JP7329953B2 - Connection structure of precast concrete members - Google Patents

Description

The present invention relates to a connection structure for precast concrete members.

In conventional construction methods for reinforcing bar joints of precast concrete members, it is common to lengthen the sleeve length in order to secure the fixing length. must be ensured.

As in the conventional structure shown in FIG. 4, if the sleeve b provided on one of the precast concrete members a1 is long, shear reinforcing bars c are also provided on the outer circumference of the sleeve b in order to maintain the intervals between the shear reinforcing bars c at equal intervals. must be placed.
As a result, the cover thickness h of the precast concrete member must be calculated in advance based on the shear reinforcing bars c on the sleeve b. However, there is a problem that the total thickness of the film must be increased.

Although the following patent documents disclose inventions relating to the connection structure of precast members, they do not pay attention to the problem caused by the arrangement location of the above-described shear reinforcing bars.

Japanese Patent No. 6374668

SUMMARY OF THE INVENTION Accordingly, one object of the present invention is to provide a means in a connecting structure of precast concrete members that can maintain the arrangement intervals of shear reinforcing bars and reduce the dimensions of the precast concrete members as much as possible. It is a thing.

The present invention, which has been made to solve the above problems, is a connection structure of precast concrete members in which main reinforcements and shear reinforcements are arranged, wherein a sleeve is provided on one of the precast concrete members, and the rear end of the sleeve is a sleeve in contact with the main reinforcement of one precast concrete member; a filling material filled in the sleeve; and, wherein the shear reinforcing bars are arranged in each of the one precast concrete member and the other precast concrete member at a constant basic distance from each other, and in a connected state, one of the The distance between the shear reinforcing bar closest to the connecting end in the precast concrete member and the shear reinforcing bar closest to the connecting end in the other precast concrete member is arranged so that the length is substantially equal to the basic gap, It is characterized in that the shear reinforcement closest to the connecting end in one precast concrete member is arranged behind the sleeve .
Further, according to the present invention, in the above invention, the tip of the insertion portion may be enlarged in diameter.
Further, according to the present invention, in the above invention, the filling material may have expandability.
Further , in the invention of the present application, the width of projection of the sleeve with respect to the main reinforcement may be substantially equal in length to the diameter of the shear reinforcement.

ADVANTAGE OF THE INVENTION According to this invention, there exists an effect described below.
(1) It is possible to reduce the surplus associated with securing the cover thickness.
By setting the reference position of the cover thickness of each precast concrete member to the position of the sleeve or the shear reinforcing bar instead of placing the shear reinforcing bar on the sleeve, compared to the conventional case where the end bar is placed on the sleeve. , It is not necessary to increase the thickness of the precast concrete member only for securing the cover thickness, which contributes to reducing the overall size of the precast concrete member.
(2) It is possible to maintain an appropriate interval between the shear reinforcing bars.
By designing the length of the sleeve to be shorter than the basic spacing of each shear reinforcing bar, the spacing between the shear reinforcing bars is maintained at appropriate intervals even in the joints of precast concrete members, which tend to be structurally weak points. resistance can be ensured.
(3) It is possible to improve resistance to withdrawal of the insertion portion.
By enlarging the diameter of the distal end of the insertion portion formed by extending the main reinforcement of the other precast concrete member, it is possible to improve the resistance against the insertion portion coming out of the sleeve.
(4) The restraining effect of the insertion portion can be improved.
By expanding the filler inside the sleeve, the effect of restraining the insertion portion can be enhanced.
(5) The fixing force of the insertion portion can be increased as much as possible.
In one precast concrete member, the separation distance (L1) from the shear reinforcing bar closest to the connecting end to the connecting end, and the separation distance (L1) from the shear reinforcing bar closest to the connecting end to the connecting end in the other precast concrete member ( By setting the length longer than L2), it is possible to secure the length of the sleeve as long as possible within the range in which the basic spacing is maintained, thereby increasing the fixing force of the insertion portion.
(6) It is possible to design an optimum structure that is highly effective in reducing the size of the entire precast concrete member.
By making the projection width of the sleeve with respect to the main reinforcing bar almost equal to the diameter of the shear reinforcing bar, it is possible to align the reference position of the cover thickness between the sleeve and the shear reinforcing bar, thereby reducing the overall size of the precast concrete member. can be effective.

Schematic which shows each precast concrete member before connection in Example 1. FIG. Schematic which shows each precast concrete member after connection in Example 1. FIG. FIG. 10 is a diagram showing the relationship among sleeves, main reinforcing bars, and shear reinforcing bars in Example 2; Schematic which shows the conventional connection structure.

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

<1> Overall configuration (Fig. 1)
FIG. 1 shows the configuration of each precast concrete member before connection.
A precast concrete member is a concrete member manufactured in advance in a factory, and is a structure in which the main reinforcing bars 30 and the shear reinforcing bars 50 are arranged inside.
Precast concrete members include structures such as floors (slabs), beams, columns and walls.
A main reinforcing bar is a reinforcing bar placed horizontally to a precast concrete member to resist bending. Depending on the type, they are also called hoops or stirrups.
In the present invention, a sleeve 70 provided on one precast concrete member 10, a filler 80 to be filled in the sleeve 70, and an insertion portion 40 made of an extended portion of the main reinforcement 30 provided on the other precast concrete member 20 are provided. used to connect opposing precast concrete members.
Details of each component will be described below.

<2> One precast concrete member (Fig. 1)
One precast concrete member 10 is a member that constitutes the female side in the connecting structure according to the present invention.
One precast concrete member 10 is factory-manufactured in such a manner that a sleeve 70 is arranged in advance at the connection end with the other precast concrete member 20 and the main reinforcement 30 is connected to the rear end of this sleeve 70 .
Then, before connecting with the other precast concrete member 20, the inside of the sleeve 70 is filled with the filler 80 for use.

<2.1> Position of end bar (Fig. 1)
Of the shear reinforcing bars 50 used in one precast concrete member 20, the shear reinforcing bar 50 (end bar 60) closest to the connecting end has a separation distance L1 from this end bar 60 to the connecting end. The shear reinforcing bars 50 are arranged so as to be shorter than the interval (basic interval L) of the shear reinforcing bars 50 required for the design of the precast concrete member 20, and are arranged not on the sleeve 70 but behind the sleeve 70. . The reason for this will be described later.

<3> Sleeve (Fig. 1)
The sleeve 70 is a member forming a joint portion of reinforcing bars.
The sleeve 70 is a hollow member having an open end for connecting to the other precast concrete member 20 and having a filling space inside.
The shape of the peripheral wall forming the sleeve 70 is not particularly limited, and can be appropriately designed in consideration of the concrete outside the sleeve 70 and the adhesiveness to the filler 80 inside the sleeve 70 .

<3.1> Sleeve length (Fig. 1)
In the present invention, the length of the sleeve 70 is determined by the distance between the shear reinforcing bars 50 required for the design of the precast concrete member, and the shear reinforcing bar 50 (end bar 60) closest to the connecting end in one precast concrete member 10. to the connecting end.
By adopting this configuration, as in the conventional technology, in order to maintain the interval (basic interval L) between the shear reinforcing bars 50 required for the design of the precast concrete member at the connection point of the precast concrete member, shear is formed on the sleeve 70. It becomes unnecessary to arrange the reinforcing bar 50 (end bar 60).

<4> Filler (Fig. 1)
The filling material 80 is a material that fills the interior of the sleeve 70 so as to make the filling space after the inserting portion 40 (described later) is inserted into a solid state.
The filling material 80 can use a known material for filling the inside of the sleeve 70 .

<4.1> Addition of expansibility The filling material 70 is configured to have expansibility by a known method such as mixing an expansive material, thereby increasing the effect of constraining the insertion portion 40 inside the sleeve 70. can be

<5> The other precast concrete member (Fig. 1)
The other precast concrete member 20 is a member that constitutes the male side in the connection structure according to the present invention.
The other precast concrete member 20 is provided with an insertion portion 40 in which the internal main reinforcement 30 is extended and exposed at the connecting end.
By inserting this insertion portion 40 into a sleeve 70 provided in one of the precast concrete members 10, the precast concrete members are connected to each other.

<5.1> Shape of Insertion Portion In the present invention, the shape of the insertion portion 40 is not particularly limited, and various known shapes can be adopted.
In this embodiment, by expanding the diameter of the distal end 41 of the insertion portion 40 larger than the diameter of the reinforcing bar, it is possible to prevent the insertion portion 40 from coming out of the sleeve 70 after the insertion into the sleeve 70 and the filling material 80 are solidified. Improves resistance.

<5.2> Position of end bar (Fig. 1)
The shear reinforcing bar (end bar 60) closest to the connecting end in the other precast concrete member 20 has a separation distance L2 from the shear reinforcing bar 50 (end bar 60) to the connecting end, and one precast concrete member side The sum of the separation distance L1 from the shear reinforcing bar 50 (end bar 60) to the connecting end is approximately equal to the interval between the shear reinforcing bars (basic interval L) required for the design of the precast concrete member. do.

<6> Arrangement form after connection (Fig. 2)
Hereinafter, the arrangement form of various members after connection will be described with reference to FIG. 2 .

<6.1> Spacing between shear reinforcing bars After connecting the precast concrete members, the separation distance between the end bars 60 straddling the opposing precast concrete members is the gap between the other shear reinforcing bars 50 (basic spacing L). It maintains approximately equal length.
Therefore, it is possible to maintain an appropriate interval between the shear reinforcing bars 50 even at the connection points of the precast concrete members, which tend to be structurally weak points, and to secure the resistance against shearing.

<6.2> Cover Thickness Calculation Standard In one precast concrete member 10 , the end reinforcement 60 is not arranged on the sleeve 70 , but is arranged along the main reinforcement 30 behind the sleeve 70 .
Therefore, the reference position for calculating the cover thickness H of the precast concrete member can be set to the position of the sleeve 70 or the position of the shear reinforcing bar 50. Compared to the above, it is not necessary to increase the thickness of the precast concrete member only for securing the cover thickness, and the overall size of the precast concrete member can be designed to be small.

[Sleeve diameter setting] (Fig. 3)
FIG. 3 shows the relationship between sleeves, main bars and shear reinforcing bars.
In the present invention, a structure is adopted in which the diameter of the sleeve 70 is reduced to such an extent that the projection width B with respect to the main reinforcement 30 connected to the rear is approximately equal to the diameter D of the shear reinforcing reinforcement 50 (including the end reinforcement 60). You may

For example, as shown in FIG. 3( a ), when the protrusion width B is larger than the diameter D of the shear reinforcing bar 50 (including the end bar 60 ), the cover thickness reference position is set at the position of the sleeve 70 . Therefore, if the diameter of the sleeve is reduced within this range, the size of the entire precast concrete member can be designed to be small.

On the other hand, as shown in FIG. Therefore, even if the sleeve diameter is reduced within this range, it does not contribute to size reduction of the entire precast concrete member.

Therefore, the diameter and position of the sleeve 70, the diameter and position of the main reinforcement 30, the diameter of the shear reinforcing reinforcement 50 (end reinforcement 60), etc. are designed to such an extent that the protruding width B is approximately equal to the diameter D. It becomes the aspect which can contribute to size reduction of the whole dimension of a concrete member.

10 One precast concrete member 20 The other precast concrete member 30 Main bar 40 Insertion part 41 Tip 50 Shear reinforcing bar 60 End bar 70 Sleeve 80 Filler L Design interval L1 Separation distance L2 Separation distance L3 Sleeve length H Cover thickness B Projection width D Diameter of shear reinforcement

Claims (4)

A connection structure of precast concrete members in which main reinforcing bars and shear reinforcing bars are arranged,
a sleeve provided on one of the precast concrete members, the sleeve having a rear end in contact with the main reinforcement of the one of the precast concrete members;
a filler filling the sleeve;
an insertion portion formed by extending the main reinforcement of the other precast concrete member and inserted into the sleeve;
has at least
The shear reinforcing bars are arranged in each of the one precast concrete member and the other precast concrete member at a constant basic distance from each other, and in a connected state, the most connecting end of the one precast concrete member and the shear reinforcing bar closest to the connecting end in the other precast concrete member is arranged so that the distance therebetween is substantially equal to the basic spacing,
In one precast concrete member, the shear reinforcement closest to the connecting end is arranged behind the sleeve ,
Connected structure of precast concrete members. characterized in that the tip of the insertion portion is expanded in diameter,
The connection structure of precast concrete members according to claim 1. characterized in that the filler has expandability,
The connection structure of precast concrete members according to claim 1 or 2. The protruding width of the sleeve with respect to the main reinforcement is substantially equal in length to the diameter of the shear reinforcement,
The connection structure of precast concrete members according to any one of claims 1 to 3 .

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