JP6276613B2 - Precast wall railing joint structure - Google Patents

Description

  The present invention relates to a bridge in which a precast wall rail is installed at a side end portion of a floor slab, and particularly relates to a joint structure for joining a precast wall rail to a floor slab.

  Conventionally, as a structure of a bridge, a structure in which a precast wall rail is installed at a side end portion of a floor slab is known.

  “Patent Document 1” describes a joining structure for joining a precast wall rail to a floor slab in such a bridge.

  That is, in this joining structure, reinforcing bars protruding from the upper surface are arranged at the side end of the floor slab, while reinforcing bars protruding from the lower end surface are arranged in the precast wall height column, and the precast wall height column is arranged. After the reinforcing bar is placed in the gap between the lower end surface of the floor slab and the upper surface of the side edge of the floor slab, the non-shrink mortar is filled in the gap. Yes.

  On the other hand, “Patent Document 2” describes a joint structure using the precast wall rail itself as a part of the outer mold.

  That is, in this joining structure, as a precast wall rail, a configuration including a rail main body portion having a recess formed on the inner side surface, and a hanging portion extending downward from the outer region on the lower end surface of the rail main body portion; Then, this precast wall rail is placed on the upper surface of the side end of the floor slab at the lower end surface of the rail main body, and the non-shrink mortar is made using the recess formed on the inner surface of the rail main body. It is designed to be filled.

JP2013-36205A Japanese Patent No. 2859158

  In the joining structure described in “Patent Document 1”, when the non-shrink mortar is filled in the gap between the lower end surface of the precast wall rail and the upper surface of the side end portion of the floor slab, the outer mold frame is placed outside the gap. It is necessary to install the armrest scaffold for that purpose on the outside of the floor slab.

  For this reason, there is a problem that if the construction is carried out with sufficient safety, the construction period will be very long. Further, it is not easy to place reinforcing reinforcing bars in the gaps, and there is a problem that the construction period is long in this respect.

  On the other hand, if the joining structure described in the above-mentioned “Patent Document 2” is adopted, it is possible to eliminate the need to install the brace scaffold.

  On the other hand, in this joint structure, it is necessary to form a space for filling the non-shrink mortar on the upper side of the floor slab. However, it is not easy to install the outer mold on the upper side of the floor slab, and reinforcement is required. The work of arranging reinforcing bars is also not easy. For this reason, there is still a problem that the construction period takes a long time.

  This invention is made in view of such a situation, Comprising: It aims at providing the joining structure of the precast wall rail which can aim at shortening of the construction period for joining the precast wall rail to a floor slab. It is what.

  In the present invention, the above object is achieved by devising a joining position when joining the precast wall rail to the floor slab.

That is, the joint structure of the precast wall rail according to the present invention is:
In a bridge in which a precast wall rail is installed at the side edge of the floor slab, a joining structure for joining the precast wall rail to the floor slab,
The side end portion of the floor slab and the side end portion vicinity region located on the inner side in the bridge axis orthogonal direction of the side end portion are formed stepwise with respect to the general portion of the floor slab,
The floor slab is provided with a first reinforcing bar that protrudes from the outer surface of the general portion of the floor slab, and a second cast that protrudes from the lower end of the inner surface of the precast wall rail to the precast wall rail. There are reinforcing bars,
Recessed space formed by the inner surface of the precast wall rail placed on the upper surface of the side end portion of the floor slab, the outer surface of the general portion of the floor slab, and the upper surface of the area near the side end portion of the floor slab The precast wall railing is joined to the floor slab by placing the interstitial concrete on the floor ,
In the state in which the floor slab has a plurality of precast ribs extending in a direction perpendicular to the bridge axis at predetermined intervals in the bridge axis direction, and a plurality of precast plates are bridged between the precast ribs. It is formed by placing floor slab concrete on top,
The precast wall rail is placed on the upper surface of the side end of the plurality of precast ribs,
The interstitial concrete is placed in a recessed space formed by the inner surface of the precast wall rail, the outer surface of the floor slab concrete, and the upper surface of the outermost precast plate among the plurality of precast plates. It is characterized by that.

  If the above-mentioned “floor slab” is formed so that the side end portion and the region near the side end portion are stepped down with respect to the general portion (that is, the portion other than the side end portion and the region near the side end portion). The specific configuration is not particularly limited.

  As shown in the above configuration, in the present invention, the side end portion of the floor slab and the region near the side end portion are formed stepwise with respect to the general portion. The first reinforcing bar that protrudes from the outer side of the wall is arranged, while the precast wall rail is provided with the second reinforcing bar that protrudes from the lower end of the inner side, and the floor slab Filled concrete is placed in the recessed space formed by the inner surface of the precast wall rail placed on the upper surface of the side edge, the outer surface of the general part of the floor slab, and the upper surface of the area near the side edge of the floor slab. Since the precast wall rail is configured to be joined to the floor slab by being placed, the following operational effects can be obtained.

  That is, when placing the interstitial concrete in the recessed space, it is not necessary to install an outer formwork on the outside thereof, and therefore it is not necessary to install an armrest scaffold for that purpose on the outside of the floor slab. The construction efficiency can be greatly improved compared to Moreover, since the operation | work which arranges a reinforcing bar in the said recessed space becomes an operation | work on a horizontal surface, construction efficiency can be improved significantly also in this point.

  Therefore, according to this invention, the construction period shortening of the construction for joining a precast wall rail to a floor slab can be aimed at.

  In the above configuration, as a configuration of the floor slab, a plurality of precast ribs extending in a direction perpendicular to the bridge axis are arranged at predetermined intervals in the bridge axis direction, and a plurality of precast plates are bridged between the precast ribs. In this state, a precast wall rail is placed on the upper surface of the side end portion of the plurality of precast ribs, and the floor cast concrete is placed on these precast plates. If the interstitial concrete is placed in a recessed space formed by the inner surface of the precast wall rail, the outer surface of the floor slab concrete, and the upper surface of the precast plate located on the outermost side among the plurality of precast plates, The following effects can be obtained.

  That is, by adopting such a configuration, it is possible to easily adopt a configuration in which the side end portion and the region near the side end portion are stepped down with respect to the general portion as the configuration of the floor slab. As a result, the construction period can be further shortened.

  At that time, as a configuration of the precast wall height column, a configuration placed on the upper surface of the side end portions of the plurality of precast ribs in a state where the inner side surface and the outer side surface of the outermost precast plate are substantially flush with each other. By doing so, the precast wall rail can be easily used as a part of the outer formwork.

  At that time, if the height adjustment structure for adjusting the installation height of the precast wall height column is provided on the upper surface of the side end portion of each precast rib, the dimensional accuracy of the precast wall height column and each precast rib can be increased. Even if it is not strictly controlled, it is possible to reliably perform the precast wall railing.

  Further, at that time, as a precast wall rail, with a configuration including a rail main body portion and a hanging portion extending downward from the outer region at the lower end surface thereof, each of the precast wall rails at each lower end surface of the rail main body portion. If it is set as the structure mounted in the upper surface of the side edge part of a precast rib, the positioning precision at the time of mounting the precast wall height column on the upper surface of the side edge part of several precast rib can be improved.

  The specific configuration of the “height adjustment structure” is not particularly limited, and for example, a structure using a bolt or a structure using a shim can be employed.

The perspective view which shows the joining structure of the precast wall railing which concerns on one Embodiment of this invention. Side sectional view showing an outline of the construction process of the above embodiment (A1) is a detailed view of the main part of FIG. 2 (a), and (a2) is a plan view thereof. (B1) is a detail view of the main part of FIG. 2 (b), and (b2) is a plan view thereof. (C1) is a detailed view of the main part of FIG. 2 (c), and (c2) is a plan view thereof. (D1) is a detail view of the main part of FIG. 2 (d), and (d2) is a plan view thereof. Detail view of part VII in FIG. 4 (b2) Detailed view of part VIII in FIG. 5 (c2) IX-IX cross-sectional detail view of FIG. 6 (d2) The same figure as FIG. 8 which shows the 1st modification of the said embodiment. The same figure as FIG. 9 which shows the 2nd modification of the said embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a perspective view showing a joint structure of a precast wall rail according to an embodiment of the present invention. FIG. 9 is a side sectional view showing in detail the main part of this joint structure. As will be described later, FIG. 9 is a detailed sectional view taken along line IX-IX in FIG.

  As shown in these drawings, this joint structure is a structure for joining the precast wall rail 30 to the floor slab 20 in the bridge 10 in which the precast wall rail 30 is installed at the side end of the floor slab 20. .

  The floor slab 20 has a side end portion 20B and a side end portion vicinity region 20C located on the inner side in the bridge axis orthogonal direction of the side end portion 20B, which are formed stepwise with respect to the general portion 20A of the floor slab 20. Yes.

  The floor slab 20 is provided with a first reinforcing bar 22 that protrudes from the outer surface 20Aa of the general portion 20A toward the outside in the direction perpendicular to the bridge axis. The reinforcing bar 22 is composed of a plurality of loop reinforcing bars arranged at predetermined intervals in the bridge axis direction.

  On the other hand, the precast wall rail 30 has a configuration including a rail main body 30A and a hanging part 30B extending downward from the outer region of the lower end surface 30Aa of the rail main body 30A. In that case, as for the railing main-body part 30A, lower end part 30Ab1 of the inner surface 30Ab is formed thickly.

  The precast wall rail 30 is provided with a second reinforcing bar 32 that protrudes inward in the direction perpendicular to the bridge axis from the lower end 30Ab1 of the inner side surface 30Ab of the rail main body 30A. The reinforcing bar 32 is composed of a plurality of loop reinforcing bars arranged at predetermined intervals in the bridge axis direction.

  The first and second reinforcing bars 22 and 32 have a high bar arrangement density in the vicinity of both ends of the precast wall height column 30 in the bridge axis direction.

  And in this bridge 10, inner surface 30Ab of the handrail main-body part 30A of the precast wall handrail 30 mounted on the upper surface of the side end part 20B of the floor slab 20, and the outer surface 20Aa of the general part 20A of the floor slab 20 The precast wall rail 30 is joined to the floor slab 20 by placing the padded concrete 40 in the recessed space C formed by the upper surface 20Ca of the side edge vicinity region 20C of the floor slab 20. ing.

  At that time, in the recessed space C, the first reinforcing bars 22 protruding from the floor slab 20 side and the second reinforcing bars 32 protruding from the precast wall rail 30 side are alternately arranged in the bridge axis direction. ing. Further, a plurality of reinforcing reinforcing bars 42 extending in the bridge axis direction are arranged in the recess space C so as to be in contact with each other in the loops of the first and second reinforcing bars 22 and 32.

  The floor slab 20 has a plurality of precast ribs 24 extending in a direction perpendicular to the bridge axis at a predetermined interval in the bridge axis direction, and a plurality of precast plates 26 are bridged between the precast ribs 24, It is formed by placing floor slab concrete 28 on these precast plates 26.

  Thus, the general portion 20A of the floor slab 20 is composed of floor slab concrete 28, the side end 20B is composed of the side ends 24B of the plurality of precast ribs 24, and the side end vicinity region 20C is The exposed portion 26C is located outside the floor slab concrete 28 of the outermost precast plate 26.

  On the upper surface 24a of each precast rib 24, a portion other than the side end 24B and both ends in the bridge axis direction is formed as a stepped portion 24a1. Each precast plate 26 is placed on the bridge axis direction end of the upper surface 24a of the two precast ribs 24 adjacent in the bridge axis direction.

  Further, a pair of screw holes 24b are formed in the portion of the side end portion 24B on the upper surface 24a of each precast rib 24 at a predetermined interval in the bridge axis direction. A height adjusting bolt 50 is attached to each of the screw holes 24b so that a part thereof protrudes from the upper surface 24a.

  The precast wall rail 30 is formed so as to extend in the bridge axis direction over a predetermined length, and the two precast ribs 24 adjacent to each other in the bridge axis direction at both ends in the bridge axis direction of the lower end surface 30Aa of the rail main body 30A. It is placed on the upper surface 24a of the side end 24B.

  At this time, the precast wall rail 30 is mounted in a state where the lower end portion 30Ab1 of the inner side surface 30Ab of the rail main body portion 30A and the outer side surface 26a of the outermost precast plate 26 are substantially flush with each other. Is placed.

  The installation height of the precast wall height column 30 is adjusted by adjusting the upward protruding amount of the height adjustment bolt 50 provided at the side end 24B of each precast rib 24.

  A stainless steel plate 34 is embedded and fixed to the lower end surface 30Aa of the rail main body 30A in the precast wall rail 30 so as to be flush with the lower end surface 30Aa. An anchor pin 36 is embedded and fixed at a position directly above each height adjustment bolt 50 in the stainless steel plate 34.

  A convex portion 30c extending in the vertical direction is formed on one end surface in the bridge axis direction of the precast wall height column 30, and a concave portion 30d extending in the vertical direction is formed on the other end surface in the bridge axis direction. Yes. When the precast wall height column 30 is placed on the upper surface 24a of the side end portion 24B of each precast rib 24, one convex portion 30c is formed between the precast wall height column 30 adjacent to the existing precast wall height column 30 in the bridge axis direction. And the other concave portion 30d are engaged with each other so as to be positioned in the direction perpendicular to the bridge axis.

  FIG. 2 is a diagram showing an outline of the construction process when the precast wall rail 30 is joined to the floor slab 20.

  First, as shown in FIG. 3A, a general portion 20A of the floor slab 20 is formed by placing floor slab concrete 28 on a plurality of precast plates 26 spanned between the precast ribs 24.

  FIG. 3 (a1) is a detailed view of the main part of FIG. 2 (a), and FIG. 3 (a2) is a plan view thereof. In this case, FIG. 3A1 is a side sectional view taken along the line IIIa-IIIa in FIG.

  As shown in the figure, when the floor slab concrete 28 is constructed, PC steel materials 60 extending in a direction perpendicular to the bridge axis at a predetermined interval in the bridge axis direction are arranged, and each of these PC steel materials 60 is used with the jack 2. get nervous. At that time, the tension is performed with the extension nose 4 interposed, thereby preventing the jack 2 from interfering with the first reinforcing bar 22 in advance.

  Next, as shown in FIG. 2 (b), the precast wall rail 30 is made to have side end portions 24B (that is, floor slabs) of two precast ribs 24 adjacent to each other in the bridge axis direction at the lower end surface 30Aa of the rail main body portion 30A. 20 on the upper surface 24a of the side end 20B).

  4 (b1) is a detailed view of the main part of FIG. 2 (b), and FIG. 4 (b2) is a plan view thereof. In this case, FIG. 4B1 is a side cross-sectional view taken along the line IVa-IVa in FIG. FIG. 7 is a detailed view of a portion VII in FIG. 4 (b2).

  As shown in these drawings, the precast wall height column 30 is placed in a state where the precast wall height column 30 is suspended and supported, and the lower end portion 30Ab1 of the inner side surface 30Ab of the rail main body portion 30A and the precast located on the outermost side. This is performed with the outer surface 26a of the plate 26 being substantially flush. At that time, the drooping portion 30B of the precast wall rail 30 is used as a guide for placement.

  When the precast wall height column 30 is placed, the installation height is adjusted by adjusting the upward protruding amount of the height adjusting bolt 50 provided at the side end 24B of each precast rib 24.

  At that time, in a state where the backup material 72 is disposed on the peripheral edge of the upper surface 24a of the side end 24B of the precast rib 24, the non-shrink mortar is provided in the space on the inner peripheral side by the amount of upward protrusion of the height adjusting bolt 50. 70 is filled. At this time, as shown in FIG. 7, the backup material 74 is also disposed in the gap between the stepped portion 24a1 of the upper surface 24a of the precast rib 24 and each precast plate 26 located on both sides in the bridge axis direction, thereby causing no shrinkage. The filling of the mortar 70 is performed smoothly.

  Next, as shown in FIG. 2 (c), the lower end 30Ab1 of the inner side surface 30Ab of the rail main body 30A in the precast wall rail 30 and the outer side surface 20Aa of the floor slab concrete 28 (that is, the general portion 20A of the floor slab 20). And a plurality of reinforcing rebars 42 extending in the bridge axis direction in the recessed space C formed by the upper surface 20Ca of the exposed portion 26C of the precast plate 26 located on the outermost side (that is, the side edge vicinity region 20C of the floor slab 20). Arrange the bars.

  FIG. 5 (c1) is a detailed view of the main part of FIG. 2 (c), and FIG. 5 (c2) is a plan view thereof. At this time, FIG. 5 (c1) is a side sectional view showing the position of the Va-Va line in FIG. 5 (c2). FIG. 8 is a detailed view of a portion VIII in FIG. 5 (c2).

  As shown in these drawings, a back-up material 76 extending in the bridge axis direction along the lower end portion 30Ab1 of the inner side surface 30Ab of the balustrade body portion 30A is disposed in the recessed space C, whereby the precast wall balustrade 30 and the precast are disposed. The gap between the plate 26 is sealed.

  Further, when the precast wall rail 30 is installed, a convex portion 30c formed on one end surface in the bridge axis direction is formed with a concave portion 30d formed on the other end surface of the existing precast wall rail 30 adjacent to the precast wall rail 30. Engage and position in the direction perpendicular to the bridge axis. At this time, an adhesive 78 is interposed between the convex portions 30c and the concave portions 30d.

  Next, as shown in FIG. 2 (d), the padded concrete 40 is placed in the recessed space C, and thereby the precast wall rail 30 is joined to the floor slab 20.

  6 (d1) is a detailed view of the main part of FIG. 2 (d), and FIG. 6 (d2) is a plan view thereof. In this case, FIG. 6 (d1) is a side cross-sectional view taken along the line VIa-VIa in FIG. 6 (d2). FIG. 9 is a detailed sectional view taken along line IX-IX in FIG.

  As shown in these drawings, the interstitial concrete 40 is placed so as to be flush with the upper surface of the floor slab concrete 28. Then, the precast wall rail 30 is joined to the floor slab 20 by placing the interstitial concrete 40, and then the pavement 80 is applied to the upper surface of the floor slab 20.

  Next, the operation of this embodiment will be described.

  In the present embodiment, the side edge 20B and the side edge vicinity region 20C of the floor slab 20 are formed stepwise with respect to the general part 20A. The floor slab 20 includes the general part 20A. The first rebar 22 projecting from the outer side surface 20Aa is arranged, while the precast wall rail 30 has a second rebar 32 projecting from the lower end 30Ab1 of the inner side surface 30Ab of the rail main body 30A. The lower end portion 30Ab1 of the inner surface 30Ab of the rail main body portion 30A in the precast wall rail 30 placed on the upper surface of the side end portion 20B of the floor slab 20 and the general portion 20A of the floor slab 20 are arranged. Precast wall rails 30 are formed by placing the compacted concrete 40 in the recessed space C formed by the outer side surface 20Aa and the upper surface 20Ca of the side edge vicinity region 20C of the floor slab 20. Because are configured to be joined to the floor plate 20, it is possible to obtain the following effects.

  That is, when placing the interstitial concrete 40 in the recessed space C, there is no need to install an outer formwork on the outside thereof, and therefore there is no need to install a brace scaffold for that purpose on the outside of the floor slab 20. The construction efficiency can be greatly improved compared to the joint structure. Moreover, since the operation | work which arrange | positions the reinforcement reinforcement 42 in the recessed part space C becomes a work on a horizontal surface, construction efficiency can be improved significantly also in this point.

  Therefore, according to the present embodiment, it is possible to shorten the construction period for joining the precast wall rail 30 to the floor slab 20.

  At this time, in the present embodiment, as the configuration of the floor slab 20, a plurality of precast ribs 24 extending in the direction orthogonal to the bridge axis are arranged at predetermined intervals in the bridge axis direction, and a plurality of precast ribs 24 are arranged between the precast ribs 24. In the state where the precast plate 26 is bridged, the floor slab concrete 28 is placed on the precast plate 26, and the upper surface of the side end portions 24B of the plurality of precast ribs 24 is formed. 24a, the precast wall rail 30 is placed, the lower end 30Ab1 of the inner surface 30Ab of the rail main body 30A in the precast wall rail 30, the outer surface 20Aa of the floor slab concrete 28, and the plurality of precast plates 26 The concave space C is formed with the upper surface of the precast plate 26 located on the outermost side. , It is possible to obtain the following effects.

  That is, by adopting such a configuration, as the configuration of the floor slab 20, the side end portion 20B and the side end portion vicinity region 20C may be configured to be stepped down with respect to the general portion 20A. This makes it possible to easily reduce the work period.

  Moreover, in the present embodiment, the precast wall rail 30 is substantially flush with the lower end 30Ab1 of the inner surface 30Ab of the rail main body 30A and the outer surface 20Aa of the outermost precast plate 26, Since it becomes the structure mounted in the upper surface 24a of the side edge part 24B of the some precast rib 24, it can make it easy to utilize the precast wall height column 30 as a part of outer mold.

  In the present embodiment, the height adjustment bolt 50 is provided as a height adjustment structure for adjusting the installation height of the precast wall height column 30 on the upper surface 24a of the side end portion 24B of each precast rib 24. Therefore, the precast wall height column 30 and the precast rib 24 can be reliably joined without strictly managing the dimensional accuracy of the precast wall height column 30 and each precast rib 24.

  Further, in the present embodiment, the precast wall rail 30 includes a rail main body portion 30A and a hanging portion 30B extending downward from the outer region of the lower end surface 30Aa. Since the rail 30 is mounted on the upper surface 24a of the side end 24B of each precast rib 24 at the lower end surface 30Aa of the rail main body 30A, the precast wall rail 30 is connected to the side end 24B of the precast rib 24. The positioning accuracy at the time of mounting on the upper surface 24a can be improved.

  Next, a modification of the above embodiment will be described.

  First, a first modification of the above embodiment will be described.

  FIG. 10 is a view similar to FIG. 8 showing the joint structure of the precast wall rail according to this modification.

  As shown in the figure, the basic configuration of the present modification is the same as that of the above embodiment, but the first rebar 122 projecting from the floor slab 20 side and the second projecting from the precast wall rail 30 side. The configuration of the reinforcing bar 132 is different from that of the above embodiment.

  That is, in the present modification, the first reinforcing bar 122 projects linearly from the outer surface 20Aa of the general portion 20A of the floor slab 20 toward the outside in the bridge axis orthogonal direction, and the second reinforcing bar 132 is also formed. Further, the precast wall height column 30 protrudes linearly from the lower end 30Ab1 of the inner side surface 30Ab of the rail main body 30A toward the inside in the bridge axis orthogonal direction. The first and second reinforcing bars 122 and 132 constitute a lap joint.

  Also in this modified example, a plurality of reinforcing bars 42 extending in the bridge axis direction are arranged in the recessed space C so as to be in contact with the first and second reinforcing bars 122 and 132.

  Even when the joining structure according to this modification is employed, the same effects as those of the above-described embodiment can be obtained.

  Instead of adopting the configuration of the present modification, the first rebar 122 protruding from the floor slab 20 side and the second rebar 132 protruding from the precast wall rail 30 side have their tip surfaces on the same straight line. It is also possible to adopt a configuration in which the first and second rebars 122 and 132 are mechanically connected using a coupler or the like after being arranged so as to abut each other at a predetermined interval. It is.

  Next, a second modification of the above embodiment will be described.

  FIG. 11 is a view similar to FIG. 9 showing the joint structure of the precast wall rail according to this modification.

  As shown in the figure, the basic configuration of this modification is the same as that of the above embodiment, but in this modification, the floor slab 220 is made of cast-in-place concrete. It is different from the case.

  That is, the floor slab 220 has a side end portion 220B and a side end vicinity region 220C that are stepped down with respect to the general portion 220A of the floor slab 220, and from the outer side surface 220Aa of the general portion 220A. The first reinforcing bar 222 protrudes outward in the direction perpendicular to the bridge axis.

  In this modification, the lower end portion 30Ab1 of the inner side surface 30Ab of the rail main body portion 30A in the precast wall rail 30 placed on the upper surface 220Ba of the side end portion 220B of the floor slab 220, and the outside of the general portion 220A of the floor slab 220 The precast wall rail 30 is joined to the floor slab 220 by placing the interstitial concrete 240 in the recessed space C formed by the side surface 220Aa and the upper surface 220Ca of the side edge vicinity region 220C of the floor slab 220. It has a configuration.

  Even when the joining structure according to this modification is employed, the same effects as those of the above-described embodiment can be obtained.

  In addition, the numerical value shown as a specification in the said embodiment and its modification is only an example, and of course, you may set these to a different value suitably.

  The invention of the present application is not limited to the configuration described in the above-described embodiment and its modifications, and a configuration with various other changes can be adopted.

2 Jack 4 Extension nose 10 Bridge 20, 220 Floor slab 20A, 220A General part 20Aa, 220Aa Outer side face 20B, 220B Side end part 20C, 220C Side end vicinity area 20Ca, 220Ba, 220Ca Top face 22, 122, 222 First Reinforcing bar 24 Precast rib 24a Upper surface 24a1 Stepped up portion 24b Screw hole 24B Side end portion 26 Precast plate 26a Outer side surface 26C Exposed portion 28 Floor slab concrete 30 Precast wall rail 30c Convex portion 30d Concave portion 30A High rail main body portion 30Aa Bottom side surface 30Ab Lower end portion 30B Suspended portion 32, 132 Second reinforcing bar 34 Stainless steel plate 36 Anchor pin 40, 240 Filled concrete 42 Reinforcing bar 50 Height adjusting bolt 60 PC steel 70 Non-shrink mortar 72, 74, 7 6 Backup material 78 Adhesive 80 Pavement C Recessed space

Claims (4)

In a bridge in which a precast wall rail is installed at the side edge of the floor slab, a joining structure for joining the precast wall rail to the floor slab,
The side end portion of the floor slab and the side end portion vicinity region located on the inner side in the bridge axis orthogonal direction of the side end portion are formed stepwise with respect to the general portion of the floor slab,
The floor slab is provided with a first reinforcing bar that protrudes from the outer surface of the general portion of the floor slab, and a second cast that protrudes from the lower end of the inner surface of the precast wall rail to the precast wall rail. There are reinforcing bars,
Recessed space formed by the inner surface of the precast wall rail placed on the upper surface of the side end portion of the floor slab, the outer surface of the general portion of the floor slab, and the upper surface of the area near the side end portion of the floor slab The precast wall railing is joined to the floor slab by placing the interstitial concrete on the floor ,
In the state in which the floor slab has a plurality of precast ribs extending in a direction perpendicular to the bridge axis at predetermined intervals in the bridge axis direction, and a plurality of precast plates are bridged between the precast ribs. It is formed by placing floor slab concrete on top,
The precast wall rail is placed on the upper surface of the side end of the plurality of precast ribs,
The interstitial concrete is placed in a recessed space formed by the inner surface of the precast wall rail, the outer surface of the floor slab concrete, and the upper surface of the outermost precast plate among the plurality of precast plates. A precast wall railing joint structure characterized by that.   The precast wall rail is placed on the upper surface of the side end portions of the plurality of precast ribs, with the inner surface of the precast wall rail and the outer surface of the outermost precast plate being substantially flush with each other. The joint structure of a precast wall railing according to claim 1, wherein:   The precast wall height column according to claim 1 or 2, wherein a height adjustment structure for adjusting an installation height of the precast wall height column is provided on an upper surface of a side end portion of each precast rib. Bonding structure. The precast wall rail is provided with a rail main body portion and a hanging portion extending downward from an outer region in a lower end surface of the rail main body portion,
The joint of the precast wall rail according to any one of claims 1 to 3, wherein the precast wall rail is placed on an upper surface of a side end portion of each precast rib at a lower end surface of the rail main body portion. Construction.

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