JP2017218865A - Precast floor slab erection machine, and transfer method for precast floor slab erection machine at replacement location of precast floor slab - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a precast floor slab erection machine that may be transferred without using a rail for traveling, even when there is a stepped part on an existing floor slab.SOLUTION: A precast floor slab erection machine 1 includes: a pair of gate-form frames 2 having a first front support leg 10 disposed in front, a first rear support leg 11 disposed in rear, and a traveling frame 12; a pair of second front support legs 20 that includes a support body expansion jack 24, is disposed in front, and faces each other in a width direction; and a frame support body 3 that includes the support body expansion jack 24, is disposed in rear, and includes a pair of second rear support legs 21 that face each other in the width direction. The traveling frame 12 lifts and moves the gate-form frame 2 or the frame support body 3, by being supported by the frame support body 3 from below and relatively changing a length of the gate-form frame 2 in a vertical direction and a length of the frame support body 3 in the vertical direction.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a precast floor slab erection machine used when replacing an existing concrete slab of a deteriorated steel girder bridge with a precast slab, and a method of moving the precast floor slab erection machine at a precast floor slab replacement position. is there.

  The existing concrete slabs of steel girder bridges may be damaged due to deterioration and cracks, and the existing concrete slabs need to be replaced. In the replacement of the concrete floor slab, noise is generated by cutting the existing concrete floor slab and removing the existing concrete floor slab. Therefore, if the replacement work period is long, the influence on the surrounding environment becomes a problem. In addition, the bridge construction time increases due to the replacement work, so the influence on the traffic environment becomes a problem.

To replace the existing concrete floor slab, a precast floor slab is used to shorten the replacement work period. In this method, a precast floor slab manufactured in another place such as a factory is continuously laid at the replacement position. For the replacement of the precast floor slab, for example, a self-propelled precast floor slab erection machine is used (Patent Document 1). This self-propelled precast floor slab erection machine has a portal structure that is held by four legs, and four units (with rubber tires or crawlers) that are equipped with the four legs of the portal structure. A rail-type traveling device is provided.
This self-propelled precast floor slab erection machine is self-propelled to a predetermined position and used by a rail-free traveling device after being transported to the work site.

JP 2004-300688 A

Unevenness is formed on the existing concrete floor slab that has deteriorated, resulting in a stepped portion.
Since the self-propelled precast slab erection machine of Patent Document 1 travels on an existing concrete floor slab by a rail-free traveling device, the rail-free traveling device catches on the step portion and cannot get over the step portion.
Moreover, the method of moving regardless of a level | step-difference part by installing the rail for a railless traveling apparatus to drive | work on an existing concrete slab is also considered. However, when rails are used, it takes time to install or remove the rails, resulting in a problem that the replacement work period is prolonged.

  Therefore, an object of the present invention is to provide a precast floor slab erection machine that can move without using rails for traveling even if a stepped portion is formed on the existing floor slab.

  The present invention is a precast floor slab erection machine that is installed at a concrete floor slab replacement position, conveys the precast floor slab by a traveling suspension device, and lays the precast floor slab at the replacement position. The first front support leg disposed at the rear, the first rear support leg disposed rearward of the replacement position, and the traveling of the suspension device provided between the first front support leg and the first rear support leg. A pair of gate-type frames having a frame, a support body extension jack, a pair of second front support legs disposed in front of the replacement position and facing the width direction, and a support body extension jack; A frame support having a pair of second rear support legs disposed rearward of the replacement position and facing in the width direction, and the traveling frame is supported by the frame support from below. The portal frame or frame support is lifted by moving the portal frame or frame support in the front-rear direction by relatively changing the vertical length of the portal frame and the vertical length of the frame support. It is characterized by making it.

  The precast floor slab erection machine of the present invention is characterized by having a width direction frame in which the second front support legs and the second rear support legs are connected in the width direction.

  The precast floor slab erection machine of the present invention has a front-rear frame in which the second front support leg and the second rear support leg are connected in the front-rear direction.

  The precast floor slab erection machine according to the present invention is characterized in that the first front support leg and the first rear support leg include a frame telescopic jack.

  The precast slab erection machine of the present invention is characterized in that the second front support leg and the second rear support leg are provided with moving means, and the portal frame is moved in the front-rear direction by the moving means.

  The precast floor slab erection machine according to the present invention is characterized in that a suspended portion is formed on the frame support, and the suspended portion is suspended from the traveling frame when the frame support is lifted.

  In the precast slab erection machine of the present invention, the suspension device is a cantilever crane.

  The present invention also provides a method of moving the precast floor slab erection machine at the floor slab replacement position. The movement method of the precast floor slab erection machine at the floor slab replacement position is the movement method of the precast floor slab erection machine at the floor slab replacement position, which extends the frame telescopic jack and shortens the support telescopic jack. The frame support is suspended from the traveling frame, the second front support leg and the second rear support leg are moved to a predetermined position in the front-rear direction, the support extension jack is extended, and the frame extension jack is reduced, A step of floating the portal frame, balancing the load while moving the traveling suspension device, and moving the traveling frame to a predetermined position in the front-rear direction.

The precast floor slab erection machine according to the present invention floats the portal frame or the frame support by relatively changing the vertical length of the portal frame and the vertical length of the frame support, and the portal frame Alternatively, the frame support can be moved in the front-rear direction. Therefore, the precast slab erection machine of the present invention can get over the step portion formed on the existing concrete slab.
Moreover, since the precast slab erection machine of this invention can be moved without using a rail, it does not require the time for installation or removal of a rail, and can shorten a replacement construction period.

  Further, the precast floor slab erection machine of the present invention has the second front support legs and the width direction frame connecting the second rear support legs in the width direction. Can be moved in conjunction with each other. Furthermore, since the precast floor slab erection machine of the present invention has a front-rear frame that connects the second front support leg and the second rear support leg in the front-rear direction, the second front support leg and the second rear support leg Can be moved in conjunction with the front-rear direction.

Since the precast floor slab erection machine of the present invention is provided with moving means on the second front support leg and the second rear support leg, the portal frame can be easily moved in the front-rear direction.
In the precast floor slab erection machine according to the present invention, the frame support is provided with a suspension part that is suspended from the traveling frame when the frame support floats. Therefore, the frame support can be suspended from the traveling frame and can be moved in the front-rear direction.
The precast floor slab erection machine of the present invention can use a cantilever crane. If there is space below the bridge, you can use a cantilever crane to remove the divided blocks into that space. In addition, the precast floor slab temporarily placed in the lower space can be directly installed without being transported to the bridge surface.

1 is a perspective view (bird's eye view) of a precast slab erection machine according to an embodiment of the present invention. It is explanatory drawing when removing the block of the overhang | projection part of the existing concrete floor slab by the precast floor slab laying machine which concerns on embodiment of this invention. (A) Side view, (b) Unloading procedure It is explanatory drawing when installing the existing floor slab peeling apparatus after installing the precast floor slab erection machine concerning the embodiment of the present invention. (A) Cross section of floor slab peeling position, (b) Cross section of loading position of transport vehicle The side view when installing the existing floor slab peeling device after installing the precast floor slab erection machine according to the embodiment of the present invention at the replacement position of the existing concrete slab It is explanatory drawing when the precast floor slab erection machine concerning the embodiment of the present invention constructs a precast floor slab. (A) Side view during transportation of precast slab, (b) Cross section during transportation of precast slab It is a side view after rotating to the state which installs a precast floor slab with the precast floor slab framing machine which concerns on embodiment of this invention. It is sectional drawing which shows the rotation point of the precast floor slab conveyed with the precast floor slab erection machine which concerns on embodiment of this invention. It is a side view which shows the procedure for moving the flame | frame support body of the precast floor slab construction machine which concerns on embodiment of this invention. It is a side view which shows the procedure for moving the flame | frame support body of the precast floor slab construction machine which concerns on embodiment of this invention. It is a side view which shows the procedure for moving a flame | frame support body with the flame | frame moving apparatus of the precast slab erection machine which concerns on embodiment of this invention. It is a side view which shows the procedure of the movement of the portal frame of the precast slab erection machine concerning the embodiment of the present invention. It is a side view which shows the procedure for moving a portal frame | frame with the frame moving apparatus of the precast floor slab erection machine which concerns on embodiment of this invention. It is a side view which shows the procedure which fine-tunes after the portal frame of the precast floor slab erection machine concerning the embodiment of the present invention moves. It is a side view when a support | pillar member is provided in the precast floor slab construction machine which concerns on embodiment of this invention. It is a side view when the telescopic tent of the precast floor slab erection machine concerning the embodiment of the present invention is extended. In the precast slab erection machine according to the embodiment of the present invention, it is a detailed explanatory diagram when a cantilever crane is used as a traveling suspension device. In the precast floor slab erection machine according to the embodiment of the present invention, the second front support leg and the second rear support leg of the frame support are independent from each other, and are explanatory diagrams when a cantilever crane is used as a traveling suspension device. It is. It is a figure for demonstrating the method for respond | corresponding to the influence of a plane alignment for the precast floor slab construction machine which concerns on embodiment of this invention.

The precast floor slab erection machine 1 according to the present embodiment is used for replacing the existing concrete floor slab 6 of a steel girder bridge that has progressed with a new precast floor slab 5.
Hereinafter, a precast slab erection machine 1 (hereinafter referred to as erection machine 1) according to the present embodiment will be described with reference to FIGS.
In the drawings, the direction in which the construction machine 1 moves is defined as the front-rear direction X, and the direction intersecting the front-rear direction is defined as the width direction Y.

  As shown in FIG. 1, the erection machine 1 includes a pair of portal frames 2 installed across a position (hereinafter referred to as a replacement position A) where the existing concrete floor slab 6 is replaced with a precast floor slab 5, A frame support 3 that supports the portal frame 2 from below and a crane 4 as a traveling suspension device that travels on the portal frame 2 are provided.

[Portrait frame 2]
The portal frame 2 includes a first front support leg 10 disposed in front of the replacement position A, a first rear support leg 11 disposed rearward of the replacement position A, a first front support leg 10 and a first frame. A travel frame 12 provided between the rear support legs 11 is provided and formed integrally.
Two portal frames 2 are provided and are arranged to face each other in the width direction Y.
At the bottoms of the first front support leg 10 and the first rear support leg 11, a first hydraulic jack 13 is provided as a frame telescopic jack. The portal frame 2 is installed before and after the replacement position A via the first hydraulic jack 13.
A rail is installed on the upper surface of the traveling frame 12, and the crane 4 travels on this rail. Further, a groove (not shown) that is continuous in the front-rear direction X is formed on the side wall of the traveling frame 12.
As shown in FIG. 2A, a crane departure prevention device 18 and an extendable tent 19 are provided on the upper portion of the traveling frame 12.
In addition, the 1st front support leg 10, the 1st back support leg 11, and the traveling frame 12 which comprise the portal frame 2 may be formed separately.

[Frame support 3]
The frame support 3 supports the traveling frame 2 from below and is used to float the portal frame 2.
The frame support 3 includes a pair of second front support legs 20 disposed in front of the replacement position A, a pair of second rear support legs 21 disposed rearward of the replacement position A, and a second front support. A width-direction frame 22 that connects the legs 20 and the second rear support legs 21 in the width direction, and a front-rear direction frame 23 that connects the second front support legs 20 and the second rear support legs 21 in the front-rear direction are provided. (Fig. 1).
The 2nd front support leg 20 and the 2nd back support leg 21 are rod-shaped members, and the 2nd hydraulic jack 24 as a support body expansion-contraction jack is provided in those bottom parts, respectively.
The second front support leg 20 is arranged closer to the replacement position A than the first front support leg 10, and the second rear support leg 21 is also arranged closer to the replacement position A than the first rear support leg 11.
The second front support leg 20 and the second rear support leg 21 are designed to have such a length that the wall rail of the precast floor slab 5 does not contact the front-rear direction frame 23.

The front / rear direction frame 23 is for connecting the second front support leg 20 and the second rear support leg 21 facing the front / rear direction X to support the traveling frame 12.
The front-rear direction frame 23 is provided with a plurality of suspension devices 25 as suspension portions. The suspension device 25 includes a plurality of rollers and sandwiches the side wall of the traveling frame 12. This roller moves in the front-rear direction X along the groove on the side wall of the traveling frame 12. The suspension device 25 can also be provided directly on the second front support leg 20 and the second rear support leg 21. The suspension device 25 is assumed to have a drive device, but a suspension device 25 that does not have a drive device can also be constructed.
The front-rear direction frame 23 is designed to be longer than the length of the precast floor slab 5.
The width direction frame 22 is designed to be longer than the width between the portal frames 2. Therefore, the front end of the width direction frame 22 protrudes outward from the second front support leg 20 and the second rear support leg 21.
Further, as shown in FIG. 2 (b), rollers 26 as moving means are provided on the upper portions of the second front support legs 20 and the second rear support legs 21. The roller 26 is in contact with the bottom surface of the traveling frame 12. The roller 26 is assumed to have a driving device, but a roller 26 that does not have a driving device can also be applied.

[Crane 4]
The crane 4 transports the existing concrete floor slab 6 to the transport vehicle 7 or transports the precast floor slab 5 to the replacement position A.
The crane 4 can be a portal crane. The crane 4 is provided with four rollers 30, and when the rollers 30 move along the rails on the traveling frame 12, the crane 4 moves on the portal frame 2 in the front-rear direction X. .
Each roller 30 is provided with a stopper. The crane 4 is fixed at an arbitrary position on the traveling frame 12 by the stopper.

Next, the construction operation of the precast slab 5 of the construction machine 1 according to the present embodiment will be described with reference to FIGS. 3 to 15.
First, the existing concrete floor slab 6 at the replacement position A is cut into blocks 9 having a size that can be transported by a concrete cutter or the like, and at the same time, in order to install the floor slab peeling device 8, a hole is drilled with a core drill or the like. And as shown to Fig.3 (a), the floor slab peeling apparatus 8 is installed. Then, the existing concrete floor slab 6 is peeled off by the floor slab peeling device 8.
In addition, when the floor strip peeling apparatus 8 cannot be used, it can be cut with a concrete cutter so as to leave the steel girder directly above.
Then, as shown in FIGS. 3B and 4, the block peeled off by the floor slab peeling device 8 is suspended on the crane 4, the crane 4 is moved rearward, and is transported to the transport vehicle 7.

After the removal of the existing concrete floor slab 6, as shown in FIG. 5 (a), the precast floor slab 5 loaded on the transport vehicle 7 is placed more than the portal frame 2 so that the longitudinal direction is the front-rear direction X. It is suspended from the crane 4 at a high position and transported to the replacement position A.
After the precast floor slab 5 is transported to the replacement position A, the precast floor slab 5 is lowered to a position lower than the front-rear direction frame 23 as shown in FIG. Then, as shown in FIG. 7, the precast floor slab 5 is slowly rotated by about 90 degrees in the horizontal direction and then further lowered to install the precast floor slab 5 at a target position.
This erection operation is repeated to install a plurality of precast floor slabs 5 at the replacement position A.

Next, an operation (movement method) for moving the construction machine 1 to the next replacement position A will be described.
First, as shown in FIG. 8, the roller 30 is fixed to the traveling frame 12 by a stopper, and the crane 4 is fixed to the portal frame 2 at the position where the precast floor slab 5 is installed. Then, the hydraulic pressure of the second hydraulic jack 24 is released, and the second hydraulic jack 24 is released. Then, the vertical length of the frame support 3 is shortened, the first hydraulic jack 13 is lifted from the ground surface, the suspension device 25 is suspended from the traveling frame 12, and the frame support 3 is suspended from the portal frame 2. .
Then, as shown in FIG. 9, the suspension device 25 is caused to travel, the frame support 3 is moved rearward, and moved to the next replacement position A (enforcement section). After the movement, the second hydraulic jack 24 is pressurized to a height at which the frame support 3 supports the traveling frame 12.
Further, when the suspension device 25 is not provided with a drive device, the frame support 3 is moved backward by adjusting the frame moving device 27 as shown in FIG.
And as shown to Fig.11 (a), the 2nd hydraulic jack 24 is further pressurized, and the 1st front support leg 10 and the 1st back support leg 11 (1st hydraulic jack 13) are floated.

With the first front support leg 10 and the first rear support leg 11 floating, the roller 26 is run to move the portal frame 2 rearward. At this time, since the crane 4 is fixed to the traveling frame 12 with a stopper, the crane 4 moves together with the portal frame 2.
When the portal frame 2 is moved, the position of the center of gravity moves rearward, and the portal frame 2 may fall down. Therefore, as shown in FIG. The mold frame 2 is moved. It is desirable to move the portal frame 2 and the crane 4 separately from the viewpoint of safety.
Further, when the roller 26 is not provided with a driving device, the portal frame 2 is moved backward by adjusting a frame moving device 27 as shown in FIG.

When the portal frame 2 is moved to a predetermined position, the first hydraulic jack 13 is pressurized.
At this time, as shown in FIG. 13, the heights of the first hydraulic jack 13 and the second hydraulic jack 24 are adjusted so that the traveling frame 12 becomes horizontal. The second hydraulic jack 24 is adjusted, and the hydraulic pressure of the second hydraulic jack 24 is adjusted to match the height until the frame support 3 appropriately supports the portal frame 2.
Depending on the shape of the concrete floor slab to be removed and the shape of the precast floor slab 5 to be newly installed during this operation, a large load may be temporarily applied to the frame support 3, as shown in FIG. A wedge member may be disposed as a support member between the traveling frame 12 and the frame support 3, or a support member 36 may be provided as a support member between the traveling frame 12 and the existing concrete floor slab 6. A plurality of these support members can be provided.

  Moreover, after removing the existing concrete floor slab 6, the steel girder cleaning such as removal of anchor bars and rust may be performed, or the work may be interrupted due to rain. In that case, as shown in FIG. 15, the telescopic tent 19 is extended backward so as to cover the replacement position A.

The effect of the construction machine 1 according to the present embodiment will be described.
The construction machine 1 adjusts the hydraulic pressure of the first hydraulic jack 13 or the second hydraulic jack 24 to relatively change the vertical length of the portal frame 2 and the vertical length of the frame support 3. Thus, the portal frame 2 or the frame support 3 can be lifted and easily moved to a predetermined position.
Therefore, even when unevenness and a groove are formed in the existing concrete floor slab 6, the portal frame 2 or the frame support 3 can be passed over the unevenness and the groove.
Therefore, the construction machine 1 can be moved to an appropriate position while avoiding irregularities and grooves of the existing concrete floor slab 6.
Further, since the portal frame 2 or the frame support 3 can be moved by the roller 26 provided between the traveling frame 12 and the frame support 3, the portal frame 2 and the frame support 3 can be easily moved. Can be.
Therefore, the construction machine 1 can be moved in a short time, and the replacement work period of the existing concrete floor slab 6 can be shortened.

  The construction machine 1 can adjust the length of the first front support leg 10 and the first rear support leg 11 by adjusting the hydraulic pressure of the first hydraulic jack 13. Further, by adjusting the hydraulic pressure of the second hydraulic jack 24, the lengths of the second front support leg 20 and the second rear support leg 21 of the frame support 3 that supports the traveling frame 12 can be adjusted. Therefore, the height of the traveling frame 12 can be kept horizontal, and the crane 4 can be smoothly moved in the front-rear direction X even when the front precast slab 5 and the rear existing concrete slab 6 are different in height. .

  Further, the front-rear direction frame 23 of the construction machine 1 connects the second front support leg 20 and the second rear support leg 21. Therefore, when the frame support 3 is moved, the second front support leg 20 and the second rear support leg 21 can be moved in the front-rear direction in conjunction with each other.

  Further, since the suspension device 25 is suspended from the traveling frame 12 when the second hydraulic jack 24 is contracted, the frame support 3 can be suspended from the traveling frame 12 and floated. Since the frame support 3 can be floated, the frame support 3 can be easily moved in the front-rear direction X along the traveling frame 12.

  The erection machine 1 includes an extendable tent 19 and can be freely expanded and contracted. Therefore, dust can be prevented from being scattered around during cleaning, and work near the replacement position A can also be performed when it rains.

  Since the portal frame 2 and the frame support 3 constituting the construction machine 1 have a structure formed by a combination of linear members, they can be manufactured or assembled more easily than members having a complicated structure.

Next, the construction operation of the construction machine 1 when the lower side of the bridge can be used will be described. FIG. 16 shows the construction machine 1 in more detail.
When the space below the bridge is available, a cantilever crane 40 is used as a suspension device. As shown in FIG. 16, the cantilever crane 40 includes a base portion 41 that travels on the traveling frame 12, a frame member 42 that extends upward from the base portion 41, and a piece that is disposed above the frame member 42. A holding portion 43 and a hook 44 provided on the cantilever portion 43 are provided.
The cantilever portion 43 is a plate-like member that extends to the outside of the portal frame 2, and the hook 44 can move in the width direction of the cantilever portion 43.

The moving operation of the erection machine 1 when using the cantilever crane 40 is the same as that when using the crane 4 except for the transportation of the block 9.
First, the portal frame 2 and the frame support 3 are installed at the replacement position A, and the cantilever crane 40 is moved to the replacement position A. Then, the existing precast floor slab 6 is divided into blocks 9. Next, the block 9 is suspended from the hook 44, and the hook 44 is moved to the outside of the portal frame 2. Then, the hook 44 is lowered, and the block 9 is removed below the bridge.

When the lower side of the bridge is available, unloading can be performed outside the gate type claim 2 by using the cantilever crane 40 for the construction machine 1. If it does so, it is not necessary to convey the block 9 etc. to the conveyance vehicle 7 many times, and the precast floor slab 5 can be replaced in a short time.
Further, the precast slab 5 temporarily placed in the lower space can be directly installed at the replacement position A without being transported to the bridge surface.

FIG. 17 shows in detail the erection machine 1 in which the second front support leg 20 and the second rear support leg 21 have independent frame supports 3.
The second front support leg 20 includes two suspension devices 25, and a moving means 26 is provided between the suspension devices 25. The second front support leg 20 is provided with two second hydraulic jacks 24 in the front-rear direction X (FIG. 17B). The second rear support leg 21 has the same structure as the second front support leg 20.
When the second front support leg 20 and the second rear support leg 21 have such shapes, the size of the entire support leg increases and the weight increases, but the width direction frame 22 and the front-rear direction frame 23 are not necessary. In addition, since the two second hydraulic jacks 24 are provided on one support leg, the frame support 3 can stably support the traveling frame 2. The shape of the second rear support leg 20 and the second front support leg 21 and the necessity of each frame can be appropriately selected according to the construction conditions.

So far, the operation to replace the straight existing concrete floor slab 6 has been described. However, since the lengths of the portal frame 2 and the frame support 3 are different, it is necessary to take measures when replacing the existing concrete floor slab 6 having a curvature. It becomes.
In this case, as shown in FIG. 18, the portal frame 2 has one traveling frame 12 shifted to the projecting portion of the width direction frame 22 and the other traveling frame 12 shifted to the width direction frame 22 side.
By doing so, the construction machine 1 can be used even when the existing concrete slab 6 having a curvature is replaced.

Although the present embodiment has been described above, the configuration described in the above embodiment can be selected or changed to other configurations as appropriate without departing from the gist of the present invention. .
For example, in the present embodiment, the frame support 3 may be anything that can adjust the lengths of the second front support legs 20 and the second rear support legs 21. Therefore, even when the front-rear direction frame 23 and the width direction frame 22 are not provided, the portal frame 2 can be floated and moved in the front-rear direction X. In addition, even when the roller 30 is not provided, the traveling frame 12 can be moved, for example, by placing a Teflon (registered trademark) plate with a small friction on the contact surface and sliding it.
Moreover, although the example which provided the 1st hydraulic jack 13 in the portal frame 2 was shown in this embodiment, even when this 1st hydraulic jack 13 is not provided, the height of the 2nd hydraulic jack 24 is adjusted. Thus, the gate frame 2 or the frame support 3 can be floated by relatively changing the vertical length of the portal frame 2 and the vertical length of the frame support 3.
Further, the crane 4 is not limited to the one shown in the present embodiment, and the shape of the crane 4 is not limited as long as it can move on the traveling frame 12.

1 Precast floor slab erection machine (erection machine)
2 Gate frame 3 Frame support 4 Crane (traveling suspension)
5 Precast floor slab 6 Existing concrete floor slab 7 Transport vehicle 8 Floor slab peeling device 9 Block 10 First front support leg 11 First rear support leg 12 Traveling frame 13 First hydraulic jack (frame telescopic jack)
18 Crane departure prevention device 19 Telescopic tent 20 Second front support leg 21 Second rear support leg 22 Width direction frame 23 Front / rear direction frame 24 Second hydraulic jack (support expansion / contraction jack)
25 Suspension device (suspension part)
26 Roller (moving means)
27 Moving device 30 Roller 36 Strut member 40 Cantilever crane 41 Base 42 Frame member 43 Cantilever 44 Hook A Replacement position X Front-rear direction Y Width direction

Claims (8)

In the precast floor slab erection machine that is installed at the replacement position of the existing concrete floor slab, conveys the precast floor slab by a traveling suspension device, and constructs the precast floor slab at the replacement position,
A first front support leg disposed forward of the replacement position, a first rear support leg disposed rearward of the replacement position, and between the first front support leg and the first rear support leg. A pair of portal frames provided and having a traveling frame on which the suspension device travels;
A support telescopic jack, disposed in front of the replacement position, a pair of second front support legs facing in the width direction, and a support telescopic jack, disposed rearward of the replacement position; A frame support having a pair of second rear support legs facing in the width direction,
The traveling frame is supported from below by the frame support,
By relatively changing the vertical length of the portal frame and the vertical length of the frame support, the portal frame or the frame support is floated,
Moving the portal frame or the frame support in the front-rear direction;
Precast floor slab erection machine characterized by that. The second front support leg and the second rear support leg have a width direction frame continuously provided in the width direction,
The precast slab erection machine according to claim 1. A front-rear frame that continuously connects the second front support leg and the second rear support leg in the front-rear direction;
The precast floor slab erection machine according to claim 1 or 2, characterized in that. The first front support leg and the first rear support leg include a frame telescopic jack,
The precast floor slab erection machine according to any one of claims 1 to 3, wherein Movement means is provided on the second front support leg and the second rear support leg,
Moving the portal frame in the front-rear direction by the moving means;
The precast floor slab erection machine according to any one of claims 1 to 4, wherein A suspension is formed on the frame support,
When the frame support floats, the suspension part is suspended from the traveling frame.
The precast slab erection machine according to any one of claims 1 to 5, wherein The suspension device is a cantilever crane,
The precast floor slab erection machine according to any one of claims 1 to 6, wherein A moving method of the precast floor slab erection machine at the precast floor slab replacement position according to any one of claims 4 to 7,
By extending the frame telescopic jack and shortening the support telescopic jack, the frame support is suspended from the traveling frame, and the second front support leg and the second rear support leg are set in a predetermined direction in the front-rear direction. Moving to a position;
Elongate the support telescopic jack, shorten the frame telescopic jack,
Floating the portal frame, balancing the load while moving the suspension device, and moving the traveling frame to a predetermined position in the front-rear direction.
A method for moving a precast slab erection machine at a precast slab replacement position.

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