JP2023079020A - Junction structure of existing concrete girder and precast slab - Google Patents

Abstract

To provide a junction structure of an existing concrete girder and a precast slab that conforms to road bridge specifications.SOLUTION: In a junction structure 1 of an existing concrete girder and a precast slab that joins an existing concrete girder 2 from which an existing concrete slab is removed and a new precast slab 3 that is placed on and connected to the existing concrete girder 2, an upper end of a stirrup 20 is fixed to the upper surface of the existing concrete girder 2 by mechanical fixing means, an upper edge side reinforcing bar 30 of the precast slab 3 is surrounded by a new stirrup 31 having a hook portion 31a formed thereon, there are provided a girder side connection steel material 4 joined to the existing concrete girder 2, a slab side connection steel material 5 joined to the precast slab 3 and multiple connecting rods 6 that connect them, and by surrounding the upper edge side reinforcing bar 30 by the new stirrup 31 and the existing stirrup 20, the precast slab 3 is effectively joined to the existing concrete girder 2.SELECTED DRAWING: Figure 1

Description

TECHNICAL FIELD The present invention relates to a joint structure between an existing concrete girder and a precast floor slab.

In bridges such as road bridges, the concrete floor slabs are damaged by repeated wheel loads caused by vehicle traffic. It is being replaced and updated. Further, in recent years, new floor slabs after renewal have been renewed with precast floor slabs. This is because precast floor slabs are manufactured in a factory or the like with a well-equipped surrounding environment, so high-quality products can be stably supplied, and the construction period for renewal work can be shortened.

For example, Patent Literature 1 discloses a replacement method for precast floor slabs for PC composite girders to replace cast-in-place RC floor slabs of concrete bridges with T-shaped composite girders with precast floor slabs for PC composite girders (Patent Document 1). 1, paragraphs [0034] to [0041], FIGS. 5 to 14 of the drawings, etc.).

However, in the method for replacing precast floor slabs for PC composite girders described in Patent Document 1, the anti-slip reinforcing bars 12 and stirrups 13 of the main girders 3 are removed at the joints of the integrated composite girders with the RC floor slabs. Since it is necessary to leave it, there was a problem that a large amount of concrete had to be scraped off with ultra-high pressure water such as a breaker or water jet, which took a long time.

In addition, in the method for replacing precast floor slabs for PC composite girders described in Patent Document 1, in order to leave the anti-slip reinforcing bars 12 and stirrups 13 placed on the main girders, the steel plates embedded in the precast floor slabs and There is a problem that the reinforcing bars interfere with each other, making it difficult to install the precast floor slabs at appropriate positions, or that installation takes time.

In addition, in the method for replacing a precast floor slab for PC composite girders described in Patent Document 1, a space for fixing the anti-slip reinforcing bars 12 and stirrups 13 under the precast floor slab for PC composite girders, and an upper part of the space Since the thickness of the floor slab is required to place the horizontal tightening PC steel materials, the thickness of the floor slab after the renewal will be thicker than before the renewal, placing a burden on the existing main girders and substructures. There was also

In order to solve such a problem, it is conceivable to cut off the anti-slip reinforcing bars and stirrups in the middle. However, according to the concept of road specifications, the stirrups, which are tensile resistance materials for composite girders, must be designed based on truss theory. There is a problem that the web part of the is no longer functioning effectively.

Therefore, in order to solve such problems, the applicants of the present application have proposed a method of replacing concrete bridges with precast floor slabs described in Patent Documents 2 and 3. Tensile resistance materials such as stirrups for concrete bridge main girders can be effectively anchored to replace old and damaged existing RC floor slabs with new high quality precast floor slabs.

However, when the inventions described in Patent Documents 2 and 3 are applied to continuous girders, the following problems occur because the tensile reinforcing bars are arranged on the upper edge side. In "Specifications for Highway Bridges, Commentary III Concrete Bridges and Concrete Members Edition, November 2017, Japan Road Association, Chapter 5, 5.2.5 Fixation of reinforcing bars (10)", "The stirrup surrounds the tensile reinforcing bars and hooks It will be fixed to the concrete of the compression part by attaching. Therefore, in the continuous girder, since the tension reinforcing bars are arranged on the upper edge side, the stirrups must be arranged so as to surround the upper edge side reinforcing bars. However, in the methods of replacing concrete bridges with precast floor slabs described in Patent Documents 2 and 3, no specific methods are described, and the inventions described in Patent Documents 2 and 3 are applied. Then, when the RC floor slab of a concrete bridge consisting of continuous girders is replaced with a precast floor slab, there is a demand for a specific method of joining the precast floor slabs, which are continuous girders, and the existing concrete girders.

Japanese Patent Application Laid-Open No. 2019-132070 Japanese Patent No. 6845456 Japanese Patent No. 6845457

Therefore, the present invention has been devised in view of the above-mentioned problems, and its object is to provide a joint structure between an existing concrete girder and a precast floor slab that satisfies the specifications of road bridge specifications. That's what it is.

The joint structure between the existing concrete girder and the precast floor slab according to claim 1 consists of the existing concrete girder from which the existing concrete floor slab has been removed and the new precast floor slab placed on and connected to the existing concrete girder. A joint structure between an existing concrete girder and a precast floor slab that joins , wherein the upper end of the existing stirrup is removed from the existing concrete girder, and the upper end of the remaining stirrup is fixed by mechanical fixing means. Fixed on the upper surface of the concrete girder, the precast floor slab is joined to the existing concrete girder by surrounding the upper edge side reinforcing bar, which is a tension resistance material in the bridge axis direction, with a newly installed stirrup with a hook formed. a girder-side connecting steel material joined to the precast floor slab, and a plurality of connecting rods connecting them, and the newly installed stirrup and the existing stirrup The precast floor slab is effectively joined to the existing concrete girder by surrounding the upper edge side reinforcing bars.

A joint structure between an existing concrete girder and a precast floor slab according to claim 2 is the joint structure between an existing concrete girder and a precast floor slab according to claim 1, wherein the existing concrete girder is a continuous girder. do.

A joint structure between an existing concrete girder and a precast floor slab according to claim 3 is the joint structure between an existing concrete girder and a precast floor slab according to claim 2, wherein the mechanical fixing means is configured such that the upper end of the remaining stirrup It is characterized by being a crimped grip with a steel cylinder crimped to it.

The joint structure between the existing concrete girder and the precast floor slab according to claim 4 is the joint structure between the existing concrete girder and the precast floor slab according to claim 2, wherein the mechanical fixing means is the upper end of the remaining stirrup. It is a wedge fixing type in which a steel cylinder is fixed using a wedge, or a screw fixing type in which a thread groove is cut on the upper end of the remaining stirrup and a long nut is screwed. .

A joint structure between an existing concrete girder and a precast floor slab according to claim 5 is the joint structure between an existing concrete girder and a precast floor slab according to claim 2, wherein the mechanical fixing means is the upper end of the remaining stirrup. It is characterized by a filling material filling type in which a cylindrical steel material is fitted on the outer surface of the opening and a filling material made of a material that hardens with time is filled and hardened and fixed.

A joint structure between an existing concrete girder and a precast floor slab according to claim 6 is a joint structure between an existing concrete girder and a precast floor slab according to any one of claims 2 to 5, wherein the girder-side connecting steel material is a cross-sectional core. The floor slab-side connecting steel material is a steel plate formed in a V-shape, the floor slab-side connecting steel material is made of a strip-shaped steel plate, and the connecting rod material is a steel bar having threaded portions at both ends, and the girder-side connecting steel material and the The floor slab-side connecting steel material is bolted to the connecting rod material.

A joint structure between an existing concrete girder and a precast floor slab according to claim 7 is a joint structure between an existing concrete girder and a precast floor slab according to any one of claims 2 to 6, wherein the girder side connection steel material is made of steel. It is a frame body made of rods with a step above and below, the floor slab side connection steel material is made of a strip-shaped steel plate, the connection bar material is a steel bar having screw portions formed at both ends, and the girder side connection The steel materials and the floor slab-side connecting steel materials are joined by the girder-side connecting steel materials straddling over the connecting rods bolted between the floor slab-side connecting steel materials.

The joint structure between an existing concrete girder and a precast floor slab according to claim 8 is the joint structure between an existing concrete girder and a precast floor slab according to any one of claims 2 to 7, wherein the girder side connection steel material is made of steel. A frame made of rods with a step above and below, the floor slab side connecting steel material is a U-shaped deformed steel rod with a hook portion, and the connecting rod material is a U-shaped steel rod, The girder-side connecting steel material and the floor slab-side connecting steel material are formed by inserting the connecting rods into a plurality of U-shaped floor slab-side connecting steel materials adjacent to each other in the bridge axis direction, and then extending above the connecting rods. It is characterized in that the girder-side connecting steel materials are joined by straddling.

According to the invention according to claims 1 to 8, by indirectly surrounding the upper edge side reinforcing bar with the existing stirrup via the tensile resistance material, the existing concrete Newly installed precast floor slabs can be effectively joined to the girders.

FIG. 1 is a vertical cross-sectional view of a T-girder bridge cut along the direction perpendicular to the bridge axis, showing the configuration of the joint structure between the existing concrete girder and the precast floor slab according to the first embodiment of the present invention. FIG. 2 is a perspective view showing the main configuration of the joint structure between the existing concrete girder and the precast floor slab. FIG. 3 is a perspective view showing only the girder-side connecting steel members of the joint structure between the existing concrete girder and the precast floor slab. FIG. 4 is a perspective view showing only the floor slab side connection steel members of the joint structure between the existing concrete girder and the precast floor slab. FIG. 5 is a vertical cross-sectional view of a T-girder bridge cut along the direction perpendicular to the bridge axis, showing the configuration of the joint structure between the existing concrete girder and the precast floor slab according to the second embodiment of the present invention. FIG. 6 is a perspective view showing the main configuration of the joint structure between the existing concrete girder and the precast floor slab of the same. FIG. 7 is a perspective view showing only the girder-side connecting steel members of the joint structure between the existing concrete girder and the precast floor slab. FIG. 8 is a perspective view showing only the floor slab side connecting steel members of the joint structure between the existing concrete girder and the precast floor slab. FIG. 9 is a vertical cross-sectional view of a T-girder bridge cut along the direction perpendicular to the bridge axis, showing the configuration of the joint structure between the existing concrete girder and the precast floor slab according to the third embodiment of the present invention. FIG. 10 is a perspective view showing the main configuration of the joint structure between the existing concrete girder and the precast floor slab of the same. FIG. 11 is a perspective view showing only the floor slab side connecting steel members of the joint structure between the existing concrete girder and the precast floor slab.

An embodiment of a joint structure between an existing concrete girder and a precast floor slab according to the present invention will be described below in detail with reference to the drawings.

[First embodiment]
A joint structure between an existing concrete girder and a precast floor slab according to a first embodiment of the present invention will be described with reference to FIGS. 1 to 4. FIG. This embodiment will be described by exemplifying a case where the present invention is applied to a T-girder bridge B, which is an existing bridge with continuous girders. FIG. 1 is a vertical cross-sectional view of a T-girder bridge B cut along the direction Y perpendicular to the bridge axis, showing the configuration of a joint structure 1 between an existing concrete girder and a precast floor slab according to the first embodiment of the present invention. Moreover, FIG. 2 is a perspective view showing the main configuration of the joint structure 1 between the existing concrete girder and the precast floor slab according to this embodiment.

The T girder bridge B to which the joint structure 1 of the existing concrete girder and the precast floor slab according to the first embodiment is applied is a prestressed concrete T girder bridge from which the aged or damaged existing RC floor slab made of reinforced concrete has been removed. An upper structure B1 is composed of an existing PC girder 2 of a mold and a newly installed precast floor slab 3 made of precast concrete placed on and connected to the PC girder 2 . This T-girder bridge B is a continuous girder in which the upper structure B1 is supported at three or more locations on the lower structure (not shown) over two or more spans. In addition, X in the figure is the direction X of the bridge axis, Y in the figure is the direction Y perpendicular to the axis of the bridge, and Z is the vertical direction Z in the figure.

(Precast floor slab)
For this reason, in the joint structure 1 between the existing concrete girder and the precast floor slab shown in FIG. Therefore, even if the existing RC floor slab is renewed to the newly installed precast floor slab 3, the T-girder bridge B will not use stirrups to surround the upper edge side reinforcing bars and attach hooks according to the above-mentioned specifications for highway bridges. It needs to be anchored to the concrete in the compression section.

Therefore, in the joint structure 1 between the existing concrete girder and the precast floor slab according to the present embodiment, the upper edge side reinforcing bar 30 is surrounded by the newly installed stirrup 31, and the stirrup 31 is formed with a hook portion 31a. This hook portion 31 a is arranged along the bridge-axis-perpendicular rebar 32 of the precast floor slab 3 and fixed to the concrete below the precast floor slab 3 . Here, the fact that the upper edge reinforcing bar 30 is surrounded by the newly installed stirrup 31 means that, as shown in FIG. It refers to surrounding at least three sides with the stirrups 31 newly installed to restrain that, and does not necessarily refer to surrounding and restraining the upper edge side reinforcing bars 30 on all four sides.

(PC digit)
As described above, the damaged reinforced concrete RC floor slab (existing concrete floor slab) has been removed from the PC girder 2, and along with this, the upper end portion of the existing stirrup 20 has been scraped off and removed. ing. Then, in order to fix the end of the stirrup 20 to the PC beam 2, the crimping grip 21 made of a steel cylinder (cylindrical steel material) is crimped to the upper end of the remaining stirrup 20. As shown in FIG. Here, the fixing means for fixing the upper end of the remaining stirrup 20 to the upper surface of the PC girder 2 is not limited to the crimping grip 21, but is mechanically attached to the stirrup by screws or other methods. Any mechanical fixing means may be used as long as it can fix and fix the expanded diameter portion with the enlarged diameter.

In addition, as a mechanical fixing means other than the crimping grip, a wedge fixing type fixing the cylindrical steel material to the upper end portion of the existing stirrup 20 using a wedge, or a screw groove at the upper end portion of the existing stirrup 20 There is a screw fixation type in which a long nut is screwed into the thread groove after cutting. In addition, a filling material filling type mechanical fixing means in which a cylindrical steel material is fitted around the upper end portion of the existing stirrup 20 and a filling material made of a material that hardens over time is filled and hardened to fix it, or the above-mentioned various It is also possible to use a mechanical fixing means in which the mechanical fixing means and filler are combined. Inorganic, organic (for example, epoxy, acrylic, urea, and urethane), resin mortar, and the like can be used as the filler composed of the material that hardens over time.

As shown in FIGS. 1 and 2, the joint structure 1 between the existing concrete girder and the precast floor slab consists of a girder-side connecting steel member 4 joined to the PC girder 2 and a left and right pair of steel members joined to the precast floor slab 3. and a plurality of connecting bars 6 for connecting and joining them.

(Girder side connection steel)
As shown in FIG. 3, the girder-side connecting steel member 4 has a rectangular (rectangular) bottom portion 40 and two side portions 41, 41 rising upward from both ends of the bottom portion 40 in the width direction. It is a member formed of a steel plate having a thickness of 12 mm and having a U-shaped cross section. FIG. 3 is a perspective view showing only the girder-side connecting steel members 4 of the joint structure 1 between the existing concrete girder and the precast floor slab according to this embodiment.

The bottom surface portion 40 has a plurality of left and right rows of stirrup holes along the edge in contact with the side surface portion 41 along the longitudinal direction (bridge axis direction X) for inserting the ends of the stirrups 20 of the PC girder 2. 42 and a plurality of circular holes 43 for ensuring weight reduction and filling properties of a filler such as non-shrinking mortar. In addition, the stirrup hole 42 is an elongated hole elongated in the longitudinal direction (bridge axis direction X) to enable position adjustment.

Further, the side surface portion 41 is provided with a rod insertion hole 44 for inserting the connecting rod 6 . This rod insertion hole 44 is also an elongated hole elongated in the longitudinal direction (bridge axis direction X) in order to allow position adjustment for inserting the connecting rod 6 on site.

As shown in FIG. 2, the girder-side connecting steel material 4 is fixed to the upper end of the stirrup 20 (not shown, see FIG. 1) with a crimping grip 21 via a washer plate 7, thereby connecting the PC girder 2. It is placed on the upper end.

(Floor slab side connection steel)
As shown in FIG. 4, the floor slab side connecting steel material 5 is made of a strip-shaped steel plate with a thickness of 12 mm, the upper half 51 indicated by the broken line is embedded in the precast floor slab 3, and the lower half 52 indicated by the solid line is the precast floor slab. 3 protrudes downward from the lower surface of 3 (see FIG. 1). FIG. 4 is a perspective view showing only the floor slab-side connecting steel member 5 of the joint structure 1 between the existing concrete girder and the precast floor slab according to this embodiment.

As shown in FIGS. 4 and 1, the upper portion 51 of the floor slab-side connecting steel member 5 is formed with a circular reinforcing bar insertion hole 53 through which the reinforcing bar 32 perpendicular to the bridge axis of the precast floor 3 is inserted. Since the floor slab side connecting steel material 5 is installed when concrete is poured into the precast floor slab 3, the reinforcing bar insertion hole 53 does not need to be adjusted in position. It has become.

On the other hand, the lower part 52 of the floor slab-side connecting steel material 5 is provided with a bar insertion hole 54 for inserting the connecting bar 6 therethrough. Since the connecting rod 6 is inserted through the rod insertion hole 54 on site, the position of the rod insertion hole 54 can be adjusted in the same manner as the rod insertion hole 44 described above. It's becoming

(connecting bar)
The connecting rod 6 is a steel rod with a diameter of 25 mm, and as shown in FIG. It has the function of connecting and joining the girder-side connecting steel material 4 and the floor slab-side connecting steel material 5 by being fixed with bolts. As a result, the newly installed stirrup 31 and the stirrup 20 of the PC girder 2 can indirectly surround the upper edge side reinforcing bar 30 of the precast floor slab 3, and the above-mentioned specifications for road bridges can be satisfied. .

Around the joint structure 1 between the existing concrete girder and the precast floor slab between the precast floor slab 3 and the PC girder 2, a formwork or the like is assembled and a filling material (not shown) such as non-shrink mortar is filled. hardened and united.

According to the joint structure 1 between the existing concrete girder and the precast floor slab according to the present embodiment described above, the stirrup 31 in the newly installed precast floor slab 3 and the existing stirrup 20 indirectly connect the upper edge side reinforcing bar 30. will be surrounded by As a result, the new precast floor slab 3 can be effectively joined to the PC girder 2, which is the existing concrete girder, while satisfying the above specifications of the road bridge specifications.

[Second embodiment]
Next, a joint structure 1' between an existing concrete girder and a precast floor slab according to a second embodiment of the present invention will be described with reference to FIGS. 5 to 8. FIG. This embodiment will also be described by exemplifying a case where it is applied to a T-girder bridge B, which is an existing bridge with continuous girders. FIG. 5 is a vertical cross-sectional view of a T-girder bridge B cut along the direction Y perpendicular to the bridge axis, showing the configuration of a joint structure 1' between an existing concrete girder and a precast floor slab according to a second embodiment of the present invention. 6 is a perspective view showing the main configuration of a joint structure 1' between an existing concrete girder and a precast floor slab according to the second embodiment. 7 is a perspective view showing only the girder-side connecting steel material 4' of the existing concrete girder-precast floor slab joint structure 1', and FIG. It is a perspective view which shows only floor-slab-side connection steel material 5' of '.

The difference between the existing concrete girder-precast floor slab joint structure 1′ according to the second embodiment and the existing concrete girder-precast floor slab joint structure 1 described above is as shown in FIGS. , girder-side connecting steel members 4' placed on the PC girder 2, floor slab-side connecting steel members 5', . The PC girder 2 and the precast floor slab 3 having the same configuration are denoted by the same reference numerals, and detailed description thereof will be omitted.

(Girder side connection steel)
The girder-side connecting steel material 4' is made of a steel bar with a diameter of 20 mm, and as shown in FIG. 7, has a rectangular frame in plan view. In addition, the girder-side connecting steel material 4' has a rectangular long side portion 40' in a plan view, and an upper side portion 41' in a short side portion. It has a stepped frame.

This girder-side connecting steel member 4' has a lower side portion 40 placed on the PC girder 2, and an upper side portion 41 straddling the connecting bar member 6' which is bolted between the floor slab-side connecting steel members 5', with a filler. It has a function of connecting the precast floor slab 3 and the PC girder 2 by hardening the surroundings.

(Floor slab side connection steel)
The floor slab side connecting steel material 5' is made of a rectangular steel plate with a thickness of 12 mm, and as shown in FIG. It protrudes downward from the lower surface of the precast floor slab 3 (see FIG. 5). As shown in FIG. 6, a plurality of floor slab-side connecting steel members 5' are provided in two rows on the left and right with a predetermined interval.

As shown in FIGS. 8 and 5, the upper portion 51' of the floor slab-side connecting steel member 5' is formed with a circular reinforcement insertion hole 53' through which the reinforcement 32 perpendicular to the bridge axis of the precast floor slab 3 is inserted. there is Since the floor slab side connecting steel member 5 is installed when concrete is poured into the precast floor slab 3, the reinforcing bar insertion hole 53' does not need to be adjusted in position. It has holes.

On the other hand, a lower portion 52' of the floor slab-side connecting steel material 5 is provided with a bar insertion hole 54' for inserting the connecting bar 6'. The rod insertion hole 54' is elongated in the longitudinal direction (bridge axis direction X) so as to be positionally adjustable for inserting the connecting rod 6' on site.

(connecting bar)
The connecting rods 6' need to be thicker than the connecting rods 6 described above because the number of connecting rods per length along the bridge axis direction X is smaller, and is a steel rod with a diameter of 35 mm. As shown in FIG. 6, like the connecting rod 6, the connecting rod 6' has threaded portions 60' at both ends, is inserted into the rod insertion hole 54', and is bolted with a nut 61'. As a result, the floor slab side connection steel materials 5' are connected to each other, and the girder side connection steel materials 4' and the floor slab side connection steel materials 5' are connected and joined via the filler.

As a result, in the joint structure 1′ between the existing concrete girder and the precast floor slab, the stirrup 20 of the PC girder 2 can indirectly surround the upper edge reinforcing bar 30 of the precast floor slab 3 via the stirrup 31. , can satisfy the provisions of the above-mentioned highway bridge specifications.

Around the joint structure 1' between the existing concrete girder and the precast floor slab between the precast floor slab 3 and the PC girder 2, a formwork or the like is assembled and a filling material (not shown) such as non-shrink mortar is filled. are hardened and integrated.

(washer plate)
In addition, unlike the washer plate 7 described above, the washer plate 7 ′ is installed across a plurality of crimping grips 21 crimped to the ends of different stirrups 20 to increase the fixing force of the upper end of the stirrup 20. Compensating. This is because the girder-side connecting steel material 4' does not have a plate shape and is not interposed in contact with the crimping grip 21. As shown in FIG.

According to the joint structure 1' between the existing concrete girder and the precast floor slab according to the second embodiment described above, the existing concrete girder, which is a continuous girder, is newly installed after satisfying the above-mentioned specifications for highway bridges. of precast floor slabs can be effectively joined. However, since the girder-side connecting steel material 4' may be deformed at the end, it can be said that the joint structure 1 of the existing concrete girder and the precast floor slab according to the first embodiment has higher durability.

[Third embodiment]
Next, a joint structure 1″ between an existing concrete girder and a precast floor slab according to a third embodiment of the present invention will be described with reference to FIGS. 9 to 11. This embodiment is also an existing continuous girder bridge. A case of application to a T-girder bridge B will be described as an example.Fig. 9 shows a T-girder bridge B showing the configuration of a joint structure 1'' between an existing concrete girder and a precast floor slab according to a third embodiment of the present invention. FIG. 10 is a vertical cross-sectional view cut along the direction Y perpendicular to the bridge axis, and FIG. 10 is a perspective view showing the main configuration of a joint structure 1″ between an existing concrete girder and a precast floor slab according to the third embodiment. 11 is a perspective view showing only the floor slab side connection steel material 5'' of the joint structure 1'' between the existing concrete girder and the precast floor slab.

The difference between the existing concrete girder-precast floor slab joint structure 1″ according to the third embodiment and the existing concrete girder-precast floor slab joint structure 1′ described above is as shown in FIGS. 2, floor slab side connecting steel members 5″, . ', washer plate 7', etc. are denoted by the same reference numerals, and detailed description thereof is omitted.

As shown in FIGS. 9 and 10, the joint structure 1'' between the existing concrete girder and the precast floor slab according to the third embodiment includes the girder-side connecting steel members 4' placed on the PC girder 2 and the precast It is provided with floor slab side connecting steel members 5'', .

(Floor slab side connection steel)
The floor slab side connecting steel material 5 ″ is made of a deformed steel bar of D16 unlike the steel plates of the floor slab side connecting steel material 5 and the floor slab side connecting steel material 5 ′ described above (ribs and knots are omitted in the figure. As shown in FIG. 11, the floor slab-side connecting steel member 5'' is composed of a U-shaped connecting steel main body 50'' and a pair of hook portions 51'' respectively formed at the ends thereof. It is

Further, as shown in FIGS. 9 to 11, the hook portion 51 ″ and its vicinity are embedded and fixed in the precast floor slab 3 , and the U-shaped connecting steel main body 50 ″ protrudes from the lower surface of the precast floor slab 3 . is provided as follows.

Then, as shown in FIGS. 9 and 10, the connecting rod 6'' is inserted into the U-shaped connecting steel main body 50'' and connected to the girder-side connecting steel 4' via the filler.・It is connected.

(connecting bar)
The connecting rod 6 ″ is made of a steel rod with a diameter of 35 mm like the above-described connecting rod 6 ′, but since the floor slab side connecting steel 5 ″ is not a steel plate and cannot be bolted, it does not have a threaded portion. It is not bolt-shaped. As shown in FIG. 10, this connecting rod 6'' is bent into a U-shape, and straddles a plurality of floor slab-side connecting steel members 5'', 5'' adjacent along the bridge axis direction X. is inserted.

According to the joint structure 1 ″ between the existing concrete girder and the precast floor slab according to the third embodiment described above, the existing concrete girder, which is a continuous girder, is newly installed after satisfying the above-mentioned specifications of the road bridge specification. of precast floor slabs can be effectively joined.

In addition, although the joint structures 1 to 1'' between the existing concrete girder and the precast floor slab according to the embodiments of the present invention have been described in detail, any of the above-described or illustrated embodiments can be embodied in carrying out the present invention. Therefore, the technical scope of the present invention should not be construed to be limited by these.

In particular, the T girder bridge B made of PC girders to which prestress was introduced was exemplified as an existing bridge, but the present invention is not limited to this, and the present invention is applied to a joint structure between a newly existing concrete girder and a precast floor slab. be able to.

1, 1', 1": Connection structure between existing concrete girder and precast floor slab 2: PC girder (existing concrete girder)
20: Stirrup (new stirrup)
21: Crimp grip (mechanical fixing means)
3: Precast floor slab 30: Upper edge side reinforcement (tensile resistance material)
31: Stirrup (existing stirrup)
31a: hook portion 32: bridge axis perpendicular reinforcing bars 4, 4': girder side connecting steel material 40: bottom portion 41: side portion 42: stirrup hole 43: circular hole 44: bar insertion hole 40': lower side portion 41' : Upper part 42': Rising parts 5, 5', 5'': Floor slab side connecting steel members 51, 51': Upper parts 52, 52': Lower parts 53, 53': Reinforcing bar insertion holes 54, 54': Bar insertion holes 50″: Connecting steel main body 51″: Hooks 6, 6′, 6″: Connecting bars 60, 60′: Threaded parts 61, 61′: Nuts 7, 7′: Washer plate B: T girder bridge (existing bridge )
B1: superstructure

Claims (8)

A joint structure between an existing concrete girder and a precast floor slab that joins an existing concrete girder from which the existing concrete floor slab has been removed and a new precast floor slab that is placed on and connected to the existing concrete girder. ,
The existing concrete girder has the upper end portion of the existing stirrup removed, and the remaining upper end of the stirrup is fixed to the upper surface of the existing concrete girder by mechanical fixing means,
In the precast floor slab, the upper edge reinforcing bar, which is a tensile resistance material in the bridge axis direction, is surrounded by a newly installed stirrup with a hook portion.
A girder-side connecting steel member joined to the existing concrete girder, a floor slab-side connecting steel member joined to the precast floor slab, and a plurality of connecting bars that connect them,
An existing concrete girder and a precast floor slab, characterized in that the precast floor slab is effectively joined to the existing concrete girder by surrounding the upper edge reinforcing bar with the newly installed stirrup and the existing stirrup. Junction structure with. The joint structure between the existing concrete girder and the precast floor slab according to claim 1, wherein the existing concrete girder is a continuous girder. The joint between the existing concrete girder and the precast floor slab according to claim 2, wherein the mechanical fixing means is a crimping grip in which a steel cylinder is crimped to the upper end of the remaining stirrup. structure. The mechanical fixing means is a wedge fixing type in which a steel cylindrical body is fixed using a wedge on the upper end of the remaining stirrup, or a long nut by cutting a thread groove on the upper end of the remaining stirrup The joint structure of the existing concrete girder and the precast floor slab according to claim 2, characterized in that it is a screw fixing type that screws together. The mechanical fixing means is a filling material filling type in which a cylindrical steel material is fitted around the upper end of the remaining stirrup, and a filling material made of a material that hardens over time is filled and hardened to fix it. A joint structure between an existing concrete girder and a precast floor slab according to claim 2. The girder-side connecting steel material is a steel plate formed into a U-shaped cross section,
The floor slab-side connecting steel material is made of a strip-shaped steel plate,
The connecting rod material is a steel rod having threaded portions at both ends,
The connection between the existing concrete girder and the precast floor slab according to any one of claims 2 to 5, characterized in that the girder-side connecting steel material and the floor slab-side connecting steel material are bolt-joined by the connecting bar. structure. The girder-side connecting steel material is a frame body made of steel bars and having a step in the upper and lower directions,
The floor slab-side connecting steel material is made of a rectangular steel plate,
The connecting rod material is a steel rod having threaded portions at both ends,
The girder-side connecting steel materials and the floor slab-side connecting steel materials are joined by the girder-side connecting steel materials straddling above the connecting rods bolted between the floor slab-side connecting steel materials. A joint structure between an existing concrete girder and a precast floor slab according to any one of claims 2 to 6. The girder-side connecting steel material is a frame body made of steel bars and having a step in the upper and lower directions,
The floor slab side connection steel material is made of a U-shaped deformed steel bar with a hook,
The connecting rod material is a U-shaped steel rod,
The girder-side connecting steel material and the floor slab-side connecting steel material are formed by inserting the connecting rods into a plurality of U-shaped floor slab-side connecting steel materials adjacent to each other in the bridge axis direction. The joint structure of the existing concrete girder and the precast floor slab according to any one of claims 2 to 7, wherein the girder-side connection steel material is joined by straddling.

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