JP2016204925A - Prestressed Concrete Slab - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a prestressed concrete slab capable of improving earthquake resistance of the whole bridge by reducing weight of a floor slab.SOLUTION: A prestressed concrete slab 1 using fiber-reinforced concrete includes a plate part 2, and a lattice-shaped rib 3 that comprises longitudinal and transverse ribs 31 and 32 formed on an undersurface of the plate part 2. The longitudinal rib 31 is prestressed by a post-tensioning system, and the transverse rib 32 is prestressed by a pre-tensioning system.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a prestressed concrete floor slab.

  Design guidelines have been revised due to large-scale disasters such as the Great Hanshin Earthquake and the Great East Japan Earthquake. On the other hand, some existing bridges do not meet the revised design guidelines. For such bridges, renovation work may be implemented for the purpose of seismic reinforcement.

In some cases, the floor slabs are replaced as an improvement work for existing bridges.
If the floor slab used for the replacement work is lightweight, it will be possible to reduce the burden on the existing bridge pier, and in turn improve the earthquake resistance of the entire bridge.
In addition, the workability can be improved by reducing the weight of the precast slab.

Currently, many prestressed concrete slabs are used for bridge slabs.
In prestressed concrete slabs, it is common to place PC steel and reinforcing bars. Considering the arrangement of PC steel and reinforcing bars, it was efficient to use a flat plate structure as the basic shape of the prestressed concrete slab (see, for example, Patent Document 1).

JP 2009-264040 A

In the conventional prestressed concrete slab, in addition to the arrangement of the PC steel material, it is necessary to consider the concrete covering of the reinforcing bars and the perforation between the reinforcing bars or between the reinforcing bars and the PC steel material. End up. When the floor slab thickness is large, the weight of the floor slab becomes heavy.
From such a viewpoint, an object of the present invention is to propose a prestressed concrete slab capable of improving the earthquake resistance of the entire bridge by reducing the weight.

  In order to solve the above-mentioned problem, the prestressed concrete floor slab of the present invention uses fiber reinforced concrete, and a grid-like rib composed of a plate portion and vertical and horizontal ribs formed on the lower surface of the plate portion. And prestress is introduced into the vertical rib and the horizontal rib.

According to such a prestressed concrete slab, since the fiber reinforced concrete is adopted, the reinforcing bars can be omitted. Therefore, as the minimum shape necessary for arranging the reinforcing material, it is only necessary to consider the arrangement and covering of the PC steel material, so that it is possible to reduce the thickness of the floor slab and thus to reduce the weight. be able to.
Then, by arranging the PC steel material on the grid-like ribs, the plate portion can be thinned. Therefore, the plate portion may have a minimum member thickness of 40 mm or less, for example.

  If prestress is introduced into one of the longitudinal ribs and the transverse ribs by a pretension method and prestress is introduced to the other by a posttension method, prestress can be introduced evenly. Become.

  In addition, it is desirable that at least a pair of pretension PC steel materials be arranged at positions facing each other across the post tension PC steel material at the intersection between the vertical ribs and the horizontal ribs.

  According to the prestressed concrete floor slab of the present invention, it is possible to improve the earthquake resistance of the entire bridge by reducing the weight of the floor slab.

It is a figure which shows the prestressed concrete floor slab of embodiment of this invention, Comprising: (a) is a perspective view desired from an upper surface, (b) is a perspective view desired from a lower surface. (A) is AA sectional drawing of FIG. 1, (b) is BB sectional drawing, (c) is CC sectional drawing. (A) is an expanded plane sectional view of the junction part of a prestressed concrete floor slab, (b) is DD sectional drawing of (a).

  In the embodiment of the present invention, a precast prestressed concrete floor slab 1 (hereinafter simply referred to as “floor slab 1”) using fiber reinforced concrete used for floor slab replacement work of an existing road bridge will be described. .

  As shown in FIGS. 1A and 1B, the floor slab 1 of the present embodiment includes a plate portion 2 formed in a flat plate shape and lattice-like ribs formed on the lower surface (back surface) of the plate portion 2. 3, a tension material 4 disposed on the lattice-like rib 3, and a joint portion 5 formed at an end portion in the bridge axis direction LG.

The plate part 2 constitutes the upper part (road surface side part) of the floor slab 1, is formed of fiber-reinforced concrete, and no reinforcing bars are arranged inside.
The plate thickness of the plate portion 2 may be set as appropriate according to the assumed loading load, own weight, etc., but in the present embodiment, the minimum member plate thickness t _{min is set} to 40 mm or less (see FIG. 2A). ). The minimum member thickness t _min of the plate portion 2 is not limited to 40mm or less, it may be set as appropriate.

A thickened portion may be formed on the plate portion 2 according to the position of the bridge girder.
The height (thickness) of the thickened portion is set so that the road surface height of the bridge constructed using the newly installed floor slab 1 is the same as the road surface height before the repair.
Note that the cross-sectional shape of the thickened portion is not limited, and for example, it may be formed in a rectangular shape or a trapezoidal shape when viewed in cross section.

The grid-like ribs 3 are parts formed integrally with the plate portion 2 and extend along the bridge axis direction LG (the short side direction of the floor slab 1) as shown in FIG. The vertical ribs 31 and the horizontal ribs 32 extending along the direction perpendicular to the vertical ribs 31 (long side direction of the floor slab) are formed.
Prestress is introduced into the longitudinal ribs 31 and the transverse ribs 32 by a tension material (PC steel material) 4.

  In the present embodiment, ten vertical ribs 31 are juxtaposed at intervals in the long side direction of the floor slab 1 (direction orthogonal to the bridge axis direction LG). Moreover, in this embodiment, the two horizontal ribs 32 are arranged in parallel at intervals in the short side direction (bridge axis direction LG) of the floor slab 1.

  In addition, the number of the vertical ribs 31 and the horizontal ribs 32 is not limited. Further, the interval between the vertical ribs 31 and the horizontal ribs 32 may be set as appropriate in accordance with the assumed loading load and the location of action, and is not necessarily equal. Furthermore, the vertical rib 31 may be inclined with respect to the short side direction of the floor slab 1, and the horizontal rib 32 may not be orthogonal to the vertical rib 31.

The interval between the lattice ribs 3 is, for example, the maximum value of the tensile principal stress generated when the T load of the road bridge specification is applied to the position of the minimum member plate thickness t _min of the plate portion, and fiber reinforcement. What is necessary is just to determine by comparing with the crack generation intensity of concrete.

  Prestress by a post tension system is introduced into the vertical ribs 31, and prestress by a pre tension system is introduced into the horizontal ribs 32.

  In addition, although the introduction method of the prestress to the vertical rib 31 and the horizontal rib 32 is not limited, From a viewpoint of introducing the prestress to the whole floor slab 1 more effectively, the vertical rib 31 and the horizontal rib 32 are used. It is desirable that either one of them is a pretension type and the other is a post tension type.

  As shown in FIG. 2A, a pipe material 40 is embedded in the center of the cross section of the vertical rib 31. A PC steel rod 41 as a post-tension tension material 4 is inserted into the tube material 40.

  Although the material which comprises the pipe material 40 is not limited, a sheath pipe | tube is used in this embodiment. Moreover, the material which comprises the tension | tensile_strength material 4 is not limited to a PC steel rod, For example, a PC steel strand may be sufficient.

The end of the steel bar 41 is fixed to the joint 5 as shown in FIG.
A bolt box 50 is formed in the joint portion 5 corresponding to the position of the pipe material 40.
Both end portions of the steel bar 41 protrude into the bolt box 50 and are fixed to the joint portion 5 by screwing a nut 43 in the bolt box 50.

As shown in FIG. 2 (c), a PC steel strand 42 is embedded in the lateral rib 32 as the tension material 4 for pretension. In the present embodiment, in each horizontal rib 32, two PC steel strands 42 arranged side by side in the horizontal direction are arranged in two upper and lower stages (four in total).
The PC steel strand 42 is embedded in the cross section of the lateral rib 32 and is fixed in the lateral rib 32.

The upper PC steel stranded wire 42 and the lower PC steel stranded wire 42 are opposed to each other with the PC steel rod 41 interposed therebetween at the intersection between the vertical rib 31 and the horizontal rib 32 as shown in FIG. Arranged in position.
In addition, arrangement | positioning and the number of the strands 42 from PC steel are not limited. Further, the tension member 4 embedded in the lateral rib 32 is not limited to the strand made of PC steel, and may be a PC steel rod, for example.

  As shown in FIG. 1, the joint 5 is formed in a rectangular shape in cross section at the end of the floor slab 1. In the present embodiment, the height of the joint portion 5 is made equal to the height of the grid rib 3. In addition, the height of the junction part 5 is not limited, It may be higher than the grid | lattice-like rib 3, and may be low.

  As shown in FIGS. 3A and 3B, the joint portion 5 is formed with a plurality of through holes 51 along the bridge axis direction LG. The through hole 51 is disposed at a position where it does not overlap the PC steel rod 41 and the PC steel wire 42.

  The through hole 51 is parallel to the PC steel rod 41 and is formed by a pipe material (for example, a sheath pipe) embedded in the joint portion 5. A joint PC steel rod 52 for joining with another adjacent floor slab 1 is inserted into the through hole 51.

The joint PC steel bar 52 is disposed across the joints 5, 5 of the adjacent floor slabs 1, 1. One end of the joint PC steel bar 52 is the joint 5 of one floor slab 1. The other end projects from the end surface of the joint 5 of the other floor slab 1. When the nut 53 is screwed to both ends (protruding portions) of the joint PC steel rod 52, the floor slabs 1 are connected to each other.

Next, the construction method of the floor slab 1 of this embodiment is demonstrated.
First, the floor slab 1 prestressed in a direction orthogonal to the bridge axis direction LG by the PC steel strand 42 is placed on the bridge girder. The floor slab 1 is installed in a state where the other floor slab 1 placed on the bridge girder in advance and the joints 5 are abutted with each other.

When the floor slab 1 is placed, the steel bar 41 is used to introduce prestress in the bridge axis direction LG, and the adjacent floor slabs 1 are joined to each other using the through hole 51.
The steel bar 41 may be inserted through the pipe 40 in advance, or may be inserted through the pipe 40 after placing the floor slab 1 on the bridge girder.

  Moreover, the joining between the floor slabs 1 is performed by inserting the joining part PC steel rod 52 between the joining parts 5 (through holes 51) of the adjacent floor slabs 1 and screwing the nuts 53 ( (See (a) of FIG. 3).

  According to the floor slab 1 of this embodiment, since the fiber reinforced concrete is adopted, the reinforcing bars can be omitted in the plate portion 2. Furthermore, since the tension members 4 are disposed on the lattice-like ribs 3, it is possible to reduce the thickness of the plate portion 2 and to reduce the weight of the floor slab 1 as a whole.

Moreover, since the dimension and shape of the grid | lattice-like rib 3 should just be a dimension and shape which can ensure a covering with the circumference | surroundings of the PC steel material 4, the cross-section of the floor slab 1 can be reduced.
By reducing the weight of the floor slab 1, dead loads can be reduced, and consequently the seismic performance of foundations such as piers and footings can be improved.

  Since prestress is introduced into the vertical ribs 31 by a post-tension method and prestress is introduced into the horizontal ribs 32 by a pre-tension method, it is possible to introduce prestress evenly over the entire floor slab 1. .

When the post-tension method is adopted, it is not necessary to consider the fixing loss length of the PC steel material 4, so that prestress is effectively introduced.
In addition, since prestress is introduced through the lattice-like ribs 3, prestress introduction efficiency is better than that of a conventional flat plate floor slab.

Although the embodiment of the present invention has been described above, the present invention is not limited to the above-described embodiment, and the above-described components can be appropriately changed without departing from the spirit of the present invention.
For example, in the above-described embodiment, the case where the prestressed concrete slab of the present invention is used to replace an existing bridge floor slab has been described, but the purpose of use of the prestressed concrete slab is not limited thereto. For example, it may be used for a new bridge.

  In the above embodiment, the case where the prestressed concrete slab of the present invention is used for the road bridge repair work has been described. However, the type of the bridge to be repaired is not limited. For example, a bridge for a railway It may be.

  In the above-described embodiment, two pre-tension PC steel materials are disposed above and below the post-tension PC steel material at the intersection of the vertical rib and the horizontal rib. The PC steel material for use only needs to be opposed to the PC steel material for post tension, and the number of pre-tension PC steel materials is not limited.

1 Floor slab (Prestressed concrete floor slab)
2 Plate part 3 Grid-shaped rib 31 Vertical rib 32 Horizontal rib 4 Tension material (PC steel material)
41 PC steel bar (PC steel for post tension)
42 PC steel strand (PC steel for pre-tensioning)

Claims (4)

It is a prestressed concrete slab using fiber reinforced concrete,
A plate portion, and a grid-like rib composed of a longitudinal rib and a lateral rib formed on the lower surface of the plate portion,
A prestressed concrete floor slab, wherein prestress is introduced into the vertical rib and the horizontal rib.   2. The prestressed state according to claim 1, wherein prestress is introduced into one of the longitudinal ribs and the transverse ribs by a pretension method, and prestress is introduced into the other side by a posttension method. Concrete floor slab. At the intersection of the vertical rib and the horizontal rib,
3. The prestressed concrete floor slab according to claim 2, wherein at least a pair of pretension PC steel materials are disposed at positions facing each other with the post tension PC steel material interposed therebetween.   The prestressed concrete floor slab according to any one of claims 1 to 3, wherein a minimum member thickness of the plate portion is 40 mm or less.

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