JP2008121287A - Steel-concrete compound beam and method of constructing steel-concrete compound beam - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a steel-concrete compound beam used for constructing elevated roads or bridges and a method of constructing the steel-concrete compound beam. <P>SOLUTION: This steel-concrete compound beam comprises an upper flange formed of steel plates, a lower flange formed of reinforced concrete, and steel plate webs vertically connecting the upper flange and the lower flange. The plurality of compound beams are installed on bridge piers. Precast prestressed concrete boards are installed between the upper flanges. Reinforced concrete floor slabs are so deposited that the upper flanges, the upper parts of the precast prestressed concrete boards, and the upper parts of the steel plate webs can be buried therein. The precast prestressed concrete boards are left buried even if mold forms and timbering removed after the reinforced concrete slabs are deposited. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a steel-concrete composite girder used for construction of an elevated road or a bridge and a method for constructing a steel-concrete composite girder.

In the steel-concrete composite girder described in Japanese Patent No. 2667129, an upper flange and a lower flange are made of a precast concrete plate, and a corrugated steel plate is provided between the upper flange and the lower flange. The steel-concrete composite girder is manufactured in a nearby yard or factory. A reinforced concrete floor slab is provided on the top of the plurality of steel concrete composite girders. The reinforced concrete floor slab is provided with a formwork and a supporting work so as to be integrated with the steel-concrete composite girder, and concrete is placed after the reinforcing bars are laid in the formwork.
Japanese Patent No. 2667129

  The steel-concrete composite girder manufactured in the factory has restrictions in transportation cost or length and weight in transportation or erection. Moreover, even if the steel-concrete composite girder is produced in a nearby yard, there is a problem that workability is poor due to the use of heavy machinery or work at a high place. Conventional steel-concrete composite girders have been devised to improve work at high places, or shapes and construction methods therefor.

  In order to solve the above-described problems, the present invention can omit the formwork and supporting work for filling concrete packed between the steel concrete composite girders, and can improve the workability of construction. It aims at providing the construction method of a concrete composite girder and a steel concrete composite girder. Moreover, an object of this invention is to provide the construction method of an inexpensive steel concrete composite girder and a steel concrete composite girder.

(First invention)
The steel-concrete composite girder according to the first aspect of the present invention comprises a plurality of steel pipes composed of an upper flange made of steel plate, a lower flange made of reinforced concrete, and a steel plate web connecting the two flanges, and is sandwiched from both upper sides of the steel plate web. Precast prestressed installed between one upper flange of the steel concrete composite girder and the other upper flange of the steel concrete composite girder different from the steel concrete composite girder It comprises at least a concrete plate and a reinforced concrete floor slab placed on the upper flange, the upper part of the precast prestressed concrete plate and the upper part of the web.

(Second invention)
The steel-concrete composite girder of the second invention is characterized in that a through-hole is provided in the upper part of the web sandwiched between one and the other upper flanges in the first invention, and a reinforcing bar is inserted into the through-hole. .

(Third invention)
A steel-concrete composite girder according to a third aspect of the present invention comprises a plurality of steel pipes composed of an upper flange made of a steel plate, a lower flange made of reinforced concrete, and a steel plate web connecting the both flanges, and is attached to the upper portion of the steel plate web. A precast prestressed concrete plate installed between the upper flange, one end of the upper flange in the steel-concrete composite girder, and the other end of the upper flange in a steel-concrete composite girder different from the steel-concrete composite girder, It consists at least of a reinforced concrete floor slab placed on top of a precast prestressed concrete board.

(Fourth invention)
The steel-concrete composite girder of the fourth invention is characterized in that the steel sheet web in the first to third inventions is corrugated.

(Fifth invention)
The steel-concrete composite girder of the fifth invention is characterized in that the lower flange in the first to third inventions is prestressed by a pre-tension and / or post-tension method.

(Sixth invention)
The construction method of the steel-concrete composite girder according to the sixth invention is a precast prestressed concrete plate in which a steel-concrete composite girder having a web and an upper flange made of steel plate and a lower flange made of reinforced concrete is installed between a plurality of bridge piers. And laying a cast-in-place reinforced concrete floor slab in the upper flange, precast prestressed concrete plate, and formwork, and constructing a composite girder by integrating the upper flange and precast prestressed concrete plate. .

  According to the present invention, since the precast prestressed concrete plate is laid between the steel-concrete composite girders, not only the formwork and supporting work provided between the steel-concrete composite girders become unnecessary, but the formwork and supporting work are also provided. Manufacturing, mounting at high places, and removal are omitted. Moreover, since the said precast prestressed concrete board is united with the said steel concrete composite girder, the intensity | strength of the width direction is improved.

(First invention)
The steel-concrete composite girder of the first invention is composed of an upper flange made of steel plate, a lower flange made of reinforced concrete, and a steel plate web that vertically connects the upper flange and the lower flange, and a plurality of them are on the pier. Provided. The upper flange is attached by, for example, welding such that one and the other are sandwiched from both upper sides of the steel sheet web. The upper part of the steel sheet web protrudes above the upper flange. The precast prestressed concrete board is installed so as to bridge between one upper flange of the steel concrete composite girder and another upper flange of a steel concrete composite girder different from the steel concrete composite girder.

  The reinforced concrete slab is placed so that the upper flange and the upper part of the precast prestressed concrete plate and the upper part of the steel plate web are embedded. The precast prestressed concrete slab is buried and left as it is even if the formwork and supporting work are removed after the reinforced concrete floor slab is placed. Since the precast prestressed concrete plate also serves as a lower formwork and support for a reinforced concrete slab, not only strengthens the strength of the steel-concrete composite girder in the width direction but also installs and removes the formwork and support for the part. Can be omitted.

(Second invention)
The steel-concrete composite girder of the second invention is sandwiched between one and the other upper flange, and a desired number of through holes are provided in the upper part of the formed steel sheet web. A reinforcing bar having a predetermined strength is inserted into the through hole. The steel-concrete composite girder can easily have the strength as designed by the size of the through-holes, the number thereof, the strength of the reinforcing bars, and the number of reinforcing bars to be inserted.

(Third invention)
The steel-concrete composite girder of the third invention is different from the first invention in that the upper flange is attached to the upper part of the steel plate web by welding or the like. The upper flange is fixed to a reinforced concrete floor slab, for example, a dowel (a stud, a steel plate or a flat steel having a through hole, and a steel plate) attached to the upper flange.

(Fourth invention)
The steel sheet web of the fourth invention has a cross section in which the waveform is continuous in the longitudinal direction. Even if the steel plate web is provided with a continuous waveform, the rigidity in the vertical direction can be increased. The waveform is a continuous curve composed of a wave shape having a radius between straight portions, a continuous curve composed of a U-shape and an inverted U-shape, a V-shaped continuous curve, other sine curves, forward and reverse This includes various deformations such as a curve that repeats a semicircular shape, a continuous curve of Ω-shaped in the opposite direction.

(Fifth invention)
The lower flange made of reinforced concrete according to the fifth aspect of the invention is prestressed by the pretension and post tension methods by the PC steel material inserted therein.

(Sixth invention)
In the construction method of the steel-concrete composite girder according to the sixth aspect of the invention, a web and an upper flange made of a steel plate and a lower flange made of reinforced concrete are assembled, and then a plurality of them are installed between the piers. Next, a precast prestressed concrete board is laid between adjacent steel upper flanges. Reinforced concrete floor slabs are made by placing rebar and concrete on the top flange and precast prestressed concrete plate and in a frame made of formwork or the like on site. The upper flange and the precast prestressed concrete plate also serve as a part of the formwork and the support work. Strength can be obtained.

  FIG. 1 (a) is an upper assembly view of a steel-concrete composite girder according to the present invention, and (b) is a longitudinal sectional view of a stomach plate and an upper flange. FIG. 2 is a view for explaining a cross section of the steel-concrete composite girder according to the first embodiment of the present invention. 1 (a) and 1 (b) and FIG. 2, a steel concrete composite girder includes a corrugated steel plate 11 as a belly plate, and upper flanges 12 and 13 provided so as to be sandwiched from both sides of the upper portion of the corrugated steel plate 11. A precast prestressed concrete plate 23 laid on the upper flanges 12 and 13; a lower flange 22 made of reinforced concrete; At least.

  The corrugated steel sheet 11 includes a longitudinal portion 111, an inclined portion 112, and a rounded portion 113 between the longitudinal portion 111 and the inclined portion 112, which are continuously repeated. Moreover, the shape of the said longitudinal direction part 111, the said inclination direction part 112, and the said rounded part 113 is continuing in arbitrary shapes.

  The upper flanges 12, 13 are provided with one end face that follows the shape of the corrugated steel plate 11, leaving the upper portion of the corrugated steel plate 11, and sandwiching from both sides, for example, the entire circumference of the corrugated steel plate 11. They are connected by welding 16 or the like. In addition, a predetermined number of through holes 114 are provided in the corrugated steel sheet protruding portion 11 ′ protruding from the upper flanges 12 and 13 in the corrugated steel sheet 11. The horizontal reinforcing bar 15 is inserted into the through-hole 114, and the lateral strength is improved.

  The precast prestressed concrete plate 23 is laid between one upper flange 12 of the corrugated steel plate 11 and the other upper flange 13 of the different corrugated steel plate 11. Concrete is cast in the lower flange 22 together with the reinforcing bar 221 and the PC steel material 222.

  Construction of steel-concrete composite girders is performed in the following order. An assembly including the corrugated steel plate 11, the upper flanges 12 and 13, and the lower flange 22 provided with reinforcing bars is manufactured at a factory or a nearby yard and transported to an assembly site of a steel-concrete composite girder. The assembly is fixed on a pier, not shown. A precast prestressed concrete plate 23 is laid between the upper flange 12 and an upper flange 13 attached to a different corrugated steel plate. Thereafter, the upper flanges 12 and 13 and the precast prestressed concrete plate 23, and the formwork and supporting work (not shown) are provided with distribution reinforcing bars 211, PC steel 212, and the like. Thereafter, the concrete 213 is placed in the mold and cured for a predetermined period, and then the mold and the support work are removed. The upper flanges 12 and 13 and the precast prestressed concrete plate 23 are left embedded in the concrete floor slab 21.

  FIG. 3 (a) is another embodiment of the present invention, and is an upper assembly view of a steel-concrete composite girder, and (b) is a longitudinal sectional view of a stomach plate and an upper flange. FIG. 4 is a view for explaining a cross section of a steel-concrete composite girder in another embodiment. 3A and 3B and FIG. 4, the corrugated steel sheet 31 includes a longitudinal portion 311, an inclined portion 312, and a rounded portion 313 between the longitudinal portion 311 and the inclined portion 312. Any shape is repeated continuously. The upper flange 32 is joined to the top of the corrugated steel plate 31 by welding 36 or the like. Further, on the upper flange 32, a plurality of dowels 33 (a stud, a steel plate, a flat steel having a through hole, and a steel plate) are planted.

  In the construction of the steel-concrete composite girder in Example 2, a precast prestressed concrete plate 23 is laid between the upper flange 32 and an upper flange 32 'attached to a different corrugated steel sheet. Thereafter, the upper flanges 32 and 32 'and the precast prestressed concrete plate 23 are provided with a formwork and a supporting work (not shown), and a distribution reinforcing bar 211, a PC steel 212 and the like are provided in the formwork. Thereafter, the concrete 213 is placed in the mold and cured for a predetermined period, and then the mold and the support work are removed. The upper flanges 12 and 13 and the precast prestressed concrete plate 23 become part of the mold and remain embedded in the concrete floor slab 21.

  Although the present embodiment has been described in detail above, the present invention is not limited to the present embodiment. The present invention can be modified in various ways without departing from the scope of the present invention described in the claims. As the reinforcing bar of the present invention, a known or well-known material such as a normal one, a stress added in advance, or a stress added later is used. The concrete of this invention can use a well-known or well-known thing as a steel concrete composite girder according to the place used. Further, in this embodiment, a conventional object can be applied to a place where the description is omitted, and a conventional construction method can be used as the construction method. Further, the prestress on the rebar or cable can be pretension and / or post tension as required. In addition, although the steel plate web of an Example demonstrated as a corrugated steel plate, it cannot be overemphasized that it can use the steel plate without a wave, or can change a waveform arbitrarily.

(A) is an upper assembly view of the steel-concrete composite girder of the present invention, and (B) is a longitudinal sectional view of the abdominal plate and the upper flange. Example 1 It is a figure for demonstrating the cross section of the steel concrete composite girder which is 1st Example of this invention. (A) is another embodiment of the present invention, and is an upper assembly view of a steel-concrete composite girder, and (b) is a longitudinal sectional view of a stomach plate and an upper flange. (Example 2) It is a figure for demonstrating the cross section of the steel concrete composite girder in another Example.

Explanation of symbols

11 ... Corrugated steel plate (belly plate)
DESCRIPTION OF SYMBOLS 111 ... Longitudinal part 112 ... Oblique part 113 ... Earl part 114 ... Through-hole 12 ... Upper flange 121 ... Corrugated notch 13 ... Upper flange 15 ... Horizontal reinforcing bar DESCRIPTION OF SYMBOLS 16 ... Welding 21 ... Reinforced concrete floor slab 211 ... Power supply reinforcement 212 ... PC steel material 22 ... Lower flange 221 ... Power supply reinforcement 222 ... PC steel material 223 ... Concrete 23 ... Precast prestressed concrete plate 31 ... Corrugated steel plate (belt plate)
32 ... Upper flange 33 ... Giber 36 ... Welded part

Claims (6)

In a plurality of steel concrete composite girders composed of an upper flange made of steel plate, a lower flange made of reinforced concrete, and a steel plate web connecting the both flanges,
One and the other upper flange attached so as to be sandwiched from both upper sides of the steel sheet web;
A precast prestressed concrete plate installed between one upper flange of the steel concrete composite girder and another upper flange of a steel concrete composite girder different from the steel concrete composite girder;
A reinforced concrete floor slab placed on the upper flange and the upper part of the precast prestressed concrete plate and the upper part of the web;
A steel-concrete composite girder that is at least composed of.   The steel-concrete composite girder according to claim 1, wherein a through hole is provided in an upper portion of the web sandwiched between the one and the other upper flanges, and a reinforcing bar is inserted into the through hole. In a plurality of steel concrete composite girders composed of an upper flange made of steel plate, a lower flange made of reinforced concrete, and a steel plate web connecting the both flanges,
An upper flange attached to the upper part of the steel sheet web;
A precast prestressed concrete plate installed between one end of the upper flange in the steel concrete composite girder and the other end of the upper flange in a steel concrete composite girder different from the steel concrete composite girder;
Reinforced concrete slab placed on top of the upper flange and precast prestressed concrete plate,
A steel-concrete composite girder that is at least composed of.   The steel-concrete composite girder according to any one of claims 1 to 3, wherein the steel sheet web is a corrugated steel sheet web.   The steel-concrete composite girder according to any one of claims 1 to 4, wherein the lower flange is prestressed by a pretension and / or post tension system. A steel-concrete composite girder consisting of steel plates for the web and upper flange and reinforced concrete for the lower flange is installed between multiple piers.
Laying a precast prestressed concrete board between adjacent steel upper flanges,
Place the in-situ reinforced concrete floor slab in the upper flange, precast prestressed concrete plate, and formwork,
A construction method for a steel-concrete composite girder, wherein a composite girder is constructed by integrating the upper flange and the precast prestressed concrete plate.

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