (22) and a positioning spring (23 ) includes. A sealing structure according to claim 6, characterized in that the tracking rod (5) has an upper fixed flange (17) fixedly welded to the outer side wall and the tracking rod (5) 16 has an upper movable flange flange (19), the housing (15) ie has a lower fixed flange (18) firmly welded to the side wall, and the housing (15) is movably provided with a lower movable flange (20). 8. Sealing structure according to claim 7, characterized in that the isolation sealing membrane (22) has the shape of a cylinder, the upper end of which is fixedly clamped by means of an upper fixed flange (17) and an upper movable flange (19) and the lower end of which is fixed by means of a lower Fixed flange (18) and a lower movable flange (20) is firmly clamped. 9. A sealing structure according to claim 8, characterized in that the positioning spring (23) is provided in the inner cavity of the insulation sealing membrane (22), and the positioning spring (23) is firmly bonded to the inner side wall of the insulation sealing membrane (22), and the isolation seal membrane (22) is in an erected state when the positioning spring (23) is in a restoring state. 17