JP2019210755A - Floor slab erection method - Google Patents

Abstract

To transport floor slabs and rails with one erection machine and simultaneously proceed with the installation of the floor slabs and the laying of the rails when the floor slabs are erected from the near side and erected while moving forward to the front.SOLUTION: A floor slab 2D for installation and rails 5D are transported by moving an erection machine 10 traveling on rails 5A to 5C laid above floor slabs 2A to 2C which have been installed already. The transported floor slab 2D is installed at a floor slab installation position X adjacent to the latest installed floor slab 2C, and after the installation of the floor slab, the transported rail 5D is laid next to the laid rail 5C. After the rails are laid, the erection machine 10 is retreated on the laid rails to receive floor slabs and rails for installation.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a method of laying a floor slab in a bridge, that is, a method of installing a precast concrete floor slab with reinforcing bars arranged in the extending direction on a main girder extending in the direction of the bridge axis.

  As shown in Patent Document 1, as a method of laying the floor slab, (1) a method of laying the floor slab from the front, and erection while sequentially retreating to the near side; There is a method of erection from the side and erection while moving forward. Which method is used depends on the situation at the site.

JP 2003-074018 A

  When the latter method, that is, the method of laying the floor slab from the near side and erection while sequentially moving forward, the erection machine that transports the installation floor slab runs on the installed floor slab, that is, It will run on the rails laid on the installed floor slab. Therefore, it is necessary to lay rails prior to installation of the floor slab.

  However, if the rails are laid prior to the installation of the floor slab, the work becomes double and the work efficiency deteriorates.

  The present invention has been made in view of such a situation, and in the case of adopting a method in which a floor slab is erected from the front side and erected while sequentially moving forward, a single erection machine can be used to It is an object of the present invention to provide a floor slab erection method capable of carrying and carrying out the simultaneous installation of the floor slab and the rail laying.

In order to solve the above problems, the present invention is a floor slab erection method in which a floor slab is installed on the main girder in the extending direction,
By the forward movement of the erection machine that runs on the rail laid above the installed floor slab, the installation floor slab and rail are transported,
Install the transported floor slab at the floor slab installation position adjacent to the latest installed floor slab,
After installing the slab, laying the transported rail connected to the laid rail,
After laying the rail, the laying machine is moved backward on the laid rail for receiving the floor slab for installation and the rail.

  According to the present invention, it is possible to carry the floor slab and the rail with a single laying machine, and to simultaneously proceed with the installation of the floor slab and the laying of the rail, thereby obtaining the effect of improving the work efficiency.

The figure which shows step 1-4 of 1st Embodiment of the floor slab erection method concerning this invention The figure which shows step 5-7 of 1st Embodiment same as the above. Front view corresponding to the A arrow view of FIG. Plan view corresponding to the view of arrow B in FIG. The figure which shows steps 1-4 of 2nd Embodiment of the floor slab erection method concerning this invention The figure which shows step 5-7 of 2nd Embodiment same as the above. Front view corresponding to the A arrow view of FIG. Plan view corresponding to the view of arrow B in FIG. The figure which shows step 1-4 of 3rd Embodiment of the floor slab erection method concerning this invention The figure which shows step 5-7 of 3rd Embodiment same as the above. The figure which shows steps 1-4 of 4th Embodiment of the floor slab erection method concerning this invention The figure which shows steps 5-8 of 4th Embodiment same as the above.

Hereinafter, embodiments of the present invention will be described in detail.
FIG. 1 shows steps 1 to 4 of the first embodiment of the slab erection method according to the present invention, and FIG. 2 shows steps 5 to 7 of the first embodiment.

  Note that “[1] STEP 1” to “[1] STEP 7” in FIGS. 1 and 2 indicate Steps 1 to 7 in the first embodiment. Similarly, “[2] STEP1” to “[2] STEP7” in FIGS. 5 and 6 described later indicate Steps 1 to 7 of the second embodiment, and in FIGS. 9 and 10 described later. “[3] STEP1” to “[3] STEP7” indicate steps 1 to 7 of the third embodiment, and “[4] STEP1” to “[4” in FIGS. 11 and 12 described later. [STEP 8] indicates Steps 1 to 8 of the fourth embodiment.

  3 is a front view corresponding to the A arrow view of FIG. 1 ([1] STEP 1), and FIG. 4 is a plan view corresponding to the B arrow view of FIG.

  A main girder (bridge girder) 1 of the bridge is made of H-section steel or the like and extends in the bridge axis direction. As can be seen from FIGS. 3 and 4, the main girder 1 has a four-row configuration in this embodiment.

  The floor slabs 2 (2A, 2B, 2C, 2D,...) Are transported one by one by the erection machine 10, and are arranged on the main girder 1 in the extending direction of the main girder 1, This constitutes the road surface. The floor slab 2 is written as 2A, 2B, 2C, 2D,... In the order of installation.

  In FIG. 1, the installation direction of floor slab installation is from left to right, and on the left side are floor slabs 2A, 2B and 2C which are already installed on the main girder 1. The installation floor slab 2D) transported by the machine 10 is installed at the floor slab installation position X adjacent to the latest installed floor slab 2C. In addition, that the construction machine 10 advances in the construction direction is referred to as advance, and movement in the direction opposite to the construction direction is referred to as retreat.

  In the present embodiment, the floor slab 2 (2A, 2B, 2C, 2D,...) Is made of precast concrete with reinforcing bars, the short side is along the bridge axis direction, and the long side is perpendicular to the bridge axis. Install along. The length of the bridge slab 2 in the bridge axis direction (front-rear direction) is approximately 2 m, for example, and the length in the direction perpendicular to the bridge axis (bridge width direction) is approximately 10 m, for example.

  The floor slabs 2 (for example, 2A and 2B) adjacent in the bridge axis direction (front-rear direction) are installed with a gap (s) of about 30 to 40 cm. Reinforcing bars (fixing joints) 20 protrude from each floor slab 2 toward the gap. In this gap, after the floor slab 2 is installed, the concrete to be filled (mortar) is placed.

  The erection machine 10 conveys the installation floor slab 2 (for example, 2D) by lifting it with a hoist crane etc. one by one from the material storage place outside the left figure, and has wheels 11 and 12 on the front and rear legs, respectively. And travel on rails 5 (5A, 5B, 5C,...).

The rail 5 is used by connecting standard rails 5A, 5B, 5C,... Divided into the same length as the arrangement pitch of the floor slab 2, and each rail 5A, 5B, 5C,. , Installed on the installed floor slabs 2A, 2B, 2C,. Accordingly, the rail 5 is also indicated as 5A, 5B, 5C,... Corresponding to the floor slabs 2A, 2B, 2C,.
If an aluminum material is used as the rail instead of the steel material, the weight can be reduced to about 1/3 and the working efficiency can be improved.

The rails 5 (5A, 5B, 5C, 5D,...) Are also transported one by one (a pair of left and right) by the construction machine 10 and installed on the installed floor slab 2.
Accordingly, the erection machine 10 transports the installation floor slab 2 (for example, 2D), installs the transported floor slab 2D on the main girder 1, and also transports and transports the installation rail 5 (for example, 5D). It installs on the floor slab 2D which installed the rail 5D. Specifically, when the rail 5D is installed on the floor slab 2D, the rail 5D is slightly shifted to the rear side and installed on the floor slabs 2D and 2C.

  The erection machine 10 also has an auxiliary wheel 13 that can move up and down together with auxiliary legs in front of the front wheel 11, and the auxiliary wheel 13 can travel on the main girder 1. The front wheels 11 can also be lifted and lowered together with the front legs.

  Next, a first embodiment of a floor slab erection method will be described with reference to FIGS. 1 and 2 in order of steps.

The state before the work start in step 1 will be described.
On the left side of the floor slab installation position X, the floor slab 2 (2A, 2B, 2C) has already been installed on the main girder 1. And the rail 5 (5A, 5B, 5C) is laid on the installed floor slab 2 (2A, 2B, 2C) 1.

In step 1, the erection machine 10 receives the floor slab 2D for installation and the rail 5D from the material storage place outside the left side figure, and lifts and conveys them with a hoist crane or the like.
The construction machine 10 travels on the rails 5A, 5B, and 5C, and the front wheels 11 are positioned on the rails 5C and the rear wheels 12 are positioned on the rails 5B. At this time, the auxiliary wheel 13 in front of the front wheel 11 is positioned above the main girder 1 in front of the tip of the rail 5C.

  In step 2, the leg portion supporting the front auxiliary wheel 13 is extended, the front auxiliary wheel 13 is lowered, and is brought into contact with the main girder 1. After the auxiliary wheel 13 is grounded, the front wheel 11 is raised and stored together with the legs supporting the front wheel 11. Thereby, the construction machine 10 is supported by the front side auxiliary wheel 13 and the rear side wheel 12.

  In step 3, the construction machine 10 is moved forward. That is, the front auxiliary wheel 13 is made to travel on the main beam 1 and the rear wheel 12 is made to travel on the rails 5B and 5C. Thereby, the construction machine 10 straddles the floor slab installation position X.

  In step 4, the installation floor slab 2D is lowered onto the main beam 1 from the erection machine 10. As a result, the floor slab 2D is installed at a position having a regular pitch with respect to the installed floor slab 2C.

  In step 5, the installation rail 5D is lowered from the laying machine 10 onto the floor slab 2D (specifically, slightly shifted to the rear side and on the floor slabs 2D and 2C). Thereby, rail 5D is installed in the form connected with installed rail 5C.

In step 6, the construction machine 10 is moved backward to a position where the front wheel 11 of the construction machine 10 is located above the rail 5D installed this time.
Next, the leg portion that supports the front wheel 11 is extended, and the front wheel 11 is lowered and brought into contact with the rail 5D. After the front wheel 11 is grounded, the front auxiliary wheel 13 is raised and stored together with the legs supporting the front auxiliary wheel 13. Thereby, the construction machine 10 is supported by the front wheel 11 and the rear wheel 12.

In step 7, the construction machine 10 is moved backward. That is, the front and rear wheels 11 and 12 are caused to travel on the rails 5D, 5C, 5B, and 5A. As a result, the erection machine 10 goes to the material storage area outside the left side figure to receive the floor slab and rail to be installed next.
Thereafter, the process returns to step 1 to repeat the slab erection work.

  According to the present embodiment, the floor slab 2D for installation and the rail 5D are moved by the forward movement of the erection machine 10 traveling on the rails 5A, 5B, 5C laid above the installed floor slabs 2A, 2B, 2C. And the transported floor slab 2D is installed at the floor slab installation position X adjacent to the latest installed floor slab 2C. After the floor slab is installed, the transported rail 5D is placed on the already installed rail 5C. It is characterized by laying in series, and after laying the rail, the construction machine 10 is moved backward on the installed rail for receiving the installation floor slab and the rail. As a result, the floor slab and rail can be transported by one erection machine 10, and the installation of the floor slab and the laying of the rail can be advanced at the same time, so that the work efficiency can be improved.

  Further, according to the present embodiment, the erection machine 10 is provided with a front wheel 11 and a rear wheel 12 that travel on the rail, and a front side that can be moved forward and backward from the front wheel 11 and can travel on the main girder 1. Auxiliary wheels 13 are provided, and the erection machine 10 is characterized in that when the floor slab is installed, the front auxiliary wheel 13 is placed on the main girder 1 and the rear wheel 12 is placed on the rail to straddle the floor slab installation position. To do. By using such a construction machine 10, the floor slab erection work can be performed without laying the rail ahead of the floor slab installation position.

  Moreover, according to this embodiment, the rail 5 is directly laid on the installed floor slab 2. By adopting such a rail support structure, the rail laying operation can be simplified.

  Next, a second embodiment of the present invention will be described with reference to FIGS. In the second embodiment, elements corresponding to those in the first embodiment are denoted by the same reference numerals, and description thereof is simplified.

FIG. 5 shows steps 1 to 4 of the second embodiment of the slab erection method according to the present invention, and FIG. 6 shows steps 5 to 7 of the second embodiment.
7 is a front view corresponding to the A arrow view of FIG. 5 (part [2] STEP 1), and FIG. 8 is a plan view corresponding to the B arrow view of FIG.

In the first embodiment, the rail 5 (5A, 5B, 5C) is directly laid on the installed floor slab 2 (2A, 2B, 2C).
However, the floor slab immediately after installation is in an incomplete state. The floor slab made of precast concrete with reinforcing bars is installed with a predetermined gap between the floor slabs, and reinforcing bars (joining joints) protrude from both floor slabs. Therefore, the concrete is completed by placing the interstitial concrete (mortar) in this gap.
For this reason, it may be unpreferable to apply the load of a construction machine to the floor slab in an incomplete state immediately after installation of a floor slab.

  Therefore, in the second embodiment, the construction structure of the rail is devised so that the construction machine can run without applying the load of the construction machine to the installed floor slab. For this reason, the rail 5 (5A, 5B, 5C) is arranged above the installed floor slab 2 (2A, 2B, 2C) and floated from the floor slab 2, without applying a load to the floor slab 2, The main girder 1 is laid and supported.

The support structure of the rail 5 will be described in detail.
Each rail 5 (5A, 5B, 5C,...) Is supported by the main girder 1 via support legs (bundles) 6 and receiving beams 7.

  The support leg 6 is a short column (bundle) made of steel, and is positioned on the main girder 1 between the adjacent front and back floor slabs 2 (for example, 2A and 2B). , Removably fixed.

  Therefore, the support legs 6 are arranged at the same pitch as the arrangement pitch of the floor slab 2 in the bridge axis direction. Since the main girder 1 is provided in a plurality of rows as shown in FIGS. 7 and 8, a plurality of support legs 6 are arranged in a direction perpendicular to the bridge axis. Further, there are reinforcing bars (fittings for fixing) 20 protruding from the floor slabs 2 in the gaps between the adjacent floor slabs 2, but the reinforcing bars 20 do not exist on the main girder 1.

  The receiving beam 7 is, for example, an H-shaped steel, is arranged so as to extend in a direction perpendicular to the bridge axis, and is fixed on a plurality of support legs 6 arranged in a direction perpendicular to the bridge axis. Accordingly, the receiving beams 7 are also arranged at the same pitch as the arrangement pitch of the floor slabs 2 in the bridge axis direction.

  In actual handling, one receiving beam 7 and four supporting legs (bundles) 6 in this example on the lower surface side are integrated in advance, and an integrated object (receiving beam 7 with supporting legs 6). Treat as. As a result, it is possible to attach / remove the receiving beam 7 at the site by simply attaching / detaching the support leg 6 to / from the main girder 1.

  Here, each rail 5 (5A, 5B, 5C,...) Is fixed by placing both ends on receiving beams 7 adjacent in the bridge axis direction (front-rear direction). Thereby, the several rail 5 (5A, 5B, 5C, ...) is connected.

  Accordingly, the rail 5 is supported by the support legs 6 and extends in a direction perpendicular to the main girder 1 via the support legs (bundles) 6 disposed on the main girder 1 between the adjacent front and rear floor slabs 2. (The receiving beam 7 is supported as a sleeper).

  In the second embodiment, since such a support structure for the rail 5 is employed, the floor frame 2 and the receiving beam 7 with the support legs 6 and the rail 5 are transported together with the floor slab 10 by the erection machine 10, and the floor 5 is used. While installing the plate 2, the receiving beam 7 with the support legs 6 and the rail 5 are installed.

  Next, a second embodiment of the floor slab erection method will be described with reference to FIGS. 5 and 6 in order of steps.

The state before the work start in step 1 will be described.
On the left side of the floor slab installation position X, the floor slab 2 (2A, 2B, 2C) has already been installed on the main girder 1. And, on the main girder 1, the receiving beam 7 with the supporting leg 6 is arranged between the adjacent front and rear floor slabs 2 (front and rear of each floor slab 2), and the rail 5 ( 5A, 5B, 5C) are supported.

In step 1, the erection machine 10 receives the floor slab 2D for installation, the rail 5D, and the receiving beam 7 with the supporting legs 6 from the material storage area not shown on the left side, and lifts and conveys them with a hoist crane or the like. .
The construction machine 10 travels on the rails 5A, 5B, and 5C, and the front wheels 11 are positioned on the rails 5C and the rear wheels 12 are positioned on the rails 5B. At this time, the auxiliary wheel 13 in front of the front wheel 11 is positioned above the main girder 1 in front of the tip of the rail 5C.

  In step 2, the leg portion supporting the front auxiliary wheel 13 is extended, the front auxiliary wheel 13 is lowered, and is brought into contact with the main girder 1. After the auxiliary wheel 13 is grounded, the front wheel 11 is raised and stored together with the legs supporting the front wheel 11. Thereby, the construction machine 10 is supported by the front side auxiliary wheel 13 and the rear side wheel 12.

  In step 3, the construction machine 10 is moved forward. That is, the front auxiliary wheel 13 is made to travel on the main beam 1 and the rear wheel 12 is made to travel on the rails 5B and 5C. Thereby, the construction machine 10 straddles the floor slab installation position X.

  In step 4, the floor slab 2D for installation is lowered from the construction machine 10. At this time, it is lowered slightly forward from the regular installation position so as not to interfere with the receiving beam 7 supporting the front end of the installed rail 5C.

  In Step 5, the floor slab 2D is slid to the normal position on the left side of the drawing (position where the pitch is normal with respect to the installed floor slab 2C) while being hung by the hoist crane of the construction machine 10. Thereby, the floor slab 2D is installed at a regular position.

In step 6, the receiving beam 7 is installed by lowering the receiving beam 7 with the supporting legs 6 from the erection machine 10 and supporting it on the main girder 1 on the front side of the floor slab 2D installed this time.
Then, the rail 5D is lowered from the construction machine 10 so as to be supported by the receiving beams 7 before and after the floor slab 2D installed this time, and the rail 5D is installed.

In step 7, the construction machine 10 is moved backward to a position where the front wheel 11 of the construction machine 10 comes above the rail 5D installed this time.
Next, the leg portion that supports the front wheel 11 is extended, and the front wheel 11 is lowered and brought into contact with the rail 5D. After the front wheel 11 is grounded, the front auxiliary wheel 13 is raised and stored together with the legs supporting the front auxiliary wheel 13. Thereby, the construction machine 10 is supported by the front wheel 11 and the rear wheel 12.
Next, the construction machine 10 is moved backward. That is, the front and rear wheels 11 and 12 are caused to travel on the rails 5D, 5C, 5B, and 5A. As a result, the erection machine 10 goes to the material yard outside the left side figure to receive the floor slab, rail, and receiving beam with support legs to be installed next.
Thereafter, the process returns to step 1 to repeat the slab erection work.

  According to the present embodiment, the rail 5 is laid and supported above the installed floor slab 2 by the main girder 1 without applying a load to the floor slab 2. Thereby, the construction machine 10 can be traveled without applying a load to the installed floor slab 2.

  Further, according to the present embodiment, the rail 5 is supported by the support leg 6 via the support leg (bundle) 6 disposed on the main girder 1 between the adjacent front and back floor slabs 2 and the main girder 1. It is supported by the receiving beam 7 extending in the orthogonal direction. Thereby, the rail 5 can be reliably supported without applying a load to the floor slab 2.

  Further, according to the present embodiment, when the floor slab is installed, the floor slab 2 is hung forward from the regular floor slab installation position and then slid rearward (front side) to be installed at the regular floor slab installation position. It is characterized by doing. Thereby, the floor slab 2 can be correctly installed regardless of the presence of the receiving beam 7.

  Next, a third embodiment of the present invention will be described with reference to FIGS. Note that in the third embodiment, elements corresponding to those in the first embodiment are denoted by the same reference numerals, and description thereof is simplified.

  FIG. 9 shows steps 1 to 4 of the third embodiment of the floor slab erection method according to the present invention, and FIG. 10 shows steps 5 to 7 of the third embodiment.

In the first embodiment, the installation of the floor slab and the laying of the rail are simultaneously advanced.
In contrast, in the third embodiment, the rail 5 is laid before the floor slab 2 is installed, and a temporary rail RL longer than the standard rail is laid at the floor slab installation position X. Therefore, the construction machine 10 has only the front wheels 11 and the rear wheels 12, travels on the rail 5, and can straddle the floor slab installation position X. And whenever the floor slab 2 is installed, the rail of the floor slab installation position X is transferred.

  Next, a third embodiment of the floor slab erection method will be described with reference to FIGS. 9 and 10 in order of steps.

The state before the work start in step 1 will be described.
On the left side of the floor slab installation position X, the floor slab 2 (2A, 2B) has been installed on the main beam 1. And the rail 5 (5A, 5B) is laid on the installed floor slab 2 (2A, 2B).

Further, temporary rails RL, standard rails 5D, 5E,... Are laid in a form connected to the standard rails 5A, 5B on the installed floor slabs 2A, 2B.
The temporary rail RL is disposed above the floor slab installation position X and is longer than the standard rail. The temporary rail RL and the standard rails 5D and 5E are supported on the main girder 1 via support legs (or receiving beams) 6 having a height corresponding to the thickness of the floor slab 2.

  The erection machine 10 carries the installation floor slab 2 (for example, 2C) by lifting it with a hoist crane etc. one by one from the material storage place outside the left side figure, and replacing it with a temporary rail at the previous floor slab installation work. The floor slab 2 is received and transported in a state where a rail (for example, 5C) temporarily collected in step 1 is lifted.

  In step 1, the temporary rail RL above the floor slab installation position X is manually removed from the state where the construction machine 10 straddles the floor slab installation position X as indicated by the dotted line. This is because it hinders the suspension of the floor slab 2C from the construction machine 10.

  In step 2, the floor slab 2C for installation is lowered from the construction machine 10. Thereby, the floor slab 2C is installed at a position having a regular pitch with respect to the installed floor slab 2B.

  In step 3, the installation rail (standard rail) 5C is lowered from the installation machine 10 onto the installed floor slab 2C (specifically, slightly shifted to the rear side and on the floor slabs 2C and 2B). As a result, the rail 5C is installed in a form connected to the installed rail 5B.

  In step 4, the construction machine 10 is moved forward, the front wheel 11 is placed on the rail 5E, the rear wheel 12 is placed on the rail 5C, and the construction machine 10 is above the next floor slab installation position X. It straddles the rail 5D.

  In step 5, the hoist crane of the construction machine 10 is lifted and the rail 5D is removed as shown by the dotted line. Next, the support leg (or receiving beam) 6 that has supported the rear end of the rail 5D is removed manually as indicated by the dotted line.

  In step 6, the temporary rail RL longer than the standard rail is manually supported by the front edge of the installed floor slab 2C and the support leg (or receiving beam) 6 supporting the front end of the rail 5E. Install. This is for enabling the construction machine 10 to move backward.

In step 7, the erection machine 10 moves backward while lifting and holding the rail 5D, receives the next floor slab 2D to be installed from the material storage place outside the left side figure, and moves forward to receive the next floor. Return to plate setting position X.
Thereafter, the process returns to step 1 and the slab erection work is repeated from the removal of the temporary rail RL.

  According to the present embodiment, the rail 5 is laid in advance from above the installed floor slab 2 to a position exceeding the floor slab installation position X, and the rail at the floor slab installation position X is longer than the standard rail. As the temporary rail RL, the erection machine 10 is located on the rail 5 before and after the floor slab installation position X across the floor slab installation position X, and removes the temporary rail RL at the floor slab installation position X when the floor slab is installed. After that, the floor slab 2 is installed on the main girder 1, and after the floor slab is installed, the standard rail transported by the laying machine 10 is connected to the already-laid rail 5 and laid. Thus, the floor slab erection machine 10 can always travel on the rail 5 and can have a simple structure.

  Next, a fourth embodiment of the present invention will be described with reference to FIGS. Note that in the fourth embodiment, elements corresponding to those in the first embodiment and the second embodiment are denoted by the same reference numerals, and description thereof is simplified.

  FIG. 11 shows steps 1 to 4 of the fourth embodiment of the floor slab erection method according to the present invention, and FIG. 12 shows steps 5 to 8 of the fourth embodiment.

  The fourth embodiment is a modification of the third embodiment. Like the second embodiment, the rail is lifted from the floor slab so that the load of the construction machine is not applied to the installed floor slab. .

  Next, a fourth embodiment of a floor slab erection method will be described with reference to FIGS. 11 and 12 in order of steps.

  In step 1, the temporary rail RL above the floor slab installation position X is manually removed from the state where the construction machine 10 straddles the floor slab installation position X as indicated by the dotted line. This is because it hinders the suspension of the floor slab 2C from the construction machine 10.

  In step 2, the floor slab 2C for installation is lowered from the construction machine 10. Since the span of the front and rear receiving beams 7 is longer than the standard, the floor slab 2C can be lowered without interfering with the front and rear receiving beams 7.

  In Step 3, the floor slab 2C is slid to the normal position on the left side of the drawing (position where the pitch is normal with respect to the installed floor slab 2B) while being suspended by the hoist crane of the construction machine 10.

In step 4, the receiving beam with the supporting leg 6 is positioned at a regular pitch with respect to the receiving beam 7 with the supporting leg 6 on the rear side of the floor slab 2 installed on the front side of the floor slab 2 </ b> C installed this time. 7 is installed manually.
Thereafter, the installation rail (standard rail) 5C is lowered from the construction machine 10. As a result, the rail 5C is installed by being supported by the receiving beams 7 before and after the floor slab 2C installed this time.

  In step 5, the construction machine 10 is moved forward, the front wheel 11 is placed on the rail 5E, the rear wheel 12 is placed on the rail 5C, and the construction machine 10 is above the next floor slab installation position X. It straddles the rail 5D.

  In step 6, the hoist crane of the construction machine 10 is lifted and the rail 5D is removed as shown by the dotted line. Next, the receiving beam 7 with the supporting leg 6 that has supported the rear end portion of the rail 5D is removed manually as indicated by the dotted line.

  In step 7, the temporary rail RL longer than the standard rail is manually installed so as to be supported by the receiving beams 7 before and after the next floor slab installation position X. This is for enabling the construction machine 10 to move backward.

In step 8, the construction machine 10 moves backward while lifting and holding the rail 5D, receives the next floor slab 2D to be installed from the material storage place outside the left side figure, moves forward, and moves forward to the next floor. Return to plate setting position X.
Thereafter, the process returns to step 1 and the slab erection work is repeated from the removal of the temporary rail RL.

  The illustrated embodiments are merely examples of the present invention, and the present invention is not limited to those directly described by the described embodiments, and various improvements and modifications made by those skilled in the art within the scope of the claims. Needless to say, it encompasses changes.

1 Main girder 2 (2A, 2B, 2C, 2D, ...) Floor slab 5 (5A, 5B, 5C, 5D, ...) Rail 6 Support leg (bundle)
7 Receiving beam 10 Construction machine 11, 12 Wheel 13 Auxiliary wheel

Claims (7)

A floor slab installation method in which a floor slab is installed on the main girder in the extending direction,
By the forward movement of the erection machine that runs on the rail laid above the installed floor slab, the installation floor slab and rail are transported,
Install the transported floor slab at the floor slab installation position adjacent to the latest installed floor slab,
After installing the slab, laying the transported rail connected to the laid rail,
A floor slab erection method, wherein after the rail has been laid, the erection machine is moved backward on the laid rail to receive the floor slab for installation and the rail. The construction machine includes a front wheel and a rear wheel that travel on a rail, and a front auxiliary wheel that can be moved up and down forward from the front wheel and can travel on the main girder,
2. The construction machine according to claim 1, wherein when the floor slab is installed, the front auxiliary wheel is placed on the main girder and the rear wheel is placed on the rail to straddle the floor slab installation position. Floor slab construction method. The rail is laid in advance from above the installed floor slab to a position exceeding the floor slab installation position, and the rail at the floor slab installation position is a temporary rail longer than the standard rail,
The laying machine is located on the rails before and after the floor slab installation position, straddling the floor slab installation position during floor slab installation,
After removing the temporary rail at the floor slab installation position, install the floor slab on the main girder,
2. The floor slab erection method according to claim 1, wherein after installation of the slab, the standard rail transported by the erection machine is laid along with the already laid rail.   The said rail is directly laid on the installed floor slab, The floor slab erection method as described in any one of Claims 1-3 characterized by the above-mentioned.   4. The rail according to claim 1, wherein the rail is laid and supported above the installed floor slab without applying a load to the floor slab. The slab erection method described in 1.   The rail is supported by a receiving beam supported by the support leg and extending in a direction orthogonal to the main girder via a support leg arranged on the main girder between adjacent floor slabs. Item 5. A slab erection method according to item 5.   The floor slab according to claim 6, wherein when the floor slab is installed, the floor slab is suspended from the regular floor slab installation position and then slid backward to be installed at the regular floor slab installation position. Construction method.