JP2021105316A - Obstacle crushing method, and obstacle removal method - Google Patents

Abstract

To provide a method capable of efficiently crushing or removing obstacles in the ground.SOLUTION: An obstacle crushing method is a method of crushing obstacles in the ground. The method includes: a casing preparation step of preparing a casing that has a top casing 1 with a lid 1a on a top thereof, including a water air supply unit 1b capable of supplying water, or, water and air from the lid to an inside, and to a bottom of the top casing, a bottom casing comprising on its bottom, a drilling blade is connected; and a crushing step of crushing obstacles in the ground by lowering the same in the ground while rotating the caching with an all-around rotating machine. In the obstacle crushing method, water, or, water and air are supplied from the water/air supply part of the top casing.SELECTED DRAWING: Figure 1

Description

The present invention relates to an obstacle crushing method for crushing and removing obstacles such as concrete and steel frames buried in the ground when rebuilding a building structure, and an obstacle removing method.

In building structures such as buildings and condominiums, concrete and steel frames such as piles and walls are buried underground to support the load. When rebuilding these building structures, it is necessary to crush or remove the embedded obstacles such as concrete and steel frames.

Patent Document 1 describes a method of press-fitting a casing into the ground using an all-around rotating machine, crushing an obstacle with a bit provided at the tip of the casing, and then removing the obstacle with a hammer club. ..

Patent Document 1: Japanese Unexamined Patent Publication No. 2017-75451

However, in the method described in Patent Document 1, it is necessary to use a large all-around rotating machine because the excavation force of the casing may be weakened by earth pressure, and it takes time to embed the casing in the ground. There was a problem that there was.

An object of the present invention is to solve the above problems and efficiently crush or remove obstacles in the ground even in a narrow space.

In order to solve the above problems, the present invention is an obstacle crushing method for crushing an obstacle in the ground.
The most having a cutting blade at the lower end at the lower part of the uppermost casing having a lid on the top surface and a water / air supply part capable of supplying water or water and air from the lid to the inside. The casing preparation process to prepare the casing to which at least the lower casing is connected, and
It is equipped with a crushing step of crushing obstacles in the ground while burying the casing in the ground while rotating the casing with an all-around rotating machine.
The crushing step provides an obstacle crushing method characterized by supplying water or water and air from the water / air supply unit of the uppermost casing.

With this configuration, water and air can be supplied from the inside of the casing to the earth pressure at the lower end to soften the soil and improve the excavation force of the casing, so that it can be embedded with a small all-around rotating machine. It is possible to efficiently crush obstacles in the ground even in a narrow space.

Further, in order to solve the above problems, the present invention is an obstacle removing method for crushing an obstacle in the ground.
The most having a cutting blade at the lower end at the lower part of the uppermost casing having a lid on the top surface and a water / air supply part capable of supplying water or water and air from the lid to the inside. The casing preparation process to prepare the casing to which at least the lower casing is connected, and
A crushing process that crushes obstacles in the ground while burying the casing in the ground while rotating the casing with an all-around rotating machine.
An obstacle removing step of inserting a hammer club into the casing buried in the ground to grasp an obstacle and removing the obstacle from the ground is provided.
The crushing step provides a method for removing obstacles, which comprises supplying water or water and air from the water / air supply unit of the uppermost casing.

With this configuration, water and air can be supplied from the inside of the casing to the earth pressure at the lower end to soften the soil and improve the excavation force of the casing, so that it can be embedded with a small all-around rotating machine. Obstacles in the ground can be efficiently crushed and removed even in a narrow space.

According to the obstacle crushing method and the obstacle removing method of the present invention, water and air can be supplied from the inside of the casing to the earth pressure at the lower end to soften the soil and improve the excavation force of the casing. It can be embedded by machine and can efficiently crush obstacles in the ground even in a narrow space.

It is a figure explaining the uppermost casing in Example 1 of this invention. It is sectional drawing explaining how water and air are supplied from the water-air supply part of the uppermost casing in Example 1 of this invention. It is a figure explaining the obstacle crushing method in Example 1 of this invention. It is a figure explaining the obstacle removal method in Example 2 of this invention.

Example 1 of the present invention will be described with reference to FIGS. 1 to 3. FIG. 1 is a diagram illustrating an uppermost casing according to a first embodiment of the present invention. FIG. 2 is a cross-sectional view illustrating how water or air is supplied from the water / air supply unit of the uppermost casing according to the first embodiment of the present invention. FIG. 3 is a diagram for explaining the obstacle crushing method according to the first embodiment of the present invention.

(casing)
The casing K in the first embodiment includes the uppermost casing 1 at the uppermost portion. As shown in FIGS. 1 and 2, the uppermost casing 1 has a cylindrical shape (φ700 to 3000 mm), and a lid portion 1a is provided on the entire surface of the top surface to close the casing 1. Further, the lid portion 1a is provided with a water / air supply portion 1b so that the water W supplied by the water hose 1c can be supplied to the inside of the uppermost casing 1. Similarly, the air A supplied by the air hose 1d in the water / air supply unit 1b can be supplied to the inside of the uppermost casing 1. The water W and the air A are mixed in the water / air supply unit 1b and supplied into the casing K. Water W and air A can be selected from supply of water W alone or supply of water W and air A by a control unit (not shown).

Here, the uppermost casing 1 is usually called a drainer, and the casing is connected under the drainer, but in the present invention, it is called the uppermost casing.

As shown in FIG. 1, a water / air supply unit 1b and a sebel 4 are provided on the upper part of the uppermost casing 1, and water is supplied from the water hose 1c and the air hose 1d to the water / air supply unit 1b via the sebel 4. W and air A are supplied. An intermediate casing 3 (see FIG. 3) is connected to the lower part of the uppermost casing 1 by bolts, and a lowermost casing 2 (see FIG. 3) is connected to the lower part of the intermediate casing 3 by bolts. An excavation blade is provided at the lower end of the lowermost casing 2. The intermediate casing 3 is not essential and may not be connected if the underground depth to be excavated is shallow. That is, the casing K in the present invention may or may not have one or more intermediate casings 3 connected between the uppermost casing 1 and the lowermost casing 2, and may or may not be connected to at least the uppermost casing 1. It suffices if the lowermost casing 2 is connected.

The water W and air A supplied from the water / air supply unit 1b of the uppermost casing 1 are mixed and spread throughout the inside of the casing K, and the water W and air A are supplied to the soil at the lower end of the casing K to soften the soil. By doing so, the excavation force is improved, and the casing K can be efficiently embedded in the ground. A plurality of holes are formed on the side surface of the conventional casing in order to reduce the weight and remove the soil inside. However, since the casing K in the first embodiment is originally used for pile driving, prevent the ready-mixed concrete from leaking. No holes are formed in the side surface portions of the uppermost casing 1, the lowermost casing 2, and the intermediate casing 3, and only the lower end portion of the casing K is open. Therefore, the supplied water W and air A do not go out of the casing K, and the water W and air A are efficiently supplied to the soil at the lower end of the casing K to soften the soil and excavate the casing. Can be improved. In particular, by supplying air A in addition to water W, gravel and the like can be blown up and the soil can be softened by a synergistic effect with water.

In the past, obstacles were crushed by embedding the casing in the ground without supplying water or air. In that case, when embedding the casing in the ground while rotating it, it is necessary to embed it with a large all-around rotating machine because the excavation force is weak and the obstacle may not be crushed efficiently. On the other hand, in the first embodiment, since water and air can be supplied into the uppermost casing 1, about twice the excavating force can be obtained, and obstacles can be efficiently crushed and removed. can. Therefore, the casing can be embedded with a small all-around rotating machine, and obstacles can be efficiently crushed in a narrow space even if the separation from an adjacent building or the like is small.

As the water W and the air A supplied from the water / air supply unit 1b, those to be supplied such as only the water W, the water W and the air A can be selected depending on the soil excavated in the casing K. For example, in the case of highly viscous soil, the effect of air is small, so only water W may be supplied.

(Obstacle crushing method)
The obstacle crushing method of Example 1 will be described with reference to FIG. FIG. 3A is a diagram for explaining a casing preparation process, and FIG. 3B is a diagram for explaining a crushing process.

First, the casing preparation step is carried out. In the casing preparation step, the casing K having the uppermost casing 1 at the upper part is attached to the all-around rotating machine 7. The uppermost casing 1 has a lid portion 1a on the top surface and has a water air supply portion 1b capable of supplying water or water and air from the lid portion 1a to the inside. At this time, the intermediate casing 3 is connected to the casing K with bolts to deepen the excavation depth to the lower part of the uppermost casing 1, and the lowermost casing 2 having the excavation blade at the lower end is bolted to the intermediate casing 3. It is connected.

Here, the intermediate casing 3 is not always necessary, and is not necessary when the excavation depth is shallow. That is, at least the lowermost casing 2 may be connected to the uppermost casing 1. On the contrary, when the excavation depth is to be deepened, a plurality of intermediate casings 3 may be connected. In this case, a plurality of intermediate casings 3 may be connected from the beginning, but the intermediate casing 3 may be added later. That is, once excavated by the casing K, after that, only the uppermost casing 1 is lifted and separated by the crane 11 while leaving the other casings in the ground, and the additional intermediate casing 3 is connected to the lower part of the uppermost casing 1. You just have to do it.

Here, the all-around rotary machine 7 is also called a full-rotation tubing device, which is a device capable of pushing the casing K into the ground while rotating the entire circumference, and is installed horizontally so that the casing K can be vertically embedded. .. The casing K attached to the all-around rotating machine 7 is grabbed by a chuck and is embedded in the ground while rotating. In the first embodiment, water or air is supplied from the inside of the casing K to the soil at the lower end to soften the soil and improve the excavation force. Therefore, the casing K is efficiently embedded by the small all-around rotary machine 7. be able to.

Next, a crushing step is carried out. In the crushing step, the casing K is press-fitted into the ground while being rotated by the all-around rotating machine 7, and if there is an obstacle such as concrete or steel frame, it is crushed. At that time, in order to increase the excavation force of the casing K, water W and air A are supplied from the water / air supply unit 1b to soften the soil at the lower end of the casing K, thereby improving the excavation force and efficiently removing obstacles. Can be crushed. Conventionally, since the casing is embedded in the ground without supplying water or air, it is necessary to use a large-sized (about 10 m × 10 m) all-around rotating machine because the casing has a weak excavating force. Further, although it may take time to embed, in the first embodiment of the present invention, this problem is solved and the casing is efficiently embedded in the ground with a small (about 4 m × 4 m) all-around rotating machine. You can crush obstacles with.

Whether to supply both water W and air A or to use only water W is selected depending on the soil to be excavated. That is, in the case of soil having a high viscosity, the effect of air is small, so only water W may be supplied. In other cases, water W and air A may be supplied. In particular, it is effective to supply water W and air A to the place where crushed rocks are deposited and the gravel layer.

After that, the casing K is pulled up while being rotated by the all-around rotating machine 7, and is lifted by the crane 11. The place where the casing K was buried is backfilled with soil to finish the work.

In the first embodiment, at least the lowermost casing 2 is connected to the uppermost casing 1, but the present invention is not limited to this and can be changed as appropriate. For example, when the drilling blade is provided at the lower end of the uppermost casing 1, it is not always necessary to connect the lowermost casing 2.

As described above, in the first embodiment, it is an obstacle crushing method for crushing an obstacle in the ground.
The most having an excavation blade at the lower end at the lower part of the uppermost casing having a lid on the top surface and a water / air supply part capable of supplying water or water and air from the lid to the inside. The casing preparation process to prepare the casing to which at least the lower casing is connected, and
It is equipped with a crushing step of crushing obstacles in the ground while burying the casing in the ground while rotating the casing with an all-around rotating machine.
In the crushing step, water or air is supplied from the water / air supply unit of the uppermost casing to water or air with respect to the earth pressure at the lower end from the inside of the casing by an obstacle crushing method characterized by supplying water or water and air. Since it is possible to soften the soil and improve the excavation force of the casing, it can be embedded with a small all-around rotating machine, and obstacles in the ground can be efficiently crushed even in a narrow space.

Example 2 of the present invention is different from Example 1 in that it includes an obstacle removing step of crushing an obstacle in the ground and then removing the crushed obstacle. The obstacle removing method in the second embodiment will be described with reference to FIG. FIG. 4 is a diagram illustrating a method for removing obstacles in Example 2 of the present invention.

FIG. 4A shows a casing preparation step, FIG. 4B shows a crushing step, and FIG. 4C shows an obstacle removing step. First, the casing preparation step is carried out. In the casing preparation step, the casing K having the uppermost casing 1 at the upper part is attached to the all-around rotating machine 7. The uppermost casing 1 has a lid portion 1a on the top surface and has a water air supply portion 1b capable of supplying water or water and air from the lid portion 1a to the inside. At this time, the intermediate casing 3 is connected to the casing K with bolts to deepen the excavation depth to the lower part of the uppermost casing 1, and the lowermost casing 2 having the excavation blade at the lower end is bolted to the intermediate casing 3. It is connected.

Here, the intermediate casing 3 is not always necessary, and is not necessary when the excavation depth is shallow. That is, at least the lowermost casing 2 may be connected to the uppermost casing 1. On the contrary, when the excavation depth is to be deepened, a plurality of intermediate casings 3 may be connected. In this case, a plurality of intermediate casings 3 may be connected from the beginning, but the intermediate casing 3 may be added later. That is, once excavated by the casing, then only the uppermost casing 1 is lifted and separated by the crane 11 while leaving the other casings in the ground, and the additional intermediate casing 3 is connected to the lower part of the uppermost casing 1. You just have to do it. In that case, one or a plurality of intermediate casings 3 may be connected so that the crushing step and the obstacle removing step described later are performed again.

Next, a crushing step is carried out. In the crushing step, the casing K is press-fitted into the ground while being rotated by the all-around rotating machine 7, and if there is an obstacle B such as concrete or steel frame, it is crushed. At that time, in order to increase the excavation force of the casing K, water W and air A are supplied from the water / air supply unit 1b to soften the soil. As a result, excavation by the excavation blade at the tip of the casing K is improved, and obstacles can be crushed efficiently. Conventionally, since the casing is embedded in the ground without supplying water or air, it is necessary to use a large-sized (about 10 m × 10 m) all-around rotating machine because the casing has a weak excavating force. Further, although it may take time to embed, in the first embodiment of the present invention, this problem is solved and the casing is efficiently embedded in the ground with a small (about 4 m × 4 m) all-around rotating machine. You can crush obstacles with.

As the water or air supplied from the water / air supply unit 1b, those supplied such as water W only, water W and air A can be selected depending on the soil excavated in the casing K. For example, in the case of highly viscous soil, the effect of air is small, so only water W may be supplied. In other cases, water W and air A may be supplied to soften the soil and the gravel may be blown up by the force of air A.

Next, a crushing step in the casing is carried out (not shown). That is, in the crushing step, after the casing K is embedded in the ground while supplying water or air to crush the obstacle B, and then the casing K is crushed but there is a large obstacle, the casing crushing step is performed. implement. In the casing crushing step, a crushing tool (not shown) is attached to the crane 11 while leaving the casing K in the ground. Then, the crusher is lowered into the casing K by the crane 11. When the crusher arrives at the obstacle B, the crusher is rotated and pressure is applied to the obstacle B to crush it. The crusher is composed of a large screw-like cutting blade, and obstacles are crushed by applying pressure while rotating.

The in-casing crushing step is not always necessary, and may be carried out when a large obstacle B is present in the casing K. Whether or not a large obstacle exists in the casing K may be checked by sensing with a sensor or the like, but it may be performed when the hammer club cannot grasp the obstacle in the obstacle removing step described later.

Next, an obstacle removal step is carried out. In the obstacle removing step, the hammer club 6 is attached to the crane 11. Then, the hammer club 6 is inserted into the casing K buried in the ground and lowered. When the hammer club 6 arrives at the crushed obstacle B, the obstacle B is grasped, pulled up to the ground, and placed in a predetermined place. The hammer club 6 includes a plurality of gripping claws, and the obstacle B can be gripped by closing the plurality of gripping claws.

After that, the casing K is pulled up while being rotated by the all-around rotating machine 7, and is lifted by the crane 11. The place where the casing K was buried is backfilled with soil to finish the work.

In the second embodiment, at least the lowermost casing 2 is connected to the uppermost casing 1, but the present invention is not limited to this and can be changed as appropriate. For example, when the drilling blade is provided at the lower end of the uppermost casing 1, it is not always necessary to connect the lowermost casing 2.

As described above, in the second embodiment, it is an obstacle removing method for crushing an obstacle in the ground.
The most having an excavation blade at the lower end at the lower part of the uppermost casing having a lid on the top surface and a water / air supply part capable of supplying water or water and air from the lid to the inside. The casing preparation process to prepare the casing to which at least the lower casing is connected, and
A crushing process that crushes obstacles in the ground while burying the casing in the ground while rotating the casing with an all-around rotating machine.
An obstacle removing step of inserting a hammer club into the casing buried in the ground to grasp an obstacle and removing the obstacle from the ground is provided.
In the crushing step, water or air is supplied from the water / air supply unit of the uppermost casing to water or air with respect to the earth pressure at the lower end from the inside of the casing by an obstacle removing method characterized by supplying water or water and air. Because it can soften the soil and improve the excavation force of the casing, it can be embedded with a small all-around rotating machine, and obstacles in the ground can be efficiently crushed and removed even in a narrow space. can.

The obstacle crushing method and the obstacle removing method in the present invention can be widely used in the field of efficiently crushing or removing obstacles in the ground even in a narrow space.

1: Top casing 1a: Lid 1b: Water / air supply
1c: Water hose 1d: Air hose 4: Sebel
6: Hammer club 7: All-around rotating machine
11: Crane
B: Obstacle K: Casing
W: Water A: Air

In order to solve the above problems, the present invention is an obstacle crushing method for crushing an obstacle in the ground.
At the bottom of the uppermost casing, which has a lid portion whose entire top surface is closed, and which has a water or air supply portion capable of supplying water or water and air from the lid portion to the inside. A casing preparation process for preparing a casing to which at least the bottom casing having an excavation blade at the lower end is connected,
It is equipped with a crushing step of crushing obstacles in the ground while burying the casing in the ground while rotating the casing with an all-around rotating machine.
The crushing step provides an obstacle crushing method characterized by supplying water or water and air so as to be ejected from the water / air supply unit of the uppermost casing.

In order to solve the above problems, the present invention is an obstacle removing method for crushing an obstacle in the ground.
At the bottom of the uppermost casing, which has a lid portion whose entire top surface is closed, and which has a water or air supply portion capable of supplying water or water and air from the lid portion to the inside. A casing preparation process for preparing a casing to which at least the bottom casing having an excavation blade at the lower end is connected,
A crushing process that crushes obstacles in the ground while burying the casing in the ground while rotating the casing with an all-around rotating machine.
An obstacle removing step of inserting a hammer club into the casing buried in the ground to grasp an obstacle and removing the obstacle from the ground is provided.
The crushing step provides a method for removing obstacles, which comprises supplying water or water and air so as to be ejected from the water / air supply unit of the uppermost casing.

Claims (2)

It is an obstacle crushing method that crushes obstacles in the ground.
The most having an excavation blade at the lower end at the lower part of the uppermost casing having a lid on the top surface and a water / air supply part capable of supplying water or water and air from the lid to the inside. The casing preparation process to prepare the casing to which at least the lower casing is connected, and
It is equipped with a crushing step of crushing obstacles in the ground while burying the casing in the ground while rotating the casing with an all-around rotating machine.
In the crushing step, an obstacle crushing method comprising supplying water or water and air from the water / air supply unit of the uppermost casing. It is an obstacle removal method that crushes obstacles in the ground.
The most having an excavation blade at the lower end at the lower part of the uppermost casing having a lid on the top surface and a water / air supply part capable of supplying water or water and air from the lid to the inside. The casing preparation process to prepare the casing to which at least the lower casing is connected, and
A crushing process that crushes obstacles in the ground while burying the casing in the ground while rotating the casing with an all-around rotating machine.
An obstacle removing step of inserting a hammer club into the casing buried in the ground to grasp an obstacle and removing the obstacle from the ground is provided.
The obstacle removing method, characterized in that, in the crushing step, water or water and air are supplied from the water / air supply unit of the uppermost casing.

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