JP2021101069A - Beam-column positioning structure - Google Patents

Abstract

To easily position a beam in a horizontal direction with respect to a column.SOLUTION: A beam-column positioning structure comprises a precast column 10 to which a full-precast beam 20 and a half-precast column 40 are joined, and a column-side guide member 80 that is attached to the precast column 10 and extended above a top surface 10U of the precast column 10 and with which a side surface 20S or 40S of the full-precast beam 20 or the half-precast column 40 is engaged.SELECTED DRAWING: Figure 5

Description

The present invention relates to a beam-column positioning structure.

A height adjusting material that is attached to a bracket fixed to a column and adjusts the height of a beam is known (see, for example, Patent Document 1).

As the hardware fixed to the column, a metal fitting for joining the column and the beam (see, for example, Patent Document 2) and a building jig for adjusting the height of the column are known (for example, Patent Document 3). reference).

Japanese Unexamined Patent Publication No. 2003-268885 Japanese Unexamined Patent Publication No. 2004-250932 Japanese Unexamined Patent Publication No. 10-204985

With the height adjusting material disclosed in Patent Document 1, the height of the beam with respect to the column can be adjusted, but it is difficult to position the beam horizontally with respect to the column, and the workability of the beam may be lowered. There is sex.

In view of the above facts, an object of the present invention is to easily position a beam in the horizontal direction with respect to a column.

The column-beam positioning structure according to claim 1 is a column-side guide member that is attached to the column to which the beam is joined, extends upward from the upper surface of the column, and engages the side surface of the beam. To be equipped.

According to the column-beam positioning structure according to claim 1, a beam is joined to the column. A pillar-side guide member is attached to this pillar. The column-side guide member extends upward from the upper surface of the column. By engaging the side surface of the beam with the column-side guide member, the beam is positioned in the beam width direction (horizontal direction) with respect to the column. Therefore, the beam can be easily positioned horizontally with respect to the column.

The beam-column positioning structure according to claim 2 includes a pair of column-side guide members that are attached to the column at intervals in a plan view in the beam-column positioning structure according to claim 1.

According to the column-beam positioning structure according to claim 2, the pair of column-side guide members are attached to the columns at intervals in a plan view. By arranging the beam between the pair of column-side guide members and engaging the side surface of the beam with one of the column-side guide members, the beam is positioned in the beam width direction (horizontal direction) with respect to the column.

By arranging the beam between the pair of adjacent column-side guide members in this way, the horizontal positioning accuracy of the beam with respect to the column can be improved.

The beam-positioning structure according to claim 3 is attached to a beam joined to the column, extends downward from the lower surface of the beam, and is engaged with a side surface of the column on the beam side. A beam side guide member is provided.

According to the column-beam positioning structure according to claim 3, the beam is joined to the column. A beam-side guide member is attached to this beam. The beam-side guide member extends downward from the lower surface of the beam. By engaging the beam-side guide member with the beam-side side surface of the column, the beam is positioned in the material axial direction (horizontal direction). Therefore, the beam can be easily positioned horizontally with respect to the column.

The beam-positioning structure according to claim 4 is provided on the column in the column-beam positioning structure according to any one of claims 1 to 3, and a beam end portion of the beam is placed on the column-beam positioning structure. It has a beam receiving part.

According to the beam-column positioning structure according to claim 4, the column is provided with a beam receiving portion. By placing the beam end portion of the beam on the beam receiving portion, the beam is positioned in the vertical direction with respect to the column. Therefore, the positioning of the beam with respect to the column becomes easier.

Further, by providing the beam receiving portion on the column, it is possible to omit the support work for supporting the beam. Therefore, the workability of the beam is improved.

As described above, according to the present invention, the beam can be easily positioned in the horizontal direction with respect to the column.

It is a top view which shows the pair of full precast beams and a pair of half precast beams to which the column beam positioning structure according to one embodiment is applied. It is a cross-sectional view taken along the line 2-2 of FIG. FIG. 3 is a cross-sectional view taken along the line 3-3 of FIG. It is an exploded elevation view which shows the precast column, the beam receiving bracket, and the column side guide member shown in FIG. It is an elevation view explaining the construction method of the full precast beam shown in FIG. (A) and (B) are plan sectional views which show the modification of the pillar side guide member in one Embodiment. It is a top view which shows the precast column and the full precast beam to which the column beam positioning structure which concerns on one Embodiment is applied. It is a top view which shows the precast column and the full precast beam to which the column beam positioning structure which concerns on one Embodiment is applied. It is an elevation view which shows the precast column and the full precast beam to which the column beam positioning structure which concerns on one Embodiment is applied. It is an elevation view which shows the precast column and the full precast beam to which the column beam positioning structure which concerns on one Embodiment is applied.

Hereinafter, the column-beam positioning structure according to the embodiment will be described with reference to the drawings.

As shown in FIGS. 1, 2, and 3, the column-beam positioning structure according to the present embodiment includes a precast column 10 (see FIG. 2), a pair of full precast beams 20, and a pair of half precast beams 40. A plurality of beam receiving brackets 70 and a plurality of column-side guide members 80 are provided.

The precast column 10 is an example of a column, and the full precast beam 20 and the half precast beam 40 are examples of beams. Further, the beam receiving bracket 70 is an example of the beam receiving portion, and the column side guide member 80 is an example of the guide member.

(Precast pillar)
As shown in FIGS. 2 and 3, the precast pillar 10 is made of precast concrete. Further, the cross-sectional shape of the precast pillar 10 is rectangular. A plurality of column main bars 12 are embedded in the outer peripheral portion of the precast column 10. The cross-sectional shape of the precast pillar 10 can be changed as appropriate.

The plurality of column main bars 12 are arranged along the material axis direction of the precast column 10. Further, the plurality of column main bars 12 are arranged at intervals in the circumferential direction of the precast column 10. The upper end side of these column main bars 12 projects upward from the outer peripheral portion of the upper surface 10U of the precast column 10. The upper surface 10U of the precast pillar 10 is formed in a rectangular shape in a plan view.

(Full precast beam)
As shown in FIG. 2, the full precast beam 20 is formed of precast concrete. Further, the full precast beam 20 is formed of ordinary concrete. The cross-sectional shape of the full precast beam 20 is rectangular. The beam end portion of the full precast beam 20 is placed on the beam receiving bracket 70, which will be described later.

A plurality of lower end beam main bars 22, a plurality of upper end beam main bars 24, and a plurality of shear reinforcing bars 26 are embedded in the full precast beam 20. The lower end beam main bar 22 and the upper end beam main bar 24 are examples of the beam main bar.

The plurality of lower end beam main bars 22 and the upper end beam main bars 24 are embedded along the material axis direction of the full precast beam 20. The plurality of lower end beam main bars 22 are embedded in the lower end side of the full precast beam 20. Further, the plurality of lower end beam main bars 22 are arranged at intervals in the beam width direction of the full precast beam 20. One end side of these lower end beam main bars 22 protrudes from the end surface 20A of the full precast beam 20.

The plurality of upper end beam main bars 24 are embedded in the upper end side of the full precast beam 20. Further, the plurality of upper end beam main bars 24 are arranged at intervals in the beam width direction of the full precast beam 20. One end side of these upper end beam main bars 24 protrudes from the end surface 20A of the full precast beam 20.

Fixing bodies 28 are provided at one ends (tips) of the lower end beam main bar 22 and the upper end beam main bar 24, respectively. The fixing body 28 is, for example, mechanically fixed such as a plate nut, and is embedded in cast-in-place concrete 16 (column-beam joint portion 18) described later.

(Half precast beam)
As shown in FIG. 3, the half precast beam 40 is formed of half precast concrete. The half precast beam 40 forms a beam 60 together with a top concrete 58 cast on the half precast beam 40.

The beam 60 is usually made of concrete. The cross-sectional shape of the beam 60 (half precast beam 40) is rectangular. The beam end portion of the half precast beam 40 is placed on a beam receiving bracket 70, which will be described later.

A plurality of lower end beam main bars 42, a plurality of upper end beam main bars 44, and a plurality of shear reinforcing bars 46 are embedded in the beam 60. The lower end beam main bar 42 and the upper end beam main bar 44 are examples of the beam main bar.

The plurality of lower end beam main bars 42 and upper end beam main bars 44 are arranged along the material axis direction of the beam 60. Further, the plurality of lower end beam main bars 42 are embedded in the lower end side of the beam 60, that is, the lower end side of the half precast beam 40. These lower end beam main bars 42 are arranged at intervals in the beam width direction of the half precast beam 40. Further, one end side of each lower end beam main bar 42 protrudes from the end surface 40A of the half precast beam 40.

The plurality of upper end beam main bars 44 are embedded in the upper end side of the beam 60, that is, in the top concrete 58. Further, the plurality of upper end beam main bars 44 are arranged on the upper surface 40U of the half precast beam 40 at intervals in the beam width direction of the half precast beam 40. These upper end beam main bars 44 are held by a plurality of shear reinforcing bars 46 protruding from the upper surface 40U of the half precast beam 40.

One end of the upper end beam main bar 44 projects from the end surface 40A of the half precast beam 40 in a plan view. Here, the upper end beam main bar 44 has two beam main bars 44A and 44B and a mechanical joint 44C connecting the two beam main bars 44A and 44B.

The mechanical joint 44C is arranged so as not to protrude from the end surface 40A of the half precast beam 40 in a plan view. Beam main bars 44A and 44B are connected to the mechanical joint 44C. The beam main bar 44A protrudes from the end face 40A of the half precast beam 40 in a plan view.

A fixing body 48 is provided at one end (tip) of the lower end beam main bar 42 and the upper end beam main bar 44, respectively. The fixing body 48 is, for example, mechanically fixed such as a plate nut, and is embedded in cast-in-place concrete 16 described later.

(Column and beam joint)
As shown in FIG. 2, the pair of full precast beams 20 are arranged so that their end faces 20A face each other. Further, the pair of full precast beams 20 are arranged in a state where the lower end beam main bars 22 are opposed to each other (closely opposed to each other) and the upper end beam main bars 24 are opposed to each other (closely opposed to each other).

Similarly, as shown in FIG. 3, the pair of half precast beams 40 are arranged with their end faces 40A facing each other. Further, the pair of half precast beams 40 are arranged in a state where the lower end beam main bars 42 are opposed to each other (closely opposed to each other) and the upper end beam main bars 44 are opposed to each other (closely opposed to each other).

As shown in FIG. 1, the pair of full precast beams 20 and the pair of half precast beams 40 are arranged so as to intersect each other. Then, cast-in-place concrete 16 is cast in the space 14 surrounded by the beam ends of the full precast beam 20 and the half precast beam 40. As a result, the column-beam joint 18 is formed.

The cast-in-place concrete 16 is made of fiber reinforced concrete. The fiber reinforced concrete in the present embodiment is, for example, concrete mixed with steel fiber, glass fiber, carbon fiber, organic fiber and the like. The cast-in-place concrete 16 is an example of concrete.

(Beam bracket)
As shown in FIG. 4, a pair of beam receiving brackets 70 are detachably attached to each side surface 10S of the upper part of the precast column 10. The pair of beam receiving brackets 70 are formed in a substantially triangular shape when viewed from the side. Each beam receiving bracket 70 has a mounting portion 72, a receiving portion 74, and a connecting portion 76.

The mounting portion 72, the receiving portion 74, and the connecting portion 76 are formed of shaped steel such as L-shaped steel or C-shaped steel, for example. The mounting portion 72 is arranged along the vertical direction on the side surface 10S of the precast pillar 10, and is detachably attached to the side surface 10S of the precast pillar 10 by a bolt 78. A nut member 79 to which the bolt 78 is fastened is embedded in the side surface 10S of the precast pillar 10.

The mounting portion 72 is arranged so as not to project upward from the upper surface 10U of the precast pillar 10. From the upper end of the mounting portion 72, the receiving portion 74 extends substantially horizontally to the outside of the precast pillar 10. The receiving portion 74 and the mounting portion 72 are connected by a brace-shaped connecting portion 76.

Here, at the time of construction of the full precast beam 20 and the half precast beam 40, the beam end portion of the full precast beam 20 or the half precast beam 40 is temporarily placed (temporarily placed) on the receiving portion 74. As a result, the full precast beam 20 or the half precast beam 40 is positioned in the vertical direction with respect to the precast column 10.

The upper surface of the receiving portion 74 of the beam receiving bracket 70 is not limited to being flush with the upper surface 10U of the precast column 10, and may be arranged above or below the upper surface 10U of the precast column 10. Is also good. Further, the shape, arrangement, and number of the beam receiving brackets 70 can be changed as appropriate.

(Pillar side guide member)
As shown in FIG. 1, a pair of pillar-side guide members 80 are detachably attached to each side surface of the upper part of the precast pillar 10. The pair of column-side guide members 80 are formed of shaped steel such as L-shaped steel. Further, the pair of pillar-side guide members 80 are attached to the precast pillar 10 at intervals in a plan view. More specifically, the pair of pillar-side guide members 80 are arranged along the vertical direction on both sides of the side surface 10S of the precast pillar 10 in the width direction.

The pair of column-side guide members 80 are arranged on both sides of the pair of beam receiving brackets 70. In other words, the pair of beam receiving brackets 70 are arranged between the pair of column-side guide members 80.

The pillar side guide member 80 is bent in an L shape in a plan view. As shown in FIG. 4, the pillar-side guide member 80 has a mounting portion 82 and a guide portion 84. The mounting portion 82 is detachably attached to the side surface 10S of the precast pillar 10 by the bolt 88 in a state of being overlapped with the side surface 10S of the precast pillar 10. A nut member 89 to which the bolt 88 is fastened is embedded in the side surface 10S of the precast pillar 10.

The guide portion 84 extends from the mounting portion 82 to the outside of the precast pillar 10 in a rib shape. The upper portion of the guide portion 84 extends upward from the upper surface 10U of the precast pillar 10. Further, the pair of column-side guide members 80 have a guide surface 84G to which the side surfaces 20S and 40S (see FIG. 1) of the full precast beam 20 or the half precast beam 40 are engaged.

As shown in FIG. 5, the pair of column-side guide members 80 are attached to the precast column 10 with their guide surfaces 84G facing each other in the beam width direction (arrow W). A full precast beam 20 or a half precast beam 40 (see FIG. 1) is inserted between the pair of guide surfaces 84G. In this state, the side surfaces 20S and 40S of the full precast beam 20 or the half precast beam 40 are engaged (surface contact) with the guide surface 84G of one of the pillar side guide members 80. As a result, the full precast beam 20 or the half precast beam 40 is positioned in the beam width direction (horizontal direction) with respect to the precast column 10.

There may be a gap for absorbing construction errors between the pair of guide surfaces 84G and the side surfaces 20S and 40S on both sides of the full precast beam 20 or the half precast beam 40.

(Construction method of column-beam positioning structure)
Next, an example of the construction method of the column-beam positioning structure will be described.

First, as shown in FIG. 4, a pair of beam receiving brackets 70 are detachably attached to each side surface 10S of the precast column 10 by bolts 78, and a pair of column side guide members 80 are detachably attached by bolts 88. ..

The beam receiving bracket 70 and the column-side guide member 80 may be attached to the precast column 10 before the precast column 10 is built, or may be attached to the precast column 10 after the precast column 10 is built.

Next, as shown in FIG. 3, a pair of half precast beams 40 are sequentially lifted by a crane or the like (not shown), and the beam ends of the pair of half precast beams 40 are lifted from above the precast columns 10 to receive the beam receiving bracket 70. Place each on 74. As a result, the pair of half precast beams 40 are positioned in the vertical direction with respect to the precast columns 10.

At this time, the beam end portion of the half precast beam 40 is prevented from being arranged on the upper surface 10U of the precast column 10. Further, the beam end portion of the half precast beam 40 is dropped between the pair of column side guide members 80, and the side surface 40S of the half precast beam 40 is engaged with the guide surface 84G (see FIG. 5) of one column side guide member 80. Match. As a result, the half precast beam 40 is positioned in the beam width direction (horizontal direction) with respect to the precast column 10.

The beam main bar 44B is not connected to the mechanical joint 44C of each upper end beam main bar 44 of the half precast beam 40.

Next, as shown in FIG. 2, a pair of full precast beams 20 (see FIG. 2) are sequentially lifted by a crane (not shown), and the beam ends of the pair of full precast beams 20 are attached to the beam receiving brackets from above the precast columns 10. It is placed on the receiving portion 74 of 70. As a result, the pair of full precast beams 20 are positioned in the vertical direction with respect to the precast columns 10.

At this time, as shown in FIG. 5, the beam end portion of the full precast beam 20 is dropped between the pair of column side guide members 80, and the full precast beam 20 is placed on the guide surface 84G of one column side guide member 80. The side surface 20S is engaged. As a result, the full precast beam 20 is positioned in the beam width direction (horizontal direction) with respect to the precast column 10.

Here, as described above, the beam main bar 44B is not connected to the mechanical joint 44C of each upper end beam main bar 44 of the half precast beam 40. Therefore, it is possible to prevent the lower end beam main bar 22 of the full precast beam 20 from interfering with the upper end beam main bar 44 of the half precast beam 40.

Next, as shown in FIG. 3, the beam main bar 44B is connected to the mechanical joint 44C of each upper end beam main bar 44 of the half precast beam 40.

Next, as shown in FIG. 1, the gap between the adjacent pillar-side guide members 80 is closed by a formwork or the like (not shown). Alternatively, the plurality of column-side guide members 80 are removed from the precast column 10, and the gaps between the beam ends of the adjacent full precast beam 20 and the half precast beam 40 are closed by a formwork or the like (not shown).

Next, a formwork (not shown) is temporarily installed on the half precast beam 40. Next, cast-in-place concrete (fiber reinforced concrete) 16 is placed in the space 14 surrounded by the beam ends of the pair of full precast beams 20 and the pair of half precast beams 40. As a result, the column-beam joint 18 is formed.

Further, as shown in FIG. 3, a top concrete (ordinary concrete) 58 is cast on the pair of half precast beams 40 to form the beam 60.

After that, the beam receiving bracket 70 and the column side guide member 80 are removed.

The beam receiving bracket 70 and the column side guide member 80 may be left without being removed. Further, the full precast beam 20 or the half precast beam 40 may be inserted between the pair of column side guide members 80 from the side instead of being dropped between the pair of column side guide members 80 from above. Further, the order of the above-mentioned construction steps (procedures) may be appropriately changed depending on the situation.

(effect)
Next, the effect of this embodiment will be described.

According to the beam-column positioning structure according to the present embodiment, a pair of beam receiving brackets 70 are detachably attached to each side surface 10S of the precast column 10. By placing the beam end portion of the full precast beam 20 or the half precast beam 40 on the receiving portion 74 of the pair of beam receiving brackets 70, the full precast beam 20 or the half precast beam 40 is placed on the precast column 10. Is positioned in the vertical direction.

Further, a pair of pillar-side guide members 80 are detachably attached to each side surface 10S of the precast pillar 10. Then, by engaging the side surfaces 20S and 40S of the full precast beam 20 or the half precast beam 40 with the guide surface 84G of one of the column side guide members 80, the full precast beam 20 or the half precast beam 40 becomes the width of the precast column 10. Positioned in the direction.

As described above, in the present embodiment, the full precast beam 20 and the half precast beam 40 are vertically and horizontally attached by attaching the pair of beam receiving brackets 70 and the pair of column side guide members 80 to each side surface 10S of the precast column 10. It can be easily positioned in the direction. Therefore, the workability of the full precast beam 20 and the half precast beam 40 is improved.

Further, the pair of pillar-side guide members 80 are attached to the precast pillar 10 at intervals in a plan view. A full precast beam 20 or a half precast beam 40 is arranged between the pair of column side guide members 80, and the side surfaces 20S and 40S of the full precast beam 20 or the half precast beam 40 are arranged on the guide surface 84G of one column side guide member 80. To engage. As a result, the full precast beam 20 or the half precast beam 40 is positioned with respect to the precast column 10 in the beam width direction.

Therefore, in the present embodiment, the positioning accuracy of the full precast beam 20 or the half precast beam 40 in the beam width direction is improved as compared with the case where one column side guide member 80 is attached to the side surface 10S of the precast column 10, for example. be able to.

The pillar-side guide member 80 also functions as a formwork for cast-in-place concrete 16. Therefore, the workability of the cast-in-place concrete 16 (column-beam joint 18) is improved.

Further, in the present embodiment, the full precast beam 20 or the half precast beam 40 is supported by supporting the beam end portion of the full precast beam 20 or the half precast beam 40 by the beam receiving bracket 70 attached to the precast column 10. Support work etc. can be omitted. Therefore, the workability of the full precast beam 20 and the half precast beam 40 is further improved.

Moreover, the beam receiving bracket 70 and the column side guide member 80 are detachably attached to the precast column 10. Therefore, since the beam receiving bracket 70 and the column side guide member 80 can be reused, cost reduction can be achieved.

Further, fixing bodies 28 and 48 embedded in cast-in-place concrete 16 are provided at the tips of the lower end beam main bars 22 and 42 and the upper end beam main bars 24 and 44 of the full precast beam 20 and the half precast beam 40, respectively. .. Further, the cast-in-place concrete 16 is made of fiber reinforced concrete. As a result, the joint strength between the lower end beam main bars 22, 42 and the upper end beam main bars 24, 44 and the cast-in-place concrete 16 is increased.

Therefore, in the present embodiment, the mechanical joint connecting the lower end beam main bars 22 of the pair of full precast beams 20 and the mechanical joint connecting the upper end beam main bars 24 can be omitted. Similarly, a mechanical joint for connecting the lower end beam main bars 42 of the pair of half precast beams 40, a mechanical joint for connecting the upper end beam main bars 44, and the like can be omitted. Therefore, the workability of the column-beam joint 18 is improved.

Further, the cast-in-place concrete 16 is made of fiber reinforced concrete as described above. As a result, the split strength of the column-beam joint 18 is increased, so that the shear reinforcing bar or the like embedded in the column-beam joint 18 can be omitted. Therefore, since the configuration of the column-beam joint portion 18 can be simplified, the workability of the column-beam joint portion 18 is further improved.

In addition, in order to omit the shear reinforcing bar embedded in the beam-column joint 18, it is desirable that the entire or substantially the entire beam-column joint 18 is formed of fiber reinforced concrete.

Here, as a comparative example, for example, it is conceivable that the beam end portion of the full precast beam 20 is supported by the upper surface 10U of the precast column 10 and the beam receiving bracket 70 is omitted.

However, in this embodiment, the full precast beam 20 is formed of ordinary concrete. Therefore, when the beam end portion of the full precast beam 20 is placed on the upper surface 10U of the precast column 10, the column beam joint portion 18 is partially formed of ordinary concrete, and the split strength of the column beam joint portion 18 is lowered. there's a possibility that.

As a countermeasure, for example, it is conceivable to form only the beam end portion of the full precast beam 20 mounted on the upper surface 10U of the precast column 10 with fiber reinforced concrete, and form the other portions with ordinary concrete. However, in this case, since it is necessary to separate the fiber reinforced concrete and the ordinary concrete between the beam end portion of the full precast beam 20 and the other portion, it takes time and effort to produce the full precast beam 20.

On the other hand, in the present embodiment, by supporting the beam end portion of the full precast beam 20 with the beam receiving bracket 70, the entire column beam joint portion 18 can be formed of fiber reinforced concrete. Therefore, the split strength of the column-beam joint 18 can be ensured.

(Modification example)
Next, a modified example of the above embodiment will be described.

In the modified example shown in FIG. 6A, the pillar-side guide member 90 is bent in a Z shape (crank shape) in a plan view. Specifically, the pillar-side guide member 90 has a mounting portion 92 and a guide portion 94.

The mounting portion 92 is bent in an L shape. The mounting portion 92 is detachably attached to the precast pillar 10 by a bolt 88 in a state of being arranged along the corner portion of the precast pillar 10. Further, the guide portion 94 has a guide surface 94G, and extends from the mounting portion 92 to the outside of the precast pillar 10 in a rib shape.

Here, the mounting portions 92 of the adjacent pillar-side guide members 90 are mounted on the corners of the precast pillar 10 in a state of being overlapped. As a result, it is possible to prevent the cast-in-place concrete 16 from leaking from the corners of the precast pillar 10 when the cast-in-place concrete 16 is placed. Therefore, the formwork and the like temporarily installed at the corners of the precast pillar 10 can be omitted, so that the workability is improved.

Further, in the modified example shown in FIG. 6B, the pillar-side guide member 100 is bent in a W shape in a plan view. Specifically, the pillar-side guide member 100 has a mounting portion 102 and a pair of guide portions 104.

The mounting portion 102 is bent in an L shape, and is detachably attached to the precast pillar 10 by a bolt 88 in a state of being arranged along the corner portion of the precast pillar 10. Further, the pair of guide portions 104 have a guide surface 104G, and are ribbed from both sides of the mounting portion 102 in the lateral width direction to the outside of the precast pillar 10.

Here, the mounting portion 102 of the pillar-side guide member 100 is arranged along the corner portion of the precast pillar 10. As a result, it is possible to prevent the cast-in-place concrete 16 from leaking from the corners of the precast pillar 10 when the cast-in-place concrete 16 is placed. Therefore, the formwork and the like temporarily installed at the corners of the precast pillar 10 can be omitted, so that the workability is improved.

Further, the pillar-side guide member 100 has a pair of guide portions 104. As a result, in this modification, the number of pillar-side guide members 100 is reduced as compared with the above embodiment. Therefore, the labor of attaching the pillar-side guide member 100 to the precast pillar 10 is reduced.

Next, in the above embodiment, the pillar side guide member 80 is attached to the precast pillar 10. However, the guide member can be provided on at least one of the precast column 10 and the precast beam (full precast beam 20, half precast beam 40).

For example, in the modified example shown in FIG. 7, the column-side guide member 110 is detachably attached to the precast column 10, and the beam-side guide member 120 is detachably attached to the full precast beam 20. The column-side guide member 110 and the beam-side guide member 120 are examples of guide members.

The pillar-side guide member 110 is formed in a cross shape in a plan view. The pillar-side guide member 110 has a mounting portion 112 and a pair of guide portions 114. The mounting portion 112 is bent in an L shape and is detachably attached to the precast pillar 10 by a bolt 88 in a state of being arranged along the corner portion of the precast pillar 10. Further, the outer surface of the mounting portion 112 is a guide surface 114G. The pair of guide portions 114 have a guide surface 114G, and each of the pair of guide portions 114 extends from the bent portion of the mounting portion 112 to the outside of the precast pillar 10 in a rib shape.

The beam side guide member 120 is bent in an L shape in a plan view. The beam-side guide member 120 has a mounting portion 122 and a guide portion 124. The mounting portion 122 is detachably attached to the side surface 20S of the full precast beam 20 by bolts 128 in a state of being overlapped with the side surface 20S of the full precast beam 20. A nut member 129 to which the bolt 128 is fastened is embedded in the side surface 20S of the full precast beam 20.

The guide portion 124 extends from the mounting portion 112 to the outside of the full precast beam 20 in a rib shape. The tip portion 124T of the guide portion 124 is engaged with the guide surface 114G of the pillar-side guide member 110. As a result, the full precast beam 20 is positioned in the beam width direction with respect to the precast column 10.

Further, the surface of the guide portion 124 on the precast pillar 10 side is a guide surface 124G. The guide surface 124G is engaged with the guide surface 114G of the mounting portion 112 of the pillar-side guide member 110. As a result, the full precast beam 20 is positioned in the material axis direction (arrow X direction).

As described above, in the modified example shown in FIG. 7, the full precast beam 20 can be positioned in the beam width direction and the material axis direction with respect to the precast column 10.

Next, in the modified examples shown in FIGS. 8 and 9, the column-side guide member 80 is detachably attached to the precast column 10, and the beam-side guide member 140 is detachably attached to the full precast beam 20. The beam-side guide member 140 is an example of a guide member.

The column side guide member 80 is arranged on one side of the full precast beam 20 in the beam width direction. One side surface 20S of the full precast beam 20 is engaged (surface contact) with the guide surface 84G of the pillar side guide member 80. As a result, the full precast beam 20 is positioned in the beam width direction with respect to the precast column 10.

The beam side guide member 140 is arranged on the other side of the full precast beam 20 in the beam width direction. Further, the beam side guide member 140 is bent in an L shape in a plan view. The beam-side guide member 140 has a mounting portion 142 and a guide portion 144.

The mounting portion 142 is detachably attached to the side surface 20S of the full precast beam 20 by bolts 128 in a state of being overlapped with the side surface 20S of the full precast beam 20. The guide portion 144 extends from the mounting portion 142 to the outside of the full precast beam 20 in a rib shape. The surface of the guide portion 144 on the precast pillar 10 side is a guide surface 144G.

Here, as shown in FIG. 9, the lower portion of the beam-side guide member 140 extends downward from the lower surface 20L of the full precast beam 20. The lower guide surface 144G of the beam-side guide member 140 is engaged with the side surface 10S on the full precast beam 20 side of the precast column 10. As a result, the full precast beam 20 is positioned in the material axis direction (arrow X direction) with respect to the precast column 10.

As described above, in the modified examples shown in FIGS. 8 and 9, the full precast beam 20 can be positioned in the beam width direction and the material axis direction (horizontal direction) with respect to the precast column 10.

The guide member (column-side guide member and beam-side guide member) may be any as long as the beam can be positioned at least in one of the beam width direction and the material axis direction with respect to the column.

Next, in the modified example shown in FIG. 10, the overhanging portion 130 is provided on the precast pillar 10. The overhanging portion 130 is integrally formed with the precast pillar 10 by precast concrete. Further, the overhanging portion 130 projects outward from the precast pillar 10. For example, a beam end portion of a half precast beam 40 or a full precast beam 20 (see FIG. 1) is placed on the upper surface (receiving surface) 130U of the overhanging portion 130. As a result, the half precast beam 40 or the full precast beam 20 is positioned in the vertical direction.

In this way, the overhanging portion 130 can be integrally formed on the precast pillar 10. The overhanging portion 130 is an example of a beam receiving portion.

Next, in the above embodiment, the beam ends of the full precast beam 20 and the half precast beam 40 are not arranged on the upper surface 10U of the precast column 10. However, the beam ends of the full precast beam 20 and the half precast beam 40 may be arranged on the upper surface 10U of the precast column 10.

Further, in the above embodiment, the upper end beam main bar 44 of the half precast beam 40 is arranged below the upper end beam main bar 24 of the full precast beam 20. However, the upper end beam main bar 44 of the half precast beam 40 may be arranged above the upper end beam main bar 24 of the full precast beam 20. In this case, since the beam main bar 44B can be connected to the mechanical joint 44C of the half precast beam 40 on the upper side of the upper end beam main bar 24 of the full precast beam 20, the workability is improved.

Further, in the above embodiment, the lower end beam main bars 22 and the upper end beam main bars 24 of the pair of full precast beams 20 are not connected to each other. However, the lower end beam main bars 22 and the upper end beam main bars 24 of the pair of full precast beams 20 may be connected by a mechanical joint or a lap joint. Similarly, the lower end beam main bars 42 of the pair of half precast beams 40 and the upper end beam main bars 44 may be connected by a mechanical joint or a lap joint.

Further, in the above embodiment, the cast-in-place concrete 16 is made of fiber reinforced concrete. However, the cast-in-place concrete 16 may be ordinary concrete.

Further, in the above embodiment, a pair of full precast beams 20 and a pair of half precast beams 40 are joined to the precast columns 10. However, four full precast beams may be joined to the precast column 10, or four half precast beams may be joined. Further, two or three precast beams may be joined to the precast column. The precast beam is a concept including a full precast beam and a half precast beam.

Further, in the above embodiment, the pillar is a precast pillar 10. However, the columns are not limited to precast concrete and may be formed by cast-in-place concrete.

Further, the columns and beams are not limited to the reinforced concrete structure, and may be a steel-framed reinforced concrete structure or a steel-framed structure.

Although one embodiment of the present invention has been described above, the present invention is not limited to such an embodiment, and one embodiment and various modifications may be used in combination as appropriate. Of course, it can be carried out in various modes as long as it does not deviate.

10 Precast pillar (pillar)
10U top surface 20 full precast beam (beam)
20L Bottom surface 20S Side surface 40 Half precast beam (beam)
40S Side 70 Beam receiving bracket (Beam receiving part)
80 Pillar side guide member 90 Pillar side guide member 100 Pillar side guide member 110 Pillar side guide member 120 Beam side guide member 130 Overhanging part (beam receiving part)

Claims (4)

The columns to which the beams are joined and
A column-side guide member that is attached to the column, extends above the top surface of the column, and engages the side surfaces of the beam.
Column-beam positioning structure. A pair of pillar-side guide members that are attached to the pillar at intervals in a plan view.
The column-beam positioning structure according to claim 1. Beams joined to columns and
A beam-side guide member attached to the beam, extending downward from the lower surface of the beam, and engaging with the beam-side side surface of the column.
Column-beam positioning structure. A beam receiving portion provided on the column and on which a beam end portion of the beam is placed is provided.
The column-beam positioning structure according to any one of claims 1 to 3.

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