JP7401945B1 - Connectors and cement structures - Google Patents

Abstract

A connector capable of reducing the height of a cement structure is provided. [Solution] A connector (12) includes a connector shaft (121), a first nut (122), a housing part (124a) that houses the first nut, and prevents the first nut from coming out of the housing part. an elongated portion (125), and when an axial tensile force of a predetermined value or more is applied between the connector shaft portion and the first nut, the elongated portion deforms or breaks, thereby causing the connector shaft portion to separates from the first nut. [Selection diagram] Figure 2

Description

The present invention relates to connectors and cement structures.

Conventionally, a joint structure has been proposed in which the deck slabs of adjacent structures (for example, bridge abutments and bridge girders) of a bridge are connected using reinforced concrete. The joint structure is constructed by excavating the floor slab of an adjacent building to form a recess, fixing reinforcing bars (reinforcing members) to the floor slab in the recess, and pouring a cement-based mixture into the recess. Additionally, an expansion joint may be provided in the joint structure to absorb expansion and contraction of the bridge due to temperature. Expansion joints are fixed to reinforcing bars by welding or the like.

Furthermore, a method is known in which a flat pipe is buried in advance between a reinforcing member and a floor slab to facilitate the removal of reinforced concrete all at once. In this method, the reinforced concrete is removed by expanding the flat pipe up and down, breaking the reinforcing member, and separating the reinforcing member from the floor slab. Patent Documents 1 and 2 describe replacing an expansion joint by such a reinforced concrete removal method.

Patent Document 2 describes a configuration for separating a reinforcing member from a floor slab. Specifically, Patent Document 2 includes a connector and a bolt attached to the connector, and the hem of the connector includes a sleeve that surrounds the head of the bolt, a flange that prevents the bolt from separating from the connector, and a sleeve that surrounds the head of the bolt. Disclosed is a separation device comprising: The bolts are threadedly connected to a support member that is fixed to the floor slab. The connector is connected to an anchor bolt or a reinforcing bar (reinforcing member). In the separation device, the flange is deformed or broken when an axial tensile force of a predetermined value or more is applied between the connector and the bolt, so that the connector is separated from the bolt (that is, the reinforcing member is removed from the floor). (from the version).

Patent No. 5084237 Patent No. 6542950

However, the separation device disclosed in Patent Document 2 uses a bolt having a head and a shaft portion to fix the separation device to the floor slab, so there is a problem that the height of the cement structure increases. There is.

One aspect of the invention aims to reduce the height of cement structures.

In order to solve the above problem, a connector according to one aspect of the present invention includes a connector shaft portion, a first nut, and a connector shaft portion located on one side in the axial direction of the connector shaft portion with respect to the connector shaft portion. , an accommodating part that accommodates the first nut, and an extending part that extends from an edge of the accommodating part inward in the radial direction of the connector shaft part and prevents the first nut from coming out of the accommodating part. , when an axial tensile force of a predetermined value or more is applied between the connector shaft and the first nut, the extending portion is deformed or broken, so that the connector shaft is attached to the first nut. The connector is used to connect the foundation structure and the cement structure.

Further, a first screw hole may be formed in a side surface of the connector shaft portion. Further, a second screw hole may be formed in the end surface on the other end side of the connector shaft portion.

A cement structure according to one aspect of the present invention includes the connector, an anchor bolt extending upward from the foundation structure, and a second nut fastened to the anchor bolt, and the first nut is connected to the first nut. The apparatus further includes a flat plate member fastened to the anchor bolt above the second nut and sandwiched between the connector and the second nut.

The cement structure according to one aspect of the present invention includes the connector, an anchor bolt extending upward from the foundation structure, and a reinforcing member coupled to the first screw hole and extending laterally, 1 nut is fastened to the anchor bolt.

The cement structure according to one aspect of the present invention includes the connector, an anchor bolt extending upward from the foundation structure, and an L-shaped reinforcing member coupled to the second screw hole, A nut is fastened to the anchor bolt.

According to one aspect of the present invention, the height of the cement structure can be reduced.

FIG. 1 is a cross-sectional view showing the configuration of a joint structure according to an embodiment of the present invention. It is a sectional view showing the composition of the anchor part of the above-mentioned joint structure. FIG. 3 is a front view showing the configuration of the connector of the anchor portion. FIG. 3 is a cross-sectional view showing the configuration of the connector of the anchor portion before the caulking portion is caulked. FIG. 3 is a cross-sectional view showing the configuration of the connector of the anchor portion after the caulking portion has been caulked. FIG. 7 is a cross-sectional view showing the configuration of an anchor part of a joint structure according to another embodiment of the present invention.

[Embodiment 1]
(Schematic configuration of joint structure 100)
FIG. 1 is a sectional view showing the configuration of a bridge joint structure 100 (cement structure) according to the first embodiment. The joint structure 100 connects the floor slabs (foundation structures) of adjacent buildings in a bridge. That is, the joint structure 100 connects the floor slab 2A of the first building 1A and the floor slab 2B of the second building 1B. The joint structure 100 is provided in a recess 4 formed by excavating the upper surfaces of the floor slab 2A and the floor slab 2B in the vicinity of the play area 3 between the first building 1A and the second building 1B. The joint structure 100 is constructed by fixing reinforcing bars (reinforcing members) to the floor slabs 2A, 2B in the recess 4, and pouring a cement mixture M (for example, concrete, high-toughness jet mortar, etc.) therein. Hereinafter, the side of the bridge where the first building 1A is located will be described as the front, the side where the second building 1B is located as the rear, the left side facing the rear as the left side, and the right side as the right side.

As shown in FIG. 1, the joint structure 100 includes a plurality of first anchor parts 10A buried in a floor slab 2A, a plurality of second anchor parts 10B and a plurality of third anchor parts 10C buried in a floor slab 2B. and. The plurality of first anchor parts 10A are provided on the floor slab 2A at a predetermined pitch along the left-right direction. Similarly, the plurality of second anchor parts 10B and the plurality of third anchor parts 10C are each provided on the floor slab 2B at a predetermined pitch along the left-right direction. Hereinafter, when there is no need to particularly distinguish between the plurality of first anchor parts 10A, the plurality of second anchor parts 10B, and the plurality of third anchor parts 10C, they will simply be referred to as anchor parts 10.

Each anchor portion 10 has reinforcing bars (reinforcing members 13) extending in the front-rear direction. Specifically, the plurality of first anchor parts 10A have reinforcing bars extending rearward. Moreover, the plurality of second anchor parts 10B and the plurality of third anchor parts 10C have reinforcing bars extending forward. The reinforcing bars extending rearward of each first anchor part 10A and the reinforcing bars of the corresponding second anchor part 10B are connected by any connection method (for example, binding with a binding wire, welding, etc.). Similarly, the reinforcing bars of the plurality of second anchor parts 10B and the reinforcing bars of the plurality of third anchor parts 10C are connected. Thereby, the floor slabs 2A and 2B of adjacent buildings can be connected by reinforcing bars, and the strength of the joint structure 100 against external forces in the front-rear direction can be improved.

The joint structure 100 further includes a flat pipe 5, an upper pipe fixing reinforcing bar 6, and a pipe fixing lower reinforcing bar 7. The flat pipe 5 is provided so as to pass near the boundary between the connector 12 (see FIG. 2) of the anchor portion 10 and the anchor bolt 11 (see FIG. 2). Further, the upper pipe fixing reinforcing bars 6 and the lower pipe fixing reinforcing bars 7 fix the height position of the flat pipe 5 so that the flat pipe 5 is located near the boundary. For example, the lower reinforcing bar 7 for fixing the pipe is fixed to the flat plate member 14 under the flat plate member 14 (see FIG. 2) of the anchor part 10 by any connection method. The flat pipe 5 is placed above the lower reinforcing bar 7 for fixing the pipe so as to pass near the anchor portion 10 . The upper reinforcing bar 6 for fixing the pipe is placed on the upper side of the flat pipe 5, and is fixed to the lower reinforcing bar 7 for fixing the pipe by any connection method. As a result, the flat pipe 5 is held between the upper reinforcing bar 6 for fixing the pipe and the lower reinforcing bar 7 for fixing the pipe near the boundary.

The joint structure 100 may further include a plurality of left-right reinforcing members 8 extending in the left-right direction. A plurality of (five in the example shown in FIG. 1) left-right reinforcing members 8 are arranged in parallel along the front-back direction. The plurality of left-right reinforcing members 8 are arranged below the second straight portion 133 of the reinforcing member 13, and are fixed to the reinforcing member 13 by any connection method. The plurality of left-right reinforcing members 8 can improve the strength of the joint structure 100 against external forces in the left-right direction.

Note that the configuration shown in FIG. 1 is only an example of the joint structure 100. For example, the plurality of third anchor parts 10C may be omitted in the joint structure 100.

(Configuration of anchor part 10)
FIG. 2 is a sectional view showing the structure of the anchor part 10. As shown in FIG. 2, the anchor portion 10 includes an anchor bolt 11, a connector 12, and a reinforcing member 13. Anchor portion 10 is installed in recess 4 by driving anchor bolts 11 into floor slabs 2A, 2B and attaching reinforcing members 13 to anchor bolts 11 via connectors 12. FIG. 2 shows the anchor portion 10 assembled in this manner.

Anchor bolts 11 are bolts fixed to floor slabs 2A and 2B. The anchor bolts 11 extend upward (vertically upward) from the upper surfaces of the floor slabs 2A, 2B.

The connector 12 includes a substantially cylindrical connector shaft portion 121 that extends in the vertical direction, and a first nut 122 that is accommodated in a housing portion 124a formed below the connector shaft portion 121. A screw hole 121a (second screw hole) is formed at the upper end (end surface on the other end side) of the connector shaft portion 121. An L-shaped reinforcing member 13, which will be described later, is coupled to the screw hole 121a. The first nut 122 is fastened to the anchor bolt 11.

The connector 12 is a member that connects the reinforcing member 13 to the anchor bolt 11 and allows the reinforcing member 13 to be separated from the anchor bolt 11 when an axial tensile force of a predetermined value or more is applied. In other words, the connector 12 connects the joint structure 100 to the floor slabs 2A, 2B, and when an axial tensile force of a predetermined value or more is applied, the joint structure 100 can be removed from the floor slabs 2A, 2B. It is a member for The specific configuration of the connector 12 having such a function will be described later with reference to FIGS. 3 to 5.

The reinforcing member 13 is an L-shaped reinforcing bar having a gently bent curved portion 132. That is, the reinforcing member 13 has a first straight section 131, a curved section 132, and a second straight section 133. The reinforcing member 13 is threaded at the first straight portion 131 and fastened to the threaded hole 121a of the connector shaft portion 121. The first straight portion 131 extends upward from the connector 12 . The curved portion 132 is curved by 90 degrees with respect to the first straight portion 131 . The second straight portion 133 extends laterally and is connected to the second straight portion 133 of another anchor portion 10 by any connection method (see FIG. 1). For example, the second straight portion 133 in the first anchor portion 10A extends rearward, and the second straight portion 133 in the second anchor portion 10B extends forward. Then, the second straight portion 133 in the first anchor portion 10A and the second straight portion 133 in the second anchor portion 10B are connected. Thereby, the floor slabs 2A and 2B of adjacent buildings can be connected by the inverted U-shaped reinforcing bars, and the strength of the joint structure 100 against external forces in the front and back direction can be improved. Note that the reinforcing member 13 extends upward from the connector 12 so that the second straight portion 133 is disposed above at least the upper reinforcing bar 6 for fixing the pipe (see FIG. 1).

The anchor portion 10 may further include a flat plate member 14 and a second nut 15. The flat plate member 14 is located below the connector 12, and is provided between a first nut 122 included in the connector 12 and a second nut 15, which will be described later. Further, the flat plate member 14 is connected to the lower reinforcing bar 7 for fixing the pipe located below the flat plate member 14 . Thereby, the flat pipe 5 sandwiched between the upper pipe fixing reinforcing bars 6 and the lower pipe fixing reinforcing bars 7 can be placed near the boundary between the connector 12 and the anchor bolt 11 (see FIG. 1). The flat plate member 14 may be any plate member having a hole or notch through which a bolt passes, such as a square washer. The second nut 15 is fastened to the anchor bolt 11 below the first nut 122. The second nut 15 and the first nut 122 are fixed with the flat plate member 14 sandwiched therebetween.

(Configuration of connector 12)
FIG. 3 is a front view showing the configuration of the connector 12. FIG. 4 is a cross-sectional view showing the configuration of the connector 12 before the caulking portion 124 is caulked. FIG. 5 is a cross-sectional view showing the configuration of the connector 12 after the caulking portion 124 has been caulked. As shown in FIGS. 3 to 5, the connector 12 includes a connector shaft portion 121, a first nut 122, a head portion 123, and a caulking portion 124. The specific configuration of the connector 12 will be described below with reference to FIGS. 3 to 5.

As shown in FIG. 3, a head 123 is provided at the lower end of the connector shaft portion 121 having a substantially cylindrical shape. The head 123 has a diameter larger than that of the connector shaft 121 and has a non-circular (for example, hexagonal) cross section so as to engage with a tool (for example, a hex wrench) for fastening the connector 12 to the anchor bolt 11. has. A substantially cylindrical caulking portion 124 is provided at the lower end of the head 123. The lower portion 124b of the caulked portion 124 is formed to have a smaller outer diameter (that is, a smaller thickness) than other portions.

As shown in FIGS. 4 and 5, an accommodating portion 124a for accommodating the first nut 122 is formed inside the caulking portion 124. That is, an accommodating portion 124a is formed that is located below the connector shaft portion 121 (on one side in the axial direction) and accommodates the first nut. The caulking portion 124 has an inner diameter slightly larger than the outer diameter of the first nut 122, which is a ready-made product. Furthermore, the caulking portion 124 is formed higher than the height of the first nut 122, which is a ready-made product. Further, the caulking portion 124 is formed such that the lower end of the housed first nut 122 reaches a lower portion 124b of the caulking portion 124. The accommodating portion 124a may be a columnar recess or a hexagonal columnar recess that matches the shape of the first nut 122.

As shown in FIG. 5, the caulking portion 124 is caulked with the first nut 122 placed in the housing portion 124a. Specifically, a portion of the lower portion 124b of the caulking portion 124 extending downward from the housed first nut 122 (see FIG. 4) is bent radially inward. As a result, an extending portion 125 is formed that extends radially inward from the edge of the housing portion 124a and prevents the first nut 122 from coming off from the housing portion 124a. Then, the lower portion 124b of the caulked portion 124 is deformed inward using a press or the like. As a result, a portion of the inner surface of the caulking portion 124 (the inner surface of the accommodating portion 124a) comes into close contact with the outer surface of the first nut 122. Therefore, the first nut 122 is accommodated in the accommodating portion 124a such that it cannot rotate relative to the caulking portion 124. Note that the height of the caulked portion 124 and the length of the extended portion 125 are set so that the extended portion 125 does not block the screw hole 121a of the first nut 122.

The connector 12 is connected to the anchor bolt 11 by fastening the first nut 122 fixed by the caulking portion 124 to the anchor bolt 11 . Here, when an axial tensile force of a predetermined value or more is applied between the connector shaft portion 121 and the first nut 122, the extending portion 125 deforms or breaks, and the connector shaft portion 121 Separate from nut 122. As a result, when an axial tensile force of a predetermined value or more is applied between the connector shaft portion 121 and the first nut 122, the reinforcing member 13 (along with the connector 12 excluding the first nut 122) is removed from the anchor bolt 11. A configuration that allows separation can be realized. The thickness and material of the extended portion 125 (that is, the lower portion 124b of the caulked portion 124) may be appropriately determined according to the predetermined value of the tensile force.

(effect)
According to the above configuration, it is possible to realize a configuration in which the reinforcing member 13 can be separated from the anchor bolts 11 fixed to the floor slabs 2A, 2B by an axial tensile force of a predetermined value or more. That is, by expanding the flat pipe 5 in the vertical direction and applying an axial tensile force of a predetermined value or more between the connector 12 and the anchor bolt 11, the joint structure 100 can be separated from the floor slabs 2A and 2B. . Therefore, when replacing parts within the joint structure 100, the joint structure 100 made of reinforced concrete can be easily removed.

In the conventional joint structure, the bolts swaged into the connector and the anchor bolts driven into the floor slab are fixed with long nuts that are longer than normal nuts, and the bolts swaged into the connector are attached to the floor slab. Fixed. With this configuration, the reinforcing member connected to the connector can be separated from the floor slab. However, in order to connect the bolt and anchor bolt to each other, a long nut that is longer than a normal nut is required. In addition, since it is necessary to connect bolts to each other, the number of work steps increases and the workability is not good.

On the other hand, in this embodiment, by fastening the first nut 122 fixed to the connector 12 to the anchor bolt 11, the first nut 122 fixed to the connector 12 is fixed to the floor slabs 2A, 2B. Such a configuration allows the connector to be separated from the bolt. That is, in the present embodiment, a nut is used instead of a bolt having a head and a shaft portion to realize a configuration in which the reinforcing member can be separated from the floor slab. This allows the height of the joint structure to be reduced. Therefore, the depth of the recess 4 can be made shallow, and the amount of cement mixture M filling the recess 4 can be reduced. Further, since the depth of excavation can be made shallow, the joint structure 100 has good workability. Furthermore, since the connector 12 can be directly connected to the anchor bolt 11, the number of work steps can be reduced and workability is improved.

Further, the flat plate member 14 provided between the first nut 122 and the second nut 15 is connected to the lower reinforcing bar 7 for fixing the pipe located below the flat plate member 14 . With this configuration, the flat pipe 5 held between the upper reinforcing bar 6 for fixing the pipe and the lower reinforcing bar 7 for fixing the pipe is placed near the boundary between the connector 12 and the anchor bolt 11 (specifically, near the extension part 125). can be placed.

Further, the reinforcing member 13 is threaded at the first straight portion 131 and fastened to the threaded hole 121a of the connector shaft portion 121. With this configuration, the reinforcing member 13 can be easily connected to the connector 12 by screwing the reinforcing member 13 to the connector 12 instead of welding the reinforcing member 13 to the connector 12. Therefore, welding work in constructing the joint structure can be reduced. The strength of the welded parts decreases. In the joint structure 100 of this embodiment, strength can also be improved.

[Embodiment 2]
Other embodiments of the invention will be described below. For convenience of explanation, members having the same functions as the members described in the above embodiment are given the same reference numerals, and the description thereof will not be repeated.

FIG. 6 is a sectional view showing the configuration of the anchor part 20 of the bridge joint structure according to the second embodiment. As shown in FIG. 6, the anchor part 20 differs from the anchor part 10 in that it includes a connector 22 and a reinforcing member 23, respectively, instead of the connector 12 and reinforcing member 13 in the anchor part 10.

The connector 22 includes a connector shaft portion 221, a first nut 122, and a caulking portion 124. That is, the connector 22 is different from the connector 12 in that it includes a connector shaft portion 221 instead of the connector shaft portion 121 of the connector 12 and does not include the head portion 123 of the connector 12.

The connector shaft portion 221 is a substantially prismatic (for example, quadrangular prism) member that extends upward, which is the other side in the axial direction. A screw hole 221a (first screw hole) is formed in the side surface of the connector shaft portion 221. A reinforcing member 23 extending laterally is coupled to the screw hole 221a. The reinforcing member 23 is a straight reinforcing bar, and one end is threaded. The reinforcing member 23 is connected to the reinforcing member 23 of another anchor part 20 by any connecting method.

Note that the connector shaft portion 221 may extend at least above the pipe fixing upper reinforcing bar 6 (see FIG. 1). The screw hole 221a may be provided at a position above the upper reinforcing bar 6 for fixing the pipe so that the reinforcing member 23 is disposed above at least the upper reinforcing bar 6 for fixing the pipe (see FIG. 1).

(effect)
According to the above configuration, the reinforcing member 23 can be a linear reinforcing bar. Therefore, when screwing the L-shaped reinforcing member 13 to the connector shaft part 121, a space was required for the second straight part 133 to rotate. In some cases, this space is not required. Therefore, it is possible to improve the workability when screwing the connector shaft portion.

Moreover, the strength of the reinforcing member 23 can be improved by using a linear reinforcing member 23 instead of the L-shaped reinforcing member 13 that requires bending which reduces strength.

Further, since the connector shaft portion 221 is a substantially prismatic member, it is easy to process a screw hole in the connector shaft portion 221. Further, since the connector shaft portion 221 has a non-circular cross section, there is no need to provide a head that engages with a tool for fastening the connector 12 to the anchor bolt 11. Note that the connector shaft portion 221 may be a substantially cylindrical member. In that case, the connector 22 may or may not include the head 123.

(Additional notes)
In the above embodiment, an example in which the connectors 12 and 22 are applied to the joint structure 100 of a bridge has been described, but the application example is not limited to this. For example, the connectors 12 and 22 may be used as members for connecting foundation concrete (foundation structure) and a pedestal (cement structure) on which a machine is placed in a factory or the like. In this case, the pedestal can be easily removed from the foundation concrete by applying an axial tensile force of a predetermined value or more to the connector (for example, by expanding a flat pipe buried in the pedestal).

The present invention is not limited to the embodiments described above, and various modifications can be made within the scope of the claims, and embodiments obtained by appropriately combining technical means disclosed in different embodiments. are also included within the technical scope of the present invention.

100 Joint structure (cement structure)
2A, 2B Floor slab (foundation structure)
11 Anchor bolts 12, 22 Connectors 121, 221 Connector shaft portions 121a, 221a Screw holes 122 First nut 124a Accommodating portion 125 Extension portions 13, 23 Reinforcement member 14 Flat plate member 15 Second nut

Claims (6)

a connector shaft that can be combined with a reinforcing member disposed on the cement structure ;
a first nut that can be fastened to an anchor bolt driven into the foundation structure ;
an accommodating part located on one side of the connector shank in the axial direction with respect to the connector shank, and accommodating the first nut;
an extending portion extending from an edge of the accommodating portion inward in a radial direction of the connector shaft portion and preventing the first nut from coming off from the accommodating portion;
When an axial tensile force of a predetermined value or more is applied between the connector shaft portion and the first nut, the extension portion deforms or breaks, and the connector shaft portion is separated from the first nut. A connector used to connect the foundation structure and the cement structure to be separated. The connector according to claim 1, wherein a first screw hole is formed in a side surface of the connector shaft portion. The connector according to claim 1, wherein a second screw hole is formed in the end surface on the other end side of the connector shaft portion. A connector according to any one of claims 1 to 3;
the anchor bolt extending upward from the foundation structure;
a second nut fastened to the anchor bolt;
The first nut is fastened to the anchor bolt above the second nut,
A cement structure further comprising a flat plate member sandwiched between the connector and the second nut. A connector according to claim 2;
the anchor bolt extending upward from the foundation structure;
the reinforcing member coupled to the first screw hole and extending laterally;
The first nut is a cement structure that is fastened to the anchor bolt. A connector according to claim 3;
the anchor bolt extending upward from the foundation structure;
the L-shaped reinforcing member coupled to the second screw hole;
The first nut is a cement structure that is fastened to the anchor bolt.

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