JP6626599B1 - Floor slab cutting device - Google Patents

Abstract

An object of the present invention is to provide a floor slab cutting device using a wire saw arranged in a direction along a joint boundary surface between a bridge girder and a concrete floor slab. Enables horizontal cutting of floor slabs and shortens the construction period. A wire saw (23) laid on a bridge girder (2) and arranged along a joint boundary surface between a concrete floor slab (3) and a bridge girder (2) constituting a road surface of a bridge (1), and the wire saw (23) is connected to the junction boundary. A plurality of pulleys 83 to 90 for guiding in a direction along a surface and driving the whole of the wire slab, and the entire wire saw cutting device 81 including the plurality of pulleys 83 to 90 together with the wire saw 23. Was placed below the concrete slab 3. [Selection diagram] FIG.

Description

  The present invention relates to a floor slab cutting device using a wire saw.

Patent Document 1 discloses a dismantling system for performing dismantling and removal work of a concrete slab laid on a bridge girder and constituting a road surface of a bridge in Patent Document 1, which is movable along an extending direction of the bridge. We proposed a new movable stage and a floor slab cutting device installed in the work space between the concrete floor slab and the part to be dismantled into blocks.
The floor slab cutting device is an endless wire saw that is continuously extended in the direction along the joint interface between the bridge girder and the concrete slab and in the width and thickness directions of the concrete slab. And a plurality of pulleys for guiding the vehicle in the traveling direction along the installation route and driving the vehicle to travel.

JP 2018-87418 A

The floor slab cutting device of Patent Literature 1 uses a wire saw to simultaneously cut a direction (horizontal direction) along a joint boundary surface between a bridge girder and a concrete slab, and a width direction and a thickness direction (vertical direction) of the concrete slab. However, it was not possible to prohibit the horizontal cutting operation of the bridge girder and the concrete slab as necessary during the vertical cutting of the concrete slab.
That is, depending on various conditions and conditions at the site, for example, it is conceivable to cut the bridge girder and the concrete slab in the horizontal direction after the concrete slab is cut in the vertical direction.

An object of the present invention is to provide a floor slab cutting apparatus using a wire saw that is continuously extended in a direction along a joint boundary surface between a bridge girder and a concrete slab and in a width direction and a thickness direction of the concrete slab. Accordingly, it is possible to prohibit the cutting operation in the direction along the joint boundary surface between the bridge girder and the concrete slab.
Another object of the present invention is to make it possible to prohibit a cutting operation in a direction along a width direction and a thickness direction of a concrete floor slab, if necessary.

In order to solve the above problems, the invention described in claim 1 is
A concrete floor slab laid on the bridge girder and constituting a road surface of the bridge, and a wire saw arranged in a direction along a joint boundary surface with the bridge girder,
A plurality of pulleys for guiding and driving the wire saw in a direction along the joining boundary surface,
An apparatus body that drives the wire saw to travel,
A floor slab cutting device comprising:
Whole wire saw cutting apparatus including said device main body and the wire saw and the previous SL plurality of pulleys, disposed below the said concrete slab,
The plurality of pulleys include a driven pulley disposed on the opposite side of the bridge girder from the apparatus main body .
According to a second aspect of the present invention, in the floor slab cutting device according to the first aspect,
The cutting direction of the joining boundary surface by the wire saw is along the length direction of the bridge girder,
The driven pulley is located forward of the apparatus main body in a cutting direction of the joining boundary surface by the wire saw.

According to the present invention, there is provided a floor slab cutting device using a wire saw arranged in a direction along a joint boundary surface between a bridge girder and a concrete floor slab, wherein a plurality of driving and driven pulleys are arranged below the concrete floor slab. The bridge girder and the concrete slab can be cut horizontally along the joint interface by the wire saw wound around the bridge.
Therefore, in the daytime, the entire wire saw cutting device, including the wire saw and its driving and driven pulleys, is placed under the concrete slab and the bridge girder and the concrete are placed under the concrete slab in a state where the vehicle passes without regulating the road. The floor slab can be cut in the horizontal direction, shortening the construction period.

It is a perspective view showing composition of one embodiment of a floor slab cutting device to which the present invention is applied. It is a side view which shows the outline of the dismantling system of a concrete slab. It is a top view which shows the outline of the dismantling system of a concrete slab. It is a top view which shows a telescopic scaffold. It is an expanded sectional view showing a dismantling system of a place where dismantling and removal work is performed. It is an expanded sectional view showing a dismantling system of a place where dismantling and removal work is performed. It is a perspective view showing the outline of a slab cutting device, and a concrete slab to be cut. It is a front view which shows a slab cutting device and a concrete slab to be cut. It is a top view which shows a slab cutting apparatus and a concrete slab to be cut. It is the elements on larger scale which show the driven pulley arrange | positioned around 1st bridge girder and peripheral structure. It is a front view which shows a floor slab cutting apparatus and the cut concrete slab. It is a side view which shows the outline of the dismantling system of a concrete slab. It is a schematic perspective view which shows the floor slab cutting device of Embodiment 2. It is a schematic perspective view which shows the floor slab cutting device of the modification 1. It is a schematic perspective view which shows the floor slab cutting device of the modification 2. It is a schematic perspective view which shows the floor slab cutting device of the modification 3. It is a schematic perspective view which shows the floor slab cutting device of the modification 4. It is the schematic plan view (a) and the schematic front view (b) which show the structure of a mobile factory. It is a vertical front view of the mobile factory of FIG. It is a schematic plan view which shows the floor slab cutting device of Embodiment 3. It is a vertical front view of the floor slab cutting device of FIG. It is a schematic plan view which shows the floor slab cutting device of the modification 5.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  However, the embodiments described below are provided with various technically preferable limits for carrying out the present invention, but the technical scope of the present invention is not limited to the following embodiments and illustrated examples. Absent.

First, in FIG. 2 showing the outline of a concrete floor slab demolition system to which the floor slab cutting device of the present invention is applied, reference numeral 1 denotes a bridge. The bridge 1 is, for example, a viaduct on which a railroad or a road is constructed, and the bridge 1 in the present embodiment indicates a viaduct on which a road is constructed.
The bridge 1 as a viaduct includes a plurality of bridge girders 2 laid between piers (not shown), and a concrete floor slab 3 laid on the plurality of bridge girders 2 and constituting a road surface of the bridge 1.
Although the bridge 1 in the present embodiment is a viaduct, the invention is not limited to this, and other types of bridges may be employed without departing from the spirit of the present invention.

On the side edge of the concrete floor slab 3, a concrete wall rail 4 is provided. The wall rail 4 is provided integrally with the concrete slab 3 and can be dismantled simultaneously with the concrete slab 3.
Further, the concrete floor slab 3 is formed by concrete casting when the bridge 1 is constructed so as to include a plurality of givels 2 a (for example, stud givels with heads) protruding from the upper surface of the bridge girder 2. . Therefore, the concrete floor slab 3 is in a state of being joined to the bridge girder 2 via the plurality of gibbles 2a. The surface where the bridge girder 2 and the concrete floor slab 3 are joined in this way is referred to as a joint boundary surface C1.

The concrete floor slab 3 constitutes the road surface of the bridge 1, and usually many vehicles pass through it. For this reason, bridge rehabilitation work is carried out in a timely manner as it becomes aging with the passage of years or is damaged by a traffic load larger than the design load.
Bridge repair work is often performed in a long section along the direction in which the bridge 1 extends, so the concrete slab 3 in the repair work section is divided into a plurality of areas (planned dismantling locations) and dismantled / removed. Work shall be performed.
In addition, such bridge rehabilitation work includes a case where all traffic of the bridge 1 is stopped and the concrete floor slab 3 is dismantled and removed at one time in a width direction of the bridge 1, and a case where a part of the bridge 1 is passed. There is a case in which only a part of the concrete floor slab 3 is dismantled / removed by stopping the operation, and the dismantling system of the present invention can cope with both cases.
In the present embodiment, a case will be described in which only a part of the bridge 1 is stopped and a part of the concrete floor slab 3 is dismantled / removed. However, all the traffic of the bridge 1 is stopped and the bridge 1 is stopped. The same operation process is performed when the concrete floor slab 3 is dismantled / removed all at once in the width direction.

The demolition system according to the present embodiment is for performing demolition and removal work of the concrete floor slab 3 in bridge repair work, and includes a movable stage 10, a floor slab cutting device 20, floor slab lifting means 30, and Dust means 40, power generation means 50, and control means are provided.
The concrete floor slab 3 is disassembled into a plurality of pieces by the dismantling system such that the concrete slab 3 can be loaded on the transport vehicle T (see FIG. 12). In addition, the part dismantled by the dismantling system is in a state in which the wall rail 4 is also included. Such a dismantled (or dismantled) portion of the concrete floor slab 3 is hereinafter referred to as a block 3a.

As shown in FIGS. 2 and 3, the movable stage 10 is equipped with the above-described units for dismantling and removing the concrete floor slab 3, and the direction in which the bridge 1 extends in a state where these units are mounted. , And includes a stage main body 11, legs 12, a protective work 13, a lower protective suspension scaffold 16, a protective fence 17, and a dust collector storage 18.
The movable stage 10 cuts the concrete floor slab 3 to separate the block 3a from the remaining portion, and then moves in the working direction (arrow Y) shown in FIGS. 2, 3, 9, and 12. It is moved and then placed where it will be dismantled and removed.

The stage main body 11 is formed in a rectangular frame shape that is long in the extending direction of the bridge 1 by a plurality of steel frames 11a arranged vertically and horizontally in a plan view. The bridge 12 is supported above the road surface of the bridge 1 (for example, at a height of about 2.5 m).
A fence 11b and a ramp 11c for moving up and down between the road surface of the bridge 1 and the stage main body 11 are provided at the periphery of the stage main body 11.
Further, as shown in FIG. 3, the stage main body 11 has an opening 11d formed by a plurality of steel frames 11a arranged vertically and horizontally and formed at a position located above a work space 10S described later. The stage main body 11 is made of, for example, a metal mesh such as expanded metal, and has a floor provided at a position other than the opening 11d.
Furthermore, of the plurality of steel frames 11a, two steel frames 11a, 11a located above a work space 10S described later are provided so as to protrude outside the bridge 1 (outside the wall rail 4).

As shown in FIGS. 2 and 3, the legs 12 are respectively provided on four lower surfaces of the plurality of steel frames 11a constituting the stage main body 11, which can support the stage main body 11 and the above-described units in a well-balanced manner. .
A wheel 12 a is provided at a lower end of each leg 12, and the stage main body 11 can be moved along the extending direction of the bridge 1.

As shown in FIGS. 2 to 6, the protective work 13 is connected to the stage main body 11 and located outside the bridge 1, and extends from the side of the concrete slab 3 cut by the slab cutting device 20 to the lower side. Are located. Since the protective work 13 is disposed from the side to the lower side of the concrete floor slab 3, it functions as a scaffold at the time of work and as a safety facility for the side and the lower side.
Such a protector 13 has an upper protector 14 and a lower protector 15, and the upper protector 14 and the lower protector 15 are connected via a rotating member 13a.

The upper protective work 14 is a framework structure formed of a plurality of metal materials, and is integrally formed with the steel frames 11a, 11a of the steel frame 11a constituting the stage main body 11, which protrude outside the bridge 1 described above. Are linked.
The rotating member 13a is provided at the center of the lower end of the upper protective member 14.

The lower protective member 15 is a skeleton structure formed of a plurality of metal materials, and is located below the concrete floor slab 3.
As shown in FIGS. 4 to 6, the lower protective member 15 includes a telescopic scaffold 15 a that is provided at a lower end of the lower protective work 15 and that expands and contracts in the horizontal direction. The lower protective member 15 is formed in a substantially L-shape in a side view by including a telescopic scaffold 15a. In addition, the telescopic scaffold 15a has a floor configured by a wire mesh such as expanded metal.
The rotating member 13a is provided at the center of the upper end of the lower protective member 15. The lower protective member 15 can be turned in the horizontal direction by the rotating member 13a.

The lower protective suspension scaffold 16 is disposed from the side of the concrete floor slab 3 to be dismantled / removed to the lower side, and is provided inside the protective work 13 by a suspension member such as a chain hooked on the bridge girder 2. It is provided so as to be located.
Since this lower protective hanging scaffold 16 is arranged from the side of the concrete floor slab 3 to the lower side, it functions as a scaffold at the time of work and also functions as a safety facility for the side and the lower side.

The work space 10S refers to a space between a portion (block 3a) of the concrete floor slab 3 to be dismantled in a block shape and the movable stage 10, and is located below an opening 11d formed in the stage main body 11. To position.
A protective fence 17 is provided around the work space 10S to prevent intrusion into the work space 10S and to suppress scattering of dust generated in the cutting operation of the floor slab cutting device 20. In addition, the protective fence 17 shall be provided in four circumferences of the work space 10S.

  The dust collector storage unit 18 is provided on the lower surface of the stage main body 11 and can store a plurality of dust collectors 40 described later. The dust collector storage section 18 is located at a position surrounded by the four legs 12 and adjacent to the work space 10S.

As shown in FIGS. 6 to 10, the floor slab cutting device 20 is installed in a work space 10 </ b> S between a portion (block 3 a) of the concrete floor slab 3 to be dismantled in a block shape and the movable stage 10. , For cutting the concrete floor slab 3 into blocks.
The floor slab cutting device 20 in the present embodiment is driven by the first wire saw cutting device 21, the second wire saw cutting device 22, and the first wire saw cutting device 21 and the second wire saw cutting device 22. According to the endless wire saw 23, various pulleys 210, 211, 212 built in the first wire saw cutting device 21, various pulleys 220, 221 built in the second wire saw cutting device 22, And a guide roller 25.
The first wire saw cutting device 21 is installed above the bridge girder 2 (hereinafter, first bridge girder 2A) located on the outermost side of the bridge 1, and the second wire saw cutting device 22 is located on the outermost side. It is installed above a bridge girder 2 (hereinafter referred to as a second bridge girder 2B) located one inner side of the first bridge girder 2A.

The wire saw 23 extends continuously in the direction along the joint boundary surface C1 between the bridge girder 2 (the first bridge girder 2A and the second bridge girder 2B) and the concrete slab 3, and in the width and thickness directions of the concrete slab 3. ing.
The plurality of pulleys 210, 211, 212, 220, and 221 incorporated in the first wire saw cutting device 21 and the second wire saw cutting device 22, and the plurality of driven pulleys 24 move the wire saw 23 along the extension path. This is for guiding the vehicle in the traveling direction and driving the vehicle for traveling.

The first wire saw cutting device 21 includes a driving pulley 210, a fixed pulley 211, and a moving pulley 212 as a plurality of built-in pulleys.
The plurality of pulleys 210, 211, and 212 are housed in the housing 21a. That is, the plurality of pulleys 210, 211, and 212 are in a state of being covered by the housing 21a.
Further, the first wire saw cutting device 21 is installed on a support 21b installed on a road surface.
The first wire saw cutting device 21 includes a plurality of built-in pulleys 210, 211, and 212, as well as a cooling device that cools the wire saw 23, and is necessary for dismantling and removing the concrete floor slab 3. It has various devices and functions.

The drive pulley 210 is configured to be attached to the drive devices 210a and 210b and to rotate, and is connected to a drive pulley 210 (hereinafter, referred to as a first drive pulley 210A) located on the wall rail 4 side and a center side of the bridge 1. Driving pulley 210 (hereinafter, referred to as a second driving pulley 210B).
The wire saw 23 is drawn out with the rotation of the first driving pulley 210A and the second driving pulley 210B, and runs at high speed.

The fixed pulley 211 is fixed at a position between the first driving pulley 210A and the second driving pulley 210B and is rotatable, a second fixed pulley 211B, and a third fixed pulley 211C. And consisting of
The wire saw 23 is wound around the fixed pulleys 211A, 211B, and 211C alternately with the movable pulley 212, and functions effectively when tension is applied to the wire saw 23 that relaxes as the cutting operation proceeds. I do.

The movable pulley 212 is movable (up and down) from a position between the first drive pulley 210A and the second drive pulley 210B and is rotatable, and a second movable pulley 212A. 212B.
The wire saw 23 is wound around the movable pulleys 212A and 212B alternately with the fixed pulley 211, and tension can be applied to the wire saw 23 by moving so as to increase the interval between the pulley 211 and the fixed pulley 211. .

The second wire saw cutting device 22 includes a driving pulley 220 and a fixed pulley 221 as a plurality of built-in pulleys.
The second wire saw cutting device 22 includes, in addition to the plurality of built-in pulleys as described above, a cooling device for cooling the wire saw 23, and various other devices necessary for dismantling and removing the concrete floor slab 3. Devices and functions.
It is assumed that the plurality of pulleys are housed in the housing 22a. That is, the plurality of pulleys are covered by the housing 22a.

  The drive pulley 220 is attached to the drive device 220a and is configured to rotate. The drive pulley 220 is movable in the vertical direction. That is, the drive pulley 220 can apply tension to the wire saw 23 by moving the wire saw 23 in a vertical direction as well as moving the wire saw 23 at high speed. The rotation speed of the drive pulley 220 is equal to the rotation speed of the first drive pulley 210A and the second drive pulley 210B in the first wire saw cutting device 21.

The fixed pulley 221 is fixed at a position close to the drive pulley 220 and is rotatable.
The wire saw 23 is wound around the fixed pulley 221 alternately with the movable pulley 212, and functions effectively when tension is applied to the wire saw 23 that relaxes as the cutting operation proceeds.

  As shown in FIGS. 7 to 10, the plurality of driven pulleys 24 move the second wire saw cutting device 22 from the first driven pulley 240 provided following the first driving pulley 210 </ b> A in the first wire saw cutting device 21. And a tenth driven pulley 249 provided in front of the second drive pulley 210B in the first wire saw cutting device 21 via the first drive unit.

The first driven pulley 240 is attached to the lower end of the first wire saw cutting device 21 via an attachment member 240a, and is located below the first driving pulley 210A in the first wire saw cutting device 21. I have.
The wire saw 23 fed from the first wire saw cutting device 21 is extended via the first driven pulley 240 to a state where the wire saw 23 continues to the upper end of the wall rail 4.

The second driven pulley 241 is arranged at a position where the second driven pulley wraps around the concrete floor slab 3 from the wall rail 4. The second driven pulley 241 is attached to the first bridge girder 2A via an attachment member 241a.
The wire saw 23 is extended so as to be wound around from above the second driven pulley 241 and to be fed downward.
By applying tension to the wire saw 23 wound around the first driven pulley 240 and the second driven pulley 241, a portion of the concrete floor slab 3 that is located outside the first bridge girder 2 </ b> A is cut. be able to.

The third driven pulley 242 is disposed below the second driven pulley 241 and closer to the first bridge girder 2A. The third driven pulley 242 is attached to the first bridge girder 2A via an attachment member 242a. The attachment member 242a is formed integrally with the attachment member 241a of the second driven pulley 241.
The wire saw 23 is extended so as to be wound around the lower side of the third driven pulley 242 and fed upward.

The fourth driven pulley 243 is disposed above the third driven pulley 242 and adjacent to the second driven pulley 241. Further, the fourth driven pulley 243 is arranged in a direction crossing the second driven pulley 241. Further, the fourth driven pulley 243 is attached to the first bridge girder 2A via an attachment member 243a. The mounting member 243a is integrally formed with the mounting member 241a of the second driven pulley 241 and the mounting member 242a of the third driven pulley 242.
The wire saw 23 is wound around the upper side of the fourth driven pulley 242 and extends so as to be horizontally fed out in the length direction of the first bridge girder 2A. The wire saw 23 unreeled from the fourth driven pulley 243 is extended in a state of being wound around the edge of the joint boundary surface C1 between the first bridge girder 2A located on the outermost side of the bridge 1 and the concrete floor slab 3. I have.

The fifth driven pulley 244 is provided on the inner side (the center side of the bridge 1) of the first bridge girder 2A located on the outermost side and on the inner side of the cut plane C2 in the thickness direction of the block 3a.
The wire saw 23 wound around the edge of the joint interface C1 between the first bridge girder 2A and the concrete floor slab 3 is wound around the fifth driven pulley 244. That is, by applying tension to the wire saw 23 wound around the fourth driven pulley 243 and the fifth driven pulley 244, the cutting operation at the joint boundary surface C1 between the first bridge girder 2A and the concrete floor slab 3 is performed. It can be carried out. At this time, the plurality of dowels 2a provided on the upper surface of the first bridge girder 2A can also be cut at the same time.
The wire saw 23 wound around the fifth driven pulley 244 extends so as to be fed out toward the second bridge girder 2B.

The sixth driven pulley 245 is provided at an intermediate point between the first bridge girder 2A and the second bridge girder 2B and at an intermediate point between the fifth driven pulley 244 and a seventh driven pulley 246 described later.
The wire saw 23 extends so as to be in contact with the upper side of the sixth driven pulley 245. That is, the sixth driven pulley 245 is provided at an intermediate point between the fifth driven pulley 244 and a seventh driven pulley 246 described later, and is provided to suppress the bending of the wire saw 23.

The seventh driven pulley 246 is provided at a position parallel to the fifth driven pulley 244 and on the first bridge girder 2A side of the second bridge girder 2B. That is, the seventh driven pulley 246 is positioned opposite to the fifth driven pulley 244.
The wire saw 23 extended from the fifth driven pulley 244 is wound around the seventh driven pulley 246 via the sixth driven pulley 245, and the wire saw 23 extended from the seventh driven pulley 246 is , The second bridge girder 2B and the concrete floor slab 3 are extended so as to be wound around the edge of the joint boundary surface C1.

The eighth driven pulley 247 is provided inside the second bridge girder 2B (on the center side of the bridge 1) and at a position aligned with the plane C2 to be cut in the thickness direction of the block 3a.
The wire saw 23 wound around the edge of the joint boundary surface C1 between the second bridge girder 2B and the concrete floor slab 3 is wound around the eighth driven pulley 247. That is, by applying tension to the wire saw 23 wound around the seventh driven pulley 246 and the eighth driven pulley 247, the cutting operation at the joint boundary surface C1 between the second bridge girder 2B and the concrete floor slab 3 is performed. It can be carried out. At this time, the plurality of dowels 2a provided on the upper surface of the second bridge girder 2B can be cut at the same time.
The wire saw 23 wound around the eighth driven pulley 247 extends so as to be fed out toward the second bridge girder 2B.

The ninth driven pulley 248 is attached to the lower end of the second wire saw cutting device 22 via an attachment member 248a, and the core line cut portion 3c on the second bridge girder 2B side formed on the concrete floor slab 3. (Described later). Further, the ninth driven pulley 248 is arranged at a position and a direction in which the wire saw 23 can be extended along the cut plane C2 in the thickness direction of the block 3a.
The wire saw 23 is wound around a lower side of the ninth driven pulley 248, and extends so as to be fed upward. The wire saw 23 extended upward is wound around a driving pulley 220 built in the second wire saw cutting device 22.

The wire saw 23 extended from the ninth driven pulley 248 is wound around the drive pulley 220 of the second wire saw cutting device 22 located above the ninth driven pulley 248.
The wire saw 23 fed from the drive pulley 220 is wound around a fixed pulley 221 of the second wire saw cutting device 22.
The wire saw 23 pulled out from the fixed pulley 221 exits from the lower end of the second wire saw cutting device 22, and removes the lower surface of the portion of the concrete floor slab 3 located between the first bridge girder 2A and the second bridge girder 2B. It passes through a core line cut portion 3b (described later) (to be described later) on the first bridge girder 2A side formed on the concrete floor slab 3, and is wound around the tenth driven pulley 249.

The tenth driven pulley 249 is attached to the lower end of the first wire saw cutting device 21 via an attachment member 249a, and is located below the second drive pulley 210B in the first wire saw cutting device 21. I have.
The wire saw 23 fed from the tenth driven pulley 249 is wound around the second driving pulley 210B in the first wire saw cutting device 21.

Then, the wire saw 23 fed from the second driving pulley 210B is alternately wound around each fixed pulley 211 (211A, 211B, 211C) and each movable pulley 212 (212A, 212B) in the first wire saw cutting device 21. And reaches the first drive pulley 210A.
Since the wire saw 23 is endless, the concrete floor slab 3 can be cut by traveling along the above-described extending route.
Since the wire saw 23 relaxes as the cutting operation proceeds, each of the moving pulleys 212 (212A, 212B) in the first wire saw cutting device 21 and the driving pulley 220 in the second wire saw cutting device 22 are operated and moved as appropriate. Thus, tension is applied to the wire saw 23.

As shown in FIG. 9 and FIG. 10, the guide roller 25 has a rotating shaft along both side edges at the upper end portions of both the first bridge girder 2A and the second bridge girder 2B, and the first bridge girder 2A and the second bridge girder. The wire saw 23 is disposed so as to be in contact with the lower surface of the wire saw 23 protruding outside of both side edges at both upper ends of the wire saw 23. Such a guide roller 25 is configured to be rotatable around an axis in accordance with the travel of the wire saw 23.
That is, the guide roller 25 includes the wire saw 23 wound around the fourth driven pulley 243 and the fifth driven pulley 244 to cut the joint boundary surface C1 between the first bridge girder 2A and the concrete floor slab 3, The wire saw 23 is wound around the seventh driven pulley 246 and the eighth driven pulley 247 in order to cut the joint interface C1 between the second bridge girder 2B and the concrete floor slab 3, while suppressing the bending of the wire saw 23. This is for guiding the running of the vehicle.
The fourth driven pulley 243 and the fifth driven pulley 244 are horizontally separated from the upper end of the first bridge girder 2A, and the seventh driven pulley 246 and the eighth driven pulley 247 are horizontally separated from the upper end of the second bridge girder 2B. Are separated from each other. Therefore, the wire saw 23 wound around each of the pulleys 243, 244, 246, 247 is opened in a “C” shape toward the respective pulleys 243, 244, 246, 247. In addition, as the cutting operation proceeds, the wire saw 23 gradually approaches each of the pulleys 243, 244, 246, and 247. Therefore, a portion of the wire saw 23 where bending is to be suppressed gradually changes as the cutting operation proceeds. . The guide roller 25 is formed to be long to cope with this, and even if the bending position of the wire saw 23 gradually changes with the progress of the cutting operation, the bending of the wire saw 23 is more reliably suppressed. The traveling of the wire saw 23 can be guided while performing.
The guide roller 25 includes a first guide roller 25A and a second guide roller 25B along the side edges at the upper end of the first bridge girder 2A, and a third guide roller 25C along the side edges at the upper end of the second bridge girder 2B. And a fourth guide roller 25D.
The guide rollers 25A, 25B, 25C, 25D are fixed to the first bridge girder 2A and the second bridge girder 2B via the support member 26.

Since the concrete slab 3 is laid on the first bridge girder 2A and the second bridge girder 2B, the concrete slab 3 from which the block 3a has been cut off by the slab cutting device 20 is connected to the first bridge girder 2A and the second bridge girder 2A. There will be places that do not appear on any of the two bridge girders 2B.
In order to reliably support the concrete floor slab 3 even when such a location occurs, the second bridge girder 2B is provided with a reinforcing vertical girder 27 via a diagonal member 27a as shown in FIG. ing. The reinforcing girder 27 is provided in advance along a place where the concrete floor slab 3 is dismantled / removed. In addition, the installation work of the reinforcing stringer 27 may be performed by using the protector 13 or the lower protective suspending scaffold 16 as a working scaffold after installing the protective guard 13 or the lower protective suspending scaffold 16.

The floor slab lifting means 30 is mounted on the movable stage 10 and lifts the block 3a of the concrete slab 3 separated from other parts by the floor slab cutting device 20. In the present embodiment, a jib crane is employed, and is fixed to the steel frames 11a so as to be positioned on a plurality of steel frames 11a constituting the stage main body 11.
The hook of the jib crane as the floor slab lifting means 30 can be inserted into the work space 10S from the opening 11d of the stage main body 11.
The floor slab lifting means 30 in the present embodiment employs a jib crane, but is not limited to this. That is, any crane that can be fixed to the stage body 11, can lift the block 3a, and can lift and turn the block 3a can be used.

The dust collecting means 40 is for sucking dust generated when the concrete slab 3 is cut by the slab cutting device 20, and includes a plurality of dust collectors 40.
The plurality of dust collectors 40 are stored in the dust collector storage section 18 provided on the lower surface of the stage main body 11 as described above. Further, the plurality of dust collectors 40 include hoses (not shown), and the hoses are arranged particularly toward a location where dust is generated, such as in the work space 10S or the lower protective hanging scaffold 16.

  The power generation means 50 is a power supply device arranged on the upper surface of the stage main body 11 and adjacent to the floor slab lifting means 30. The power supply device 50 includes a power transmission cable (not shown), and is wired toward a device requiring power.

Although not shown, the control means is for controlling various means such as the floor slab cutting device 20 and the floor slab lifting means 30 which constitute the above dismantling system, and communicates with the various means. be able to. Accordingly, remote control of various means constituting the disassembly system can be performed, and safety during work can be improved.
In addition, cameras are installed around the movable stage 10 and the work site so that workers can remotely monitor the stage.

  Next, a method of dismantling the concrete floor slab 3 constituting the road surface of the bridge 1 by the dismantling system having the above configuration will be described.

In performing the repair work of the bridge 1, first, as shown in FIGS. 2 and 3, the lane is regulated in the bridge 1 using the load cone 5 and the regulation bar 6.
However, in the renovation work of the bridge 1 in the present embodiment, only a part of the bridge 1 is stopped and a part of the concrete slab 3 is dismantled / removed. When the concrete floor slab 3 is dismantled and removed at a stroke, the bridge 1 is closed.

Subsequently, the movable stage 10 is arranged so as to form a working space 10S between a part (block 3a) of the concrete floor slab 3 which is to be cut off from another part by the floor slab cutting device 20.
More specifically, the mobile stage 10 is assembled at the site of the renovation work surrounded by the load cone 5 and the regulation bar 6, and the jib crane 30, the plurality of dust collectors 40, and the power supply device 50 are connected to the mobile stage. 10
At the time of assembling the movable stage 10, assembling of the protective work 13 is also performed and the movable stage 10 is connected to the stage main body 11. Furthermore, the lower protective suspension scaffold 16 is also installed on the first bridge girder 2A and the second bridge girder 2B.

Subsequently, the reinforcing vertical girder 27 is installed on the second bridge girder 2B using the lower protection girder 15 or the lower protection hanger scaffold 16 in the protection girder 13. The reinforcing girder 27 is installed on the lower protective work 15 or the lower protective suspension scaffold 16 using, for example, a wire rope and a pulley.
During the installation work of the reinforcing girder 27 and the cutting work of the concrete floor slab 3, as shown in FIG. 4, FIG. 5, etc., the telescopic scaffold 15a of the lower protective work 15 is in a stretched state.

Subsequently, a portion of the concrete floor slab 3 that is included in the peripheral portion of the block 3a separated from other portions and that is located on the first bridge girder 2A and the second bridge girder 2B is a diamond bit (not shown). Drilling machine) (see FIG. 9 and the like).
As a result, core line cut portions 3b and 3c are formed at two locations on the first bridge girder 2A of the concrete floor slab 3, and core line cut portions 3d and 3e are formed at two locations on the second bridge girder 2B. Is formed.
In addition, only when the concrete floor slab 3 is cut first to separate the block 3a from other parts, the core line cut portion 3c on the first bridge girder 2A and the core line cut portion 3e on the second bridge girder 2B are separated. The space between the core line cut portion 3c and the outer end of the concrete floor slab 3 (including the wall rail 4) is cut by a cutting machine (not shown). As a result, a state is obtained in which the inter-core cut portion 3f is formed.
Further, a boundary portion between a portion where the renovation work is performed (removed portion) and a portion on the center side of the bridge 1 (remaining portion) is extended by the cutting machine (not shown) in the extending direction of the bridge 1 (renovation work is performed). (Extending direction of the portion: direction of arrow Y). As a result, the boundary cut portion 3g is formed.
In addition, the core line cut portions 3b to 3e and the cut portion between cores 3f are formed so as to penetrate the concrete floor slab 3 in the thickness direction.
The end of the core line cut portions 3d and 3e located on the second bridge girder 2B on the center side of the bridge 1 corresponds to the end of the removed block 3a on the center side of the bridge 1. Similarly, the boundary cut portion 3g corresponds to the central side of the bridge 1 in the removed block 3a.

  Subsequently, the guide rollers 25 (25A, 25B, 25C, 25D) are arranged along both side edges at the upper ends of both the first bridge girder 2A and the second bridge girder 2B. At this time, the rotation axis of each guide roller 25 (25A, 25B, 25C, 25D) is also along the both side edges at the upper end of both the first bridge girder 2A and the second bridge girder 2B.

Subsequently, as shown in FIG. 6 and the like, the first wire saw cutting device 21 and the second wire saw cutting device 22 are installed and fixed in the work space 10S. The first wire saw cutting device 21 is installed on the concrete floor slab 3 via the support 21b.
Further, the wire saw 23 is continuously extended in the direction along the joint boundary surface C1 between the first bridge girder 2A and the second bridge girder 2B and the concrete slab 3, and in the width direction and the thickness direction of the concrete slab 3.
That is, the driven pulleys 240 to 249 are arranged at predetermined positions and orientations. Then, the endless wire saw 23 is connected to each of the pulleys 210, 211, 212 built in the first wire saw cutting device 21, each pulley 220, 221 built in the second wire saw cutting device 22, and each driven Wrap around pulleys 240-249.
At this time, the wire saw 23 is also hooked on the upper end of the wall section 4 and is also passed through the core line cut portions 3b to 3e.
The wire saw 23 is in contact with each of the guide rollers 25 (25A, 25B, 25C, 25D) arranged along both side edges at the upper end portions of both the first bridge girder 2A and the second bridge girder 2B.

Subsequently, the protective fence 17 is installed on the outer periphery of the work space 10S.
Furthermore, hoses (not shown) extending from the plurality of dust collectors 40 are arranged toward a location where dust is particularly generated, such as in the work space 10S or the lower protective hanging scaffold 16, and other necessary locations.
Further, a sheet cover for suppressing the scattering of dust is appropriately provided in a portion where the scattering of dust is expected in the cutting range.

Subsequently, the drive pulleys 210A, 210B, 220 of the first wire saw cutting device 21 and the second wire saw cutting device 22 are rotated to drive the wire saw 23 to travel along the extending direction. Thereby, the cutting work of the concrete floor slab 3 is started.
As the cutting operation progresses, the wire saw 23 relaxes, and as shown in FIG. 7, the moving pulleys 212 </ b> A and 212 </ b> B incorporated in the first wire saw cutting device 21 and the driving pulley 220 in the second wire saw cutting device 22. The cutting work is performed while moving the slab upward to maintain the tension enough to cut the concrete floor slab 3.
While the wire saw 23 is running, the wire saw 23 is cooled by a cooling device (not shown) built in the first wire saw cutting device 21 and the second wire saw cutting device 22 to generate heat of the wire saw 23. Suppress.

By driving and driving the wire saw 23 in this way, the concrete floor slab 3 can be cut and disassembled into blocks. That is, as shown in FIG. 11, the block 3a can be separated from other portions of the concrete floor slab 3.
While the concrete slab 3 is being cut by the slab cutting device 20, a part (block 3a) to be cut off from other parts is suspended and supported by the jib crane 30.
After the block 3a is cut off, the first wire saw cutting device 21, the second wire saw cutting device 22, the wire saw 23, and the driven pulleys 240 to 249 are removed. The removed devices are transported to the next scheduled dismantling location. At this time, each device or the like may be carried on an empty space on the movable stage 10 by using a jib crane 30 or the like.

The block 3a separated from the other parts is lifted by the jib crane 30 and mounted on the transport vehicle T as shown in FIG.
When the block 3a is large enough to pass through the opening 11d of the stage body 11, the block 3a is lifted upward by passing through the opening 11d by the jib crane 30.
On the other hand, when the block 3a has a size that cannot pass through the opening 11d, the movable stage 10 is once moved in the working direction while being lifted to a height that remains in the work space 10S, and moved to the next scheduled dismantling position. Block 3a is temporarily placed. Subsequently, the movable stage 10 is further moved in the working direction, and the block 3a is moved out of the range of the working space 10S, and then lifted by the jib crane 30 and mounted on the transport vehicle T. Then, the block 3a is carried out by the transport vehicle T.

After the block 3a is mounted on the transport vehicle T, cleaning of the first bridge girder 2A and the second bridge girder 2B where the block 3a has been removed and removal of the adhered concrete are performed.
Note that this work may be performed collectively after the work of dismantling and removing the concrete slabs 3 in all sections to be repaired.

After that, the movable stage 10 is moved so that the work space 10S is positioned above the next scheduled demolition point, and the above-described work steps are repeated, and demolition / removal of all the concrete slabs 3 in the section scheduled for rehabilitation work is performed. Do the work.
If there is a pier in the section to be rehabilitated, the lower protection 15 in the protection 13 is rotated 90 or 180 degrees via the rotating member 13a so that the lower protection 15 does not contact the pier. . At this time, it is desirable to reduce the load applied to the stage body 11 by setting the retractable scaffold 15a in a contracted state.

Although not shown, after demolition and removal work has been performed on all concrete slabs 3 in the section to be rehabilitated, new slabs such as steel slabs and precast concrete slabs manufactured in advance in the factory are installed. .
Bridge rehabilitation work is performed as described above.

  According to the present embodiment, the floor slab cutting device is installed in the work space between the concrete floor slab and the mobile stage, and the floor slab lifting means is mounted on the mobile stage. They can be collected together on the stage and its vicinity. Therefore, each means is less likely to hinder each other's work, and each means can be prevented from hindering the movement of the moving stage. Furthermore, since the floor slab cutting device 20 has the wire saw 23 continuously extending in the direction along the joint boundary surface C1 between the bridge girder 2 and the concrete slab 3, and in the width and thickness directions of the concrete slab 3. In addition, the concrete floor slab 3 can be dismantled in a block shape. Thereby, the dismantling and removal work of the concrete floor slab 3 can be performed efficiently.

  In addition, the floor slab cutting device 20 has a configuration in which the rotation axis of the wire saw 23 extends along both side edges at the upper end of the bridge girder 2 (2A, 2B), and protrudes outward from both side edges at the upper end of the bridge girder 2. It has guide rollers 25 (25A, 25B, 25C, 25D) arranged so as to be in contact with the lower surface, and since the guide rollers 25 are configured to be rotatable around the axis in accordance with the traveling of the wire saw 23, The traveling of the wire saw 23 can be guided while reliably suppressing the bending of the wire saw 23 that relaxes as the cutting operation proceeds. As a result, the levelness of the wire saw 23 can be ensured, so that the work of cutting the joint boundary surface C1 between the bridge girder 2 and the concrete floor slab 3 can be performed accurately.

  In addition, the dismantling system includes a plurality of dust collectors 40 mounted on the movable stage 10 and sucking dust generated when the concrete slab 3 is cut by the slab cutting device 20, so that, for example, the work space 10S and the lower protection Dust generated particularly in a place where dust is generated such as in the hanging scaffold 16 and other necessary places can be reliably sucked. Thereby, scattering of dust to the surroundings can be suppressed, so that dismantling / removal work in consideration of the surrounding environment can be performed.

Further, the movable stage 10 has a protective work 13 connected to the stage main body 11 and located outside the pier, and disposed from the side to the lower side of the concrete slab 3 cut by the slab cutting device 20. Therefore, this protective work 13 will function as a scaffold at the time of work and also as a safety facility for the side and the lower side, so that the safety at the time of work can be improved.
In addition, since the lower protective member 15 which is a part of the protective member 13 located below the concrete floor slab 3 is configured to be able to turn in the horizontal direction with respect to the upper protective member 14, the lower protective member 15 is located in the section to be rehabilitated. When there is a pier, by rotating this lower protection 15, contact with the pier can be prevented. Therefore, even if there is a pier in the section to be repaired, the movable stage 10 can be moved, so that the concrete floor slab 3 can be dismantled and removed without delay.

  In the slab cutting device 20 in the slab demolition system described above, in the present invention, as shown in FIG. 1, a wire saw is provided near a cutting start portion in a direction along a joining boundary surface C1 between the bridge girder 2 and the concrete slab 3. While guiding the guide 23 in the traveling direction, a fixed pulley 61 is arranged to prohibit a horizontal cutting operation along the joint boundary surface C1 between the bridge girder 2 and the concrete floor slab 3 driven by the wire saw 23.

That is, in the illustrated example, in the first wire saw cutting device 21 and the second wire saw cutting device 22, the vicinity of a position just before the horizontal cutting start portion along the joining boundary surface C1 between the bridge girders 2A and 2B and the concrete floor slab 3. A rotatable fixed pulley 61 that prohibits a horizontal cutting operation along each joint boundary C1 is fixed to both sides of the bridge girders 2A and 2B with fixing members (not shown).
Regarding the first wire saw cutting device 21, the wire saw 23 wound around the fourth driven pulley 243 and the fifth driven pulley 244 is connected to a pair of left and right arranged near both sides near the cutting start portion of the bridge girder 2A. Around the fixed pulley 61.
Regarding the second wire saw cutting device 22, the wire saw 23 wound around the seventh driven pulley 246 and the eighth driven pulley 247 is connected to a pair of left and right arranged near both sides near the cutting start portion of the bridge girder 2B. Around the fixed pulley 61.

  By arranging the fixed pulley 61 in this manner, by driving the wire saw 23, the first wire saw cutting device 21 and the second wire saw cutting device 22 are both in the width direction and the thickness direction of the concrete floor slab 3, that is, The cutting is performed only in the vertical direction, and the cutting in the horizontal direction along the joining boundary surface C1 between the bridge girders 2A and 2B and the concrete floor slab 3 is not started, but is kept in the prohibited state.

Then, the drive of the wire saw 23 is stopped, and the fixed pulley 61 is removed from the mounting members on both sides of the bridge girders 2A and 2B.
As a result, as shown in FIG. 7, both the first wire saw cutting device 21 and the second wire saw cutting device 22 perform horizontal cutting along the joint boundary surface C1 between the bridge girders 2A and 2B and the concrete floor slab 3, respectively. It becomes possible.

  Therefore, by driving the wire saw 23 again, both the first wire saw cutting device 21 and the second wire saw cutting device 22 cut the horizontal direction along the joint boundary surface C1 between the bridge girders 2A and 2B and the concrete floor slab 3, respectively.

As described above, according to the floor slab cutting device 20 of the embodiment, in the first wire saw cutting device 21 and the second wire saw cutting device 22, the horizontal direction along the joint boundary surface C1 between the bridge girders 2A and 2B and the concrete floor slab 3 is used. In the vicinity of the cutting start portion, fixed pulleys 61 for inhibiting each horizontal cutting operation are arranged on both sides of the bridge girders 2A and 2B.
Therefore, by driving the wire saw 23, both the first wire saw cutting device 21 and the second wire saw cutting device 22 can cut only the vertical direction of the concrete floor slab 3, and the bridge girders 2A and 2B and the concrete floor can be cut. The cutting operation of the plate 3 in the horizontal direction is not started, and each can be held in the prohibited state.

  As described above, the horizontal cutting operation of the bridge girders 2A and 2B and the concrete floor slab 3 at the work site of the floor slab demolition can be prohibited as necessary according to various conditions and conditions of the site.

  Then, the driving of the wire saw 23 is stopped, and the fixed pulley 61 is removed from the mounting members on both sides of the bridge girders 2A and 2B. The two-wire saw cutting device 22 can cut both the bridge girders 2A and 2B and the concrete floor slab 3 in the horizontal direction.

(Embodiment 2)
FIG. 13 shows a floor slab cutting device 20 according to the second embodiment. The wire slab 23 is guided in the traveling direction near a cutting start portion in a direction along the width direction and the thickness direction of the concrete floor slab 3, and the wire is guided. Fixed pulleys 62, 63 and 64 are arranged to prohibit a vertical cutting operation along the plane C2 to be cut of the concrete floor slab 3 by driving the saw 23.

That is, as shown in the drawing, the first wire saw cutting device 21 cuts the concrete floor slab 3 in the vicinity of a position just before the vertical cutting start portion along the cutting plane C2 in the vertical direction along the cutting plane C2. A rotatable fixed pulley 62 that prohibits the operation is fixed to the outside of the concrete floor slab 3 and the wall panel 4 with a mounting member (not shown) and arranged vertically.
In this manner, the wire wound around the first driven pulley 240 and the second driven pulley 241 around the pair of upper and lower fixed pulleys 62 disposed on the outer side near the cutting start portion of the concrete floor slab 3 and the wall rail 4. Wrap the saws 23 respectively.

In addition, the second wire saw cutting device 22 also prohibits a vertical cutting operation along the planned cutting plane C2 near a position just before a vertical cutting start portion along the planned cutting plane C2 of the concrete floor slab 3. A rotatable fixed pulley 63 is fixed to an inner side of the bridge girder 2A with a mounting member (not shown) and arranged vertically.
Further, a rotatable fixed pulley 64 is fixed to the inside of the bridge girder 2B with a mounting member (not shown) and arranged vertically.
In this manner, the wire saw 23 wound around the fixed pulley 221 and the eighth driven pulley 247 is respectively mounted on the three fixed pulleys 63 and 64 disposed on both sides near the cutting start portion of the concrete floor slab 3 near the cutting position. Wrap around.

  By arranging the fixed pulleys 62, 63, and 64 in this manner, by driving the wire saw 23, the bridge girders 2A and 2B and the concrete floor slab 3 are both driven by the first wire saw cutting device 21 and the second wire saw cutting device 22. Is cut only in the direction along the joining boundary surface C1, that is, only in the horizontal direction, and the cutting in the vertical direction along the width direction and the thickness direction of the concrete floor slab 3 is not started, but is kept in the prohibited state.

Thereafter, the driving of the wire saw 23 is stopped, and the fixed pulleys 62 are removed from the mounting members on the outside of the concrete floor slab 3 and the wall rail 4, respectively, and the fixed pulleys 63 and 64 are attached to both inner sides of the bridge girders 2A and 2B. Remove from each of the mounting members.
Thereby, as shown in FIG. 7, both the first wire saw cutting device 21 and the second wire saw cutting device 22 can cut in the vertical direction along the cut surface C2 of the concrete floor slab 3.

  Therefore, by driving the wire saw 23 again, both the first wire saw cutting device 21 and the second wire saw cutting device 22 cut each in the vertical direction along the cut surface C2 of the concrete floor slab 3.

As described above, according to the floor slab cutting device 20 of the second embodiment, in the first wire saw cutting device 21 and the second wire saw cutting device 22, the cutting start portion in the vertical direction along the cut surface C <b> 2 of the concrete floor slab 3 is cut. In the vicinity, fixed pulleys 62, 63, and 64 for prohibiting each vertical cutting operation are arranged on the outside of the concrete slab 3 and the wall rail 4 and on both insides of the bridge girders 2A and 2B.
Therefore, by driving the wire saw 23, both the first wire saw cutting device 21 and the second wire saw cutting device 22 can cut only the bridge girders 2A and 2B and the concrete floor slab 3 in the horizontal direction, respectively. The cutting operation of the plate 3 and the wall rail 4 in the vertical direction is not started, and each of them can be kept in the prohibited state.

  As described above, in the work site of the floor slab demolition, the vertical cutting operation of the concrete slab 3 and the wall panel 4 can be prohibited as necessary according to various conditions and conditions of the site.

  Then, the driving of the wire saw 23 is stopped, and the fixed pulleys 62, 63, and 64 are removed from the outside of the concrete floor slab 3 and the wall rail 4 and from the attachment members on both insides of the bridge girders 2A and 2B. By driving the wire saw 23 again, both the first wire saw cutting device 21 and the second wire saw cutting device 22 can cut the concrete floor slab 3 and the wall rail 4 in the vertical direction, respectively.

(Modification 1)
FIG. 14 shows the floor slab cutting device 20 of the first modification. In the first wire saw cutting device 21, the first driven roller 240, the second driven roller 241 and the third driven roller 241 arranged at the position of the bridge girder 2A in FIG. The driven roller 242 is removed, and the wire saw 23 is directly wound around the first driving pulley 210A and the fourth driven pulley 243.
Further, the sixth driven roller 245 is removed from the first wire saw cutting device 21 to the second driven wire saw cutting device 22, and the wire saw 23 is connected to the fixed pulley 221 from the second driving roller 210B via the tenth driven roller 249. Is wrapped around.

  In this way, by driving the wire saw 23, the first wire saw cutting device 21 and the second wire saw cutting device 22 do not cut the concrete floor slab 3 and the wall rail 4 in the vertical direction, and connect the bridge girders 2A and 2B. A slab cutting device 20 that simultaneously cuts only the horizontal direction of the concrete slab 3 may be configured.

(Modification 2)
FIG. 15 shows a floor slab cutting device 20 of Modified Example 2, which is fixed to both sides of the third bridge girder 2C in the configuration of FIG. The pulleys 65 and 66 are fixedly arranged by a mounting member (not shown).
Then, the wire saw 23 wound around the eighth fixed pulley 247 and the ninth fixed pulley 249 is pulled out above the third bridge girder 2C, and the drawn wire saw 23 is put on the left and right fixed pulleys 65 and 66, respectively. After being wound, it is extended to the cutting start position on the upper surface of the third bridge girder 2C.

In this way, by employing a configuration in which the wire saw 23 is extended to the cutting start position on the upper surface of the third bridge girder 2C, only the three bridge girder 2A, 2B, 2C and the concrete floor slab 3 are simultaneously cut only in the horizontal direction. be able to.
Therefore, the efficiency of the work can be further improved by wide and large cutting.

(Modification 3)
FIG. 16 shows the floor slab cutting device 20 of the third modification. The second driven pulley 241, the third driven pulley 242, the fourth driven pulley 243, the fifth driven pulley 244, and the second wire saw cutting device of FIG. 22 (the driving pulley 220, the fixed pulley 221, the seventh driven pulley 246, the eighth driven pulley 247, and the ninth driven pulley 248) are removed, and the wire saw 23 is moved from the second driving roller 210B to the inside of the tenth driven roller 249. Is wrapped around.
A fixed pulley 67 similar to the sixth driven pulley 245 on the right side is fixed to the left side of the first bridge girder 2A with a mounting member (not shown).
Further, the wire saw 23 is extended from the sixth driven pulley 245 and the tenth driven pulley 249 to the cutting start position on the side of the cut surface C2 of the concrete floor slab 3.

  In this way, by driving the wire saw 23 by only the first wire saw cutting device 21, the bridge girders 2A and 2B and the concrete floor slab 3 are not cut in the horizontal direction, but only in the vertical direction of the concrete floor slab 3 and the wall height section 4. May be configured to simultaneously cut the floor slab.

  As described above, using the floor slab cutting device 20 of Modification 3 and the floor slab cutting device 20 of Modification 1 described above, the process of simultaneously cutting only the vertical direction of the concrete floor slab 3 and the wall height section 4 is preceded. The step of simultaneously cutting only the bridge girders 2A and 2B and the concrete floor slab 3 only in the horizontal direction can be performed later, and the two can be separately performed.

(Modification 4)
FIG. 17 shows the floor slab cutting device 20 of the fourth modification. In the configuration of FIG. 16, the driving pulley 220, the fixed pulley 221 and the ninth driven pulley 248 of the second wire saw cutting device 22 are arranged. A fixed pulley 68 is fixed above the ninth driven pulley 248 with a mounting member (not shown).
Then, the wire saw 23 wound around the ninth driven pulley 248 and the fixed pulley 68, respectively, is connected to the side of the cut scheduled plane C2 on the right side from the ninth driven pulley 248 of the concrete floor slab 3 and the wall panel installed on the right side. 4 is extended to the cutting start position on the outside.

As described above, by driving the wire saw 23 by the first wire saw cutting device 21 and the second wire saw cutting device 22, the bridge girders 2A and 2B and the concrete floor slab 3 are not cut in the horizontal direction. The floor slab cutting device 20 that simultaneously cuts only the vertical direction of the left and right wall columns 4 may be configured.
In this case, the cutting width of only the vertical direction of the concrete floor slab 3 and the left and right wall columns 4 can be made long, and there is an advantage that the wide concrete floor slab 3 can be cut.
In this way, by cutting wide and widely, work efficiency is further improved.

  As described above, using the floor slab cutting device 20 of Modification 4 and the floor slab cutting device 20 of Modification 1 described above, the step of simultaneously cutting only the vertical direction of the concrete floor slab 3 and the wall height section 4 is preceded. The step of simultaneously cutting only the bridge girders 2A and 2B and the concrete floor slab 3 only in the horizontal direction can be performed later, and the two can be separately performed.

(Mobile factory)
18 and 19 show the configuration of a mobile factory 70, in which 71 is a bellows type upper protection facility, 72 is a tire type self-propelled facility, 73 is a dust collector, and 74 is lighting equipment.
As shown in the figure, a mobile factory 70 is an all-weather, soundproof and dustproof type, and has a bellows-type upper protection facility 71 that can expand and contract along the longitudinal direction of the concrete slab 3 and a bellows-type upper protection facility 71. Self-propelled equipment 72 for moving the air in the longitudinal direction along the concrete floor slab 3, a dust collector 73 installed in a bellows-type upper protection equipment 71, a lighting equipment 74, and a ventilation device (not shown). I have.
The bellows type upper protection equipment 71 covers both sides of the upper and right and left wall rails 4 including the completely anhydrous first wire saw cutting device 21 and the second wire saw cutting device 22 on the concrete floor slab 3.

  By such a mobile factory 70, for example, in the case of a narrow one-lane bridge on a road and a vehicle, the bellows type upper protective equipment 71 incorporating a dust collecting device 73, a lighting device 74 and a ventilation device completely covers the bridge. For example, it is possible to cut and remove the entire cross section at a width of 2 m, to carry it out with a trailer, etc., and to cope with two-shift night work.

(Embodiment 3)
FIGS. 20 and 21 show the floor slab cutting device 20 of the third embodiment. As shown, a third wire saw cutting device 81 and a fourth wire saw cutting device 91 are arranged below the concrete slab 3. The wire saw 23 has one end fixed by a swing fixture 231 and the other end fixed by a fixture 232.

That is, in the third wire saw cutting device 81, the housing 82, the driving pulley 83, and the driving device 83a thereof are disposed below the concrete floor slab 3 and between the first bridge girder 2A and the second bridge girder 2B. The wire saw 23, one end of which is fixed by the swing fixture 231, is wound around the drive pulley 83.
The wire saw 23 is sequentially wound around a fixed pulley 84A, a movable pulley 85A, a fixed pulley 86, a movable pulley 85B, and a fixed pulley 84B incorporated in the housing 82, and furthermore, driven wires disposed on both sides of the right bridge girder 2B. It is wound around pulleys 87 and 88 sequentially.

In the fourth wire saw cutting device 91, a driving pulley 93 and a driving device 93a thereof are disposed below the concrete slab 3 and between the second bridge girder 2B and the third bridge girder 2C, and are wound around the driving pulley 93. The wound wire saw 23 is wound around a driven pulley 94 and turned upward.
The wire saw 23 is sequentially wound around a driven pulley 95, a fixed pulley 96A, a movable pulley 97A, a fixed pulley 98, a movable pulley 97B, and a fixed pulley 96B incorporated in the housing 22a of the second wire saw cutting device 22. Is wound around the drive pulley 220 of the second wire saw cutting device 22.

The wire saw 23 has one end fixed to the housing 21 a of the first wire saw cutting device 21 with the swing fixture 231, and the other end fixed to the fixture 232 below the concrete floor slab 3. I have. The fixture 232 is fixed to the first bridge girder 2A via an attachment member (not shown).
After the end of the concrete floor slab 3 including the wall rail 4 is cut by the wire saw 23, the wire saw 23 comes into contact with the stopper roller 233 as shown by a virtual line in FIG.

  As described above, the third wire saw cutting device 81 and the fourth wire saw cutting device 91 are newly disposed below the concrete floor slab 3, and one end is fixed by the swing fixture 231 and the other end is fixed. In the floor slab cutting device 20 using the wire saw 23 in which is fixed by the fixture 232, similarly to the first or second embodiment described above, the fixed pulley 61 or the fixed pulleys 62, 63, 64 for cutting prohibition can be arranged. It is.

(Modification 5)
FIG. 22 shows the floor slab cutting device 20 of the fifth modification, in which the first wire saw cutting device 21 and the second wire saw cutting device 22 arranged on the concrete floor slab 3 of FIGS. 20 and 21 are removed. Then, the fourth wire saw cutting device 91 disposed below the concrete floor slab 3 is also removed, and the swing fixture 231 and the fixture 232 are also removed.
Under the concrete floor slab 3, two driven pulleys 89 and 90 for guiding the endless wire saw 23 are newly disposed.

That is, as shown, the endless wire saw 23 formed only by the third wire saw cutting device 81 is disposed on the driven pulley 88 arranged on the right side of the right bridge girder 2B and on the left side of the left bridge girder 2A. It is wound around a new driven pulley 89.
Further, between the left and right driven pulleys 88 and 89, the endless wire saw 23 passed through the core line cut portions 3b and 3d on the left and right bridge girders 2A and 2B of the concrete floor slab 3, and the intermediate portion thereof is made of concrete. It is guided from below by a new driven pulley 90 arranged below the floor slab 3.

In this way, the first wire saw cutting device 21 and the second wire saw cutting device 22 are not arranged on the concrete floor slab 3 on the road upper surface, but only the third wire saw cutting device 81 arranged below the concrete slab 3. By using the endless wire saw 23, the bridge girders 2A and 2B and the concrete floor slab 3 can be simultaneously cut only in the horizontal direction.
Therefore, the third wire saw cutting device 81 is disposed under the concrete slab 3 in the daytime with the vehicle passing therethrough without any road regulation to cut the bridge girders 2A and 2B and the concrete slab 3 in the horizontal direction. Only can be performed, and the construction period can be shortened.

As described above, in order to arrange the third wire saw cutting device 81 under the concrete slab 3 in a state where vehicles are allowed to pass without restricting roads in the daytime, the bridge girder of the concrete slab 3 is required. A small-diameter hole (core line cut portions 3b and 3d) for passing the wire saw 23 is made on 2A and 2B, and the core line cut portions 3b and 3d are cured so as not to hinder the traveling of the vehicle. .
The vertical cutting of the concrete floor slab 3 and the left and right wall sections 4 is performed at night with traffic regulation by using the floor slab cutting device of the third or fourth modification.

As described above, according to the floor slab cutting device 20 of Modification Example 5, the construction period can be shortened by increasing the number of daytime operations.
In addition, traffic congestion can be reduced by avoiding daytime traffic regulations.

(Other modifications)
In the above embodiments and the modified examples, the floor slab cutting device having the guide roller is used, but the guide roller may not be provided.

DESCRIPTION OF SYMBOLS 1 Bridge 2 Bridge girder 2A First bridge girder 2B Second bridge girder 2C Third bridge girder 2a Gibber 3 Concrete floor slab 3a Block 4 Wall balustrade 10 Mobile stage 10S Work space 11 Stage body 11d Opening 12 Leg 13 Protector 13a Rotating member 15 Lower protection 20 Floor slab cutting device 21 First wire saw cutting device 210 Drive pulley 211 Fixed pulley 212 Moving pulley 22 Second wire saw cutting device 220 Drive pulley 221 Fixed pulley 23 Wire saw 24 Driven pulley 240 First driven pulley 241 2 driven pulley 242 3rd driven pulley 243 4th driven pulley 244 5th driven pulley 245 6th driven pulley 246 7th driven pulley 247 8th driven pulley 248 9th driven pulley 249 10th driven pulley 25 Guide roller 30 Floor slab lifting Means 40 Dust collecting means 5 0 power generation means 61 fixed pulley 62 fixed pulley 63 fixed pulley 64 fixed pulley 65 fixed pulley 66 fixed pulley 67 fixed pulley 68 fixed pulley 70 movable factory 71 bellows type upper protection equipment 72 tire type self-propelled equipment 73 dust collector 74 lighting equipment 81 third wire saw cutting device 83 driving pulley 84 fixed pulley 85 moving pulley 86 fixed pulley 87 driven pulley 88 driven pulley 89 driven pulley 90 driven pulley 91 fourth wire saw cutting device 93 driving pulley 94 driven pulley 95 driven pulley 96 fixed pulley 97 Moving pulley 98 Fixed pulley C1 Joining boundary surface C2 Planned cutting surface

Claims (2)

A concrete floor slab laid on the bridge girder and constituting a road surface of the bridge, and a wire saw arranged in a direction along a joint boundary surface with the bridge girder,
A plurality of pulleys for guiding and driving the wire saw in a direction along the joining boundary surface,
An apparatus body that drives the wire saw to travel,
A floor slab cutting device comprising:
Whole wire saw cutting apparatus including said device main body and the wire saw and the previous SL plurality of pulleys, disposed below the said concrete slab,
The floor slab cutting device, wherein the plurality of pulleys include a driven pulley disposed on a side opposite to the device main body with the bridge girder interposed therebetween . The floor slab cutting device according to claim 1,
The cutting direction of the joining boundary surface by the wire saw is along the length direction of the bridge girder,
The floor slab cutting device, wherein the driven pulley is located forward of the device main body in a cutting direction of the joining boundary surface by the wire saw.

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