KR102482923B1 - coupling for precast concrete - Google Patents

Abstract

Precast concrete connection device according to an embodiment of the present invention includes an upper reinforcing bar provided in the upper precast; a base holder provided on the upper precast, coupled to an end of the upper reinforcing bar, and having a lower reinforcing bar receiving portion formed therein; a lower reinforcing bar having an end exposed in the lower precast and having the end inserted into the lower reinforcing bar receiving portion; a leveler coupled to an end of the lower reinforcing bar, accommodated in the lower reinforcing bar accommodating portion, and contacting the support surface of the base holder; an adjustment member provided in the leveler to rotate the leveler; and a fixing cap passing through the lower reinforcing bars, coupled to an end of the base holder, and in contact with the leveler. includes

Description

Precast concrete coupling device {coupling for precast concrete}

The present invention relates to a precast concrete connecting device, and relates to a precast concrete connecting device capable of firmly supporting an upper reinforcing bar to a lower reinforcing bar and improving workability.

Precast concrete (PC) is a ready-made concrete product made by curing construction members such as columns, beams, walls, and floor plates into steel formwork in certain facilities such as factories. The construction method using this precast concrete is called the PC method, and since the precast concrete is manufactured in a factory with a certain standard and strength, the application of the PC method shortens the period and has the advantage of maintaining a constant construction quality.

In one precast concrete, a plurality of reinforcing bars are placed inside the concrete, and the reinforcing bars of each precast concrete are connected to each other to produce columns, beams, walls, floors, retaining walls, etc.

1 is a view showing the construction of a wall by connecting precast concrete manufactured to a certain standard. Referring to FIG. 1, a sleeve SV is provided in the upper precast PC1, and the sleeve SV is coupled to the upper reinforcing bar 10 provided inside the upper precast PC1. In addition, a lower reinforcing bar 20 is provided inside the lower precast PC2.

At this time, the upper precast PC1 is coupled to the lower precast PC2, the lower reinforcing bar 20 is inserted into the sleeve SV, and the sleeve SV is supported by the lower reinforcing bar 20, A precast wall is manufactured by filling mortar (M) between the upper precast (PC1) and the lower precast (PC2). In this case, it takes about three weeks for the mortar (M) to harden, and when the hardening of the mortar (M) is completed, the precast wall is completed.

At this time, the mortar (M) is filled into the sleeve (SV) through the filling hole (SV2) of the sleeve (SV), the sleeve (SV) has a vent hole (SV1) through which the air is discharged, but the inside Since the air is not completely discharged through the vent hole (SV1), the mortar (M) may not be completely filled in the sleeve (SV). In this case, the bond strength of the precast wall is lowered and the durability period is reduced, and safety problems such as collapse may occur in the future.

In addition, as shown in FIG. 1, when the lower precast PC2 is manufactured, the ends 21 of some lower reinforcing bars 20 disposed on the lower precast PC2 may not be disposed on the schedule line H. there is. In addition, when cutting the lower reinforcing bar 20 to a certain length, the end portion 21 of the lower reinforcing bar 20 may be bent due to cutting force.

At this time, when the lower precast (PC2) is coupled to the upper precast (PC1), in the case of some lower reinforcing bars (20), they are spaced apart without contacting the upper reinforcing bars (10), and the load of the upper precast (PC1) is the sleeve ( It is transmitted to the rest of the lower reinforcing bars 20 except for the lower reinforcing bars 20 spaced apart from SV) and exceeds the allowable load of the remaining lower reinforcing bars 20, thereby reducing the durability of the precast wall and causing accidents such as collapse. also do

In addition, the central axis C1 of the upper reinforcing bar 10 and the central axis C2 of the lower reinforcing bar 20 may not be coaxially disposed. In this case, since the lower reinforcing bars 20 are not properly inserted into the sleeve SV, and the lower reinforcing bars 20 are intentionally bent and inserted into the sleeve SV at the site, air is delayed and workability at the site is reduced.

Therefore, regardless of the position and shape of the end 21 of the lower reinforcing bar 20, the upper reinforcing bar 10 is firmly supported by the lower reinforcing bar 20 to preserve the durability of the precast concrete, and the upper reinforcing bar 10 It is necessary to develop a precast concrete connecting device that can improve workability regardless of whether the central axis (C1) of the central axis (C2) of the lower reinforcement (20) coincides.

The problem to be solved by the present invention is to provide a precast concrete connecting device capable of firmly supporting upper reinforcing bars to lower reinforcing bars and improving workability.

The tasks of the present invention are not limited to the tasks mentioned above, and other tasks not mentioned will be clearly understood by those skilled in the art from the following description.

Precast concrete connection device according to an embodiment of the present invention for solving the above problems is provided in the upper precast upper reinforcement; a base holder provided on the upper precast, coupled to an end of the upper reinforcing bar, and having a lower reinforcing bar receiving portion formed therein; a lower reinforcing bar having an end exposed in the lower precast and having the end inserted into the lower reinforcing bar receiving portion; a leveler coupled to an end of the lower reinforcing bar, accommodated in the lower reinforcing bar accommodating portion, and contacting the support surface of the base holder; an adjustment member provided in the leveler to rotate the leveler; and a fixing cap passing through the lower reinforcing bars, coupled to an end of the base holder, and in contact with the leveler. includes

In addition, an outer circumferential surface of the leveler may be spaced apart from an inner circumferential surface of the base holder to form a first gap.

Also, the leveler may flow in a horizontal direction within the range of the first gap.

In addition, the adjusting member may be integrally formed with the leveler.

Also, the adjusting member may be exposed from the base holder.

Also, the adjusting member may pass through the fixing cap.

In addition, when the leveler is disposed to be spaced apart from the support surface, the leveler may contact the support surface by rotating the adjusting member.

In addition, the adjustment member is provided in the leveler, through the fixing cap, through the hollow portion through the lower reinforcement; and a nut portion formed by being depressed at an end of the hollow portion. can include

Details of other embodiments are included in the detailed description and drawings.

According to the precast concrete connecting device according to an embodiment of the present invention, since the leveler 40 provided at the end 21 of each lower reinforcing bar 20 is disposed on a certain line H, each leveler H All of them can come into contact with each support surface 30c.

Accordingly, the load of the upper reinforcing bar 10 can be transmitted to the lower reinforcing bar 20 through the leveler 40, and as the upper reinforcing bar 10 is firmly supported by the lower reinforcing bar 20, the upper precast (PC1) is firmly supported on the lower precast (PC2).

In addition, even when the central axis C1 of the upper reinforcing bar 10 and the central axis C2 of the lower reinforcing bar 20 are different, the free space between the first gap G1 and the second gap G2 is formed, Inserting the lower reinforcing bar 20 into the lower reinforcing bar accommodating portion 32 is sufficient to insert the end 21 of the lower reinforcing bar 20 into the lower reinforcing bar accommodating portion 32 by moving the upper precast PC1 in the horizontal direction. In order to do so, work such as additionally curving the lower reinforcing bars 20 is not required at the site, and workability is improved.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a view showing the construction of a wall by connecting general precast concrete.
Figure 2 is an exploded cross-sectional view of a precast concrete connecting device according to an embodiment of the present invention.
3 is an exploded perspective view of a precast concrete connecting device according to an embodiment of the present invention.
Figure 4 is a combined view of the precast concrete connecting device shown in Figure 2.
5 is a perspective view of the leveler 40 and the adjusting member 50 according to an embodiment of the present invention.
6 is a state diagram in which the upper precast (PC1) and the lower precast (PC2) are opposed.
7 is a state diagram in which the fixing cap 60 is assembled to the lower precast PC2.
8 is a state diagram in which the leveler 40 is assembled to the lower precast PC2.
9 is a state diagram in which the leveler 40 is inserted into the lower rebar accommodating portion 32.
10 is a state diagram showing a state in which the leveler 40 is brought into contact with the support surface 30c by rotating the adjusting member 50 .
11 is a state diagram of coupling the fixing cap 60 to the base holder 30.
12 is a state diagram of filling non-shrinkage mortar (M) between the upper precast (PC1) and the lower precast (PC2).

In describing the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. Even if the terms are the same, if the marked parts are different, it is said in advance that the reference numerals do not match.

In addition, terms to be described later are terms set in consideration of functions in the present invention, and since they may vary according to the intention or custom of operators such as experimenters and measurers, the definitions should be made based on the contents throughout this specification.

In this specification, terms such as first and second may be used to describe various components, but the components should not be limited by the terms. These terms are only used for the purpose of distinguishing one component from another. For example, a first element may be termed a second element, and similarly, a second element may be termed a first element, without departing from the scope of the present invention. The terms and/or include any combination of a plurality of related recited items or any of a plurality of related recited items.

Terms used in this specification are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in this application, they should not be interpreted in an ideal or excessively formal meaning. don't

In addition, when a part "includes" a certain component, it means that it may further include other components without excluding other components unless otherwise stated.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in detail. Like reference numerals in each drawing indicate like members.

Hereinafter, a precast concrete connecting device according to an embodiment of the present invention will be described with reference to FIGS. 2 to 5.

Figure 2 is an exploded cross-sectional view of a precast concrete connecting device according to an embodiment of the present invention, Figure 3 is an exploded perspective view of another precast concrete connecting device according to an embodiment of the present invention, Figure 4 is shown in FIG. It is a combined view of a precast concrete connecting device, and FIG. 5 is a perspective view of the leveler 40 and the adjusting member 50 according to an embodiment of the present invention.

2 to 5, the precast concrete connection device according to an embodiment of the present invention is provided in the upper reinforcement 10 provided in the upper precast PC1, the upper precast PC1, The end 12 of the upper reinforcing bar 10 is coupled, and the end 21 is exposed to the base holder 30 and the lower precast PC2 in which the lower reinforcing bar receiving portion 32 is formed, The end 21 is coupled to the lower reinforcing bar 20 inserted into the lower reinforcing bar accommodating portion 32, the end 21 of the lower reinforcing bar 20, and accommodated in the lower reinforcing bar accommodating portion 32, The leveler 40 in contact with the support surface 30c of the base holder 30, the adjustment member 50 provided on the leveler 40 to rotate the leveler 40, and the lower reinforcing bar 20 It penetrates, is coupled to the end of the base holder 30, and includes a fixing cap 60 in contact with the leveler 40.

The upper reinforcing bar 10 is provided in the upper precast PC1. The upper precast (PC1) may be made of precast concrete used in the PC method described above in the prior art. The upper precast PC1 may be implemented as at least one of a column, a beam, a wall, a floor plate, and a retaining wall.

A plurality of upper reinforcing bars 10 may be provided horizontally inside the upper precast PC1. The upper reinforcing bar 10 may be implemented as a deformed bar having ribs formed on the outer circumferential surface. Both ends 11 and 12 of the upper reinforcing bar 10 may be threaded by being rolled.

The other end 12 of the upper reinforcing bar 10 is coupled to a base holder 30 to be described later. One end 11 of the upper reinforcing bar 10 may be provided to be exposed to the upper precast PC1.

The base holder 30 is provided on the upper precast PC1. The base holder 30 may be disposed to be inserted into the upper precast PC1. The end 12 of the upper reinforcing bar 10 is coupled to the base holder 30. In this case, a screw thread is formed at the end 12 of the upper reinforcing bar 10, so that the base holder 30 can be screwed to the end 12 of the upper reinforcing bar 10.

The base holder 30 is formed with a lower reinforcement receiving portion 32 opened therein. In this case, the inner circumferential surface 30a and the support surface 30c of the base holder 30 form the lower reinforcement accommodating portion 32 . The end 12 of the upper reinforcing bar 10 may be coupled to the support surface 30c of the base holder 30. A screw thread may be formed on the inner circumferential surface 30a of the base holder 30 .

A lower reinforcing bar 20 to be described later is inserted into the lower reinforcing bar accommodating portion 32 . An end portion 21 of the lower reinforcing bar 20 may be inserted into the lower reinforcing bar accommodating portion 32 .

The lower reinforcing bar 20 is provided in the lower precast PC2. Since the lower precast PC2 may be performed in the same way as the upper precast PC1, a detailed description thereof will be omitted.

A plurality of lower reinforcing bars 20 may be provided horizontally inside the lower precast PC2. The lower reinforcing bar 20 may be implemented as a deformed bar having ribs formed on the outer circumferential surface.

The end 21 of the lower reinforcing bar 20 is provided to be exposed to the lower precast PC2. The end 21 of the lower reinforcing bar 20 may be threaded by being rolled.

The end 21 of the lower reinforcing bar 20 is inserted into the lower reinforcing bar accommodating portion 32 of the base holder 30. In this case, the central axis C1 of the upper reinforcing bar 10 and the central axis C2 of the lower reinforcing bar 20 may be coaxially disposed. In addition, according to the embodiment, the central axis C1 of the upper reinforcing bar 10 and the central axis C2 of the lower reinforcing bar 20 may be different from the same axis. This will be described later.

The upper precast (PC1) and the lower precast (PC2) may be implemented with the same configuration. Referring to the upper precast PC1 as a reference, the upper reinforcing bar 10 of the upper precast PC1 has threads formed at both end portions 11 and 12. At this time, the base holder 30 is coupled to the other end 12 of the upper reinforcing bar 10, and one end 11 of the upper reinforcing bar 10 may be provided to be exposed to the upper precast PC1.

In this case, since one end 11 of the upper reinforcing bar 10 acts the same as the one end 21 of the lower reinforcing bar 20, one upper precast PC1 is replaced with another upper precast PC1. can be stacked on the lower part of At this time, one end 11 of the upper reinforcing bar 10 may be inserted into the lower reinforcing bar accommodating portion 32 formed in the base holder 30 of the other upper precast PC1.

The leveler 40 is coupled to the end 21 of the lower reinforcing bar 20. The leveler 40 may pass through the lower reinforcement 20 . The leveler 40 may be screwed to the end 21 of the lower reinforcing bar 20 . In this case, a screw thread corresponding to the end 21 of the lower reinforcing bar 20 may be formed on the inner circumferential surface 40a of the leveler 40. At this time, when the leveler 40 is rotated, the leveler 40 may be raised upward or lowered downward along the end 21 of the lower reinforcing bar 20 .

The leveler 40 is accommodated in the lower reinforcement accommodating portion 32 . When the leveler 40 is accommodated in the lower reinforcement accommodating portion 32, the leveler 40 contacts the support surface 30c of the base holder 30. At this time, one end 41 of the leveler 40 may be in contact with the support surface 30c of the base holder 30 . Accordingly, the load of the upper precast (PC1) is transmitted to the leveler (40), so that it can be transmitted to the lower reinforcement (20).

The outer circumferential surface 40b of the leveler 40 is spaced apart from the inner circumferential surface 30a of the base holder 30 . The outer circumferential surface 40b of the leveler 40 is spaced apart from the inner circumferential surface 30a of the base holder 30 to form a first gap G1. The first gap G1 may form an extra space. The leveler 40 may flow in a horizontal direction within the range of the first gap G1. This will be described later.

One end 41 of the leveler 40 is in contact with the support surface 30c of the base holder 30 described above. The other end 42 of the leveler 40 is in contact with one end 61 of a fixing cap 60 to be described later.

When the leveler 40 is rotated, the leveler 40 may be raised upward. In this case, each leveler 40 provided at the end 21 of each lower reinforcing bar 20 may be disposed on a certain line H. Accordingly, the extension line of one end 41 of each leveler 40 may be disposed on a certain line H to form a horizontal line.

The adjusting member 50 is provided on the leveler 40 . The adjusting member 50 rotates the leveler 40. That is, when the adjusting member 50 rotates, the adjusting member 50 rotates the leveler 40. In this case, the leveler 40 may be raised or lowered in the vertical direction along the end 21 of the lower reinforcing bar 20 .

The adjusting member 50 may be integrally formed with the leveler 40 . When the adjusting member 50 is integrally formed with the leveler 40, the adjusting member 50 may be included in the leveler 40.

The adjusting member 50 may be implemented as a separate component from the leveler 40. In this case, the adjusting member 50 may be coupled to the leveler 40 . In addition, the adjusting member 50 may be formed to extend from the leveler 40 .

The adjusting member 50 is disposed to be exposed from the base holder 30 . The adjustment member 50 is formed longer than the base holder 30 and is exposed from the base holder 30 . That is, when the leveler 40 is accommodated in the lower reinforcement accommodating portion 32 of the base holder 30 and contacts the support surface 30c of the base holder 30, the adjusting member 50 is removed from the base holder 30. placed exposed. In this case, the adjustment member 50 may be disposed to be exposed from the lower rebar accommodating portion 32 .

The adjusting member 50 may be rotated by an operator as will be described later. At this time, the operator can rotate the adjusting member 50 exposed from the base holder 30 . In this case, when the adjusting member 50 rotates, the adjusting member 50 rotates the leveler 40. When the leveler 40 is rotated, the leveler 40 may be raised upward or lowered along the end 21 of the lower reinforcing bar 20 .

When the adjusting member 50 is rotated to rotate the leveler 40, the leveler 40 can be raised upward. In this case, each leveler 40 provided at the end 21 of each lower reinforcing bar 20 may be disposed on a certain line H. Accordingly, the extension line of one end 41 of each leveler 40 may be disposed on a certain line H to form a horizontal line.

The fixing cap 60 is provided at the end 21 of the lower reinforcing bar 20. In this case, the fixing cap 60 may be disposed to pass through the lower reinforcing bar 20 .

The fixing cap 60 is coupled to the end 31 of the base holder 30. At this time, a screw thread may be formed on the inner circumferential surface 30a of the base holder 30, and a screw thread may be formed on the outer circumferential surface 60b of the fixing cap 60. In this case, the outer circumferential surface 60b of the fixing cap 60 may be screwed to the inner circumferential surface 30a of the base holder 30 .

When the fixing cap 60 is coupled to the end 31 of the base holder 30, the fixing cap 60 may come into contact with the leveler 40. In this case, the other end 42 of the leveler 40 is in contact with one end 61 of the fixing cap 60.

When the fixing cap 60 is coupled to the end 31 of the base holder 30, the inner circumferential surface 60a of the fixing cap 60 is spaced apart from the outer circumferential surface of the lower reinforcing bar 20. In this case, the inner circumferential surface 60a of the fixing cap 60 forms the outer circumferential surface of the lower reinforcing bar 20 and the second gap G2.

The second gap G2 forms an extra space in which the lower reinforcing bars 20 can flow when the lower reinforcing bars 20 flow in the horizontal direction. In addition, non-shrinkage mortar M, which will be described later, may be filled in the second gap G2. This will be described later.

The adjustment member 50 is disposed through the fixing cap 60 . When the fixing cap 60 is coupled to the end of the base holder 30, the adjusting member 50 penetrates the fixing cap 60. In this case, the fixing cap 60 is disposed to be spaced apart from the adjusting member 50 .

At this time, the adjusting member 50 may be disposed to be exposed to the fixing cap 60 . That is, in a state in which the fixing cap 60 is coupled to the end of the base holder 30, the adjusting member 50 may be disposed to be exposed from the fixing cap 60. At this time, the length of the adjustment member 50 may be formed longer than the length of the fixed cap (60). In this case, as will be described later, even after the fixing cap 60 is coupled to the base holder 30, the leveler 40 may be firmly brought into contact with the support surface 30c by rotating the adjusting member 50.

Here, the adjustment member 50 according to an embodiment of the present invention is provided in the leveler 40, penetrates the fixing cap 60, and penetrates the lower reinforcing bar 20 through the hollow portion 51 , and a nut portion 52 formed by being depressed at an end of the hollow portion 51 .

The hollow part 51 is provided in the leveler 40 . As described above, the hollow part 51 may be integrally formed with the leveler 40 . Also, depending on the embodiment, the hollow part 51 may be implemented as a separate component from the leveler 40.

The hollow part 51 is provided in the leveler 40 . The hollow part 51 may be provided at the other end 42 of the leveler 40 . The hollow part 51 is provided to extend from the other end 42 of the leveler 40 .

The hollow part 51 is formed with a hollow center. At this time, the hollow part 51 is disposed to pass through the lower reinforcing bar 20 . In this case, the diameter of the hollow part 51 is formed larger than the diameter of the lower reinforcing bar 20.

The hollow part 51 penetrates the fixing cap 60. In this case, the hollow part 51 may be disposed to be spaced apart from the fixing cap 60 . The hollow part 51 may be formed longer than the fixing cap 60 . In this case, the hollow part 51 may be disposed to be exposed from the fixing cap 60 .

The nut portion 52 is formed at an end of the hollow portion 51 . The nut portion 52 may be implemented in a hexagonal nut shape, but the embodiment is not limited thereto.

The nut part 52 may protrude or be recessed at the end of the hollow part 51 . Hereinafter, it will be described that the nut portion 52 is formed by being depressed at the end of the hollow portion 51, but the embodiment is not limited thereto.

A tool capable of rotating the nut portion 52 may be coupled to the nut portion 52 . When the nut portion 52 is implemented as a hexagonal nut, a worker may rotate the nut portion 52 by coupling a spanner to the nut portion 52 . When the nut part 52 is rotated, the hollow part 51 is rotated, so that the leveler 40 can be rotated.

Hereinafter, with reference to FIGS. 6 to 12, the effect of the precast concrete connecting device according to an embodiment of the present invention will be described.

6 is a state diagram in which the upper precast (PC1) and the lower precast (PC2) are opposed, FIG. 7 is a state diagram in which the fixing cap 60 is assembled to the lower precast (PC2), and FIG. 8 is a lower precast ( PC2) is a state diagram in which the leveler 40 is assembled, FIG. 9 is a state diagram in which the leveler 40 is inserted into the lower rebar accommodating portion 32, and FIG. 10 shows the leveler 40 by rotating the adjusting member 50. It is a state diagram in contact with the support surface 30c, FIG. 11 is a state diagram in which the fixing cap 60 is coupled to the base holder 30, and FIG. It is a state diagram for filling the shrinkage mortar (M).

First, as shown in FIG. 6, an upper precast PC1 is manufactured. As described above, the upper precast PC1 is provided with upper reinforcing bars 10, and a plurality of upper reinforcing bars 10 may be horizontally provided inside the upper precast PC1. The upper reinforcement 10 is coupled to the above-described base holder 30. The end 12 of the upper reinforcing bar 10 is coupled to the base holder 30. The base holder 30 may be provided at the end 12 of the upper precast PC1.

After that, a lower precast PC2 is manufactured. As described above, the lower reinforcing bars 20 are provided in the lower precast PC2, and a plurality of lower reinforcing bars 20 may be horizontally provided inside the lower precast PC2. The end 21 of the lower reinforcing bar 20 is disposed to be exposed to the lower precast PC2.

Depending on the embodiment, the upper precast PC1 and the lower precast PC2 may be manufactured identically as shown in FIG. 6 .

Referring to the upper precast PC1 as a reference, the upper reinforcing bar 10 of the upper precast PC1 forms threads at both ends 11 and 12. At this time, the base holder 30 is coupled to the other end 12 of the upper reinforcing bar 10, and one end 11 of the upper reinforcing bar 10 is disposed to be exposed to the upper precast PC1.

In this case, one end 11 of the upper reinforcing bar 10 is performed in the same way as the one end 21 of the lower reinforcing bar 20, so that any one of the upper precasts PC1 is an upper precast PC1, Another upper precast (PC1) may be implemented as a lower precast (PC2).

When manufacturing of the upper precast (PC1) and the lower precast (PC2) is completed, as shown in FIG. 6, the upper precast (PC1) is opposed to the lower precast (PC2).

Here, when manufacturing the lower precast (PC2), the end 21 of each lower reinforcing bar 20 is a certain line according to the difference in length of each lower reinforcing bar 20 disposed in the lower formwork, the arrangement position of the lower reinforcing bar 20, etc. (H) may not be placed on.

That is, according to the embodiment, the ends 21 of some of the lower reinforcing bars 20 may be spaced apart from a certain line H formed by the ends 21 of the remaining lower reinforcing bars 20 at a predetermined interval D. In addition, the central axis C1 of the upper reinforcing bar 10 and the central axis C2 of the lower reinforcing bar 20 may not be located on the same axis. In addition, since the ends 21 of some of the lower reinforcing bars 20 are manufactured in a curved state, the central axis may deviate from the coaxial phase. In this case, the load of the upper precast PC1 may not be transmitted to the lower reinforcement 20 because the lower reinforcement 20 does not contact the upper reinforcement 10 . This will be described later.

Thereafter, as shown in FIG. 7, the fixing cap 60 is placed through the end 21 of the lower reinforcing bar 20. In this case, the inner circumferential surface 60a of the fixing cap 60 forms the outer circumferential surface of the lower reinforcing bar 20 and the second gap G2. The second gap G2 may be filled with non-shrinkage mortar M, which will be described later.

Then, as shown in FIG. 8, the leveler 40 is coupled to the end 21 of the lower reinforcing bar 20. The leveler 40 is screwed to the end 21 of the lower reinforcing bar 20. In this case, when the leveler 40 is rotated, the leveler 40 may move up and down along the end 21 of the lower reinforcing bar 20 .

Thereafter, the leveler 40 is rotated to arrange the leveler 40 on a certain line H. That is, as described above, the end portion 21 of each lower reinforcing bar 20 is not disposed on a certain line H, or the central axis C1 of the upper reinforcing bar 10 and the central axis of the lower reinforcing bar 20 (C2) may not be positioned coaxially.

In this case, by rotating the leveler 40 coupled to the end 21 of the lower reinforcing bar 20, the leveler 40 is placed on a certain line H. At this time, the leveler 40 extending from the lower reinforcing bar 20 forms a constant horizontal line.

Accordingly, when the leveler 40 is inserted into the lower reinforcement receiving portion 32 of the base holder 30, since each leveler 40 is positioned on a certain line H, each leveler 40 is placed on each base holder. It is possible to contact the support surface (30c) of (30), and the load of the upper reinforcing bar (10) can be uniformly transferred to the lower reinforcing bar (20) through the leveler (40).

Depending on the embodiment, some of the levelers 40 among the plurality of levelers 40 may not be disposed on a certain line H. In this case, some of the levelers 40 may be disposed on the constant line (H) in consideration of the working environment and workability, and the remaining part of the levelers 40 may not be disposed on the constant line (H).

Some of the levelers 40 that are not disposed on a certain line H form a coupling tolerance C in the vertical direction with the base holder 30, so that the plurality of levelers 40 are easily attached to the base holder 30. to be inserted.

At this time, the leveler 40 forming the coupling tolerance C may be spaced apart from the constant line H by a predetermined interval (2 to 3 mm). In this case, among the levelers 40 inserted into each base holder 30, the leveler 40 forming the coupling tolerance C may be disposed not to contact the support surface 30c of the base holder 30. . This will be described later.

Then, as shown in FIG. 9 , the leveler 40 of the lower precast PC2 is inserted into the base holder 30 of the upper precast PC1. When the leveler 40 is inserted into the base holder 30, the leveler 40 is accommodated in the lower reinforcement accommodating portion 32.

At this time, since each leveler 40 is positioned on a certain line H, each leveler 40 may contact the support surface 30c. Accordingly, the load of the upper precast (PC1) is transmitted to the leveler (40), so that it can be transmitted to the lower reinforcement (20).

Here, as described above, some of the levelers 40 forming the coupling tolerance C with the support surface 30c of the base holder 30 are spaced apart at regular intervals (2 to 3 mm) from the regular line H. It can be. At this time, the plurality of levelers 40 can be easily coupled to the base holder 30 by the coupling tolerance C.

Here, preferably, when each leveler 40 is located on a certain line H and the central axis C1 of the upper reinforcing bar 10 and the central axis C2 of the lower reinforcing bar 20 are coaxially disposed, the upper The lower reinforcing bar 20 can completely support the load of the reinforcing bar 10.

According to the embodiment, even when each leveler 40 is located on a certain line H, the central axis C1 of the upper reinforcing bar 10 is coaxial with the central axis C2 of the lower reinforcing bar 20. It can be arranged differently without being arranged. In this case, some of the levelers 40 may not be inserted into the lower rebar accommodating portion 32 .

At this time, as shown in FIG. 9 , the upper precast PC1 may be finely moved in the horizontal direction so that each lower reinforcing bar receiving portion 32 may be positioned to face each leveler 40 .

In this case, as described above, the outer circumferential surface 40b of the leveler 40 is spaced apart from the outer circumferential surface 30b of the base holder 30 to form a first gap G1, so that the leveler 40 has a first gap ( Since it can flow in the horizontal direction within the range of G1), coupling margin is created as much as the range of the first gap G1, so that each leveler 40 can be coupled to each base holder 30.

At this time, since the leveler 40 moves in the horizontal direction in the lower reinforcement accommodating portion 32, the lower reinforcement 20 can flow in the horizontal direction, and the lower reinforcement 20 forms a second gap G2. It can flow by a small size among the first gap G1 and the second gap G2 by the free space to be formed.

That is, when the first gap G1 is smaller than the second gap G2, the end 21 of the lower reinforcing bar 20 flows in the horizontal direction within the range of the first gap G1, and the first gap G1 ) is greater than the second gap G2, the end 21 of the lower reinforcing bar 20 may flow in the horizontal direction within the range of the second gap G2.

According to the embodiment, even when each leveler 40 is located on a certain line H, the central axis C1 of the upper reinforcing bar 10 is coaxial with the central axis C2 of the lower reinforcing bar 20. It can be arranged differently without being arranged. In this case, some of the levelers 40 may not be inserted into the lower rebar accommodating portion 32 .

At this time, the upper precast (PC1) can be finely moved in the horizontal direction so that each lower reinforcing bar receiving portion 32 is positioned to face each leveler 40. In this case, since the leveler 40 can flow in the horizontal direction within the range of the first gap G1, a coupling margin is created as much as the free space formed by the first gap G1, and each leveler 40 is It can be coupled to the base holder 30.

Accordingly, since the leveler 40 is in firm contact with the support surface 30c, the load of the upper reinforcing bar 10 is transmitted to each leveler 40, and the transmitted load is transferred to the lower reinforcing bar 20 through the leveler 40. It can be delivered to, so that the upper reinforcing bar 10 can be firmly supported by the lower reinforcing bar 20.

In addition, even when the central axis C1 of the upper reinforcing bar 10 and the central axis C2 of the lower reinforcing bar 20 are different, the free space between the first gap G1 and the second gap G2 is formed, Inserting the lower reinforcing bar 20 into the lower reinforcing bar accommodating portion 32 is sufficient to insert the end 21 of the lower reinforcing bar 20 into the lower reinforcing bar accommodating portion 32 by moving the upper precast PC1 in the horizontal direction. In order to do so, work such as additionally curving the lower reinforcing bars 20 is not required at the site, and workability is improved.

Thereafter, as shown in FIG. 10 , the operator rotates some of the adjusting members 50 among the plurality of adjusting members 50 . As described above, when some of the levelers 40 form a coupling tolerance C and the levelers 40 are spaced apart from the support surface 30c, the operator rotates the adjusting member 50 to remove the levelers 40. ) can be brought into contact with the support surface 30c.

At this time, since the adjusting member 50 is disposed to be exposed from the base holder 30, the adjusting member 50 may be exposed through a gap between the upper precast PC1 and the lower precast PC2. In this case, the operator can rotate the nut part 52 with a working tool. Accordingly, the operator can rotate the leveler 40 by rotating the exposed adjusting member 50 .

When the adjusting member 50 is rotated, the adjusting member 50 rotates the leveler 40 to bring the leveler 40 into contact with the support surface 30c. In this case, the leveler 40 is firmly supported on the support surface 30c of the base holder 30.

Accordingly, the load of the upper reinforcing bars 10 is transmitted to each leveler 40 and can be finally transmitted to the lower reinforcing bars 20, so that the upper reinforcing bars 10 are firmly supported by the lower reinforcing bars 20, and workability is improved. this improves

Then, as shown in FIG. 11, the fixing cap 60 is coupled to the base holder 30. The fixing cap 60 may be screwed to the end 31 of the base holder 30. When the fixing cap 60 is coupled to the end 31 of the base holder 30, the fixing cap 60 may come into contact with the leveler 40. Accordingly, the leveler 40 can be firmly supported by the fixing cap 60.

Depending on the embodiment, tensile force may be applied to the precast concrete connecting device of the present invention. That is, when a force due to bending or bending of the precast concrete acts, a tensile force may act in a direction in which the upper reinforcing bars 10 and the lower reinforcing bars 20 are spaced apart from each other. When force is applied to the upper reinforcing bars 10 in an upward direction and to the lower reinforcing bars 20 in a downward direction, a tensile force is applied to the precast concrete connecting device.

In this case, the fixing cap 60 supports the leveler 40. When tensile force acts in the direction in which the upper reinforcing bars 10 and the lower reinforcing bars 20 are spaced apart from each other, even when tensile force is generated, the fixing cap 60 supports the leveler 40 so that the precast concrete is solid. You can stay connected.

The adjusting member 50 may be disposed through the fixing cap 60 . At this time, the adjustment member 50 may be disposed to be exposed to the fixing cap 60 according to the embodiment. In this case, even after the fixing cap 60 is coupled, by rotating the adjusting member 50, the loosely contacted leveler 40 can be firmly brought into contact with the support surface 30c. Thereafter, as the fixing cap 60 is additionally rotated to firmly couple the fixing cap 60 to the base holder 30, the fixing cap 60 can firmly support the leveler 40.

Then, as shown in FIG. 12, non-shrinkage mortar M is filled between the upper precast PC1 and the lower precast PC2. The non-shrinkage mortar M may be filled in the second gap G2.

When the non-shrinkage mortar M is hardened, the space between the upper precast PC1 and the lower precast PC2 is completely filled. In addition, when the non-shrinkage mortar M is filled in the second gap G2 and hardened, the position of the end 21 of the lower reinforcing bar 20 is fixed. Accordingly, the finished precast concrete can be manufactured as shown in FIG. 12.

As described above, those skilled in the art to which the present invention belongs will be able to understand that the present invention can be implemented in other specific forms without changing the technical spirit or essential characteristics thereof. Therefore, the embodiments described above should be understood as illustrative in all respects and not limiting.

The scope of the present invention is indicated by the claims to be described later rather than the detailed description above, and all changes or modifications derived from the meaning and scope of the claims and equivalent concepts thereof are included in the scope of the present invention. should be interpreted

10: upper reinforcing bar 20: lower reinforcing bar
30: base holder 40: leveler

Claims (8)

An upper reinforcing bar provided in the upper precast; a base holder provided on the upper precast, coupled to an end of the upper reinforcing bar, and having a lower reinforcing bar receiving portion formed therein; a lower reinforcing bar having an end exposed in the lower precast and having the end inserted into the lower reinforcing bar receiving portion; a leveler coupled to an end of the lower reinforcing bar, accommodated in the lower reinforcing bar accommodating portion, and contacting the base holder; an adjustment member provided in the leveler to rotate the leveler; and a fixing cap passing through the lower reinforcing bars, coupled to an end of the base holder, and in contact with the leveler. including,
The outer circumferential surface of the leveler is spaced apart from the inner circumferential surface of the base holder to form a first gap,
The leveler is a precast concrete connecting device that flows in the horizontal direction within the range of the first gap.
delete delete According to claim 1,
The adjusting member is a precast concrete connecting device integrally formed with the leveler.
According to claim 1,
The adjusting member is a precast concrete connecting device exposed from the base holder.
According to claim 1,
The adjusting member is a precast concrete connecting device penetrating the fixing cap.
According to claim 1,
When the leveler is disposed spaced apart from the base holder, the precast concrete connecting device for contacting the leveler with the base holder by rotating the adjusting member.
According to claim 1,
The adjusting member is
a hollow portion provided in the leveler, penetrating the fixing cap, and penetrating the lower reinforcing bar; and
a nut portion formed by being depressed at an end of the hollow portion;
A precast concrete connector comprising a.

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