KR102107131B1 - Calibration chamber test apparatus having stiffness controlling structure for trenchless emergency restoration of ground cavity - Google Patents

Abstract

Disclosed is an emergency recovery type stiffness control tojo test apparatus for submerged soil sink The ground sink emergency recovery type rigidity control tojo test apparatus of the present invention includes: a frame forming an accommodation space therein; A compartment module provided in the accommodation space and forming a compartment space open upward; And a plurality of elastic members interposed between the frame and the partition module in the accommodation space, the backfill soil and the expansion material are accommodated in the partition space, and the elastic member is elastic in the opposite direction to the load of the backfill soil and the expansion force of the expansion material Characterized by forming a resilience. According to the present invention, it is possible to provide an emergency recovery type stiffness control tojo experiment apparatus for submerged soil that is made to simulate the contraction of the surrounding ground by the stiffness and compaction effect of the surrounding ground.

Description

Emergency recovery type stiffness control tojo testing device for soil sinking {CALIBRATION CHAMBER TEST APPARATUS HAVING STIFFNESS CONTROLLING STRUCTURE FOR TRENCHLESS EMERGENCY RESTORATION OF GROUND CAVITY}

The present invention relates to an emergency recovery type stiffness-controlled earthenware experiment apparatus for ground depression, and more particularly, to a ground depression emergency recovery type stiffness-controlled saturation experiment device configured to simulate the stiffness of the surrounding ground and the contraction of the surrounding ground by compaction effect. It is about.

In recent years, underground sinks have occurred due to the aging of water and sewage pipes in urban areas where many underground facilities have been built, mainly in Seoul. Currently, in Korea, to solve this situation, various construction methods are being developed for emergency construction of submerged ground. However, there is a lack of clear data on the standards and performance of these methods, and supplementation is required.

In this regard, the Republic of Korea Patent Publication No. 2012-0114706 for the loading test is disclosed.

Published Patent Publication No. 2012-0114706 is a table standing on the ground, a body placed on the table and capable of containing soil and piles therein, a cradle detachably coupled to an open upper portion of the body, coupled to one side of the cradle There is a horizontal load-loading device that can apply a horizontal load to the pile according to the direction toward the center of the main body, coupled to the other side of the cradle, and an instrument that can measure the horizontal behavior characteristics of the pile according to the direction toward the center of the main body. And it characterized in that it comprises a vertical load-loading device that can be applied to the vertical load on the top of the pile.

However, Publication No. 2012-0114706 has a problem in that the volume of the main body is fixed, so that the surrounding ground surrounding the backfill is firmly set. That is, since the ground is not a rigid body, the ground around the cavity filled with the backfill and the expansion material absorbs the expansion pressure of the expansion material to some extent by the compaction effect, and the stiffness of the surrounding ground increases somewhat. In order to obtain reliable data of the expansion material, it is necessary to develop a test apparatus capable of simulating the shrinkage of the surrounding ground by the stiffness and compaction effect of the surrounding ground.

Republic of Korea Patent Publication No. 2012-0114706 (Publication date: October 17, 2012)

An object of the present invention is to provide a ground depression emergency recovery type stiffness control tojo test apparatus configured to simulate the contraction of the surrounding ground by the stiffness and compaction effect of the surrounding ground.

The object is, according to the present invention, a frame forming an accommodation space therein; A compartment module provided in the accommodation space and forming a compartment space open upward; And a plurality of elastic members interposed between the frame and the partition module in the accommodation space, wherein the backfill soil and the expansion material are accommodated in the partition space, and the elastic member loads the backfill and the expansion material. It is achieved by an emergency recovery type stiffness control tojo experimental device for submerged ground, characterized in that it forms an elastic recovery force in the opposite direction to the expansion force.

The partition module includes a lower isolation plate forming a bottom surface of the partition space, and a plurality of side isolation plates forming side surfaces of the partition space on the lower isolation plate, and the plurality of elastic members include the lower portion. It may include a lower elastic body to form an elastic recovery force for pushing the separator upward, and a plurality of side elastic bodies for forming an elastic recovery force for pushing the side isolation plates to each side.

The frame includes a lower panel on which the lower elastic body is mounted, and a plurality of side panels on which the side elastic bodies are respectively mounted. A plurality of rails longitudinally formed on the lower panel are formed. It may be made to be slidably mounted on the rail to move in the vertical direction together with the side isolation plate.

The backfill soil and the expanded material may be contained in a flexible sheet so that direct contact with the compartment module is blocked.

It includes a cover for covering the upper end of the partition space, the frame, may be made to be coupled to a blocking unit for blocking the upward movement of the cover.

According to the invention, the elastic member is formed by forming the elastic recovery force in the opposite direction to the loading force of the backfill and the expansion force of the expansion material, so as to simulate the shrinkage of the surrounding ground by the compaction effect and the stiffness of the surrounding ground. It will be possible to provide a controlled earthenware experimental apparatus.

1 is a front view of an emergency recovery type stiffness control tojo testing device for submerged ground according to an embodiment of the present invention.
2 and 3 is a cross-sectional view showing the state of use of the ground sink emergency recovery type rigidity control tojo test apparatus of FIG.
4 is a plan view of the ground sink emergency recovery type rigidity control tojo test apparatus of FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in describing the present invention, descriptions of already known functions or configurations will be omitted to clarify the gist of the present invention.

The ground sink emergency recovery type stiffness control tojo test apparatus of the present invention is made to simulate the contraction of the surrounding ground by the stiffness and compaction effect of the surrounding ground.

1 is a front view of the ground sink emergency recovery type stiffness control tojo test apparatus according to an embodiment of the present invention, and FIGS. 2 and 3 are cross-sectional views showing a state of use of the ground sink emergency recovery type stiffness control tojo test apparatus to be.

4 is a plan view of the ground sink emergency recovery type stiffness control tojo test apparatus of FIG. 4, the frame 100, the partition module 200, and the cover 400 are not shown components such as the elastic member 300 and the wheel W so that they can be easily observed.

As shown in Figures 1 to 4, the ground sink emergency recovery type rigidity control tojo test apparatus 10 according to an embodiment of the present invention, to simulate the contraction of the surrounding ground by the stiffness and compaction effect of the surrounding ground It is made, and includes a frame 100, a partition module 200, an elastic member 300 and a cover 400.

3 and 4, the frame 100 is configured to form the skeleton of the earthenware experiment apparatus 10, and forms an accommodation space therein. The accommodation space is not indicated with reference numerals, but it should be understood as referring to a space surrounded by the lower panel 110, the column 120 and the side panel 130.

As shown in FIG. 3, the compartment module 200 is configured to form a compartment space 201 in which the backfill soil 1 and the expansion material 2 are accommodated, and is provided in the accommodation space. The partition space 201 is opened upward.

The elastic member 300 is configured to form an elastic recovery force in a direction opposite to the load of the backfill soil 1 and the expansion force of the expansion material 2, interposed between the frame 100 and the partition module 200 in the receiving space do. The cover 400 is a configuration that mimics the road pavement layer, and covers the top of the partition space 201.

1 to 4, the frame 100 includes a lower panel 110, a column 120 and a side panel 130.

The lower panel 110 is configured to form a vertical movement boundary of the lower elastic body 310, and combines a plurality of pipes to form a rectangular frame. A plurality of lower elastic bodies 310 are mounted on the upper surface of the lower panel 110. In addition, a plurality of wheels W are mounted on the lower panel 110. The user can easily move the tojo experiment apparatus 10 by pushing the frame 100.

3 and 4, the columns 120 are formed at four corner portions of the lower panel 110, respectively. The columns 120 form a shape extending upward from each of the four corners of the lower panel 110. Flanges 121 to which the upper and lower ends of the rails R are coupled are formed above and below the column 120, respectively.

1 to 4, the side panel 130 is configured to form a horizontal movement boundary of the side elastic body 320, each provided between the columns 120. The side panels 130 are arranged to connect columns 120 adjacent to each other. Accordingly, the lower panel 110 and the plurality of side panels 130 form an accommodating space in the form of a rectangular parallelepiped inside. A plurality of side elastic bodies 320 are mounted to each side panel 130.

A plurality of rails R formed in the vertical direction are formed on the lower panel 110. Rail (R) is a configuration that forms a longitudinal movement path of the side panel 130, and forms a long rod shape in the longitudinal direction.

3 and 4, sliders 131 on which rails R are inserted are formed on both sides of the side panel 130 in the horizontal direction. The side panel 130 is mounted on the rail R through the slider 131 to be movable in the vertical direction.

As illustrated in FIG. 2, a blocking unit 140 that blocks upward movement of the lid 400 is coupled to the upper end of the column 120. The blocking unit 140 includes a fixing part 141, a rotating part 142, and a pressing part 143.

The fixing parts 141 are respectively fixed to the upper ends of the columns 120. The rotating part 142 is disposed in a form of connecting the fixing parts 141. Four rotating parts 142 are provided and are disposed in the form of a square frame. The rotating parts 142 are rotatably coupled to the fixing parts 141 by pins P at the corner portions, respectively.

The pressing portion 143 is configured to form an upward movement boundary, and is screwed vertically to the rotating portion 142 from the top of the cover 400. The pressing portion 143 is formed with a lever (V) that the user can hold and turn. When the user grasps and turns the lever V, the pressing portion 143 is raised or lowered. The user rotates the lever V to close the lower end of the pressing portion 143 to the upper surface of the cover 400.

2 to 4, the compartment module 200 is configured to form a compartment space 201 in which the backfill soil 1 and the expansion material 2 are accommodated, and is provided in the accommodation space.

The partition module 200 includes a lower isolation plate 210 and a plurality of side isolation plates 220. Referring to FIG. 3, the partition space 201 is a space surrounded by the lower isolation plate 210 and the plurality of side isolation plates 220 and is opened upward.

The lower isolation plate 210 is configured to form the bottom surface of the partition space 201, and is formed in the form of a square flat plate. As illustrated in FIG. 4, the corner portion of the lower isolation plate 210 may be manufactured in a cut form to prevent collision with the column 120. The lower separation plate 210 is separated from the lower panel 110 by the lower elastic body 310.

The side isolation plate 220 is a configuration that forms a side surface of the partition space 201 on the lower isolation plate 210, and is formed in a square flat plate shape. The lower surface of the side isolation plate 220 is in close contact with the upper surface of the lower isolation plate 210.

As shown in FIG. 4, the side isolation plates 220 are provided in plural and are arranged in a form surrounding the partition space 201 while abutting both ends in the horizontal direction. The side isolation plate 220 is spaced apart from the side panel 130 by the side elastic body 320.

As shown in FIG. 3, the backfill soil 1 and the inflation material 2 are contained in the flexible sheet S to be accommodated in the compartment space 201 in a state where direct contact with the compartment module 200 is blocked. You can.

When the backfill soil 1 and the expandable material 2 are contained in the flexible sheet S and are accommodated in the partition space 201, the partition space (by the load of the backfill soil 1 and the expansion force of the expansion material 2) Even if a gap is formed between the side isolation plates 220 in contact with the increased volume of the 201), the outflow of the backfill soil 1 is prevented.

1 to 4, the cover 400 is a configuration that covers the upper end of the partition space 201, and is manufactured in the form of a square plate. The cover 400 simulates the asphalt pavement layer by covering the upper end of the partition space 201. The lid 400 is formed with an input hole 401 that can additionally input the backfill soil 1 and the expansion material 2, if necessary.

2 and 3, the elastic member 300 is configured to form an elastic recovery force in a direction opposite to the load of the backfill soil 1 and the expansion force of the expansion material 2, the frame ( 100) and the partition module 200.

The elastic member 300 includes a lower elastic body 310 that forms an elastic recovery force that pushes the lower isolation plate 210 upwards, and a plurality of side elastic bodies that form elastic recovery forces that push the side isolation plates 220 laterally ( 320).

The lower elastic body 310 is provided in plurality between the lower panel 110 and the lower isolation plate 210, and the side elastic body 320 is provided in plurality between the side panel 130 and the side isolation plate 220. The lower end of the lower elastic body 310 is coupled to the lower panel 110, and the upper end of the lower elastic body 310 is coupled to the lower isolation plate 210.

One end of the side elastic body 320 is coupled to the side panel 130, and the other end of the side elastic body 320 is coupled to the side isolation plate 220. As described above, the side panel 130 is mounted to the rail R through the slider 131 to be movable in the vertical direction. Therefore, when the side isolation plate 220 is moved in the vertical direction, the side panel 130 is moved in the vertical direction together with the side isolation plate 220.

2 and 3, a displacement meter (DM) such as LVDT is installed between the lower panel 110 and the lower isolation plate 210 and between the side panel 130 and the side isolation plate 220, respectively. . The displacement meter DM is connected to a control unit (not shown).

The displacement meter DM continuously measures the distance between the lower panel 110 and the lower isolation plate 210 and between the side panel 130 and the side isolation plate 220. The user can know the linear expansion rate data of the backfill soil 1 and the expansion material 2 over time.

The LVDT (The linear variable differential transformer) is a type of electrical transducer that measures the difference in linear distance. Three solenoid coils are positioned around the tube. The middle coil is the main and the other two are located outside. The cylinder-shaped magnetic core moves along the center of the tube to inform the position value of the measurement object.

2 and 3, a soil pressure gauge PG is installed on the upper surface of the lower isolation plate 210 and the inner surface of the side isolation plate 220, respectively. The earth pressure meter PG is connected to a control unit (not shown). The user can recognize the horizontal soil pressure and vertical soil pressure data of the backfill soil 1 and the expansion material 2 over time through the measurement value of the earth pressure gauge PG output to the control unit.

According to the invention, the elastic member is formed by forming the elastic recovery force in the opposite direction to the loading force of the backfill and the expansion force of the expansion material, so as to simulate the shrinkage of the surrounding ground by the compaction effect and the stiffness of the surrounding ground. It will be possible to provide a controlled earthenware experimental apparatus.

In the foregoing, although specific embodiments of the present invention have been described and illustrated, the present invention is not limited to the described embodiments, and it is common knowledge in the field of this technology that various modifications and modifications can be made without departing from the spirit and scope of the present invention. It is obvious to those who have it. Therefore, such modifications or variations should not be individually understood from the technical spirit or viewpoint of the present invention, and the modified embodiments should belong to the claims of the present invention.

10: earthenware experiment device
100: frame 200: compartment module
101: accommodation space 201: compartment space
110: lower panel 210: lower isolation plate
W: Wheel 220: Side isolation plate
120: column 300: elastic member
R: Rail 310: Lower elastic body
121: flange 320: side elastic body
130: side panel 400: cover
131: slider 401: input hole
140: Blocking unit S: Flexible seat
141: fixing part 1: backfill
142: rotating part 2: expansion material
143: Pressing part DM: Displacement meter
P: Pin PG: Earth pressure gauge
V: lever

Claims (5)

A frame forming an accommodating space therein; A compartment module provided in the accommodation space and forming a compartment space open upward; And a plurality of elastic members interposed between the frame and the partition module in the accommodation space,
Backfill soil and expanded material are accommodated in the compartment space,
The elastic member forms an elastic recovery force in a direction opposite to the load of the backfill and the expansion force of the expansion material,
The partitioning module includes a lower isolation plate forming a bottom surface of the partition space, and a plurality of side isolation plates forming a side surface of the partition space on the lower isolation plate,
The plurality of elastic members, the ground characterized in that it comprises a lower elastic body to form an elastic recovery force to push the lower isolation plate upward, and a plurality of side elastic bodies to form an elastic recovery force to push the side isolation plate sideways, respectively. A stiffness-controlled earthenware experimental device for recessed emergency recovery delete According to claim 1,
The frame includes a lower panel on which the lower elastic body is mounted, and a plurality of side panels on which the side elastic bodies are respectively mounted,
A plurality of rails longitudinally formed on the lower panel is formed,
The side panel, the ground sink emergency recovery type rigidity control tojo test device, characterized in that mounted to the rail so as to be movable in the longitudinal direction along with the side separating plate. According to claim 1,
The backfill soil and the inflation material are contained in a flexible sheet, so that the direct contact with the compartment module is blocked. According to claim 1,
Includes a cover that covers the upper end of the compartment space,
The frame, the ground sink emergency recovery type stiffness control tojo experiment device, characterized in that a blocking unit for blocking the upward movement of the cover is coupled.

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