JP2012057457A - Parachute type anchor and ground improvement construction using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a parachute type anchor enabling magnetic exploration and ground improvement to be simultaneously performed by single-time boring and a ground improvement construction method using the parachute type anchor.SOLUTION: A paper drain 20 is attached to a parachute type anchor 100 in which a plurality of foldable anchoring arms 1 are stored in the axial direction, and then a hollow pipe 11 is pulled up to a required depth. Next, the hollow pipe 11 is inserted into a magnetic exploration drilling hole and then the parachute type anchor 100 is inserted into the hollow pipe 11. Next, the parachute type anchor 100 is pushed out from the hollow pipe 11 while pushing the parachute type anchor 100 by a push rod 12, and then the anchoring arms 1 open radially around a shaft 3 as a center by the resilience of a spring 6 and are anchored into the ground.

Description

  The present invention relates to a parachute anchor and a ground improvement construction method using the same, and more particularly to a parachute anchor that enables simultaneous magnetic exploration and ground improvement by one boring and a ground improvement construction method using the same. .

In areas where many unexploded bombs dropped during the war are still buried in the ground, such as Okinawa Prefecture, there should be no unexploded bombs under the ground when performing ground improvement and construction work. It is necessary to conduct magnetic exploration (unexploded bomb investigation) to confirm.
As shown in FIG. 11, this magnetic exploration is carried out by excavating the ground by rotary boring, for example, every 50 cm for a 50 kg bomb or every 1 m for a 250 kg bomb. Insert a stainless steel cylindrical casing into the drilling hole, and then insert a magnetic sensor into the cylindrical casing to confirm that there is no unexploded shell at the bottom of the drilling hole. It is performed by repeating the work of excavating until the required depth (planned depth) is reached.

After conducting such magnetic exploration at predetermined intervals and confirming that there were no unexploded shells under the entire area of the ground (the magnetic exploration was completed), the ground improvement by the paper drain method was applied according to the process shown in FIG. To do. The paper drain method is to place a flexible belt-like sheet material made of water-absorbing material on the ground at a predetermined interval while burying most of it in the ground while exposing one end of the sheet to the ground surface. The sheet material absorbs moisture in the ground and drains (drains) to the ground surface to promote consolidation settlement of soft ground.
Soil stabilization treatment (ground improvement) using this paper drain is used in places with compressibility such as clay and silt clay and places with saturated soil. These soils are composed of very weak soil particles and large gaps and are always filled with pore water. If such soils are placed in places such as road embankments, loading embankments, slabs, etc., the soils will cause consolidation settlement due to the load and cause serious problems. For this reason, vertical drains are placed to discharge moisture in the soil. The vertical drain has the role of reducing the length of the flow path for pore water.

On the other hand, conventionally, the paper drain construction method is performed using a large dedicated device that drives a hollow casing having a predetermined axial length into the ground, and the paper drain is inserted into the hollow casing (placed pipe). By placing the casting tube vertically on the ground and pulling out the casing with the paper drain tip reaching the predetermined depth, only the paper drain remains in the ground and the top end is projected to the ground. Is done. For this reason, it is necessary to fix the tip of the paper drain to the ground so that the paper drain is not pulled out together with the casing when the casing is pulled out, and an anchor member is attached to the tip of the paper drain to give resistance to pulling out. Conventionally, as an anchor member therefor, the tip of the paper drain is projected from the tip of the casing, and an anchor plate made of a plate material such as a rectangular steel plate having a larger area than the opening end of the casing is attached to the projection. It is known that when an anchor plate is placed in the ground through a casing and the casing is pulled out, the anchor plate is stopped in the soil by resistance received from the soil, and only the casing is pulled out from the soil (for example, a patent) References 1 and 2).
In such a conventional method, driving is performed with the anchor plate positioned outside the lower end of the casing. Therefore, when the area of the anchor plate is large, the driving resistance increases correspondingly. There is a problem that a sufficient anchor effect cannot be obtained, and in order to obtain a sufficient anchor effect, it was necessary to drive an anchor plate with a predetermined area using a large dedicated device with a large pressure force. .
Thus, in the conventional paper drain method, it is necessary to lay a paper drain at predetermined intervals by a placement device through a casing on the ground. When performing the magnetic exploration, In addition to drilling by boring, it was necessary to install a new casting pipe.
In addition, the anchor member in the paper drain method has the opposite effect, but in the foundation support pile placing method on the soft ground, the screw-fed press-fitting rod is used as an anchor to prevent the settlement of the pile. When the slide steel pipe is pushed down, the slide steel pipe is relatively displaced while sliding on the inner peripheral surface of the threaded main column steel pipe, and the sheet pile arranged radially at the tip of the slide steel pipe is pulled by the ring rod. There is known a parachute anchor that opens in a parachute shape and makes it possible to construct a strong and strong foundation on soft ground (see, for example, Patent Document 3).

Japanese Utility Model Publication No. 5-57028 JP 2000-20451 A JP 2002-121735 A

As can be seen from FIGS. 11 and 12, in the conventional magnetic exploration / ground improvement construction method, after drilling for magnetic exploration, new drilling for ground improvement had to be performed.
As described above, since the conventional construction method separately performs magnetic exploration and ground improvement, it takes time and cost, and since it is performed using dedicated devices, there is a problem that the equipment cost also increases. .
The parachute anchor is a fixing means for fixing a building on soft ground, and is too large in size to be used as a fixing means for a paper drain for ground improvement.
Accordingly, the present invention has been made in view of the problems of the prior art, and a parachute anchor that enables simultaneous magnetic exploration and ground improvement by one boring and ground improvement using the same. It is to provide a construction method.

The parachute anchor according to claim 1 for achieving the above object is for a paper drain as an anchor lock that is driven to a predetermined depth in the ground via a hollow pipe to fix the paper drain in the ground. A plurality of anchor main bodies having a shaft extending in the vertical direction, and a base end portion pivotally attached to a mounting portion formed at a lower end portion of the shaft. The anchor body has a paper drain mounting portion, the arm is held in a closed state in the pipe, and when the arm penetrates the hollow pipe, it opens radially into the ground and extends in the pulling direction. It is characterized by being configured to give resistance to it.
The inventor of the present application drilled to lay a paper drain for ground improvement using a drilling hole bored in magnetic exploration, that is, a drilling hole used for passing a magnetic sensor through a cylindrical casing (hollow pipe). If it can be used as a hole, it can pass through the cylindrical casing (hollow pipe) used in the magnetic exploration while thinking that magnetic exploration and ground improvement can be performed with one boring. If the anchor is an anchor that can be opened after passing through the cylindrical casing (hollow pipe), the idea is that the magnetic exploration and ground improvement can be carried out with one boring, and the parachute type of the above configuration I came up with an anchor.

The parachute anchor according to claim 2 for achieving the above-mentioned object is a parachute anchor for paper drain as an anchor lock that is driven to a predetermined depth in the ground and fixes the paper drain to the ground. An anchor body having a shaft extending in the vertical direction and a plurality of arms having proximal ends pivoted so as to open radially to a mounting portion formed at the lower end of the shaft; The anchor body has a paper drain attachment portion, the arm is locked in advance by a locking means and held in a closed state, and the arm is automatically or manually opened radially into the ground by releasing the lock. And is configured to give resistance to the drawing direction.
The inventor of the present application does not allow the anchor to open, and if it has a long axis (vertically long) shape that is stored and locked in the axial direction in advance, it does not pass through the cylindrical casing, and pressure is applied with a rod-shaped object. When the required depth is reached, if the lock is unlocked and the anchor is opened, the magnetic exploration and ground improvement can be carried out with a single boring, and the parachute anchor with the above configuration is installed. It came to devise.

In the parachute anchor according to claim 3, the arm is urged by an elastic body in a radial opening direction at the lower end portion of the shaft.
In the parachute type anchor, since the arm is urged by the elastic body in the above-mentioned form, when the anchor body passes through the cylindrical casing or when the locking means is released, all the arms are automatically centered on the shaft. It opens radially and gives resistance in the pulling direction.

In the parachute anchor according to claim 4, the elastic body is an elastic rubber attached to the shaft, and the arm is closed by compressing and deforming the elastic rubber in a radial direction.
In the parachute type anchor, the elastic rubber is attached to the shaft in a state of being compressed and deformed in the radial direction by the arm, and the arm is closed by the cylindrical casing or the locking means, so that the anchor body passes through the cylindrical casing. When the lock means is released or when the lock means is released, the elastic force of the elastic rubber causes all the arms to automatically open in a radial manner around the shaft to provide resistance in the pulling direction.

The parachute type anchor according to claim 5 for achieving the above object is a parachute type as an anchor lock which is driven to a predetermined depth position in the ground through a hollow pipe and fixes an object to be fixed in the ground. An anchor main body having a shaft extending in a vertical direction, and a plurality of arms having proximal ends pivoted so as to be able to open radially to a mounting portion formed at a lower end portion of the shaft. The anchor body has a fixed object mounting portion, the arm is held in a closed state in the pipe, and when the arm penetrates the hollow pipe, it opens radially into the ground and extends in the pulling direction. It is configured to provide resistance.
In the parachute type anchor, since the anchor body has a fixed object attaching portion, it is possible to attach anchoring means other than paper drain. Therefore, when the anchor body to which the anchoring means is attached penetrates the hollow pipe, the arm opens radially around the shaft to provide resistance in the pulling direction, and against structures or materials on land or sea It can be used as a fixing means.

The parachute anchor according to claim 6 for achieving the object, is a parachute anchor as an anchor lock that is driven to a predetermined depth position in the ground and fixes an object to be fixed in the ground. An anchor body having a shaft extending in the vertical direction and a plurality of arms having proximal ends pivoted so as to open radially to a mounting portion formed at the lower end of the shaft, the anchor body Has a fixed object mounting portion, the arm is locked in advance by a locking means and held in a closed state, and when unlocked, the arm is automatically or manually opened radially into the ground and pulled out. It is configured to give resistance to the direction.
In the parachute type anchor, since the anchor body has a fixed object attaching portion, it is possible to attach anchoring means other than paper drain. Therefore, by pushing the anchor body to which the anchoring means is attached to the required depth and releasing the locking means, the arm opens radially around the shaft to provide resistance in the pulling direction, and a structure on land or at sea. Alternatively, it can be used as a fixing means for materials and the like.

The ground improvement construction method using the parachute anchor according to claim 7 for achieving the object is a ground improvement construction method using the parachute anchor according to any one of claims 1 to 4. A paper drain that absorbs soil moisture is attached to the parachute anchor, a cylindrical casing is inserted into a drilling hole, the anchor main body is inserted into the cylindrical casing, and then the anchor main body is inserted by a rod. The anchor body is pushed out from the cylindrical casing while pushing in, and the arms are opened radially to anchor the paper drain.
In the ground improvement construction method using the parachute anchor, an arm is formed by penetrating the parachute anchor according to any one of claims 1 to 4 through a cylindrical casing provided in the excavation hole. Opens radially around the shaft to provide resistance in the pulling direction and allows paper drains to be placed in the ground.

The ground improvement construction method using the parachute anchor according to claim 8 for achieving the object is a ground improvement construction method using the parachute anchor according to any one of claims 1 to 4. A paper drain that absorbs moisture in the soil is attached to the parachute anchor, the arm is locked by a fixing ring so that it cannot be opened in advance, the anchor body is inserted into a drilling hole, and then a rod By pressing the anchor body to a required depth while applying pressure to the anchor body, the arm is opened radially by releasing the lock, and the paper drain is anchored.
In the ground improvement construction method using the parachute-type anchor, the parachute-type anchor according to any one of claims 1 to 4 is pushed into the excavation hole to the required depth to release the lock, so that all the arms are shafts. The paper drain can be placed in the ground by providing a resistance in the pulling direction by opening radially around the center.

In the ground improvement construction method using the parachute anchor according to claim 9, the excavation hole is a boring hole for magnetic exploration, and the cylindrical casing is placed in the excavation hole used in the magnetic exploration. A nonmagnetic cylindrical casing for magnetic exploration, wherein the magnetic exploration hole and the nonmagnetic cylindrical casing are also used for laying a paper drain.
In the ground improvement construction method, the parachute anchor according to any one of claims 1 to 4 is used, whereby the magnetic exploration hole is laid and a ground drain paper drain is laid. As a result, it becomes possible to perform magnetic exploration and ground improvement by one boring.

According to the parachute anchor of the present invention, it becomes possible to lay a paper drain for ground improvement by diverting a bored excavation hole, for example, a magnetic exploration excavation hole as it is. As a result, magnetic exploration and ground improvement can be performed simultaneously with one boring.
In addition, the conventional anchor can only be anchored only on the hard ground, but unlike the conventional anchor, the parachute anchor of the present invention can be anchored even on the hard ground and the soft layer, and when the necessary depth is reached. Parachute type that automatically or manually bends each arm or rotates around the fastener as a fulcrum, and all arms open radially around the shaft and anchors, so it can fix objects widely from the ground surface to the deep part. Will be able to.
Moreover, according to the ground improvement construction method of the present invention, by using the parachute anchor of the present invention, it is possible to suitably lay a paper drain for ground improvement by using the magnetic exploration drilling hole. become.

It is principal part explanatory drawing which shows the parachute type anchor which concerns on Example 1 of this invention. It is explanatory drawing which shows the ground improvement construction method using the parachute type anchor which concerns on Example 1 of this invention. It is principal part explanatory drawing which shows the parachute type anchor which concerns on Example 2 of this invention. It is explanatory drawing which shows the ground improvement construction method using the parachute type anchor which concerns on Example 2 of this invention. It is principal part explanatory drawing which shows the parachute type anchor which concerns on Example 3 of this invention. It is explanatory drawing which shows the ground improvement construction method using the parachute type anchor which concerns on Example 3 of this invention. It is principal part explanatory drawing which shows the parachute type anchor which concerns on Example 4 of this invention. It is explanatory drawing which shows the ground improvement construction method using the parachute type anchor which concerns on Example 4 of this invention. It is explanatory drawing which shows the ground state after laying a paper drain. It is a flowchart which shows the procedure of the magnetic exploration (unexploded bullet investigation) and ground improvement simultaneous construction of this invention. It is a flowchart which shows the procedure of the magnetic exploration (unexploded bullet investigation) of the conventional construction method. It is explanatory drawing which shows the procedure of the ground improvement (paper drain construction method) of the conventional construction method. It is principal part explanatory drawing which shows the closed state of the parachute type anchor which concerns on Example 5 of this invention. It is principal part explanatory drawing which shows the open state of the parachute type anchor which concerns on Example 5 of this invention. It is principal part explanatory drawing which shows the open state of the parachute type anchor which concerns on Example 6 of this invention. It is principal part explanatory drawing which shows the open state of the parachute type anchor which concerns on Example 7 of this invention.

  Hereinafter, the present invention will be described in more detail with reference to embodiments shown in the drawings.

FIG. 1 is an explanatory view of main parts showing a parachute anchor 100 according to a first embodiment of the present invention. 1A is a perspective view showing a state in which the arms are closed, and FIG. 1B is a perspective view showing a state in which the arms are folded and all the arms are radially opened.
The parachute anchor 100 has a base end portion pivotally attached to an anchor body 10 having a shaft extending in the vertical direction and a head as a mounting portion formed at the lower end portion of the shaft so as to be opened radially. The paper drain 20 which absorbs the moisture in the soil which anchors to the anchor main body 10 is comprised.
In this parachute anchor 100, as shown in FIG. 1 (b), the plurality of arms are linked to each other to be anchored in the soil, and are configured to be bent along the axial direction by a known link joint mechanism. An anchoring arm 1 composed of a pair of linked arms, and a support arm 2 having one end rotatably attached to the anchoring arm 1 and supporting the anchoring arm 1, and an anchor The main body 10 has a slider 4 that moves on the shaft 3 while freely supporting one end of the anchoring arm 1, a sub-slider 5 that moves on the shaft 3 while freely supporting one end of the support arm 2, and a slider. 4 and the spring 6 that connects the sub-slider 5 and the other end of the anchoring arm 1 can be freely rotated. A head 7 for supporting, and comprises a push plate 8 for receiving the rod to push the anchor body 10.

  In this parachute type anchor 100, the spring 6 is released from the compressed state and is ejected to push out the slider 4, so that the sub slider 5 moves (jumps) in the direction of the head 7 and compresses the anchoring arm 1. As a result, the anchoring arm 1 is bent into a “<” shape and all the arms are opened radially. The spring 6 in FIG. 1 (a) is in a compressed state, and therefore the anchoring arm 1 is in a state of being biased in the direction of folding in a “shape”. Although details will be described later with reference to FIG. 2, when the parachute anchor 100 is inserted into the hollow pipe (cylindrical casing), pushed by the rod, and exits the hollow pipe, the spring 6 The anchoring arm 1 is bent in a "<" shape by the elastic force of the above, and all the arms are opened radially to provide resistance in the drawing direction (anchoring).

FIG. 2 is an explanatory diagram showing a ground improvement construction method using the parachute anchor 100 according to the first embodiment of the present invention. The main part is shown in time series from FIG. 2 (a) to FIG. 2 (d).
First, as shown in FIG. 2 (a), the hollow pipe 11 is inserted into an excavation hole drilled in magnetic exploration. Here, the hollow pipe 11 is again used as a guide for passing the magnetic sensor in the magnetic exploration (a stainless steel casing having no magnetism), but the parachute anchor 100 to which the paper drain 20 is attached is used. There is no particular limitation on the type of the hollow pipe as long as it has an inner diameter that can pass through the inside. However, in this embodiment, the stainless steel casing driven for magnetic exploration is used as it is as a casing for paper drain placement without being pulled out after magnetic exploration.

  Further, in this ground improvement construction method, as shown in FIG. 2 (a), the depth required for anchoring the hollow pipe 11 in advance is adjusted so that all the arms of the parachute anchor 100 penetrating the hollow pipe 11 can be opened. It is necessary to pull up and form a cavity below the outlet of the hollow pipe 11.

  Next, the parachute anchor 100 to which the paper drain 20 is attached is inserted into the hollow pipe 11, and the parachute anchor 100 is pushed vertically downward by the push rod 12.

  Next, the anchor body 10 is further pushed vertically downward by the push rod 12 until the parachute anchor 100 is pushed out of the hollow pipe 11.

  When the anchoring arm 1 of the parachute anchor 100 is opened, the hollow pipe 11 and the push rod 12 are pulled out, and the laying of the paper drain 20 is completed.

  In the above method, the parachute anchor 100 to which the paper drain 20 is attached by the hollow pipe 11 and the push rod 12 is sent out to a necessary depth by using the drilling hole bored in the magnetic exploration, and the anchoring arm 1 is spring-loaded there. 6 is a so-called casing driving method (jump type) that opens and anchors radially by the elastic force of 6. According to this method, since the boring for laying the paper drain 20 is not required, the magnetic exploration and the ground improvement can be performed by one boring.

FIG. 3 is a main part explanatory view showing a parachute anchor 200 according to a second embodiment of the present invention. 3A is a perspective view showing a state in which the arm is closed, and FIG. 3B is a perspective view showing a state in which the arm is radially opened.
The parachute anchor 200 is a mechanism obtained by removing the spring 6 from the parachute anchor 100. Accordingly, since the anchoring arm 1 cannot be automatically opened radially, a load acting on the anchor main body 30 (a mechanism in which the spring 6 is removed from the anchor main body 10) so that the anchoring arm 1 is opened is separately provided from the outside. Need to add. In this parachute anchor 200, the paper drain 20 is attached to the parachute anchor 200, and the paper drain 20 is pulled vertically upward to open the anchoring arm 1 against the earth pressure when the anchor body 30 resists the excavation hole. It is used as a load.

FIG. 4 is an explanatory view showing a ground improvement construction method using the parachute anchor 200 according to the second embodiment of the present invention. The main part is shown in time series from FIG. 4 (a) to FIG. 4 (d).
First, as shown in FIG. 4A, the hollow pipe 11 is inserted into the excavation hole drilled in the magnetic exploration. In addition, the hollow pipe 11 in a present Example is used as a paper drain casting casing as it is, without pulling out the stainless steel casing driven in for magnetic exploration after magnetic exploration. Also, in this ground improvement construction method, as in the ground improvement construction method according to the first embodiment, the anchoring arm 1 of the parachute anchor 200 penetrating the hollow pipe 11 can be opened in advance as shown in FIG. It is necessary to raise the hollow pipe 11 to a necessary depth for anchoring as shown in FIG.

  Next, the parachute anchor 200 to which the paper drain 20 is attached is inserted into the hollow pipe 11, and the parachute anchor 200 is pushed vertically downward by the push rod 12.

  Next, the anchor body 30 is further pushed vertically downward by the push rod 12 until the parachute anchor 200 is pushed out of the hollow pipe 11. When the parachute anchor 200 is pushed out from the hollow pipe 11, the hollow pipe 11 and the push rod 12 are pulled out from the excavation hole.

  The paper drain 20 is pulled vertically upward, and the anchoring arm 1 is opened radially to perform anchoring.

  In the above method, the process until the parachute anchor 200 to which the paper drain 20 is attached by the hollow pipe 11 and the push rod 12 is sent out to the required depth using the borehole drilled in the magnetic exploration is the parachute type. Although it is common to the ground improvement construction method using the anchor 100, as the load for opening the anchoring arm 1, the earth pressure when the anchor body 30 resists the excavation hole by pulling the paper drain 20 vertically upward is used. The point is different. This construction method is a so-called casing driving method (normal type) in contrast to the casing driving method (jump type). This method also eliminates the need for boring for laying the paper drain 20 in the same manner as the casing placing method (jump type), so that magnetic exploration and ground improvement can be performed by one boring.

FIG. 5 is an explanatory view of main parts showing a parachute anchor 300 according to a third embodiment of the present invention. 5A is a perspective view showing a state in which the arm is closed, and FIG. 5B is an explanatory view showing an uneven fitting state around the lock pin 41. FIG.
The parachute anchor 300 is a mechanism in which an anchor lock 40 and a press cup 50 are added to the parachute anchor 100. The anchor lock 40 is a restraining ring that prevents the anchoring arm 1 from automatically opening. As shown in the figure, the half ring of the convex contact and the half ring of the concave contact are coupled by a hinge mechanism, and the concave and convex contact is fixed by a lock pin 41. The press cup 50 is a pressure receiver that is a rod-like long-axis object that presses the anchor body 10 under pressure. Therefore, the hollow pipe 11 is not used when the parachute anchor 300 is pushed to the required depth. In other words, the anchoring arm 1 is stored in the axial direction in advance by the anchor lock 40, and the anchor main body 10 that is in a vertically long state is fed to the required depth while forcibly passing the excavation hole by applying pressure with a long shaft object.

FIG. 6 is an explanatory diagram showing a ground improvement construction method using the parachute anchor 300 according to the third embodiment of the present invention. The main parts are shown in chronological order from FIG. 6 (a) to FIG. 6 (d).
First, as shown in FIG. 6 (a), the parachute anchor 300 to which the paper drain 20 is attached is inserted into the drilling hole drilled in the magnetic exploration. The casing 13 applies pressure to the parachute anchor 300 and pushes it into the borehole.

  Next, when the parachute anchor 300 reaches the required depth, the casing 13 is pulled out from the excavation hole vertically upward.

  Next, the wire 42 for pulling out the lock pin 41 is pulled vertically upward, and the lock pin 41 is pulled from the anchor lock 40 to release the lock.

  When the anchoring arm 1 of the parachute anchor 300 is opened, the wire 42 is pulled out from the excavation hole, and the laying of the paper drain 20 is completed.

  In the above method, the parachute anchor 300 to which the paper drain 20 is attached by the casing 13 is sent out to the required depth using the borehole drilled in the magnetic exploration, and the wire 42 is pulled there to pull the lock pin 41 from the anchor lock 40. This is a so-called direct driving method (jump type) in which the anchoring arm 1 is radially opened by the elastic force of the spring 6 and anchored. This method also eliminates the need for boring for laying the paper drain 20 in the same manner as the casing placing method, so that magnetic exploration and ground improvement can be performed by one boring.

FIG. 7 is a main part explanatory view showing a parachute anchor 400 according to a fourth embodiment of the present invention.
The parachute anchor 400 is a mechanism obtained by removing the spring 6 from the parachute anchor 300. Therefore, since the anchoring arm 1 cannot be automatically opened radially, it is necessary to separately apply a load acting on the anchor main body 30 so that the anchoring arm 1 is opened. As with the parachute anchor 200, the parachute anchor 400 also uses the earth pressure when the anchor body 30 resists the excavation hole as a load for opening the anchoring arm 1 by pulling the paper drain 20 vertically upward. ing.

FIG. 8 is an explanatory view showing a ground improvement construction method using a parachute anchor 400 according to Example 4 of the present invention. The main part is shown in time series from FIG. 8 (a) to FIG. 8 (d).
First, as shown in FIG. 8 (a), the parachute anchor 400 to which the paper drain 20 is attached is inserted into a drilling hole drilled in magnetic exploration. The casing 13 applies pressure to the parachute anchor 400 and pushes it into the borehole.

  Next, when the parachute anchor 400 reaches the required depth, the casing 13 is pulled out from the excavation hole vertically upward.

  Next, the wire 42 for pulling out the lock pin 41 is pulled vertically upward, and the lock pin 41 is pulled from the anchor lock 40 to release the lock.

  The paper drain 20 is pulled vertically upward, the anchoring arm 1 is opened and anchored in the soil, and the installation of the paper drain 20 is completed.

In the above-described method, pressure is applied to the parachute anchor 400 to which the paper drain 20 is attached by the casing 13 using the borehole drilled in the magnetic exploration, and the parachute anchor 400 is pulled to the required depth, whereupon the wire 42 is pulled and the anchor lock 40 is pulled. Pulling out the lock pin 41 from the top, and further pulling the paper drain 20 vertically upward, the direct placement method using the earth pressure when the anchor body 30 resists the excavation hole as a load for opening the anchoring arm 1 (normal type) It is.
This method also eliminates the need for boring for laying the paper drain 20 in the same manner as the casing placing method and the direct placing method (jump type), so that magnetic exploration and ground improvement are performed by one boring. Will be able to.

FIG. 9 is an explanatory diagram showing a ground state after the paper drain 20 is laid.
As time passes, the ground collapses, and the paper drain 20 sucks up moisture in the ground, drains the moisture in the ground vertically, and releases it to the surface. When the paper drain 20 continues to release moisture, the ground is consolidated and the strength increases.

FIG. 10 is a flowchart showing the procedure of the magnetic exploration (unexploded bomb investigation) and ground improvement simultaneous construction of the present invention using the parachute anchor.
Here, as a construction method for laying the paper drain, a so-called casing driving method (jump type or normal type) using the parachute anchor 100 or the parachute anchor 200 is used.
First, the explosive burial depth and ground improvement depth are calculated in advance by soil investigation, and the position of the exploration hole for boring the exploration hole is determined. This bored exploration hole is also used as a laying hole for laying a paper drain.
Next, the exploration hole position is excavated by rotary boring. Excavation to the required depth is performed in stages. That is, drilling is performed every 50 cm when a 50 kg bomb is assumed, or every 1 m when a 250 kg bomb is assumed, and excavating while confirming that there is no unexploded bomb under the hole. Further, the confirmation that there is no unexploded bullet is performed by inserting a cylindrical casing having no magnetic charge into the excavation hole, inserting a magnetic sensor therein, and the magnetic sensor sensing magnetism under the hole.
When it is confirmed that there are no unexploded shells under the excavation hole reaching the required depth (confirmation that there is no magnetic abnormality), the ground improvement construction method shown in FIG. Thus, a paper drain is laid. Then, after confirming the installation of the paper drain, the casing is pulled out from the installation hole, and the construction is completed.
Thus, according to this ground improvement construction method, magnetic exploration and ground improvement can be performed by one boring.

FIG. 13 is an explanatory diagram of relevant parts showing a parachute anchor 500 according to a fifth embodiment of the present invention.
Each of the parachute anchors 100 and 300 according to the first and third embodiments employs a mechanism that opens the anchoring arm 1 (anchor) radially around the shaft 3 by the elastic force of the spring 6. The parachute anchor 500 employs a mechanism that radially opens the anchor by the elastic force of rubber. Further, as the anchoring arm, a twisted blade 14 in which a longitudinal plate is twisted is adopted.
Therefore, the parachute anchor 500 is provided perpendicularly to the outer periphery of the sleeve 16 that receives the rubber 15 that radially opens the twisting blade 14 as the anchoring arm about the shaft 3. Are newly provided with a locking plate 17, a screw 18 and a nut 19 for attaching the torsion blade 14 to the locking plate 17, and a washer 21 for restraining the movement of the rubber 15 in the axial direction. .

  In this embodiment, the twisting blade 14 is twisted by twisting a vertically long plate about 90 ° in the axial direction. The torsion angle is not limited to 90 °, but is suitably determined within a range of 0 ° to 180 ° depending on the soil soil and the like on which the torsion blades 14 anchor. The number of torsion blades 14 is three in this embodiment, but is not limited to three, and is determined by the soil quality of the ground where the torsion blades 14 are anchored.

  As shown in FIG. 14, the torsion blade 14 is configured to be able to rotate with a screw 18 as a fulcrum. Therefore, the length of the screw 18 from the lower surface of the plate portion to the upper surface of the nut 19 is twisted so as to be larger than the total value of “the thickness of the locking plate 17” and “the thickness of the torsion blade 14”. The blades 14 are loosely fastened to the locking plate 17 by screws 18 and nuts 19 so as to be rotatable. The torsion blade 14 is in a state where the opening operation is restricted (closed state) by the hollow pipe 11 or the anchor lock 40 before anchoring into the ground.

  The rubber 15 is in a state of being compressed and deformed in the radial direction when the torsion blade 14 is closed. Therefore, when the restriction on the torsion blades 14 is released, the torsion blades 14 fall outwardly with the screw 18 as a fulcrum by the elastic force in the radial direction of the rubber 15, so that all the torsion blades 14 radiate around the shaft 3. It opens to give resistance to the pulling direction (anchoring).

  Locking beads 3a for locking the washer 21 are provided on the outer peripheral surface of the shaft 3 at a plurality of places, for example, two places.

  In addition, about the ground improvement construction method using this parachute type anchor 500, the parachute type anchor 500 with which the paper drain 20 was attached was inserted in the inside of the hollow pipe 11 similarly to the construction method shown in FIG. By pushing the parachute anchor 500 vertically downward by the push rod 12 and pushing it out from the hollow pipe 11, the torsion blades 14 open radially around the shaft 3 by the elastic force of the rubber 15 and anchor into the ground. The placement method (jump type) can be applied.

  Alternatively, as in the construction method shown in FIG. 5 of the third embodiment, the anchor lock 40 and the press cup 50 are further added to the parachute anchor 500 to which the paper drain 20 is attached, and the casing as shown in FIG. 13 pressurizes the parachute anchor 500 and pushes it into the borehole. When the parachute anchor 500 reaches the required depth, the wire 42 is pulled vertically upward, the lock pin 41 is pulled from the anchor lock 40 to release the lock, and the torsion blade 14 is centered on the shaft 3 by the elastic force of the rubber 15. Thus, it is possible to apply the direct placement method (jump type) in which the anchoring is performed radially in the open ground.

FIG. 15 is a main part explanatory view showing a parachute anchor 600 according to a sixth embodiment of the present invention.
The parachute anchor 600 is configured by removing the rubber 15, the locking bead 3 a and the washer 21 from the parachute anchor 500. In this case, similar to the parachute anchors 200 and 400 of the second and fourth embodiments, the earth pressure that the torsion blade 14 resists the excavation hole when the paper drain 20 is pulled in the vertical direction is used as a load for opening the torsion blade 14. ing.

  Therefore, also in the ground improvement construction method using the parachute anchor 600 to which the paper drain 20 is attached, the parachute anchor using the hollow pipe 11 and the push rod 12 is used in the same manner as the method shown in FIG. When the parachute anchor 600 reaches the required depth by pushing 600 into the ground, the torsion blade 14 resists the excavation hole by pulling out the hollow pipe 11 and the push rod 12 and pulling the paper drain 20 vertically upward. The casing casting method (normal type) in which the torsion blades 14 open radially around the shaft 3 and anchor in the ground can be applied by the earth pressure applied to the ground.

  Alternatively, similarly to the construction method shown in FIG. 8 of the fourth embodiment, the anchor lock 40 and the press cup 50 are further added to the parachute anchor 600 to which the paper drain 20 is attached, and the casing as shown in FIG. 13 pressurizes the parachute anchor 600 and pushes it into the borehole. When the parachute anchor 600 reaches the required depth, the casing 13 is pulled out, the wire 42 is pulled vertically upward, the lock pin 41 is pulled from the anchor lock 40 to release the lock, and the paper drain 20 is pulled vertically upward. Accordingly, the direct placement method (normal type) in which the torsion blades 14 open radially and anchor into the ground by the earth pressure received when the torsion blades 14 resist the excavation hole can be applied.

FIG. 16 is an explanatory view of a main part showing a parachute anchor 700 according to Example 7 of the present invention.
The parachute anchor 500 employs a mechanism that opens the torsion blades 14 (anchoring arms) radially around the shaft 3 by the elastic force of the rubber 15. A mechanism is employed in which the torsion blades 14 are opened radially by the elastic force around the shaft 3. Other configurations are the same as those of the parachute anchor 500.
The ground improvement construction method using the parachute anchor 700 to which the paper drain 20 is attached is also the same as the ground improvement construction method using the parachute anchor 500 to which the paper drain 20 is attached.

  In Examples 5 to 7, the preferred shape of the anchoring arm is a torsional blade. However, the anchoring arm is not necessarily limited to the shape of this example, and the anchor that provides resistance to the drawing direction such as a plate shape or a rod shape. Any ring arm shape may be used.

  In addition, any of the parachute anchors according to the first to seventh embodiments is used as a laying means for laying a paper drain in the ground by diverting an existing drilled hole, for example, a magnetic exploration hole. However, the present invention is not limited to this, and it is also possible to newly drill a borehole and use it as a fixing means (tethering means) for the structure. In this case, instead of the paper drain 20 according to the first embodiment to the seventh embodiment, a tether such as a cable (wire) or a rope is used, and the parachute anchor to which the tether is attached is the first to sixth embodiments. It will be anchored in the ground by a method similar to the construction method related to.

  The parachute anchor of the present invention is used as a fixing means for fixing signs and structures such as buoys at sea and in the sea, or as a fixing means for fixing materials such as ground improvement materials at sea and in the sea, or on land Can be suitably applied as a fixing means for fixing.

DESCRIPTION OF SYMBOLS 1 Anchoring arm 2 Support arm 3 Shaft 4 Slider 5 Sub slider 6 Spring 7 Head 8 Push plate 10 Anchor main body 11 Hollow pipe 12 Push rod 13 Casing 14 Torsion blade 15 Rubber 16 Sleeve 17 Locking plate 18 Screw 19 Nut 20 Paper drain 21 Washer 22 Mainspring spring 100,200,300,400,500,600,700 Parachute anchor

Claims (9)

  A parachute anchor for paper drain as an anchor lock that is driven through a hollow pipe to a predetermined depth in the ground and fixes the paper drain to the ground, and is provided with a shaft extending in the vertical direction. And a plurality of arms pivotally attached to the base end portion so as to open radially to the attachment portion formed at the lower end portion of the shaft, the anchor body has a paper drain attachment portion, The arm is held in a closed state in the pipe, and when the arm penetrates the hollow pipe, the arm is configured to radially open into the ground and provide resistance in the pulling direction. anchor.   A parachute anchor for a paper drain as an anchor lock that is driven to a predetermined depth in the ground and fixes the paper drain to the ground, an anchor main body having a shaft extending in a vertical direction, and a lower end of the shaft A plurality of arms pivotally attached to the base end so as to be able to open radially to a mounting portion formed in the portion, the anchor body has a paper drain mounting portion, and the arm is locked by a locking means Pre-locked and held in a closed state, and by releasing the lock, the arm is configured to automatically or manually open radially into the ground to provide resistance in the pulling direction. Parachute anchor.   The parachute anchor according to claim 1 or 2, wherein the arm is urged by an elastic body in a direction of radially opening to the lower end portion of the shaft.   The parachute anchor according to claim 3, wherein the elastic body is an elastic rubber attached to the shaft, and the arm is in a closed state by compressing and deforming the elastic rubber in a radial direction.   A parachute type anchor as an anchor lock that is driven through a hollow pipe to a predetermined depth in the ground to fix an object to be fixed in the ground, and includes an anchor body having a shaft extending in a vertical direction, The anchor body includes a plurality of arms pivotally attached to a mounting portion formed at a lower end portion of the shaft so that the base end portion can be opened radially, and the anchor body has a fixed object mounting portion, A parachute anchor that is held in a closed state in the pipe and is configured to radially open into the ground when the arm penetrates the hollow pipe to provide resistance in the pulling direction.   A parachute anchor as an anchor lock that is driven to a predetermined depth in the ground and fixes an object to be fixed in the ground, and is formed at an anchor body having a shaft extending in a vertical direction and a lower end portion of the shaft A plurality of arms pivotally attached to the base end portion so as to be able to open radially to the attached mounting portion, the anchor body has a fixed object mounting portion, and the arm is locked in advance by a locking means. The arm is configured to be held in a closed state, and by releasing the lock, the arm is automatically or manually opened radially in the ground to provide resistance in the pulling direction. Parachute anchor.   A ground improvement construction method using the parachute anchor according to any one of claims 1 to 4, wherein a paper drain that absorbs moisture in the soil is attached to the parachute anchor, and the excavation hole is tubular. Insert the casing, insert the anchor main body into the cylindrical casing, and then push the anchor main body out of the cylindrical casing while pushing the anchor main body with a rod, open the arms radially and open the paper drain A ground improvement construction method using a parachute anchor characterized by anchoring.   A ground improvement construction method using the parachute type anchor according to any one of claims 1 to 4, wherein a paper drain that absorbs moisture in the soil is attached to the parachute type anchor, and the arm is fixed to the ring. The anchor body is locked so that it cannot be opened in advance, and the anchor body is inserted into the excavation hole, and then pressed into the anchor body while applying pressure to the anchor body by a rod, and the arm is radially released by releasing the lock. A ground improvement construction method using a parachute anchor, which opens to anchor the paper drain.   The drilling hole is a boring hole for magnetic exploration, and the cylindrical casing is a non-magnetic cylindrical casing for magnetic exploration in a state of being placed in the excavation hole used in the magnetic exploration. The ground improvement construction method using a parachute anchor according to claim 7 or 8, wherein the excavation hole and the nonmagnetic cylindrical casing are also used for laying the paper drain.

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