JP7217673B2 - Concrete floor slab, method for forming concrete floor slab, and method for repairing concrete floor slab - Google Patents

Description

The present invention relates to a concrete floor slab formed by arranging concrete precast slabs on bridge girders, and particularly to a concrete slab in which part of the precast slabs can be easily replaced, and a method of forming this concrete slab. and a method of repairing by replacing a part of a precast slab that constitutes a concrete floor slab.

A plurality of precast slabs arranged in the axial direction of the bridge girder and connected to each other are widely used as the concrete floor slab formed on the bridge girder. Then, prestress is introduced in the axial direction of the bridge girder so that the precast slabs are firmly integrated.

Concrete floor slabs formed in this manner may be damaged due to aged deterioration or the like. A damaged concrete floor slab needs to be repaired to restore its function, and the damaged part is replaced with a precast slab. However, in the concrete slab where prestress is introduced in the axial direction of the bridge girder, continuous tendons are embedded over multiple precast slabs. Moreover, cutting the prestressing tendon to remove some of the precast plates may release the prestress over a wide area. For this reason, when trying to replace the precast plate, a wide range must be replaced at the same time, requiring a lot of work and cost.

Under these circumstances, Patent Literature 2 discloses a concrete floor slab that assumes that a part of the precast slab will be replaced later.
This concrete floor slab is formed by arranging a plurality of panels made of precast concrete on a girder, and a panel group for tension fixation consisting of three panels is provided for each span of the bridge. The tension fixing panel group is composed of two fixing panels and one connection panel arranged between them, and a plurality of normal panels are arranged between the plurality of tension fixing panel groups. The prestressing tendons are connected by connectors and are tensioned sequentially, but by introducing a continuous prestress to the series of normal panels and the two anchored panels adjacent on either side thereof, to the ends of these. Fixture is installed. Thus, when the connecting panel is removed, the prestressing of the anchoring panel and the normal panel on either side of it is maintained. This permits the removal and replacement of the connecting panel of two tension anchoring panel groups and the removal and replacement of the two connecting panels and the series of normal panels between them and the adjacent anchoring panel. It's becoming

JP-A-07-102529 JP-A-07-268808

However, the conventional technique described above has the following problem that needs to be solved.
When a portion of a panel made of precast concrete is damaged and is to be replaced, at least two fixed panels, two connecting panels and a series of normal panels between the two fixed panels must be replaced. must. For this reason, it is not possible to sufficiently meet the demand for reducing repair costs by minimizing the number of panels to be replaced. In addition, when the concrete floor slab is installed, it is necessary to provide the fixing panel with a block for fixing the cap cable in advance. The cap cable is used to introduce prestress to the tension anchoring panel group after replacing the panels, and an unused anchoring block is provided when the concrete floor slab is installed.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and its object is to easily repair damaged precast plates that need to be replaced, regardless of whether the number of precast plates is small or large. To provide a concrete floor slab that can be repaired, a method for forming such a concrete floor slab, and a concrete floor slab that can be easily repaired regardless of whether the number of precast slabs to be replaced is small or large. It is to provide a repair method.

In order to solve the above problems, the invention according to Claim 1 provides a concrete floor in which a plurality of precast plates are arranged on a bridge girder, and prestress is introduced in the axial direction of the bridge girder to join the plurality of precast plates. A plate, wherein a prestress is introduced by a first tendon to a first precast plate group consisting of a predetermined number of precast plates arranged in the axial direction of the bridge girder, and adjacent to the first precast plate group. One end of the first tendon fixed to the first precast plate group of the first tendon and one end of the second tendon penetrating the second precast plate group is connected to the connector the second prestressing tendon is anchored at its other end to the second group of precast plates under tension, and the connector connects the second prestressing tendon to the first To provide a concrete floor slab abutting on a bearing plate fixed to a precast slab adjacent to a first precast slab group of a second precast slab group in a state in which tension is continuously introduced to the tendons. do.

In this concrete floor slab, a continuous prestress in the axial direction of the bridge girder can be introduced to the first precast slab group and the second precast slab group. When either one of the first precast plate group or the second precast plate group is damaged, one of the precast plates can be replaced while maintaining the prestress introduced to the other. . That is, when the first group of precast plates is removed, the second tendon is fixed to the second group of precast plates via the connector and the bearing plate, and the prestress of the second group of precast plates is maintained. Further, when the second group of precast plates is removed, the prestress of the first group of precast plates is maintained by the first tendon. Therefore, it is possible to replace each precast plate group. Then, a plurality of new precast plates are placed after the removed precast plate group, or concrete is placed after the removed precast plate group to form a concrete plate, and the first tendon or the second tendon The new prestressing tendons connected to the prestressing tendons make it possible to introduce prestress into new precast slabs or concrete slabs cast in place.

It should be noted that the concrete floor slab of the present invention is not limited to one composed only of the first precast slab group and the second precast slab group. and a third precast plate group having the same configuration as the second precast plate group is formed so as to be continuous with the second precast plate group, a fourth precast plate group, and a fifth precast plate group Groups and multiple precast version groups may be contiguous.
On the other hand, the other end of the first prestressing may be fixed to the first group of precast plates, or may be connected to another prestressing prestressing prestress via a connector. It may be connected by Also, one or a plurality of precast plate groups can be continuously formed in the first precast plate group in a symmetrical configuration with respect to the second precast plate group.

The invention according to claim 2 is the concrete floor slab according to claim 1, wherein the connector comprises a main body part for transmitting tension between the first tendon and the second tendon; and a nut that is twisted with the male thread provided on the outer peripheral surface of the part, and the nut is in contact with the bearing pressure plate.

When a tension force is continuously introduced into the first prestressing tendon and the second prestressing tendon connected via the connector, the connector is displaced relative to the second group of precast plates to be anchored. For this reason, it is not possible to bring the connector into contact with the bearing plate fixed to the second group of precast plates before tensioning the second tendon. In contrast, in the concrete floor slab of the present invention, the connector has a nut that can be displaced relative to the main body, so that the first tendon and the second tendon are connected to each other. After tension is introduced in the nut, the connector can be easily brought into contact with the bearing plate by rotating the nut about the axis.

The invention according to claim 3 is the concrete floor slab according to claim 1, wherein the bearing pressure plate with which the connector abuts is located between the bearing pressure plate and the precast slabs constituting the second group of precast slabs. It is assumed to be fixed by a filling material that has been filled and hardened.

In the concrete floor slab of the present invention, when the tension is introduced so as to continue the first tendon and the second tendon connected by the connector, the tension is applied even if the bearing plate is movable. It is possible to fix the bearing plate to the second group of precast plates by means of a filling material which is filled after the introduction of . Therefore, it is possible to easily realize a state in which the connector connecting the first tendon to which the tension force is introduced and the second tendon is in contact with the bearing plate fixed to the second group of precast plates. is possible.

In the invention according to claim 4, a first group of precast slabs made up of a predetermined number of precast slabs are arranged in the axial direction of the bridge girder, and the first prestressing tendons arranged in the axial direction of the bridge girder are tensioned to form the first tendons. arranging a second precast plate group consisting of a predetermined number of precast plates at a position adjacent to the first precast plate group; A second tendon is passed through the formed duct, and one end of the second tendon is connected to one end of the first tendon fixed to the first group of precast plates via a connector. grasping the other end of the second tendon and tensioning the second tendon to introduce a prestress in the second precast plate group contiguous with the first precast plate group; The tool has a main body for transmitting tension between the first tendon and the second tendon, and a nut that is twisted with a male thread provided on the outer peripheral surface of the main body. , after introducing tension to the second tendon, rotating the nut to abut the nut against the bearing plate fixed to the second group of precast slabs. A forming method is provided.

In this concrete floor slab forming method, prestress that is continuous in the axial direction of the bridge girder can be introduced to the first precast slab group and the second precast slab group. Then, in a state in which the tension force is continuously introduced to the first tendon and the second tendon connected by the connector, the connector can be brought into contact with the bearing plate fixed to the precast plate. can. Thus, the end of the second prestressing tendon gripped by the connector is ready for anchoring to the second group of precast plates. As a result, even if one of the first precast slab group and the second precast slab group is removed, the prestress is maintained in the other precast slab group, and each precast slab group can be replaced. can be a version. Then, a new precast slab group placed after removing the precast slab group, or a concrete slab formed by placing concrete on site, has a new tendon connected to the first tendon or the second tendon. It is possible to introduce prestress by tensioning the prestressing tendon.
The method for forming a concrete floor slab of the present invention can also be applied to the case where the second group of precast slabs, the third group of precast slabs, the fourth group of precast slabs, and the following groups are successively formed. It is.

In the invention according to claim 5, a first group of precast slabs made up of a predetermined number of precast slabs are arranged in the axial direction of the bridge girder, and the first prestressing tendons arranged in the axial direction of the bridge girder are tensioned to form the first tendons. arranging a second precast plate group consisting of a predetermined number of precast plates at a position adjacent to the first precast plate group; A second tendon is passed through the formed duct, and one end of the second tendon is connected to one end of the first tendon fixed to the first group of precast plates via a connector. grasping the other end of the second prestressing tendon and tensioning the second prestressing tendon to introduce a prestress in the second group of precast plates contiguous with the first group of precast plates; A filler is filled between the bearing plate abutted against the connector from the tendon side and the precast plate included in the second precast plate group and hardened, and the bearing plate is placed in the second precast plate group and fixing to a precast slab included in a method of forming a concrete floor slab.

In this concrete floor slab forming method, prestress that is continuous in the axial direction of the bridge girder can be introduced to the first precast slab group and the second precast slab group. Then, in a state in which tension is introduced into the first tendon and the second tendon connected by the connector, the connector is brought into contact with the bearing plate fixed to the precast plate. Therefore, even if one of the first precast slab group or the second precast slab group is removed, the prestress is maintained in the other precast slab group, and each precast slab group can be replaced. can be

The invention according to claim 6 is the concrete floor slab forming method according to claim 4 or claim 5, wherein the step of arranging the second group of precast slabs; The step of connecting comprises temporarily placing a second group of precast plates with a gap from the first group of precast plates, inserting a second tendon into a duct formed in the second group of precast plates, connecting one end of the second tendon to the first tendon via a connector between the first precast plate group and the second precast plate group, and connecting the second precast plate group to the first precast It moves in the axial direction of the bridge girder toward the group of slabs, accommodates the connector in the enlarged diameter portion of the duct formed in the second group of precast slabs, and moves the second group of precast slabs to the first precast slab. It shall be placed in a position adjacent to the group.

In this method, the first prestressing tendon and the second prestressing tendon are connected and the second prestressing tendon is connected to the upper surface of the floor slab without providing a portion where it is necessary to add concrete after removing the box or the like as much as possible. of tendons can be tensioned.

The invention according to claim 7 is the concrete floor slab according to any one of claims 1 to 3, wherein the other end of the second tendon and the one end of the third tendon are the same as the connector. A second concrete deck slab having a third precast plate group connected via a second connector having a configuration and prestressed in series with the second precast plate group by a third tendon. A method of repairing a concrete floor slab for repairing a group of precast slabs, wherein the second group of precast slabs is removed and one end and the other end of the second tendon are removed from the connector and the second connector , placing a new precast slab group at the position where the second precast slab group was removed, or placing concrete at the position where the second precast slab group was removed to form a new concrete slab, and connecting a new tendon to each of the ends of the first tendon and the third tendon where the connection with the second tendon is eliminated; and tensioning the new tendon to form a new concrete slab. Secondly, there is provided a method for repairing a concrete floor slab that introduces a prestress that is continuous with the first group of precast slabs and the third group of precast slabs.

In this concrete floor slab repair method, when the second precast slab group is damaged, the second precast slab group is repaired while maintaining the prestress of the first precast slab group and the third precast slab group. can be removed. Then, after placing a new precast slab at the removed position or forming a concrete slab with cast-in-place concrete, the newly formed concrete slab has the first precast slab group and the third precast slab group. It becomes possible to introduce a continuous prestress.

As described above, the concrete floor slab of the present invention can be easily repaired regardless of whether the number of damaged precast slabs requiring replacement is small or large. Further, in the method for forming a concrete floor slab of the present invention, it is possible to form a concrete floor slab that can be easily repaired by replacing the precast slab. In addition, according to the concrete floor slab repair method of the present invention, it is possible to easily repair both a small number and a large number of precast slabs to be replaced.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic perspective view which shows the structure of the bridge which has a concrete deck of this invention. 1 is an axial schematic sectional view showing an example of a bridge having a concrete floor slab of the present invention, and a concrete floor slab of this bridge, which is an embodiment of the present invention, showing an enlarged part of the concrete slab; FIG. It is a sectional view. FIG. 3 is a schematic cross-sectional view showing a method of forming the concrete floor slab shown in FIG. 2; FIG. 3 is a schematic cross-sectional view showing a method of forming the concrete floor slab shown in FIG. 2; FIG. 3 is a schematic cross-sectional view showing a method of repairing by replacing a part of a precast slab that constitutes the concrete floor slab shown in FIG. 2 ; FIG. 3 is a schematic cross-sectional view showing a method of repairing by replacing a part of a precast slab that constitutes the concrete floor slab shown in FIG. 2 ; Figure 7 is a side view of an anchor member that can be used in the repair method shown in Figures 5 and 6; FIG. 4 is a schematic cross-sectional view showing another example of a method of introducing prestress to a new concrete slab that has been replaced. FIG. 4 is a schematic cross-sectional view showing another example of a method of introducing prestress to a new concrete slab that has been replaced. FIG. 5 is a cross-sectional view showing anchoring portions and connecting portions of tendons in another embodiment of the concrete floor slab according to the present invention. FIG. 11 is a schematic cross-sectional view showing a method of forming a concrete floor slab using the structure of the tendon anchoring portion and connecting portion shown in FIG. 10 ; FIG. 4 is a cross-sectional view showing another example of the structure of the tendon anchoring portion and connecting portion that can be employed in the concrete floor slab according to the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a schematic perspective view showing the construction of a bridge having a concrete floor slab of the present invention. Moreover, FIG. 2 is a schematic sectional view showing an example of a bridge having a concrete floor slab of the present invention, and an enlarged sectional view of the concrete floor slab of the present invention.
This bridge is used as a road bridge, and precast slabs 10 are arranged on bridge girders 1 supported by abutments or bridge piers 2, and these are connected and fixed to the bridge girders 1 to form concrete floor slabs 3. It is. Each precast slab 10 is provided with a plurality of ducts 13 in the axial direction of the bridge girder 1, and the tendons inserted through these are tensioned and fixed to the concrete floor slab 3 in the axial direction of the bridge girder 1. Prestress is introduced.

The bridge girder 1 is constructed by connecting a plurality of steel girders 4 in parallel and connecting them with horizontal girders 5. Each steel girder 4 has an upper flange 6, a lower flange 7, and a web connecting them vertically. 8. An anti-slip member 9 for fixing the precast plate is provided on the upper surface of the upper flange.

The precast slab 10 is formed by pouring concrete in a factory, production yard, or the like in advance, and has a predetermined dimension in the axial direction of the bridge girder 1 . In addition, the dimension in the direction perpendicular to the axis of the bridge girder corresponds to the width of the road. These precast slabs 10 may have prestress introduced in a direction perpendicular to the axis of the bridge girder 1, and the prestress may be introduced by either a pretension method or a posttension method. .

These precast plates 10 are arranged on the bridge girder in the axial direction of the bridge girder, connected and fixed to the steel girder 4 by anti-slip members 9 . Adjacent precast plates may be joined by a synthetic resin adhesive or the like, or the precast plates are arranged with a gap of about 10 mm to 40 mm and the space between them is filled with non-shrink mortar. may be combined.

The precast slabs 10 arranged on the bridge girders are fixed in a state in which tendons are arranged for every predetermined number and a tension force is introduced. As shown in FIG. 2( a ), the first group of precast plates 21 is provided with a first tension member 31 that penetrates each precast plate, and the first tension member 31 is applied to the arranged precast plates at both ends. Both ends of the material 31 are fixed by fixing tools 11 . A prestress in the axial direction of the bridge beam 1 is thereby introduced into the first precast plate group 21 . A second precast plate group 22 is arranged adjacent to the first precast plate group 21, and a second tendon 32 is inserted into the duct formed in the second precast plate group 21. It is One end of the second tendon 32 is connected to one end of the first tendon 31 fixed to the first precast plate group 21 via the connector 12, and the other end of the second tendon 32 is The other end of the arranged second precast plate group 22 is fixed to the precast plate by the fixing tool 11 . Furthermore, a third precast plate group 23 is arranged at a position adjacent to the second precast plate group 22, and a third tendon 33 connected to the other end of the second tendon 32 via the connector 12. prestress is introduced by the tension of Similarly, prestress is sequentially applied to the fourth precast plate group 24 and the subsequent precast plate groups by the tendons connected in the same manner.

On the other hand, another precast plate group 29 can also be arranged in the direction opposite to the direction in which the second precast plate group 22 is adjacent to the first precast plate group 21, and the second precast plate group 22 and below can be arranged. Similarly, precast plates can be aligned and prestressed.
Although the number of precast plates included in each precast plate group is three in this embodiment, it is not limited to this number and can be designed appropriately.

Each tendon 31, 32, . 13. It is then fixed to the precast plate using wedges. The fixture 11 for fixing the first tendon 31 to the precast plate comprises a set of wedges 41 for holding the first tendon 31 and a set of wedges 41 mounted outside the wedges 41 as shown in FIG. 2(b). It has a cylindrical wedge holding member 42 that holds the wedge, a nut 43 that is twisted with a male thread formed on the outer peripheral surface of the wedge holding member 42, and a bearing pressure plate 44 that is pressed against the precast plate. be.

The wedge 41 is divided into a plurality of parts, held in a pressed state around the first tendon 31, and gradually reduced in cross-section toward the precast plate to which the first tendon 31 is fixed. It is. The wedge holding member 42 has a tubular shape, has a hollow hole with a circular cross section, and has an inner diameter gradually reduced in the direction in which the first tendon 31 extends. A wedge 41 attached to the first tendon is pressed against the inner peripheral surface of the hollow hole to hold the first tendon 31 so as not to come off. The nut 43 can be moved relative to the wedge holding member 42 in the axial direction by rotating it around the axis of the tendon. Therefore, the wedge holding member 42 can be gripped and rotated around the axis of the first tendon 31 in a state in which tension is introduced into the first tendon 31 to abut against the pressure plate 44 . As a result, the introduced tension of the first tendon 31 is fixed to the precast plates 21a constituting the first precast plate group 21 via the wedge 41, the wedge holding member 42, the nut 43 and the bearing plate 44. It is a thing.

The connector 12 includes two sets of wedges 51 and 52, two wedge holding members 53 and 54 holding the respective wedges, and male threads formed on the outer peripheral surfaces of both of these two wedge holding members. and mating coupling members 55 which form the body of the fitting 12 . The connector 12 also includes a nut 56 that is twisted with a male thread formed on the outer peripheral surface of the connecting member 55 .
The two sets of wedges 51, 52 and the two wedge holding members 53, 54 are attached to the ends of the first tendon 31 and the second tendon 32 to be connected, respectively. It firmly grips the material. A connecting member 55 is twisted onto the two wedge retaining members 53,54 attached to the ends of both tendons 31,32 to connect the two wedge retaining members 53,54. As shown in FIG. 2(b), the nut 56 can be rotated about the axis and protruded toward the second precast plate group 22. It bears against a bearing plate 57 fixed to the group 22 .

In the duct through which the second tendon 32 is inserted, and in the enlarged diameter portion 14 of the duct in which the connector 12 is accommodated, after introducing tension to the second tendon 32, a cement-based grout material 58 has been injected and cured. Corrosion of the tendon 31, the fixture 11 and the connector 12 is thereby prevented.

Next, a method for forming the concrete floor slab will be described.
A predetermined number of precast slabs 21a constituting a first precast slab group 21 are arranged on the bridge girder 1, and non-shrinkage mortar is filled between the precast slabs to form continuous precast slabs. . Then, as shown in FIG. 3( a ), tension is applied to the first tendon 31 inserted into the duct 13 , and both ends are fixed to the arranged precast plates by the fixtures 11 . Next, the precast plates 22a constituting the second precast plate group 22 are arranged. At this time, the arranged precast plates 22a are temporarily placed at a predetermined distance from the end face of the first precast plate group 21 as shown in FIG. 3(b). This interval is set to a size that allows the tendons 31 and 32 to be connected by the connector 12 . A second tendon 32 is inserted into the duct provided in the temporarily placed second precast plate group 22, and one end is connected to the fixed end of the first tendon 31 via the connector 12. Connect with

After that, the second precast plate group 22 is moved to a position close to the first precast plate group 21 as shown in FIG. 3(c). Along with this, the connector 12 connecting the two tendons 31 and 32 is accommodated in the enlarged diameter portion 14 of the duct formed in the second group of precast plates 22 . Then, the gap between the first precast plate group 21 and the second precast plate group 22 is filled with the non-shrinkage mortar 15 . In addition, non-shrinking mortar is also filled between the respective precast plate groups 22a that constitute the second precast plate group 22, and the concrete slabs that are continuous from the first precast plate group 21 to the second precast plate group 22 are formed. do.

After the non-shrinkage mortar 15 has hardened, tension is introduced by gripping the other end of the second tendon 32 as shown in FIG. 4(a). At this time, the connector 12 that connects the first tendon 31 and the second tendon 32 is separated from the bearing plate 57, allowing the second tendon 32 to move in the axial direction. Therefore, the tension introduced into the second tendon 32 is transmitted to the first tendon 31 via the connector 12 . As a result, a prestress is introduced to the second precast plate group 22 up to the boundary with the first precast plate group 21, and the first precast plate group 21 to the second precast plate group 22 are continuously applied. prestress is introduced.

After fixing the tensioned end of the second tendon 32 to the end surface of the second precast plate group 22 via the fixture 16, the opening provided in the enlarged diameter portion 14 of the duct as shown in FIG. 17 rotates the nut 56 twisted to the connecting member 55 of the connector 12 and brings it into contact with the bearing plate 57 fixed to the second precast plate group 22 . Then, as shown in FIG. 4C, the inside of the duct 13 and the enlarged diameter portion 14 of the duct are filled with grout material 18 or mortar, and each precast plate is fixed to the bridge girder 1 .
Such a process is performed for the third precast slab group 23 adjacent to the second precast slab group 22, and is repeated for the fourth precast slab group 24 and below to form the concrete floor slabs 3.

Next, a method of repairing a part of the concrete floor slab 3 that is damaged and replacing a part of the precast slab will be described.
As shown in FIG. 5(a), the second precast slab group 22 of the concrete floor slab 3 where the first precast slab group 21, the second precast slab group 22 and the third precast slab group 23 are continuous is damaged. shall be repaired by replacing it.
The second precast plate group 22 to be replaced is removed as shown in FIG. At this time, even if the connection with the first tendon 31 and the connection with the third tendon 33 are released, the third precast tendon 33 is transferred through the connector 19 and the bearing plate 58 to the third precast plate group. 23. The first tendon 31 is also fixed to the first precast plate group 21 via the fixing tool 11 . Therefore, the prestress of the first precast plate group 21 and the third precast plate group 23 adjacent to the second precast plate group 22 is maintained.

A new precast plate group 28 is arranged at the position where the second precast plate group 22 has been removed, and the non-shrinkage mortar is arranged between the first precast plate group 21 and the third precast plate group 23. 61 and 62 are filled. A new precast plate group 28 is embedded with an anchor member 20 for fixing a new precast tendon almost in the center. As shown in FIG. 7, the anchor member 20 is formed by joining together two tubular portions 20a and 20b made of metal. The end can be inserted and fixed. A duct 63 provided in a newly arranged precast plate 28a can be connected to one end 20c of both tubular portions 20a and 20b. Both cylindrical portions 20a and 20b are curved and the other end 20d is opened in a notch portion 64 formed in the lower surface of the precast plate.

The newly installed prestressing tendon 39 is divided into two and inserted through the respective openings of the anchor member 20 as shown in FIG. 6(a). Then, as shown in FIG. 6(b), the first tendon 31 and the third tendon 33 are connected to the first tendon 31 and the third tendon 33 through the duct 63 via the connecting tools 12 and 19, respectively, and the tubular portion of the anchor member 20 introduces tension within the opening notch 64 . After the tendons 39a and 39b to which tension force has been introduced are fixed via the anchor member 20, the notch 64 is filled with concrete 65 or mortar to embed the fixed part as shown in FIG. 6(c). At the same time, the connecting portion between the third tendon 33 and the new tendon 39a is also embedded with concrete 66 or mortar. A grout material 67 is injected when it is difficult to fill concrete or mortar, such as the connecting portion between the first tendon 31 and the new tendon 39b shown in FIG.

In the concrete floor slab repair method described above, the anchor member 20 in which the two tubular portions are integrated is used to fix the newly installed tendons 39. However, as shown in FIG. 27 may be provided with blocks 68 for fixing the tendon, and the new tendon 38 may be inserted, applied with tension, and fixed through openings provided in these fixing blocks.
The fixing blocks 68 may be provided on the precast plates at both ends constituting the new precast plate group 28 as shown in FIG. It may be provided on two adjacent precast plates of the plate group 26 or on two precast plates at a distant position, so that a part of the two new tendons 37a, 37b, 38a, 38b overlap. The fixing block 68 can be provided at an appropriate position as long as it is arranged.

When prestress is introduced into the new precast plate groups 26, 27, and 28 by the method shown in FIGS. are fixed to the bridge girder 1, it is conceivable that they are constrained by the bridge girder 1 and do not introduce sufficient prestress to the new precast slabs 26, 27, 28. In such a case, the following method may be employed to introduce prestress instead of or in addition to the above method.
In this method, a new precast plate group 25 is arranged on the bridge girder 1 as shown in FIG. A prestress is introduced into the precast plate group 25 . The new tendons 36 used here are arranged in the axial direction of the bridge girder 1, connect all the precast plates of the new precast plate group 25, and fix both ends to the new precast plate group 25. Then, as shown in FIG. 9B, the non-shrinkage mortar 69 is filled in the gap between the remaining precast plate groups 21 and 23 and the new precast plate group 25 and hardened. After the non-shrinkage mortar 69 has set, all or part of the new prestressing tendon 36 is released.

The new precast slab group 25 is prestressed by the tension of the newly installed tendon 36 , and shrinkage occurs in the axial direction of the bridge girder 1 . After the new precast plate group 25 and the remaining precast plate groups 21 and 23 are connected with the non-shrinkage mortar 69, when the tension of the new precast plate group 36 is released, the tension of the new precast plate group 25 is released. The elongation due to the release of force is restrained by the remaining precast plate groups 21 and 23, and part of the prestress introduced to the new precast plate group 25 remains, and the new precast plate group 25 and the remaining precast plate remain. A prestress is also introduced at the joints with the groups 21,23.

FIG. 10 is a cross-sectional view showing a tendon connection portion in a concrete floor slab according to another embodiment of the present invention.
This concrete floor slab is composed of a first group of precast slabs, a second group of precast slabs, and a plurality of precast slabs in the same manner as shown in FIG. prestress is introduced by The fixture 11 used for fixing these tendons is the same as that used in the concrete floor slab 3 shown in FIG. , and the first prestressing tendon 31 that introduces prestress to the first precast plate group 21 as shown in FIG. The connector 70 used to connect the second tendon 32 to the anchored end of the first tendon 31 includes two sets of wedges 71, 72 that can be attached to the two tendons 31, 32, respectively. , two wedge holding members 73 and 74, and a connecting member 75 which is twisted with a male screw formed on the outer peripheral surface of the two wedge holding members 73 and 74 and can connect both wedge holding members 73 and 74. and The wedges 71 and 72 and the wedge holding members 73 and 74 can be the same as the connector 12 shown in FIG. 2(b). A male screw is not formed on the cylindrical outer peripheral surface of the connecting member 75 used in the connector 70 shown in FIG.

The second tendon 32 connected by the connector 70 is inserted through the central hole of the bearing plate 76, and the bearing plate 76 abuts the end face of the wedge holding member 74 attached to the second tendon 32. It is A grout material 77 is filled at least between the back surface side of the bearing plate 76 and the surface of the precast plate facing thereto, and the bearing plate 76 is placed between the first precast plate group 21 of the second precast plate group 22 and the precast plate face facing thereto. It is fixed to the adjacent precast plate 22a. The grout material 77 must be filled so that the bearing plate 76 can be fixed to the precast plate 22a. there is

A concrete floor slab using such connectors 70 can be formed as follows.
Similar to the method shown in FIG. 3, the first precast plate group 21 is placed on the bridge girder 1, and the first tendon 31 is tensioned and anchored to introduce prestress to the first precast plate group 21. . After that, as shown in FIG. 11( a ), the second precast plate group 22 is temporarily placed with a gap from the first precast plate group 21 , and the fixed end of the first tendon 31 is placed in this gap. One end of the second tendon 32 is connected via a connector 70 . This step can be performed in the same manner as the method shown in FIG. However, in this method, the end face of the wedge holding member 74 attached to the second tendon 32 of the connector 70 is brought into contact with the bearing plate 76 . The bearing pressure plate 76 may be adhered to the wedge holding member 74 with an adhesive.

Next, as shown in FIG. 11(b), the second precast slab group 22 is moved in the axial direction of the bridge girder 1, and the second precast slab group 22 is arranged at a position close to the first precast slab group 21. At the same time, the connector 70 is accommodated in the enlarged diameter portion 14 of the duct provided in the second precast plate group 22 . At this time, the bearing plate 76 does not come into contact with the precast plate 22a and is separated from the end face of the enlarged diameter portion 14. As shown in FIG. Then, the other end of the second tendon 32 is gripped to introduce tension force, thereby introducing prestress to the second precast plate group 22 . At this time as well, the bearing plate 76 is separated from the second precast plate group 22 and the prestress is introduced even to the joint end face with the first precast plate group 21 .

After the second tendon 32 is fixed, as shown in FIG. 11(c), a cement-based grout material 77 is injected into the enlarged diameter portion 14 of the duct from a grout injection pipe 78 and hardened to precast a bearing plate 76. While fixing to the plate 22a, the connector 70 and the fixture 11 are embedded.
Such a process is repeated for the third group of precast slabs and below to form a continuous concrete floor slab on the bridge girder in an arbitrary range.
Moreover, the concrete floor slab formed in this manner can be repaired by the same steps as those shown in FIGS.

FIG. 12 shows a first precast slab group 21 and a second precast slab group 21 of connectors 80 and 90 that can be used in place of the connectors 12 and 70 shown in FIG. 2 or FIG. is a cross-sectional view showing a joint portion with a precast plate group 22 of .
In the concrete floor slab shown in FIG. 12( a ), a connector 80 includes two sets of wedges 81 and 82 that can be attached to two tendons 31 and 32 respectively, two wedge holding members 83 and 84 , It has a connecting member 85 that connects two wedge holding members, and a nut 86 that is twisted around the outer peripheral surface of the wedge holding member 84 attached to the second tendon 32 . The wedges 81 and 82 are attached to the tendons 31 and 32, respectively, in the same manner as the connector shown in FIG. is possible. The wedge holding members 83 and 84 hold the wedges 81 and 82 in the same manner as those used in the connector 13 shown in FIG. A male thread is not formed on the outer peripheral surface of 83 . On the other hand, the wedge holding member 84 attached to the second tendon 32 has a male thread formed on its outer peripheral surface so that it can be twisted with the connecting member 85 and the nut 86 . The wedge holding member 84 attached to the second tendon 32 is axially longer than the wedge holding member 83 attached to the first tendon 31, and the connecting member 85 and the nut 86 are twisted together. In addition, it has a length that allows the nut 86 to be rotated and moved in the axial direction.

The connecting member 85 includes a cylindrical tubular portion 85a and a plate formed so as to protrude toward the center from the inner peripheral surface of the tubular portion 85a at the end on the side connected to the first tendon 31. and a shaped portion 85b. A central hole through which the tendon is inserted is provided at the center of the plate-like portion 85b. The inner diameter of the cylindrical portion 85a is larger than the outer diameter of the wedge holding member 83 attached to the first tendon 31, and the diameter of the central hole is smaller than the outer diameter of the wedge holding member 83. Therefore, the wedge holding member 83 that holds the end of the first tendon 31 via the wedge 81 is accommodated inside the connecting member 85 and is locked while being abutted against the plate-like portion 85b. Also, the wedge holding member 84 attached to the second tendon 32 is twisted and connected to a female thread formed on the inner peripheral surface of the connecting member 85 .

A concrete floor slab using such connectors 80 can be formed by steps similar to those shown in FIGS. The bearing plate 87 and the nut 86 are spaced apart from each other, and the nut 86 can be rotated into contact with the bearing plate 87 after tension is introduced. Also, the concrete floor slab thus formed can be repaired by adopting the steps shown in FIGS.

The connector 90 used in the concrete floor slab shown in FIG. 12(b) is similar to the connector 80 shown in FIG. 94 and a connecting member 95, the wedge retainer 94 attached to the second tendon 32 having approximately the same dimensions as the wedge retainer 93 attached to the first tendon 31. It is a thing.
The two sets of wedges 91, 92 and the two wedge holding members 93, 94 of the connecting device 90 are connected to the first tendon 31 and the second tendon 32 similarly to the connecting device 80 shown in FIG. 12(a). It is attached to the ends and similarly connected by connecting members 95 . When the tension force is introduced to the second tendon 32, the bearing plate 96 is brought into contact with the wedge holding member 94 attached to the second tendon 32, and the bearing plate 96 is separated from the precast plate 22a. It is assumed that Then, it is fixed to the precast plate by the grout material 97 injected after introducing the tension force to the second tendon 32 .

The concrete floor slab, the method for forming the concrete floor slab, and the method for repairing the concrete floor slab described above are embodiments of the present invention, and the present invention is not limited to the above-described embodiments.
For example, fixing tools, connecting tools, bearing plates, etc. are not limited to those described above, and other forms can be used. Also, the tendon is not limited to a steel stranded wire, and a steel bar, an FRP tendon obtained by bundling and binding a large number of high-strength fibers, or the like can also be used.
Each precast plate group below the first precast plate group includes three precast plates in the above embodiment, but is not limited to three and can be set arbitrarily. Each precast version group does not need to be composed of the same number of precast versions, and may be composed of appropriately different numbers of precast versions.

In the above-described embodiment, the tendon connector is accommodated in the enlarged diameter portion of the duct that opens to the end face of the precast plate. may be provided, and the tendon may be connected by operation from the upper surface side or the lower surface side. At this time, it is not necessary to temporarily place the precast plate group separately in order to secure a work space for connecting the tendons by the connector, and the first precast plate group and the second precast plate group are placed close to each other. It is possible to arrange and perform tendon connection work. Moreover, when providing such a notch, mortar or concrete can be used as a filler for fixing the bearing plate to the precast plate in addition to the grout material.
The bridge girders supporting the concrete floor slabs of the present invention are not limited to those using steel I-shaped cross-section girders as shown in FIG. It can be applied to floor slabs in which precast concrete slabs are used.

1: Bridge girder, 2: Pier, 3: Concrete slab, 4: Steel girder, 5: Cross girder, 6: Upper flange, 7: Lower flange, 8: Web, 9: Non-slip member, 10: Precast plate,
11: Fixing tool, 12: Connector, 13: Duct, 14: Expanded diameter portion of duct, 15: Non-shrinkable mortar, 16: Fixing tool, 17: Opening, 18: Grout material, 19: Connector, 20: Anchor Element,
21: First precast plate group, 22: Second precast plate group, 23: Third precast plate group, 24: Fourth precast plate group, 26, 27, 28: New precast plate group, 29: other precast plate groups adjacent to the first precast plate group,
31: first tendon, 32: second tendon, 33: third tendon, 36, 37, 38, 39: new tendon,
41: wedge, 42: wedge holding member, 43: nut, 44: bearing plate,
51, 52: wedges 53, 54: wedge holding member 55: connecting member 56: nut 57: bearing plate 58: bearing plate
61, 62: non-shrink mortar, 63: duct, 64: notch, 65, 66: concrete, 67: grout material, 68: fixing block, 69: non-shrink mortar,
70: Connector, 71, 72: Wedge, 73, 74: Wedge holding member, 75: Connecting member, 76: Bearing plate, 77: Grout material, 78: Grout injection pipe,
80: connecting tool, 81, 82: wedge, 83, 84: wedge holding member, 85: connecting member, 86: nut, 87: bearing pressure plate,
90: Connector, 91, 92: Wedge, 93, 94: Wedge holding member, 95: Connecting member, 96: Bearing plate, 97: Grout material

Claims (7)

A concrete floor slab in which a plurality of precast slabs are arranged on a bridge girder and prestress is introduced in the axial direction of the bridge girder to join the plurality of precast slabs,
A prestress is introduced by a first tendon into a first precast slab group consisting of a predetermined number of precast slabs arranged in the axial direction of the bridge girder,
a second group of precast plates arranged adjacent to the first group of precast plates;
One end of the second tendon that penetrates the second precast plate group is connected to one end of the first tendon fixed to the first precast plate group via a connector,
The second prestressing tendon has the other end fixed to the second precast plate group in a state in which tension is introduced,
The connector is fixed to a precast plate of the second precast plate group adjacent to the first precast plate group in a state in which tension is continuously introduced from the second tendon to the first tendon. A concrete floor slab, characterized in that it is in contact with a bearing pressure plate. The connector has a main body for transmitting tension between the first tendon and the second tendon, and a nut that is twisted with a male screw provided on the outer peripheral surface of the main body. and
2. The concrete floor slab according to claim 1, wherein said nut is in contact with said bearing plate. 3. The bearing plate with which the connector abuts is fixed by a filler filled between the bearing plate and the precast plates forming the second group of precast plates and hardened. 1. The concrete floor slab according to 1. A first precast plate group consisting of a predetermined number of precast plates is arranged in the axial direction of the bridge girder, and a first tendon arranged in the axial direction of the bridge girder is tensioned to apply prestress to the first precast plate group. a step of introducing;
arranging a second precast plate group consisting of a predetermined number of precast plates at positions adjacent to the first precast plate group;
A second tendon is passed through a duct formed in the second precast plate group, and one end of the second tendon is attached to one end of the first tendon fixed to the first precast plate group, a step of connecting via a connector;
gripping the other end of the second tendon and tensioning the second tendon to introduce a prestress in the second group of precast plates contiguous with the first group of precast plates;
The connector has a main body for transmitting tension between the first tendon and the second tendon, and a nut that is twisted with a male screw provided on the outer peripheral surface of the main body. and after introducing a tension force to the second tendon using Characteristic method of forming concrete slabs arranging a first precast slab group consisting of a predetermined number of precast slabs in the axial direction of the bridge girder;
tensioning a first prestressing tendon arranged in the axial direction of the bridge girder to introduce prestress into the first group of precast plates ;
arranging a second precast plate group consisting of a predetermined number of precast plates at positions adjacent to the first precast plate group;
A second tendon is passed through a duct formed in the second precast plate group, and one end of the second tendon is attached to one end of the first tendon fixed to the first precast plate group, a step of connecting via a connector;
gripping the other end of the second tendon and tensioning the second tendon to introduce a prestress in the second group of precast plates contiguous with the first group of precast plates;
A filling material is filled between the bearing plate abutted against the connector from the second tendon side and the precast plates included in the second precast plate group and hardened, and the bearing plate is formed into the second precast. A method of forming a concrete floor slab, comprising a step of fixing to a precast slab included in a group of slabs. The steps of arranging the second group of precast plates and connecting the second tendon with the first tendon comprise:
Temporarily placing the second precast plate group with a gap from the first precast plate group,
A second tendon is passed through a duct formed in the second precast plate group, and one end of the second tendon is inserted into the first precast plate group between the first precast plate group and the second precast plate group. Connect via tendons and connectors,
The second precast plate group is moved in the axial direction of the bridge girder toward the first precast plate group, and the connector is accommodated in the enlarged diameter portion of the duct formed in the second precast plate group. 6. The method of forming a concrete floor slab according to claim 4, wherein the second group of precast slabs is placed adjacent to the first group of precast slabs. In the concrete floor slab according to any one of claims 1 to 3, one end of the third tendon is connected to the other end of the second tendon to provide a second connector having the same configuration as the connector. Concrete repairing a second precast slab group of concrete floor slabs having a third precast slab group connected via and prestressed continuously with the second precast slab group by a third tendon A floor slab repair method comprising:
removing the second precast plate group and removing one end and the other end of the second tendon from the connector and the second connector;
Place a new precast slab group at the position from which the second precast slab group has been removed, or place concrete at the position from which the second precast slab group has been removed to form a new concrete slab. A step of connecting a new tendon to each of the ends of the tendon and the third tendon that have been disconnected from the second tendon;
A method of repairing a concrete floor slab, characterized by tensioning the new prestressing material to introduce prestress into the new concrete slab, which is continuous with the first group of precast slabs and the third group of precast slabs.

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