JP2015017459A - Co-lifting prevention device and method of rebar cage - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a device and a method which can give forced force to a rebar cage 2 to always position at the center of the circle of a casing 1 or a porous wall 6 and can prevent the rebar cage 2 from being co-lifted induced by lifting up of the casing 1.SOLUTION: A pressure application spacer 5 is attached in substantially equal positions by plan view to a plurality of sites in the same horizontal surface of the rebar cage 2 suspended in the casing 1. The pressure application spacer 5 gives resilience in a direction toward a porous wall and a pressure application arm 53 which is in the tip end of the pressure application spacer 5 has an enough length to reach a drilled porous wall 6.

Description

  The present invention relates to an apparatus and a method for preventing re-coiling of reinforcing bars.

Various methods for constructing underground piles of large diameter reinforced concrete in the ground have been developed.
For example, a method in which a large-diameter steel pipe is cast in the ground as a casing, a steel bar is erected after excavating the inside, and concrete is cast by a tremy pipe.
In this construction method, the casing is gradually pulled up and collected as the concrete rises. At that time, there is a problem that the internal reinforcing bar is also raised, decentered, or inclined as the casing is raised.
When the reinforcing bar is eccentric or inclined, there is a problem that the cover thickness cannot be secured around the underground pile.

JP 2011-74592 A

A spacer as described in Patent Document 1 has also been developed as a method for preventing the co-up of the reinforcing bar due to the casing lifting as described above. However, such a spacer has the following problems. is there.
<1> Apart from the reinforcing bar rod, it is necessary to install various long members and pipe groups, and the structure and handling are complicated.
<2> As another method, a method of increasing the weight of the reinforcing bar to make the resistance of the joint rise has been developed. However, even with this method, it is difficult to prevent the eccentricity of the reinforcing bar.
<3> Thus, conventionally, no structure or method has been developed that solves both the problem of re-coiling and eccentricity of the rebar rods by pulling out the casing with a simple structure.

The apparatus for preventing co-up of rebar rods according to the present invention that solves the above-mentioned problem is that a large-diameter steel pipe is cast as a casing into the ground, and after excavating the inside, the rebar rod is suspended, and the tremy tube is used for concrete. The pressure spacers are attached to a plurality of locations on the same horizontal plane of the rebar rods suspended in the casing at substantially equal positions in plan view. It is characterized in that elasticity is applied in the direction of the drilled hole wall, and the pressure arm, which is a pressure member at the tip of the hole, has a length that reaches the drilled hole wall. .
Further, in the above-described apparatus, the rebar wrinkle prevention device according to the present invention has a plate body attached as a pressure plate to a pressure arm that is a pressure member of a pressure spacer, and the outer surface of the pressure plate is a casing. This is characterized in that it is configured as the same circular arc surface as the circular arc surface of the inner surface.
Furthermore, the method for preventing co-up of rebar rods according to the present invention is a method of placing a large-diameter steel pipe into the ground as a casing, digging up the inside of the steel rod, hanging the rebar rod, and placing concrete with a tremy tube, Pressing spacers are attached to a plurality of locations on the same horizontal plane of the rebar bar at almost equal positions in plan view. This pressing spacer gives elasticity toward the hole wall that has been drilled, and a pressing arm at the tip of the pressing spacer. Is a pressure spacer with a length that reaches the drilled hole wall, suspends a reinforcing bar rod with this pressure spacer attached inside the casing, and pressurizes the pressure arm that is the pressure member at the tip of the pressure spacer. It is characterized in that the inner surface of the casing and the hole wall after the casing is pulled out are brought into contact with each other to prevent the eccentricity of the reinforcing bar rod and the co-up of the reinforcing rod rod with the casing.

Since the apparatus and method for preventing co-up of reinforcing bar rods according to the present invention are as described above, the following effects can be obtained.
<1> Since pressure spacers with elasticity are attached in the direction of the hole wall drilled at multiple locations on the same horizontal plane of the reinforcing bar rod, the pressing spacers are evenly distributed radially with respect to the center of the reinforcing bar rod Gives an extruding force. Therefore, the position of the reinforcing bar rod is always located at the center of the casing, and it is not biased toward one side, so that the cover thickness of the reinforcing bar does not become insufficient.
<2> Further, since the pressure spacers that give elasticity toward the hole wall drilled at a plurality of locations are attached, the pressure spacer bites into the hole wall when the casing is pulled out. The biting resistance prevents the reinforcing bars from rising, and prevents the reinforcing bars from rising together due to the rising of the casing.

Explanatory drawing of the Example of the co-up prevention apparatus of the steel bar of this invention. Explanatory drawing of the other Example of a pressurization arm. Explanatory drawing of the co-up prevention method of a reinforcing rod. Explanatory drawing of the action | operation of a pressurization spacer.

  DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of a rebar wrinkle prevention apparatus and prevention method according to the present invention will be described below in detail with reference to the drawings.

<1> Precondition (Figure 3)
The apparatus and method for preventing the re-coiling of the rebar rod according to the present invention are as follows: a large-diameter steel pipe is placed in the ground as a casing 1, the inside of the rebar rod 2 is suspended after excavating the inside, and the concrete 4 is removed by the tremy tube 3. It is used for the construction method.
In this case, the present invention is not limited to the all casing 1 method in which the entire length of the hole is protected by the casing 1, but can also be adopted in a method in which the protective casing 1 is stood only in a part of the upper portion, such as a reverse circulation method.

<2> Reinforcing Bar Reinforcing Bar Reinforcing Bar 2 is a cylindrical casing assembled by a linear main reinforcing bar 21 arranged in the vertical direction and an annular distribution bar 22 arranged in the horizontal direction.
This reinforcing bar 2 is suspended inside the bentonite liquid filled in the drilling hole, and the bentonite liquid in the hole is replaced with concrete 4 to fill the ground pile and foundation pile of reinforced concrete 4. .

<3> Pressure spacer (Fig. 1)
Pressure spacers 5 are attached to a plurality of locations on the same horizontal plane of the reinforcing bar 2 suspended in the casing 1.
The pressurizing spacer 5 is a member that is integrally formed of one elastic material or one steel material, and includes a fixing portion 51, an elastic force generating portion 52, and a pressurizing arm 53.
The pressurizing spacer 5 of the present invention is provided separately from a spacer that is not given elasticity.

<3-1> Fixed part The fixed part 51 is one steel bar, and is arranged along the main reinforcement 21.
Then, the fixing portion 51 is fixed to the main muscle 21 by the fixing ring 54.
The fixed ring 54 is, for example, a ring that halves a cylindrical body, and can be integrated by a bolt.
When the half-divided cylinder is integrated into the cylinder with bolts, the pressure spacer 5 can be fixed to the main bar 21 by sandwiching the fixing portion 51 of the pressure spacer 5 between the main bar 21 and the main bar 21.
One end of the fixed portion 51 is continuous with an elastic force generating portion 52 described later.

<3-2> Elasticity Generating Part The elasticity generating part 52 is a part that imparts outward elasticity to the arm at the tip of the pressure spacer 5.
Here, outward refers to a direction from the reinforcing bar 2 toward the casing 1 or the wall hole 6 of the drilling hole.
In order to generate elasticity, for example, a steel material having high elasticity is wound around the distribution bar 22 so that it can be configured like a safety pin.
One end of the elastic force generating part 52 is continuous with a pressurizing arm 53 described later.

<3-3> Pressure Arm The pressure arm 53 is a pressure member at the tip of the pressure spacer 5.
The pressure arm 53 is, for example, a single rod-like body or plate, and is given elasticity toward the casing 1 or the wall hole 6 of the drilled hole. It is a member which contacts in a pressurized state.
Therefore, since the pressure arm 53 is too short to perform its function, the tip of the pressure arm 53 has a length that can reach the hole wall 6 that has been drilled. If the length reaches the hole wall 6, it naturally reaches the inner surface of the casing 1.

<3-4> Arrangement of pressurization spacers As described above, the plurality of pressurization spacers 5 are attached to a plurality of locations on the same horizontal plane of the rebar bar 2, but particularly in the circumference of the rebar bar 2 in a plan view. On the other hand, it is attached at a position that is almost equally divided.
That is, it means that it is not biased to one side in a plan view, and thus “substantially equally divided” does not mean an equally divided at a mathematically accurate angle.
Further, the pressure arms 53 are all the same or almost the same length.
Therefore, the plurality of pressurizing spacers 5 expand in the uniform radial direction from the center of the cylindrical reinforcing bar 2.
Further, the plurality of pressure spacers 5 are attached on the same horizontal plane at least near the lower end of the reinforcing bar 2, but are also attached to the intermediate position of the reinforcing bar 2 or further to the upper end of the reinforcing bar 2.

<4> Another embodiment of the pressure arm (FIG. 2)
It is also possible to attach a plate body wider than the pressure arm 53 to the pressure arm 53 which is a pressure member of the pressure spacer 5 and configure this as the pressure plate 55.
In this case, the outer surface of the pressure plate 55 is configured as an arc surface substantially the same as the arc surface of the inner surface of the casing 1 and the hole wall 6.
Here, substantially the same arc surface means that the same arc surface is not mathematically accurate.
Then, the pressure plate contacts the inner surface of the casing 1 or the inner surface of the hole wall 6 not as a line but as a “surface”, so that it can function more efficiently.

<5> Other Embodiments of Elasticity Generating Part It is also possible to form the elastic force generating part 52 in the form of a hollow coil without winding the elastic force generating part 52 around the distribution bar 22 as in the above-described example.
Alternatively, the steel material can be forcibly bent into a V shape like a hairpin without being wound around the distribution bar 22.

<6> Function of pressurizing spacer As described above, the reinforcing bar 2 of the present invention is pressed at a plurality of locations on the same horizontal plane at positions almost equally divided with respect to the circumference of the reinforcing bar 2 in plan view. A spacer 5 is attached.
The lengths of the pressure arms 53 are the same or substantially the same.
Therefore, each pressurizing arm 53 comes into contact with the casing 1 or the drilled hole wall 6 in a pressurized state.
For this purpose, the reinforcing bar 2 is always given a forcible force so as to be positioned at the center of the casing 1 or the hole wall 6 by the pressurizing arm 53 that is uniformly expanded radially from the center of the reinforcing bar 2.
Furthermore, after the casing 1 is pulled up, the pressurizing arm 53 comes into contact with the surface of the hole wall 6 in a pressurized state and bites in somewhat.
Therefore, it becomes a big resistance with respect to the joint rise of the rebar rod 2 induced by pulling up of the casing 1, and the joint rise of the reinforcement bar can be prevented.

<7> Construction Method Next, a method for preventing the joint of the reinforcing bar 2 according to the present invention will be described.

<8> Until rebar rod suspension As described above, a large-diameter steel pipe is placed in the ground as a casing 1 and excavated while being filled with bentonite. Since the construction method for placing the concrete 4 is publicly known, detailed description thereof is omitted.
However, in the method of the present invention, the reinforcing bar 2 with the pressure spacer 5 having the above-described structure is suspended at the position of the reinforcing bar 2.

<9> Placing of concrete A tremy tube 3 with its tip closed is hung at the center of a reinforcing bar 2 in a hole filled with bentonite.
And concrete 4 is thrown in from the upper end of the tremmy pipe 3.
The lid at the tip of the tremy tube 3 is released by the weight of the concrete 4, and is filled into the casing 1 by flowing out to the surroundings.
When the casing 1 is located only at the upper part and is not the all casing 1, the concrete 4 is filled in the hole wall 6 that has been drilled.
The tremy tube 3 is gradually pulled up in accordance with the placement height of the concrete 4 while taking care that its tip is always located in the concrete 4.

<10> Function of Pressure Spacer During Placing A plurality of pressure spacers 5 are arranged on the same horizontal surface of the reinforcing bar 2 at substantially equal positions in plan view.
Since the pressurizing arm 53 provides elasticity toward the hole wall 6, the tip of the pressurizing arm 53 is in contact with the inner surface of the casing 1 in a pressurized state.
When not the all casing 1, the tip of the pressure arm 53 is in contact with the hole wall 6 in a pressurized state.
Therefore, as described above, even in the concrete 4, a force that always restores the vertical center line continues to act on the cylindrical reinforcing bar 2.

<11> Pulling up the casing Since the casing 1 is expensive, it is gradually pulled out with the filling of the concrete 4 and finally collected.
The upward force of pulling out the casing 1 is transmitted to the reinforcing bar 2 through the concrete 4.
For this reason, conventionally, as described above, there has been a problem that the rebar bar 2 is raised together or is eccentric and cannot secure the cover thickness of the rebar.
However, in the method of the present invention, as described above, when the pressure arm 53 comes out of the casing 1, the pressure arm 53 is in contact with the surrounding hole wall 6 in a pressurized state and is slightly biting.
For this reason, the reinforcing bar 2 has a resistance against the rise, and the resistance prevents the reinforcing bar 2 from rising together.
Since the pressure spacer 5 is arranged not only near the lower end of the reinforcing bar 2 but also in the middle or upper part, the above-mentioned state continues to the end and the covering thickness of the reinforcing bar 2 is secured accurately. High-quality foundation piles and underground piles that do not raise can be completed.

1: Casing 2: Steel bar 3: Tremy tube 5: Pressurized spacer 6: Hole wall

Claims (3)

A steel pipe with a large diameter is cast into the ground as a casing, and after excavating the inside, a reinforcing bar is suspended and used for a construction method in which concrete is cast with a tremy pipe,
Pressurized spacers are attached to multiple locations on the same horizontal plane of the rebar rod suspended in the casing at almost equal positions in plan view.
This pressure spacer gives elasticity toward the drilled hole wall,
The pressure arm that is the pressure member at the tip is configured to have a length that reaches the drilled hole wall.
A device to prevent rebar wrinkles. The apparatus of claim 1.
The plate body is attached as a pressure plate to the pressure arm that is the pressure member of the pressure spacer,
The outer surface of this pressure plate is configured as the same arc surface as the arc surface of the inner surface of the casing,
A device to prevent rebar wrinkles. In the construction method in which a large diameter steel pipe is placed as a casing in the ground, after excavating the inside, a reinforcing bar is suspended, and concrete is placed by a tremy pipe.
Pressurized spacers are attached to multiple locations on the same horizontal surface of the rebar bar in almost equal positions in plan view.
This pressure spacer is a pressure spacer with a length that gives elasticity to the drilled hole wall, and the length of the pressure arm at the tip of the hole reaches the hole wall,
Suspend the reinforcing bar with this pressure spacer in the casing,
The pressure arm that is the pressure member at the tip of the pressure spacer is brought into contact with the inner surface of the casing and the hole wall after the casing is pulled out,
A method for preventing rebar rods from being lifted together by preventing eccentricity of the rebar rods and preventing the rebar rods from rising together with the casing.

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