JP3735600B2 - Concrete compaction method and apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method and an apparatus for vibrating and compacting cast concrete when placing concrete for lining in a tunnel, mainly for secondary lining.
In this specification, “placement” refers to filling mud concrete that has not been cured and cured between the mold and the inner wall surface of the tunnel.
[0002]
[Prior art]
Originally, for concrete laying for tunnel lining, mainly for secondary lining, the formwork for placing concrete was folded and transported forward after the concrete placement, It was done with a mobile formwork that was unfolded and installed, and the concrete was cast there.
[0003]
Concrete placement with this formwork can be done by placing concrete transport pipes from the openable inspection windows at many places on the formwork after installation at a predetermined position in the tunnel, or using a dedicated concrete placement opening. It was done by connecting a concrete transfer pipe.
[0004]
Moreover, in order to reinforce the cast concrete, a reinforcing material such as a reinforcing bar has been disposed in advance between the formwork and the inner wall surface of the tunnel.
[0005]
In addition, in order to improve the strength and durability of the concrete after curing and curing, a vibration tool is inserted and protruded from the same or another inspection window into the concrete immediately after placement, and the vibration is caused by the vibration of the vibration tool. The concrete was compacted to remove bubbles mixed in the concrete.
[0006]
This vibration tool is mainly provided with a vibration part at the end of the power cable. For this reason, the operator directly grips the power cable, opens the inspection window to protrude, and if necessary, the inspection window. The vibration part is inserted into the placed concrete and moved to the front, back, left and right and up and down (shaking), and the placed concrete is compacted by the vibration of the vibration part, and the compaction work is completed. Then, it was stored from the inspection window (see FIG. 5).
[0007]
In FIG. 5, 60 is a mold, 62 is an inspection window, 64 is a concrete placement port, 66 is a vibration tool, 68 is a power cord, 70 is concrete, 72 is a tunnel inner wall surface, 74 is a concrete conveyance pipe, and 76. Indicates an operator.
[0008]
For this reason, there has been the following problem in the compaction work of placing concrete manually by the operator.
[0009]
First, the operator grips the power cable of the vibration tool, and manually projects the vibration part of the vibration tool from each inspection window of the formwork, inserts it into the cast concrete, moves it up and down, left and right, The cast concrete was compacted by the vibration of the vibration part, and after the compaction work was completed, it was stored from the inspection window, so the vibration due to the vibration tool to the concrete was local and uneven, and compaction efficiency was not good It was.
[0010]
Secondly, when the vibrating tool is vibrated from the inspection window and stored, the vibrating part of the vibrating tool comes into contact with the outer peripheral edge of the protruding part of the inspection window, so that the vibrating part is rotated by the vibration, This turning force acts on the gripping worker more than necessary, and this turning force is transmitted to the power cable, and sometimes the power cable is disconnected from the socket, which hinders work.
[0011]
Thirdly, it is necessary for the operator to get out of the inspection window and perform the compacting work as necessary, and there is a danger, so the work must be done carefully, and the work should be done safely and in a short time. In addition to being unable to perform the process, it was a cause of process delay.
[0012]
Fourth, when concrete is placed near the inspection window during compaction work, the vibration tool is stored from the inspection window under work, this inspection window is closed, and moved to another inspection window. However, it is necessary to open the inspection window and project the vibration tool, and to vibrate the vicinity of the inspection window where the concrete has been placed, and vibrate the vicinity of the inspection window during compaction work from the same location. I couldn't.
[0013]
Fifth, the vibrating tool comes into contact with the outer peripheral surface of the mold during vibration, and mud concrete separates into moisture and concrete at the contact surface, which is a factor that decreases the strength and durability of the concrete after curing. It was.
[0014]
In view of the above-mentioned drawbacks, there have been devices (for example, see Patent Document 1) for causing the vibration tool to protrude from the inside of the mold frame to the outside, and devices (for example, see Patent Document 2) for moving the vibration tool to the outside of the mold frame.
[0015]
[Patent Document 1]
Japanese Patent No. 3278355 (page 3-4, FIGS. 1-6, 9)
[Patent Document 2]
Japanese Patent Laid-Open No. 2001-82087 (page 3-5, FIG. 1-7)
[0016]
Further, immediately after use, the placing concrete attached to the vibration tool and the power cord was manually removed.
[0017]
[Problems to be solved by the invention]
In Patent Document 1, the place where the placing concrete of the vibration tool is compacted is limited, and in Patent Document 2, it is necessary to move the vibration tool visually by the operator, and both control mechanisms move the vibration tool. Is indispensable, the number of components is large, and the cost has increased.
[0018]
Also, in both documents and the prior art, the compacting work of the placing concrete with the vibration tool for improving the strength and durability of the concrete was performed every time immediately after the concrete was placed. The concrete flowed to the end of the formwork and could not compact the entire cast concrete.
[0019]
In addition, a reinforcing material is disposed between the formwork and the inner wall surface of the tunnel, and the position of the vibration tool inserted into the cast concrete is not constant. The sex was not good.
[0020]
In addition, the vibration member collides with or comes into contact with the reinforcing material disposed between the mold and the tunnel inner wall surface, and the outer peripheral surface of the mold, generating unpleasant noise, lowering the adhesion between the reinforcing material and the cast concrete, and the reinforcing material. In addition to the loosening of the binding, the vibration tool may be damaged, and there is a problem in durability.
[0021]
In addition, it is necessary to manually remove the cast concrete adhering to the vibration tool and the power cord after use, which is troublesome.
[0022]
In view of the above drawbacks, the present invention provides a concrete compacting method and apparatus capable of compacting cast concrete easily and safely and efficiently, and also removing cast concrete that has adhered. It is the purpose.
[0023]
[Means for Solving the Problems]
The present invention relates to a process and an apparatus for placing concrete in a tunnel using a formwork, comprising a vibration part at the end of a long traction part, and the vibration member is disposed between the formwork and the inner wall surface of the tunnel. In addition, after the base end is attached to the hoisting mechanism and disposed along the length direction of the formwork, the concrete is placed between the formwork and the inner wall surface of the tunnel, or at the time of concrete placement. The vibrating member is vibrated, and the vibrating member is wound and fed through a winding mechanism, thereby moving along the length direction of the formwork and compacting the concrete, or , Characterized in that the tip of the vibration member is attached to another hoisting mechanism via a pulling material and tension is applied to the vibration member, or the tip of the vibration member is embedded in the existing concrete placing part Attached to the guide track member extended forward of the tunnel The vibration member is moved along the guide track member, or the cleaning mechanism is provided in the vicinity of the winding mechanism, so that the vibration member is attached to the vibration member at the time of winding by the winding mechanism. The cast concrete is washed and removed.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
The concrete compaction apparatus according to the present invention is mounted on a movable mold 16 for placing concrete 14 for lining, mainly secondary lining, in a tunnel 12. As shown in FIG. 1 and FIG. 2, it has the following configuration.
[0025]
A core member 24 is disposed over the entire length of the outer periphery of the vibration member 22 including the vibration unit 20 at the tip of the long traction unit 18.
[0026]
In this example, the vibrating member 22 is connected to a power source (not shown) via a long traction part 18 in which a connecting cable (not shown) is housed.
[0027]
Further, it is desirable that the traction portion 18 is made of a material excellent in weight reduction, handleability, and wear resistance.
[0028]
Further, the core member 24 is a wire, and two wires are arranged on both sides of the outer periphery of the vibration member 22.
[0029]
By disposing the core member 24 on the outer periphery of the vibration member 22, the strength and wear resistance of the vibration member 22 are improved. The traction portion 18 is not damaged even when contacting a reinforcing member (not shown) disposed between the traction member 26 and the structure, and the structure is suitable for traction.
[0030]
A plurality of vibrating members 22 are disposed between the mold 16 and the inner wall surface 26 of the tunnel along the length direction of the mold 16 with the base end attached to the hoisting mechanism 28.
[0031]
The tip of the vibration part 20 of each vibration member 22 is attached to another hoisting mechanism 32 in the mold 16 via a traction material 30.
[0032]
In this example, the hoisting mechanism 28 is an electric winch, and the hoisting mechanism 32 is a spring-type or electric-type reel.
[0033]
The pulling material 30 is a wire and is locked to a guide roller 36 fixed to a pre-concrete placing portion 34 on the lap side of the mold 16.
[0034]
Tension is applied to the vibration member 22 by each of the hoisting mechanisms 28 and 32, and the vibration member 22 is held at an intermediate portion of the placing concrete layer, so that the placement concrete can be vibrated uniformly. Collision (occurrence of unpleasant noise) or contact (occurrence of unpleasant noise), decrease in adhesion between the reinforcing material and the cast concrete, and reinforcement of the reinforcing member disposed between the formwork 16 and the inner wall surface 26 of the tunnel. (Binding loosening) can be prevented, and damage to the vibration member 22 can also be prevented, so that the strength and quality of the cast concrete are greatly improved.
[0035]
A cleaning mechanism 40 is provided between the form plate 16 and the end plate 38 that is brought close to the hoisting mechanism 28 outside the end side of the form frame 16.
[0036]
In this example, the cleaning mechanism 40 is a ring-type shower in which a small hole is drilled in the ring tube toward the center thereof, and is attached to the vibrating member 22, particularly the traction portion 18, when the lifting mechanism 28 is wound. The cast concrete 16 is removed by washing with water pressure (water).
[0037]
Further, a seepage preventing material (not shown) prevents the cast concrete from leaching out of the end plate 38 or into the form frame 16 at the insertion portion of the vibration member 22 of the end plate 38 and the insertion portion of the pulling member 30 of the form frame 16. Is omitted).
[0038]
In the figure, 42 is a stopper for fixing the core member 24 to the outer periphery of the vibration member 22, 44 is a concrete placing port, 46 is a concrete conveying pipe, 48 is a top plate portion of the mold 16, and 50 is an operator. 52 denotes a hopper, and 54 denotes a drain pipe.
[0039]
A method for compacting the concrete 14 for secondary lining placed between the mold 16, for example, the top plate portion 48 and the tunnel inner wall surface 26 using this apparatus will be described in detail below.
[0040]
First, the mold 16 is moved to a predetermined position in the tunnel 12.
[0041]
Next, the base end of the pulling portion 18 of the vibration member 22 is attached to the hoisting mechanism 28 on the outer side 38 of the formwork 16, and the pulling material 30 is attached to another hoisting mechanism 32 in the formwork 16. A plurality of vibration members 22 are arranged along the length direction of the mold 16 by attaching the tip of the vibration part 20 of the vibration member 22 via the front end.
[0042]
Next, the concrete 14 is placed between the mold 16 and the tunnel inner wall surface 26.
[0043]
At this time, the concrete 14 is sequentially placed between the formwork 16 and the tunnel inner wall surface 26 from each concrete placement port 44 of the formwork 16.
[0044]
Next, after completion of placing the concrete 14 between the mold 16 and the inner wall surface 26 of the tunnel, each vibration member 22 is vibrated and wound through the winding mechanism 28, whereby each vibration member 22. Are sequentially moved to the wife side (right side in FIG. 1) of the mold 16.
[0045]
At this time, since the tension is applied to the vibration member 22 by the hoisting mechanisms 28 and 32, the vibration member 22 is held in the intermediate portion of the concrete layer after the placement is completed. Since the compacted concrete does not flow, the entire cast concrete is uniformly vibrated and compacted, and the mold 16 of the vibration member 22, the mold 16 and the inner wall 26 of the tunnel It can prevent collision (occurrence of unpleasant noise) or contact (occurrence of unpleasant noise, decrease in adhesion between the reinforcing material and the cast concrete, loose binding of the reinforcing material) and vibration to the disposed reinforcing material, and vibration Since damage to the member 22 can also be prevented, the strength and quality of the cast concrete are greatly improved.
[0046]
Moreover, the vibrating member 22 can be moved in the length direction of the mold 16 by winding and unwinding from the wife side of the mold 16 via the winding mechanism 28. Accordingly, there is no work for moving the vibration member by opening and closing each inspection window each time.
[0047]
Further, since the core member 24 is disposed on the outer periphery of the vibration member 22, the strength and wear resistance of the vibration member 22 are improved, and at the time of winding and unwinding to the winding mechanism 28, and the mold 16 and the tunnel. Even when contacting a reinforcing material (not shown) disposed between the inner wall surface 26 and the traction portion 18 is not damaged, the handleability is improved.
[0048]
Further, by intermittently vibrating the vibrating portion 20 of the vibration member 22, the cast concrete 14 is not continuously vibrated for a long time, the concrete is not separated into moisture and concrete, and the strength of the cast concrete, The durability can be further improved.
[0049]
Further, if necessary, the vibrating member 22 is lifted and unwound through the hoisting mechanism 28 to reciprocate the vibrating member 22 above the top plate portion 48 of the mold 16 so that the entire placing concrete is moved several times. It can be vibrated and the compaction efficiency can be further improved.
[0050]
Further, after the vibration of the cast concrete is completed, the vibrating member 22 is wound outwardly by the hoisting mechanism 28 and then the pulling material 30 at the tip of the vibrating portion 20 of the vibrating member 22 is removed. Winding and storing in another hoisting mechanism 32 in the frame 16.
[0051]
Further, every time the vibration member 22 is wound by the winding mechanism 28, the wound concrete member 14, particularly the placement concrete 14 attached to the traction portion 18 is cleaned and removed by the cleaning mechanism 40.
[0052]
For this reason, the washing | cleaning operation | work which removes the cast concrete adhering immediately after use conventionally performed can be abbreviate | omitted.
[0053]
In this method of use, the process of compacting the cast concrete between the top plate portion 48 of the mold 16 and the tunnel inner wall surface 26 has been described. The concrete to be placed in between is also compacted in the same way as this method of use.
[0054]
As described above, according to the method and the apparatus of the present invention, the vibration member 22 with improved strength, wear resistance, and handleability can be used after the entire placement between the mold 16 and the tunnel inner wall surface 26 is completed. The installed concrete can be compacted simply, safely, uniformly and with high quality, and the cast concrete that has adhered can be removed by washing.
[0055]
3 and 4 show another example of the present apparatus.
[0056]
In this example, instead of attaching the tip of the vibration member 22 of the above example to another hoisting mechanism 32 via the traction member 30, the tip of the vibration member 22 is embedded in the existing concrete placing portion 34. The guide track member 56 extended to the front of the tunnel, for example, is attached to a wire, and the vibrating member 22 is moved along the guide track member 56.
[0057]
The extension end of the guide track member 56 in front of the tunnel is preferably tensioned by a lever block (registered trademark) (not shown).
[0058]
In the method of use of this example, the vibration member 22 is moved during concrete placement (in accordance with the amount of concrete placement) to vibrate and compact the placement concrete.
[0059]
For this reason, the effect of preventing collision or contact with the reinforcing member disposed between the mold 16 of the vibrating member 22 and the mold 16 and the tunnel inner wall surface 26 is slightly smaller than the above example. After the vibration of the installed concrete is completed, the vibrating member 22 is wound outwardly by the hoisting mechanism 28 and the tip of the vibrating portion 20 of the vibrating member 22 is simply removed from the guiding track member 56. Since it is buried in the concrete, it is not necessary to store it and this work can be omitted.
[0060]
The guide track member 56 embedded in the cast concrete serves as a reinforcing material.
[0061]
In both examples, the mold 16 can be freely folded.
[0062]
Further, the arrangement position of the core member 24 for making the vibration member 22 suitable for traction is the outer periphery of the vibration member 22, but may be inside the vibration member 22, and may be arranged both on the outer periphery and inside. It is obvious that other structures suitable for traction not depending on the core material may be adopted.
[0063]
In addition, a concrete sensor that detects the amount of concrete placed between the formwork 16 and the inner wall surface 26 of the tunnel is installed, and the concrete placement from the concrete placement port 44 is performed by detecting the completion of the concrete placement of the concrete sensor. By linking the stop, the vibration of the vibration member 22, the operation of each hoisting mechanism 28 (the movement of the vibration member 22 in the length direction of the mold 16), etc., the work is automated and the workability is further improved. Can be made.
[0064]
Moreover, although the vibration member 22 and the winding mechanisms 28 and 32 are plural, the number may be one, and the number of installation is not particularly limited.
[0065]
Further, although the hoisting mechanism 32 is installed in the mold 16, it may be installed on a scaffold outside the mold 16, and it is obvious that it is installed in other places.
[0066]
In addition, the traction member 30 is locked by a guide roller 36 fixed to the existing concrete placing portion 34 on the lap side, but it is obvious that the pulling member 30 is a locking means such as a pipe or a hook.
[0067]
Further, the traction material 30 attached to the hoisting mechanism 32 in the formwork 16 can be freely separated from the hoisting mechanism 32 after being cured and hardened, and embedded in the cast concrete.
[0068]
In addition, the concrete placement between the mold 16 and the tunnel inner wall surface 26 is from the concrete placement port 44, but the concrete transfer pipe 46 is projected from each inspection window (not shown) of the mold 16. It is obvious to cast concrete.
[0069]
Further, it is obvious that the compaction efficiency can be further improved by moving the vibrating member 22 provided with tension by the hoisting mechanisms 28 and 32 in the circumferential direction of the mold 16.
[0070]
The pulling portion 18 of the vibration member 22 is a connection cable, but it is free to use a rope, an endless chain, a narrow belt, or the like with the connection cable built therein.
[0071]
Moreover, although the traction material 30 and the guide track member 56 are wires, they can be freely used as a rope, an endless chain, a narrow belt, or the like.
[0072]
Further, although the tip of the vibration member 22 is attached to another hoisting mechanism 32 via the traction member 30, the tip of the vibration member 22 may be used as a free end without being attached to the hoisting mechanism 32. The work peculiar to the present invention can be performed easily and safely, and the effect of improving the strength, wear resistance, and handleability of the vibration member 22 can be sufficiently obtained.
[0073]
Further, the cleaning mechanism 40 is a ring-type shower and is used to clean and remove the cast concrete adhering to the vibration member 22 by water pressure (water). It is self-evident to employ other cleaning mechanisms.
[0074]
Even if the cleaning mechanism 40 is omitted, the work peculiar to the present invention can be performed easily and safely, and the effect of improving the strength, wear resistance, and handleability of the vibration member 22 can be sufficiently obtained.
[0075]
In addition, the method and apparatus of the present invention are not particularly limited in use, such as a substantially semicircular tunnel, a circular tunnel, such as a submarine tunnel, a sewer, and the like.
[0076]
【The invention's effect】
According to the concrete compaction method and apparatus of the present invention, a vibration part is provided at the distal end of a long traction part, and the vibration member is wound between the mold and the inner wall surface of the tunnel, and the proximal end thereof is a hoisting mechanism. And then placed along the length of the formwork, after the placement of the entire space between the formwork and the inner wall surface of the tunnel, or at the time of concrete placement, the cast concrete is used as a vibration member. In order to vibrate, move, and compact the vibration member by winding and unwinding the vibration member via the winding mechanism, the vibration member having improved strength, wear resistance, and handleability. The cast concrete can be compacted easily and safely, and without causing the compacted cast concrete to flow.
[0077]
In addition, by attaching the tip of the vibration member to another hoisting mechanism via a traction member and applying tension to the vibration member, the vibration member is held at an intermediate portion of the placement concrete layer after completion of placement. Since the compacted concrete does not flow, the entire cast concrete is uniformly vibrated and compacted, and the formwork, the formwork, and the tunnel inner wall surface. Collisions (occurrence of unpleasant noise) or contact (occurrence of unpleasant noise, reduced adhesion between the reinforcing material and the cast concrete, loose binding of the reinforcing material) can be prevented. Moreover, since the vibration member can be prevented from being damaged, the strength and quality of the cast concrete are greatly improved.
[0078]
Further, the tip of the vibration member is attached to a guide track member embedded in the existing concrete placement portion and extended forward of the tunnel, and the vibration member is moved along the guide track member, thereby placing the concrete. After the vibration is completed, the vibrating member is hoisted outward by the hoisting mechanism, and by simply removing the tip of the vibrating portion of the vibrating member from the guide track member, the guide track member is embedded in the cast concrete as it is. There is no need to store it and this work can be omitted, and the guide track member embedded in the cast concrete serves as a reinforcing material.
[0079]
In addition, by placing the cleaning mechanism close to the hoisting mechanism, it is possible to wash and remove the cast concrete adhering to the vibration member when the hoisting mechanism is hoisted. This eliminates the cleaning work to remove the slag, thus greatly improving the work efficiency.
[Brief description of the drawings]
FIG. 1 is an enlarged side view of a main part of a concrete compaction apparatus according to the present invention.
FIG. 2 is an enlarged front view of the main part of the same.
FIG. 3 is a side view of a main part showing another example.
FIG. 4 is an enlarged side view of the main part of the same.
FIG. 5 is an enlarged side view showing a conventional concrete compacting operation.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 12 Tunnel 14 Concrete 16 Formwork 18 Traction part 20 Vibration part 22 Vibration member 24 Core material 26 Tunnel inner wall surface 28,32 Lifting mechanism 30 Traction material 40 Cleaning mechanism 56 Guide track member

Claims (4)

An apparatus for pouring concrete (14) for lining using tunnel (12) the mold in (16), comprising includes a vibrating portion (20) at the distal end of the elongated traction unit (18) arranged core (24) on the outer periphery or / and inside the longitudinal entire area of the vibrating member (22), equipped with the vibration member (22), the proximal end of it to the winch mechanism (28), the mold Arranged along the length direction of the frame (16), the tip of the vibration member (22 ) is attached to another hoisting mechanism (32) via the traction material (30) , and the vibration member (22) Concrete compaction device characterized by imparting tension to In a device for placing concrete (14) for lining using a formwork (16) in a tunnel (12), a vibration part (20) is provided at the tip of a long traction part (18). A core member (24) is arranged on the entire circumference of the vibration member (22) and / or inside the longitudinal direction, and the vibration member (22) is attached to the hoisting mechanism (28) at its base end to form a frame. (16) placed along the lengthwise is disposed, by deploying the cleaning mechanism (40) in close proximity to the winch mechanism (28), when winch according winch mechanism (28), the vibration member ( A concrete compaction device characterized by washing and removing cast concrete adhering to 22) . Vibration of the tip of the vibrating member (22), is embedded in the already concrete portion (34) mounted on the guideway members by extending the tunnel front (56), and along with this guide track member (56) concrete compaction apparatus according to claim 1 or 2, wherein the moving member (22). In the concrete compaction method using the concrete compaction apparatus as described in any one of Claim 1 to 3 , a vibration part (20) is provided in the front-end | tip of a long traction part (18) , and this vibration member (22 ) Between the formwork (16) and the inner wall surface (26) of the tunnel , with its proximal end attached to the hoisting mechanism (28) and being arranged along the length of the formwork (16). After the concrete (14) is placed between the formwork (16) and the inner wall surface (26) of the tunnel , or when the concrete is placed , the vibrating member (22) is vibrated and the hoisting mechanism (28) winch vibration member (22) via, by unwinding, is moved along a longitudinal direction of the mold (16), concrete (14) to said the compacting of Turkey Nkurito compaction Way .

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