JP2008248648A - Concrete structure and joining method of concrete structure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a concrete structure and a joining method of a concrete structure, which enables a plurality of precast concrete members to be easily connected to one another. <P>SOLUTION: Two precast panels 3 constituting the concrete structure 1 have a concavity 9 on the top surface 7, and a sheath conduit 15 is horizontally provided between the vertical surface 8 of the concavity 9 and the side 4 of the precast panel 3. In order to construct the concrete structure 1, first, the precast panel 3a is arranged in a predetermined position. A PC steel bar 11 is inserted to the sheath conduit 15 provided in the precast panel 3a, and a nut 13 is provided to the end of the PC steel bar 11 positioned in the concavity 9. Then the precast panel 3b is arranged while the PC steel bar 11 projected from the precast panel 3a is inserted to the sheath conduit 15. After the precast panel 3b has been arranged, the nut 13 is provided to the end of the PC steel bar 11 which is positioned in the concavity 9 of the precast panel 3b, and the PC steel bar 11 is fixed to the precast panel 3. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a concrete structure and a method for connecting concrete structures.

  Conventionally, in railroads, a slab track in which a rail is provided on a plate made of concrete or the like called a track slab has been used in addition to a ballast track using a ballast material. In the case of a slab track, there has been proposed a method for constructing a track slab by connecting a plurality of precast concrete members by a connecting means when a track slab is newly installed or when an old track slab is replaced. As a method of connecting the precast concrete members, for example, a method of fastening with a PC steel rod in a direction perpendicular to the track has been proposed (for example, see Patent Document 1).

JP 2006-283316 A (FIG. 1)

  However, in the connection method described above, since a long PC steel rod is used, it is difficult to handle the PC steel rod in a narrow work space. In addition, when the existing track slab is replaced, there is a possibility of a rail short circuit. Furthermore, since the precast concrete member used for the construction of the track slab has a thin cross section, the cross section of the concrete passing through the sheath tube was large. In addition, there are problems such as the need to pass the sheath tube under a rail having a large bending moment, the necessity of a specialist engineer to inject the entire length of the sheath tube, and the necessity of a PC engineer.

  This invention is made | formed in view of such a problem, The place made into the objective is providing the connection method of the concrete structure and concrete structure which can connect several precast concrete members easily.

  A first invention for achieving the above-described object includes a plurality of precast members having a recess on a predetermined surface and provided with a pipe portion connecting the inside of the recess and the outside of the member, and the plurality of precast members. A concrete structure characterized in that the plurality of precast members are arranged so that the pipe portions communicate with each other and are connected using the connection means.

  The connecting means includes, for example, a steel material inserted into the pipe portion and a fixture that is disposed in the recess and fixes the steel material to a plurality of precast members.

  2nd invention arrange | positions the several precast member which has the recessed part in the predetermined surface, and was provided with the pipe part which connects the said recessed part and the member exterior so that the said pipe parts may communicate, and a connection means It is the connection method of the concrete structure characterized by connecting using.

  In the second invention, for example, the connecting means includes a steel material inserted into the pipe portion and a fixture that is disposed in the recess and fixes the steel material to a plurality of precast members. The plurality of precast concrete members are connected by fixing the steel materials to the plurality of precast members using the fixtures that are inserted and disposed in the recesses.

  ADVANTAGE OF THE INVENTION According to this invention, the connection method of the concrete structure and concrete structure which can connect a some precast concrete member easily can be provided.

  Hereinafter, a first embodiment of the present invention will be described in detail with reference to the drawings. FIG. 1 is a perspective view of a concrete structure 1 according to the first embodiment, and FIG. 2 is a cross-sectional view of the concrete structure 1. FIG. 2 is a cross-sectional view taken along the line AA of FIG.

As shown in FIGS. 1 and 2, the concrete structure 1 has a structure in which two precast plates 3 (precast plate 3a and precast plate 3b) are connected. The precast plate 3 is so-called precast concrete.

The precast plate 3a has fan-shaped notches 5a at both ends of the side surface 4 facing the precast plate 3b. The precast plate 3b has fan-shaped notches 5b at both ends of the side surface 4 facing the precast plate 3a. The concrete structure 1 has a semicircular cutout portion 5 including a cutout portion 5a and a cutout portion 5b.

  Each of the precast plate 3 a and the precast plate 3 b has a recess 9 on the upper surface 7. Moreover, it has the sheath pipe | tube 15 which is a pipe part which connects the inside of the recessed part 9 and the exterior of a member. The sheath tube 15 is provided horizontally between the vertical surface 8 of the recess 9 and the side surface 4 of the precast plate 3.

  The precast plate 3a and the precast plate 3b are arranged so that the sheath tubes 15 communicate with each other. The PC steel rod 11 is inserted through the communicating sheath tube 15. The PC steel bar 11 is fixed to the precast plate 3a and the precast plate 3b using a nut 13 disposed in the recess 9. The inside of the sheath tube 15 is filled with a grout material 17. An epoxy resin 19 is filled between the side surface 4 of the precast plate 3a and the side surface 4 of the precast plate 3b. The recess 9 is backfilled with a non-shrink mortar (not shown).

  FIG. 3 is a diagram showing an outline of the loading test of the concrete structure 1. 4 is a diagram showing the relationship between the axial force of the PC steel bar 11 and the loaded load, and FIG. 5 is a diagram showing the relationship between the opening displacement of the connecting portion of the precast plate 3 and the loaded load.

  4 and 5 show the experimental results when the concrete structure 1 is loaded at two points as shown in FIG. The dotted line 21, the solid line 23, and the broken line 25 of FIG. 4 show the relationship between the axial force of the PC steel bar 11 and the loaded load when the initial introduction fastening force of the PC steel bar 11 is 20 kN, 120 kN, and 260 kN, respectively. The dotted line 27, the solid line 29, and the broken line 31 in FIG. 5 indicate the relationship between the opening displacement of the connecting portion of the precast plate 3 and the loaded load when the initial introduction fastening force of the PC steel bar 11 is 20 kN, 120 kN, and 260 kN, respectively. . As shown in FIGS. 4 and 5, the opening displacement of the connecting portion is smaller as the initial introduction fastening force of the PC steel rod 11 is larger.

Next, a replacement method when the concrete structure 1 is used as a replacement track slab will be described. 6 to 9 are diagrams showing a procedure for exchanging the existing track slab 33 and the concrete structure 1 shown in FIGS. 1 and 2.

First, the structure of the slab track 35 will be briefly described with reference to FIG. In the slab track 35, a CA mortar 37 is provided on the concrete roadbed 36, and a track slab 33 and a track slab 34 are provided on the CA mortar. A tie plate 41a, a tie plate 41b, a tie plate 41c, and a tie plate 41d are provided on the track slab 33 and the track slab 34, and a rail 43a and a rail 43b are provided on these tie plates. The concrete roadbed 36 has protrusions 39a and protrusions 39b, and restricts the movement of the track slab 33 and the track slab 34 in the horizontal direction. The track slab 33 is made of a single precast concrete plate.

In such a slab track 35, as shown in FIG. 6, it is assumed that the track slab 33 is damaged due to aging or the like and needs to be replaced. In this case, first, as shown in FIG. 7, after slightly lifting the rails 43 a and 43 b, the tie plate 41 b and the tie plate 41 d are removed from the track slab 33. Then, after the track slab 33 is cut, the track slab 33 is moved in the arrow B direction and removed from the slab track 35. At this time, the track slab 33 may be crushed and taken out. After the slab track 33 is removed, the CA mortar 37 under the track slab 33 is removed.

Next, as shown in FIG. 8, the precast plate 3 a of the concrete structure 1 is moved in the direction of the arrow C and arranged on the slab track 35. In the precast plate 3a, the PC steel rod 11 is inserted into the sheath tube 15 before and after the placement on the slab track 35, and the nut 13 is installed at the end of the PC steel rod 11 located in the recess 9. (FIG. 2).

Next, as shown in FIG. 9, the precast plate 3 b of the concrete structure 1 is moved in the direction of the arrow D and placed on the slab track 35. The precast plate 3b is arranged while the PC steel rod 11 protruding from the precast plate 3a is inserted into the sheath tube 15. After arranging the precast plate 3b, a nut 13 is installed at the end of the PC steel rod 11 located in the recess 9 of the precast plate 3b, and the PC steel rod 11 is fixed to the precast plate 3a and the precast plate 3b. Then, the inside of the sheath tube 15 is filled with a grout material 17, and the recess 9 is backfilled with a non-shrink mortar (not shown). Further, an epoxy resin 19 is filled between the precast plate 3a and the precast plate 3b (FIG. 2).

In the steps so far, since the CA mortar 37 has been removed, the precast plate 3a and the precast plate 3b are connected on the concrete roadbed 36, and then the whole is lifted. In addition, you may work in the state which provided the spacer etc. which are not shown in figure between the precast board 3a and the precast board 3b, and the concrete roadbed 36, and raised the whole.

Finally, CA mortar 37 is injected under the precast plate 3. In this way, the concrete structure 1 is installed.

As described above, according to the first embodiment, the two precast plates 3 are separately installed on the slab track 35 and then connected to each other, so that the precast plate 3 can be attached even if the projections 39a and 39b are present. Can be inserted from the horizontal direction. In addition, when removing the concrete structure 1 from the slab track 35, by removing the two precast plates 3 from the slab track separately after releasing the connection, even if there are the protrusions 39a and 39b, The concrete structure 1 can be easily removed from the slab track 35.

In the concrete structure 1 according to the first embodiment, the PC steel rod 11 is connected to the central portion by the PC steel rod 11 without using the long PC steel rod extending over the entire length of the precast plate 3. It is shorter than before and easy to handle. Further, the installation length of the sheath tube 15 is shortened, and the grout material 17 can be easily injected. Since the PC steel bar 11 is tightened using the nut 13, a PC engineer is unnecessary.

Furthermore, since the sheath tube 15 is provided only at the center of the connecting portion where the bending moment hardly occurs, the influence of the cross-sectional defect of the precast plate 3 is small, and it is not necessary to pass the sheath tube 15 under the rail having a large bending moment.

In the first embodiment, compressive stress is applied to the entire connection surface, and a bending moment can be transmitted on the connection surface.
In addition, in 1st Embodiment, although the precast board 3a and the precast board 3b were connected using the PC steel rod 11, you may connect using a long volt | bolt.

Next, a second embodiment will be described. FIG. 10 is a perspective view of a concrete structure 51 according to the second embodiment, and FIG. 11 is a cross-sectional view of the concrete structure 51. 11 is a cross-sectional view taken along line EE in FIG.

As shown in FIGS. 10 and 11, the concrete structure 51 has a structure in which a precast plate 53a, a precast plate 53c, and a precast plate 53b are connected in a row. The precast plate 53a, the precast plate 53b, and the precast plate 53c are so-called precast concrete.

The precast plate 53a has a semicircular cutout portion 57a on a side surface 54a that does not face the precast plate 53c. The precast plate 53b has a semicircular cutout portion 57b on a side surface 54b that does not face the precast plate 53c.

  The precast plate 53a has a concave portion 55a on the upper surface and a sheath tube 59 that is a tube portion connecting the inside of the concave portion 55a and the outside of the member. The sheath tube 59 is horizontally provided in two upper and lower stages between the vertical surface 58a of the recess 55a and the side surface 56a facing the precast plate 53c.

The precast plate 53b has a concave portion 55b on the upper surface and a sheath tube 59 that is a tube portion connecting the inside of the concave portion 55b and the outside of the member. The sheath tube 59 is horizontally provided in two upper and lower stages between the vertical surface 58b of the recess 55b and the side surface 56b facing the precast plate 53c.

The precast plate 53c has a concave portion 55c on the upper surface, and a sheath tube 59 that is a tube portion connecting the inside of the concave portion 55c and the outside of the member. The sheath tube 59 is horizontally provided in two upper and lower stages between the vertical surface 58c of the recess 55c on the precast plate 53a side and the side surface 56c facing the precast plate 53a. Further, it is also provided horizontally in two upper and lower stages between the vertical surface 58c of the recess 55c on the precast plate 53b side and the side surface 56c facing the precast plate 53b.

  The precast plate 53a, the precast plate 53c, and the precast plate 53b are arranged so that the sheath tubes 59 communicate with each other. A PC steel rod 61 is inserted through the communicating sheath tube 59. The PC steel rod 61 is fixed to the precast plate 53a, the precast plate 53b, and the precast plate 53c by using a nut 63 disposed in the recess 55a, the recess 55b, and the recess 55c. The inside of the sheath tube 59 is filled with a grout material (not shown). An epoxy resin (not shown) is filled between the precast plate 53a and the precast plate 53c and between the precast plate 53b and the precast plate 53c. The recess 55a, the recess 55b, and the recess 55c are backfilled with a non-shrink mortar (not shown).

  When the concrete structure 51 is used as a replacement track slab in the same manner as the concrete structure 1 of the first embodiment, the structure is composed of three precast plates 53a, precast plates 53b, and precast plates 53c. Can be easily installed and removed from the slab track.

In the concrete structure 51 of the second embodiment, the length of the PC steel bar is shorter than that of the conventional one, and handling is easy. Further, the installation length of the sheath tube 59 is shortened, and the grout material can be easily injected. Since the PC steel bar 61 is tightened using the nut 63, a PC engineer is unnecessary.

In the second embodiment, the PC steel bar 61 is used to connect the precast plate 53a, the precast plate 53b, and the precast plate 53c, but they may be connected using long bolts.

Next, a third embodiment will be described. FIG. 12 is a view showing a concrete structure 65 according to the third embodiment.

As shown in FIG. 12, the concrete structure 65 has a structure in which the precast plate 67a, the precast plate 67c, the precast plate 67d, and the precast plate 67b are connected in a row, and has a hollow portion 66 at the center. The precast plate 67a, precast plate 67b, precast plate 67c, and precast plate 67d are so-called precast concrete.

The precast plate 67a has a semicircular cutout 71a on a side surface 70a that does not face the precast plate 67c and the precast plate 67d. The precast plate 67b has a semicircular cutout 71b on a side surface 70b that does not face the precast plate 67c and the precast plate 67d.

  The precast plate 67a has a recess 69a on the upper surface, and has a sheath tube (not shown) that is a tube portion connecting the inside of the recess 69a and the outside of the member. The sheath tube (not shown) is provided horizontally between the vertical surface 72a of the recess 69a and the side surface 68a facing the precast plate 67c and the precast plate 67d.

The precast plate 67b has a recess 69b on the upper surface, and has a sheath tube (not shown) that is a tube portion connecting the inside of the recess 69b and the outside of the member. The sheath tube (not shown) is provided horizontally between the vertical surface 72b of the recess 69b and the side surface 68b facing the precast plate 67c and the precast plate 67d.

The precast plate 67c has a recess 69c on the upper surface, and has a sheath tube (not shown) that is a tube portion connecting the inside of the recess 69c and the outside of the member. The sheath tube (not shown) is provided horizontally between the vertical surface 72c of the recess 69c on the precast plate 67a side and the side surface 68c facing the precast plate 67a. Further, it is provided horizontally between the vertical surface 72c of the recess 69c on the precast plate 67b side and the side surface 68c facing the precast plate 67b.

The precast plate 67d has a recess 69d on the upper surface, and has a sheath tube (not shown) that is a tube portion connecting the inside of the recess 69d and the outside of the member. The sheath tube (not shown) is provided horizontally between the vertical surface 72d of the recess 69d on the precast plate 67a side and the side surface 68d facing the precast plate 67a. Further, it is provided horizontally between the vertical surface 72d of the recess 69d on the precast plate 67b side and the side surface 68d facing the precast plate 67b.

  The precast plate 67a, the precast plate 67c, the precast plate 67d, and the precast plate 67b are arranged so that sheath tubes (not shown) communicate with each other. A PC steel rod 73a and a PC steel rod 73b are inserted through the communicating sheath tube (not shown). The PC steel rod 73a and the PC steel rod 73b include a recess 69a, a recess 69b, a recess 69c, and a nut 75a, a nut 75b, a nut 75c, and a nut 75d disposed in the recess 69d, and a precast plate 67a, a precast plate 67b, and a precast. It is fixed to the plate 67c and the precast plate 67d. The inside of the sheath tube (not shown) is filled with a grout material (not shown). An epoxy resin (not shown) is filled between the precast plate 67a and the precast plate 67c and the precast plate 67d, and between the precast plate 67b and the precast plate 67c and the precast plate 67d. The recess 69a, the recess 69b, the recess 69c, and the recess 69d are backfilled with a non-shrink mortar (not shown).

  When the concrete structure 65 is used as a replacement track slab in the same manner as the concrete structure 1 of the first embodiment, the structure includes four precast plates 67a, a precast plate 67b, a precast plate 67c, and a precast plate 67d. By doing so, it can be easily installed and removed from the slab track.

In the concrete structure 65 of the third embodiment, the length of the PC steel rod is shorter than that of the conventional one, and handling is easy. Further, the installation length of the sheath tube is shortened, and the grout material can be easily injected. Since the PC steel rod 73a and the PC steel rod 73b are tightened using a nut 75a, a nut 75b, a nut 75c, and a nut 75d, a PC engineer is unnecessary.

In the third embodiment, the precast plate 67a, the precast plate 67b, the precast plate 67c, and the precast plate 67d are connected using the PC steel rod 73a and the PC steel rod 73b. Also good.

Next, a fourth embodiment will be described. FIG. 13 is a view showing a concrete structure 77 according to the fourth embodiment. As shown in FIG. 13, the concrete structure 77 has the structure which connected the precast board 79a and the precast board 79b, and the connection part is trapezoid shape. The precast plate 79a and the precast plate 79b are so-called precast concrete.

The precast plate 79a has a semicircular cutout 83a on a side surface 78a that does not face the precast plate 79b. The precast plate 79b has a semicircular cutout portion 83b on a side surface 78b that does not face the precast plate 79a.

  The precast plate 79a has a recess 81a on the upper surface, and has a sheath tube (not shown) that is a tube portion connecting the inside of the recess 81a and the outside of the member. A sheath tube (not shown) is provided horizontally between the vertical surface 82a of the recess 81a and the side surface 80a facing the precast plate 79b.

The precast plate 79b has a recess 81b on the upper surface, and a sheath tube (not shown) that is a tube portion connecting the inside of the recess 81b and the outside of the member. A sheath tube (not shown) is provided horizontally between the vertical surface 82b of the recess 81b and the side surface 80b facing the precast plate 79a.

  The precast plate 79a and the precast plate 79b are arranged so that sheath tubes (not shown) communicate with each other. A PC steel rod 85 is inserted through the communicating sheath tube (not shown). The PC steel rod 85 is fixed to the precast plate 79a and the precast plate 79b using nuts 87 disposed in the recess 81a and the recess 81b. The inside of the sheath tube (not shown) is filled with a grout material (not shown). An epoxy resin (not shown) is filled between the precast plate 79a and the precast plate 79b. The recess 81a and the recess 81b are backfilled with non-shrink mortar (not shown).

  When the concrete structure 77 is used as a replacement track slab in the same manner as the concrete structure 1 of the first embodiment, the structure including two precast plates 79a and 79b facilitates the slab track. Can be installed and removed.

In the concrete structure 77 of the fourth embodiment, the length of the PC steel rod is shorter than that of the conventional one, and handling is easy. Further, the installation length of the sheath tube is shortened, and the grout material can be easily injected. Since the PC steel rod 85 is tightened using the nut 87, a PC engineer is not required.

In the fourth embodiment, the precast member 79a and the precast member 79b are connected using the PC steel rod 85, but may be connected using a long bolt.

  Next, a fifth embodiment will be described. FIG. 14 is a perspective view of the vicinity of the PC sleeper 93 according to the fifth embodiment, and FIG. 15 is a plan view of the PC sleeper 93. FIG. 15 is a view of a portion indicated by a range F in FIG. 14 as viewed from above.

  As shown in FIG. 14, when a rail 91 is installed on a PC sleeper 93 in a railway, the PC sleeper 93 of the branching portion 89 is long. In the fifth embodiment, the concrete structure of the present invention is used as the PC sleeper 93 when the railway branch 89 is constructed.

As shown in FIG. 15, the PC sleeper 93 of the branching portion 89 has a structure in which a precast member 93a and a precast member 93b are connected. The precast member 93a and the precast member 93b are so-called precast concrete.

  The precast member 93a has a concave portion 95a on the upper surface, and has a sheath tube (not shown) that is a tube portion connecting the inside of the concave portion 95a and the outside of the member. The sheath tube (not shown) is provided horizontally between the vertical surface 98a of the recess 95a and the end surface 100a facing the precast member 93b.

The precast member 93b has a concave portion 95b on the upper surface, and a sheath tube (not shown) that is a tube portion connecting the inside of the concave portion 95b and the outside of the member. The sheath tube (not shown) is provided horizontally between the vertical surface 98b of the recess 95b and the end surface 100b facing the precast member 93a.

  The precast member 93a and the precast member 93b are arranged so that sheath tubes (not shown) communicate with each other. A PC steel rod 97 is inserted into the communicating sheath tube (not shown). The PC steel rod 97 is fixed to the precast member 93a and the precast member 93b by using a nut 99 disposed in the recess 95a and the recess 95b. The inside of the sheath tube (not shown) is filled with a grout material (not shown). An epoxy resin (not shown) is filled between the precast member 93a and the precast member 93b. The recesses 95a and 95b are backfilled with non-shrink mortar (not shown).

In order to install the PC sleeper 93 shown in FIG. 15, first, the precast member 93a is arranged at the planned installation position of the sleeper. In the precast member 93a, a PC steel rod 97 is inserted into a sheath tube (not shown) before and after installation at the planned installation position, and a nut 99 is provided at the end of the PC steel rod 97 located in the recess 95a. Installed.

Next, the precast member 93b is disposed while a PC steel rod 97 protruding from the precast member 93a is inserted through a sheath tube (not shown). After the precast member 93b is arranged, a nut 99 is installed at the end of the PC steel rod 97 located in the recess 95b of the precast member 93b, and the PC steel rod 97 is fixed to the precast member 93a and the precast member 93b. Then, the inside of the sheath tube (not shown) is filled with a grout material (not shown), and the recesses 95a and 95b are backfilled with non-shrink mortar (not shown). Further, an epoxy resin (not shown) is filled between the precast member 93a and the precast member 93b.

In the PC sleeper 93 of the fifth embodiment, since only the central portion is connected by the PC steel rod 97, the length of the PC steel rod is short, and handling is easy. Further, the installation length of the sheath tube is shortened, and the grout material can be easily injected. Since the PC steel rod 97 is tightened using the nut 99, a PC engineer is unnecessary.

Furthermore, since the sheath tube is provided only at the center of the connecting portion where almost no bending moment is generated, the influence of the cross-sectional defect of the PC sleeper 93 is small, and it is not necessary to pass the sheath tube under the rail having a large bending moment.

In the fifth embodiment, the precast member 93a and the precast member 93b are connected using the PC steel rod 97, but may be connected using a long bolt.

Next, a sixth embodiment will be described. FIG. 16 is a perspective view of the vicinity of the work beam 109 according to the sixth embodiment, and FIG. 17 is a plan view of the work beam 109.

  As shown in FIG. 16, when a tunnel 105 is constructed in a railway in which a sleeper 103 is installed on an existing embankment 101 and a rail 107 is laid on the sleeper 103, the sleeper 103 at the position where the tunnel 105 is planned to be constructed is removed. Girder 109 is installed and tunnel 105 is excavated. In the sixth embodiment, when the tunnel 105 is constructed on the existing embankment 101, the concrete structure of the present invention is used as the construction beam 109.

As shown in FIG. 17, the construction beam 109 has a structure in which a precast plate 109a and a precast plate 109b are connected. The precast plate 109a and the precast plate 109b are so-called precast concrete.

  The precast plate 109a has a recess 111a on the upper surface, and a sheath tube (not shown) that is a tube portion connecting the inside of the recess 111a and the outside of the member. A sheath tube (not shown) is provided horizontally between the vertical surface 110a of the recess 111a and the side surface 112a facing the precast plate 109b.

The precast plate 109b has a recess 111b on the upper surface, and a sheath tube (not shown) that is a tube portion connecting the inside of the recess 111b and the outside of the member. A sheath tube (not shown) is provided horizontally between the vertical surface 110b of the recess 111b and the side surface 112b facing the precast plate 109a.

  The precast plate 109a and the precast plate 109b are arranged so that sheath tubes (not shown) communicate with each other. A PC steel rod 113 is inserted through a communicating sheath tube (not shown). The PC steel bar 113 is fixed to the precast plate 109a and the precast plate 109b using nuts 115 disposed in the recesses 111a and 111b. The inside of the sheath tube (not shown) is filled with a grout material (not shown). An epoxy resin (not shown) is filled between the precast plate 109a and the precast plate 109b. The recesses 111a and 111b are backfilled with non-shrink mortar (not shown).

In order to install the construction girders 109 shown in FIGS. 16 and 17, first, the precast plate 109 a is arranged at the planned installation position of the construction girders 109. In the precast plate 109a, a PC steel rod 113 is inserted into a sheath tube (not shown) before and after the arrangement at the planned installation position, and a nut 115 is provided at the end of the PC steel rod 113 located in the recess 111a. Installed.

Next, the precast plate 109b is arranged while inserting a PC steel rod 113 protruding from the precast plate 109a into a sheath tube (not shown). After the precast plate 109b is arranged, a nut 115 is installed at the end of the PC steel rod 113 located in the recess 111b of the precast plate 109b, and the PC steel rod 113 is fixed to the precast plate 109a and the precast plate 109b. Then, the inside of the sheath tube (not shown) is filled with a grout material (not shown), and the recesses 111a and 111b are backfilled with non-shrink mortar (not shown). Further, an epoxy resin (not shown) is filled between the precast plate 109a and the precast plate 109b.

In the construction beam 109 of the sixth embodiment, since only the central portion is connected by the PC steel rod 113, the length of the PC steel rod can be shortened and the handling becomes easy. Further, the installation length of the sheath tube is shortened, and the grout material can be easily injected. Since the PC steel bar 113 is tightened using the nut 115, a PC engineer is unnecessary.

Furthermore, since the sheath tube is provided only at the center of the connecting portion where the bending moment hardly occurs, the influence of the cross-sectional defect of the construction beam 109 is small, and it is not necessary to pass the sheath tube under the rail having a large bending moment.

In the sixth embodiment, the precast member 109a and the precast member 109b are connected using the PC steel rod 113, but may be connected using a long bolt.

Next, a seventh embodiment will be described. FIG. 18 is a perspective view of the vicinity of the stepping plate 123 according to the seventh embodiment, and FIG. 19 is a plan view of the stepping plate 123.

  As shown in FIG. 18, when building the bridge 122, the ground 117 is excavated to install the abutment 119, and the back surface of the abutment 119 is backfilled with the backfill 121. Then, the tread plate 123 is installed above the backfill 121. A bridge girder 125 is installed on the abutment 119. In the bridge 122, the floor slab 127 is installed on the upper surface of the bridge girder 125, and after the backfill 131 is performed above the stepping plate 123, the pavement 129 is applied. In the seventh embodiment, when the bridge 122 is constructed, the concrete structure of the present invention is used as the stepping plate 123 on the back side of the abutment 119.

As shown in FIG. 19, the tread plate 123 has a structure in which a plurality of precast plates 123a are connected. The precast plate 123a is so-called precast concrete.

  The precast plate 123a has a concave portion 125 on the upper surface, and has a sheath tube (not shown) that is a tube portion connecting the inside of the concave portion 125 and the outside of the member. A sheath tube (not shown) is provided horizontally between the vertical surface 124 of the recess 125 and the side surface 126 facing the other precast plate 123a.

  The plurality of precast plates 123a are arranged so that sheath tubes (not shown) communicate with each other. A PC steel rod 127 is inserted into a communicating sheath tube (not shown). The PC steel rod 127 is fixed to the precast plate 123 a using a nut 129 disposed in the recess 125. The inside of the sheath tube (not shown) is filled with a grout material (not shown). An epoxy resin (not shown) is filled between the precast plates 123a. The recess 235 is backfilled with a non-shrink mortar (not shown).

In order to install the tread plate 123 shown in FIGS. 18 and 19, first, the first precast plate 123 a is disposed at a planned installation position of the tread plate 123. In the first precast plate 123a, a PC steel rod 127 is inserted into a sheath tube (not shown) before and after the arrangement at the planned installation position, and at the end of the PC steel rod 127 located in the recess 125, A nut 129 is installed.

Next, the second precast plate 123a is arranged while a PC steel rod 127 protruding from the first precast plate 123a is inserted through a sheath tube (not shown). After placing the second precast plate 123a, a nut 129 is installed at the end of the PC steel rod 127 located in the recess 125 of the second precast plate 123a, and the PC steel rod 127 is attached to the first precast plate 123a and Fix to the second precast plate.

  Further, the third, fourth,... Precast plate 123a is disposed while the PC steel rod 127 is inserted through the sheath tube, and the operation of fixing the PC steel rod 127 with the nut 129 is repeated, and the stepping plate 123 having a predetermined size is repeated. Get.

Thereafter, the inside of the sheath tube (not shown) of each precast plate 123a is filled with a grout material (not shown), and the recess 235 is filled back with a non-shrink mortar (not shown). Further, an epoxy resin (not shown) is filled between the precast plates 123a.

In the tread plate 123 of the seventh embodiment, the length of the PC steel rod is short, and the handling becomes easy. Further, the installation length of the sheath tube is shortened, and the grout material can be easily injected. Since the PC steel rod 127 is tightened using the nut 129, a PC engineer is unnecessary.

In the seventh embodiment, the plurality of precast members 123a are connected using the PC steel rod 127, but may be connected using long bolts.

  Next, an eighth embodiment will be described. FIG. 20 is a sectional view of the vicinity of a reinforced concrete plate 131 according to the eighth embodiment.

  As shown in FIG. 20, when the slab track 139 is newly installed, after the reinforced concrete plate 131 is constructed, the CA mortar 133 is installed on the upper surface of the reinforced concrete plate 131, and the track slab 135 is installed on the upper surface of the CA mortar 133. The rail 137 is installed on the upper surface of the track slab 135. In the eighth embodiment, the concrete structure of the present invention is used as the reinforced concrete plate 131 when the slab track 139 is newly installed.

As shown in FIG. 19, the reinforced concrete plate 131 has a structure in which a plurality of precast plates 123a are connected. The reinforced concrete slab 131 is constructed in the same procedure as the stepping plate 123 of the seventh embodiment.

In the reinforced concrete plate 131 of the eighth embodiment, the length of the PC steel rod is short, and the handling becomes easy. Further, the installation length of the sheath tube is shortened, and the grout material can be easily injected. Since the PC steel rod 127 is tightened using the nut 129, a PC engineer is unnecessary.

In the eighth embodiment, the plurality of precast members 123a are connected using the PC steel rod 127, but may be connected using long bolts.

  The preferred embodiments of the concrete structure and the method for connecting concrete structures according to the present invention have been described above with reference to the accompanying drawings, but the present invention is not limited to such examples. It is obvious for those skilled in the art that various modifications or modifications can be conceived within the scope of the technical idea described in the claims, and these are naturally within the technical scope of the present invention. It is understood that it belongs.

The perspective view of the concrete structure 1 which concerns on 1st Embodiment Sectional view of concrete structure 1 The figure which shows the outline of the loading test of the concrete structure 1 The figure which shows the relationship between the axial force and load load of PC steel bar 11 The figure which shows the relationship between the opening displacement of the connection part of the precast board 3, and a load load The figure which shows the procedure at the time of replacing | exchanging the existing track slab 33 and the concrete structure 1 The figure which shows the procedure at the time of replacing | exchanging the existing track slab 33 and the concrete structure 1 The figure which shows the procedure at the time of replacing | exchanging the existing track slab 33 and the concrete structure 1 The figure which shows the procedure at the time of replacing | exchanging the existing track slab 33 and the concrete structure 1 The perspective view of the concrete structure 51 which concerns on 2nd Embodiment. Sectional view of concrete structure 51 The figure which shows the concrete structure 65 which concerns on 3rd Embodiment The figure which shows the concrete structure 77 which concerns on 4th Embodiment The perspective view of PC sleeper 93 vicinity which concerns on 5th Embodiment Top view of PC sleeper 93 Perspective view of construction girder 109 and its vicinity according to the sixth embodiment Plan view of construction girder 109 Perspective view of the vicinity of the treadle 123 according to the seventh embodiment Plan view of the treadle 123 Sectional drawing of the vicinity of the reinforced concrete plate 131 according to the eighth embodiment

Explanation of symbols

1, 51, 65, 77 ......... Concrete structure 3, 3a, 3b, 53a, 53b, 53c, 67a, 67b, 67c, 67d, 79a, 79b, 109a, 109b, 123a ......... Precast plate 9, 55a , 55b, 69a, 69b, 81a, 81b, 95a, 95b, 111a, 111b, 125 ......... concave 11, 61, 73a, 73b, 85, 97, 113, 127 ......... PC steel bar 13, 63, 75a 75b, 87, 99, 115, 129 ... Nuts 15, 59 ......... Sheath tube 17 ......... Grout material 19 ......... Epoxy resin 33, 34 ......... Orbital slab 89 ......... Branch part 93 ... …… PC sleepers 93a, 93b ……… Precast member 109 ……… Construction girder 123 ……… Staff 131 ……… Reinforced concrete plate

Claims (4)

A plurality of precast members having a recess on a predetermined surface and provided with a pipe portion connecting the inside of the recess and the outside of the member;
Connecting means for connecting the plurality of precast members;
Comprising
A concrete structure, wherein the plurality of precast members are arranged so that the pipe portions communicate with each other and are connected using the connecting means. The connecting means is
A steel material inserted through the pipe part;
A fixture that is disposed in the recess and fixes the steel material to the plurality of precast members;
The concrete structure according to claim 1, comprising:   A plurality of precast members having a recess on a predetermined surface and provided with a pipe portion connecting the inside of the recess and the outside of the member are arranged so that the pipe portions communicate with each other, and are connected using a connecting means. A method for connecting concrete structures characterized by the above. The connecting means is
A steel material inserted through the pipe part;
A fixture that is disposed in the recess and fixes the steel material to the plurality of precast members;
Consists of
4. The method of connecting concrete structures according to claim 3, wherein a steel material is inserted into the communicating pipe portion, and the steel material is fixed to the plurality of precast members using a fixture disposed in the recess. .

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