JP2018021377A - Reinforcement structure for existent construction - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve earthquake-proof effects by efficiently transferring horizontal earthquake power from a beam in an axial direction of a pole.SOLUTION: A pole part frame body 7 covering a pole 1 and an intersection part frame body 8 covering an intersection part of the pole 1 and a beam 2 are laminated. The intersection part frame body 8 consists of a pole facing part 8a, a beam facing part 8b and a haunch part 8c. The pole facing part 8a covers portions of the intersection part and the pole 1 continued downwards from the intersection part. The beam facing part 8b covers the beam 2 in the intersection part. The haunch part 8c is continued to the beam facing part 8b while being tilted from a bottom face of the beam facing part 8b with a fixed gradient.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a reinforcing structure for an existing building that reinforces an existing column and an existing beam that intersects the column.

  As a reinforcing structure for improving the earthquake resistance of an existing building, a structure shown in FIG. 9 is conventionally known. This conventional reinforcing structure reinforces an existing column 1 and an existing beam 2 that intersects the column 1, and includes a column reinforcing portion 3 that reinforces the entire circumference of the column 1, the column 1 and the beam. And a beam reinforcing portion 4 that reinforces the intersection where 2 intersects. The beam reinforcing portion 4 covers a predetermined length of the beam 2 continuous from the column.

Since the beam reinforcing portion 4 covers a predetermined length of the beam 2, the beam reinforcing portion 4 has a lateral width longer than the width of the column reinforcing portion 3.
The column reinforcing portion 3 for reinforcing the vertical direction of the column 1 and the beam reinforcing portion 4 for reinforcing the horizontal direction of the beam 2 are laminated, and the column reinforcing portion 3 and the beam reinforcing portion 4 are stacked. Are installed in an existing building.

  The beam reinforcing portion 4 has a space between the beam 2 and a plurality of anchor bolts 5 fixed to the beam 2 project from the surface of the beam 2 corresponding to the space. Is provided. The space is filled with a grout material, and the beam 2 and the beam reinforcing portion 4 are integrated through the grout material. In addition, axial streaks 6 are arranged along the pillars 1 at positions corresponding to the four corners of the pillars 1 inside the pillar reinforcing parts 3 and the beam reinforcing parts 4.

  The horizontal seismic force acting on the beam 2 is transmitted to the beam reinforcing portion 4 via an anchor bolt 5 provided on the surface of the beam 2. Further, the seismic force acting on the beam reinforcing portion 4 is transmitted to the column reinforcing portion 3 and an earthquake resistance effect is exhibited.

JP 2013-181332 A JP 2011-026786 A

  In the conventional reinforcing structure, the column reinforcing portion 3 and the beam reinforcing portion 4 are provided at right angles. Therefore, the horizontal direction of the seismic force transmitted from the beam 2 does not change direction to approximately 90 degrees. It is not transmitted to part 3. However, since all the horizontal seismic force cannot be changed, the seismic force cannot be sufficiently transmitted in the axial direction of the column reinforcing portion 3.

As described above, since the conventional reinforcing structure could not sufficiently transmit the seismic force from the beam 2 in the axial direction, no matter how much the column reinforcing portion 3 is reinforced, the column reinforcing portion 3 is earthquake resistant. There was a problem that the effect could not be fully demonstrated.
An object of the present invention is to provide a reinforcing structure for an existing building that can fully exhibit an earthquake resistance effect by transmitting a horizontal seismic force from a beam in the axial direction of a column.

  In the first aspect of the present invention, a column part frame that covers an existing column and an intersection part frame that covers an intersection of the column and an existing beam are stacked. The intersecting frame is composed of a column facing portion, a beam facing portion, and a hunch portion. Further, the column facing portion covers the intersection and the portion of the column continuous downward from the intersection, and the beam facing portion covers the beam at the intersection. And the said haunch part continues to the said column opposing part, inclining with a fixed gradient from the lower surface of the said beam opposing part.

  A space is formed between the beam facing portion and the beam, and a plurality of anchor bolts fixed to the surface of the beam protrude into the space, and at least a pair along the axial direction of the column. Axial streaks are provided. The space is filled with a filler.

  According to a second aspect of the present invention, a transmission reinforcing bar penetrating therethrough is provided along the inclination of the haunch portion, one end of the transmission reinforcing bar is linked to an anchor bolt provided on the beam, and the other end is It is characterized by being linked to an axial streak provided on the column.

  According to a third aspect of the present invention, the beam is continuous on both sides of the column, and the cross frame is provided with the haunch portions on both sides of the column facing portion, and the transmission reinforcement is provided in both the haunch portions. It is characterized in that the other end side of the transmission reinforcing bar which has passed through the both hunched portions is linked to each other while passing the line.

  According to a fourth aspect of the present invention, the haunch portion covers a corner between the column and the beam.

  According to a fifth aspect of the present invention, the pillar frame body is provided on the pillar with the entire circumference of the pillar being maintained at a predetermined interval, and the crossing frame is provided on both sides of the beam opposite to each other. A body is provided, and the crossing frame bodies are continuous through the haunch part.

  The sixth invention is characterized in that a tie bar is provided in the haunch part of the crossing frame body facing each other, and both ends of the tie bar protrude from the crossing frame body and are fixed.

According to the reinforcing structure of the first invention, since the column facing portion and the beam facing portion are continuous via the haunch portion, a part of the horizontal seismic force transmitted from the beam is the haunch portion. Is transmitted to the reinforcing portion formed by the column frame. Since the transmission path that changes the direction of force to 90 degrees as in the conventional reinforcement structure is short-cut using the diagonal path of the hunch, horizontal seismic force is applied to the axial force of the column. It became easy to change the direction.
As described above, since the horizontal seismic force is transmitted obliquely to the reinforcing portion formed of the column portion frame body via the haunch portion, more force is transmitted in the axial direction of the column. For this reason, the seismic force is exerted on the reinforcing portion formed of the columnar frame so that the seismic effect can be sufficiently exerted.

According to the second invention, since the transmission reinforcing bars are provided along the inclination in the haunch portion, the horizontal seismic force is formed by the column part frame through the transmission reinforcing bars. Is transmitted to the reinforcement part. Thus, the horizontal seismic force is redirected and transmitted in the axial direction via the transmission reinforcement.
In addition, the transmission reinforcing bar exhibits a transmission function by linking the anchor bolt and the axial bar. Therefore, the horizontal force transmitted to the anchor bolt can be reliably transmitted to the axial streak.

According to the third invention, since the transmission reinforcing bars are continuously arranged on the beams on both sides of the column, the seismic force transmitted in the axial direction of the column is also transmitted in the horizontal direction of the beam. Can be made. As a result, seismic force can be absorbed by the existing building as a whole.
In addition, it acts as a bending reinforcing bar for the beam in cooperation with a slab (not shown), thereby improving the bending strength of the beam.

According to the reinforcing structure of the fourth aspect of the invention, since the corners between the side surface of the column and the lower surface of the beam are covered with the haunch portion, the coupling force between the column and the beam is improved. For this reason, cracks from the corners were difficult to enter.
Moreover, since the axial length of the column of the haunch part in the column and the horizontal length of the beam of the haunch part in the beam are reinforced, the length covered by the haunch part is already existing. The inner length of each of the columns and existing beams becomes shorter. Thus, the rigidity and strength of the existing column and the existing beam are improved by shortening the respective inner lengths.
Accordingly, the existing column and the reinforcing portion formed of the column part frame can be combined to greatly improve the rigidity and strength of the reinforced column.

According to 5th invention, since the said frame for pillar parts covers the perimeter of the said pillar, and the said frame for crossing parts covers both surfaces of the opposite side of the said beam, the reinforced column and reinforcement The cross-sectional area of each of the beams is increased. By increasing the cross-sectional area in this manner, the shear strength of the reinforced column and the reinforced beam is improved.
Further, the crossing frame bodies are respectively provided on both sides of the beam opposite to each other, and these crossing frame bodies are continuous through the hunch part. The bonding strength of the is further improved.

  According to the sixth invention, since the tie bar is provided in the haunch portion of the crossing frame body facing each other, the crossing frame body facing each other does not move integrally. Thus, since the opposing frame for an intersection does not move, the number of anchor bolts can be reduced. By reducing the number of anchor bolts driven, it is possible to reduce proof stress loss in existing beams.

It is the reinforcement structure which reinforced the existing pillar and beam of 1st Embodiment, Comprising: It is a perspective view from diagonally upward before filling with a filler. It is sectional drawing of the cross | intersection part (a) where the pillar and beam before filling with the filler of 1st Embodiment cross | intersect, and a pillar (b). It is a perspective view from the downward direction of a 1st embodiment. It is the front view which showed a mode that the axial direction stripe | line | wire, transmission reinforcement, etc. before installing each frame of 1st Embodiment were arrange | positioned. It is the front view which showed a mode that the axial direction stripe | line | wire, transmission reinforcement, etc. before installing each frame of 2nd Embodiment were arrange | positioned. It is a perspective view from the downward direction of 3rd Embodiment. It is a perspective view from the downward direction of 4th Embodiment. It is sectional drawing of the cross | intersection part formed with the pillar before filling the filler of 5th Embodiment, and the beam which cross | intersects four directions of this pillar. It is the reinforcement structure which reinforced the conventional existing pillar and beam, Comprising: It is a perspective view from diagonally before filling with grout material.

The first embodiment shown in FIGS. 1 to 4 reinforces a building in which a pair of beams 2 and 2 intersect the side surface of an existing column 1.
In the first embodiment shown in FIG. 1, the entire circumference of the column 1 is surrounded by a column part frame 7 with a predetermined distance from the surface of the column 1. As shown in FIG. 2 (b), the column portion frame body 7 is formed as a set of four L-shaped frame bodies each made of a single plate, and the end portions thereof are overlapped to form a rectangular cross section. .

And the said column part frame 7 is provided along the said pillar 1, and the column part frame 7 divided | segmented into the axial direction is laminated | stacked, and it is set as required reinforcement length. The overlapped portions of the frames arranged in this manner and the stacked connection portions are joined by welding.
In addition, in this 1st Embodiment, this required length of reinforcement means the length from the lower end of the pillar 1 which contacts the slab which is not shown in figure to the lower end of the frame 8 for cross | intersection parts mentioned later, but calculates | requires by reinforcement object. Naturally, the required reinforcement lengths differ.

  On the other hand, the crossing frame 8 shown in FIG. 1 includes a column facing portion 8a, a beam facing portion 8b, and a hunch portion 8c. The column facing portion 8a covers the intersection and the portion of the column 1 that continues downward from the intersection. The beam facing portion 8b covers the beam 2 at the intersection. And the said haunch part 8c is following the said column opposing part 8a, inclining with a fixed gradient from the lower surface of the said beam opposing part 8b.

  In the first embodiment, the crossing frame 8 is formed by processing a steel plate. The crossing frame 8 constituted by the column facing portion 8a, the haunch portion 8c, and the beam facing portion 8b is a front surface having six sides facing a specific surface of the column 1 and the beam 2. And a side surface orthogonal to the front surface.

  A portion of the intersecting portion frame 8 facing the intersecting portion is maintained at a predetermined distance from the surface of the intersecting portion, and forms a U-shaped cross section as shown in FIG. A fixing piece 9 for fixing the cross frame 8 to the beam 2 is provided at the edge of the side surface opposite to the front surface. The fixing piece 9 is fixed to the surface of the beam 2 via a bolt 10.

Further, at the position corresponding to the corner C where the side surface of the column 1 and the lower surface of the beam 2 intersect, as shown in FIG. 3, the side surface of the haunch portion 8c is formed along the inclination. A slope S is provided. In the first embodiment, crossing frame bodies 8 are provided on both sides of the beam 2 opposite to each other, and the crossing frame bodies 8 are connected to each other via the slope S of the hunch 8c. ing.
Further, the crossing frame 8 is provided by being laminated on the uppermost end of the columnar frame 7. And this laminated connection part is joined by welding.

A space is provided in the interval formed by the column part frame 7 and the cross part frame 8 formed as described above, and the column 1 and the beam 2. In addition, a space is also provided in the hunch 8c of the crossing frame 8 and the spaces are continuous.
As shown in FIG. 2A, a plurality of anchor bolts 5 protruding from the surface of the beam 2 are provided in these spaces. Further, in these spaces and in front of the pillar 1, at least a pair of axial streaks 6 are provided along the axial direction of the pillar 1. In the first embodiment, four axial streaks 6 are continuously provided in front of the pillar 1 in these spaces, corresponding to the four corners of the pillar 1.

  In addition, as shown in FIG. 4, the transmission reinforcing bar 11 that transmits the horizontal seismic force of the beam 2 in the axial direction of the column 1 is provided in the space formed in the haunch portion 8 c. It passes along the inclination of the portion 8c. In the intersecting portion frame 8, the haunch portions 8c are provided on both sides of the column facing portion 8a, and the transmission reinforcing bars 11 pass through both the haunch portions 8c. The transmission reinforcing bar 11 is bent at both ends into hooks and hooked on anchor bolts 5 provided on the beam 2. Further, the transmission reinforcing bar 11 that has passed through both the hunch portions intersects with a pair of axial bars 6 provided in front of the pillar 1.

  Further, tie bars 12 are provided on the hunch 8c of the crossing frame 8 facing each other, and both ends of the tie bar 12 protrude from the crossing frame 8 and are fixed by nuts 13. By providing the tie bar 12, the opposing cross frame 8 is not moved together. Thus, since the opposing frame member 8 does not move, the number of anchor bolts 5 can be reduced. By reducing the number of anchor bolts 5 driven, the proof stress loss in the existing beam 2 can be reduced.

The space formed as described above is filled with a filler such as mortar or grout. By filling the filler, the anchor bolt 5 and the axial reinforcement 6 and the transmission reinforcing bar 11 are embedded, and each of them cooperates to exhibit a transmission function. When the filler is cured, a column reinforcing portion and a beam reinforcing portion are formed, and the column 1 and the beam 2 are joined together to form a reinforcing column and a reinforcing beam.
Thus, since the column frame 7 covers the entire circumference of the column 1 and the intersection frame 8 covers both surfaces of the beam 2, the cross-sectional areas of the reinforcing column and the reinforcing beam are growing. By increasing the cross-sectional area in this way, the shear strength of the reinforcing column and the reinforcing beam is improved.

In the first embodiment, since the column facing portion 8a and the beam facing portion 8b are continuous via the haunch portion 8c, a part of the horizontal seismic force transmitted from the beam 2 is the haunch portion. It is transmitted to the column reinforcement along the inclination of 8c. Since the transmission path that changes the direction of force to 90 degrees as in the conventional reinforcing structure is short-cut using the slant path of the hunch 8c, the horizontal seismic force is applied to the axial direction of the pillar 1 above. It became easy to change the direction to power.
Thus, since the horizontal seismic force is transmitted obliquely to the column reinforcing portion via the haunch portion 8c, more force is transmitted in the axial direction of the column 1. Therefore, the seismic force is exerted on the column reinforcing portion, and the seismic effect is sufficiently exhibited.

Further, since the transmission reinforcing bars 11 are provided along the slope in the hunch 8c, the horizontal seismic force is transmitted to the column reinforcing parts via the transmission reinforcing bars 11. Thus, the horizontal seismic force is redirected through the transmission reinforcing bar 11 and transmitted in the axial direction.
The transmission reinforcing bar 11 exhibits a transmission function by the anchor bolt 5 and the axial direction line 6 being linked. Therefore, the horizontal force transmitted to the anchor bolt 5 can be reliably transmitted to the axial stripe 6.

Furthermore, since the transmission reinforcing bars 11 are continuously arranged on the beams 2 on both sides of the column 1, the seismic force transmitted in the axial direction of the column 1 is also transmitted in the horizontal direction of the beam 2. It is done. Therefore, the seismic force can be absorbed by the entire existing building.
In addition, it acts as a bending reinforcing bar for the beam 2 in cooperation with a slab (not shown), and the bending strength of the beam 2 is improved.

  In the first embodiment, since the corner C between the side surface of the column 1 and the lower surface of the beam 2 is covered with the hunch 8c, the coupling force between the column 1 and the beam 2 is improved. The cross frame 8 is provided on both surfaces of the beam 2 facing each other, and the cross frame 8 is continuous through the hunch 8c. The binding force with 2 is further improved. For this reason, cracks from the corners C are difficult to enter.

In addition, since the axial length of the column 1 of the haunch portion 8c in the column 1 and the horizontal length of the beam 2 of the haunch portion 8c in the beam 2 are reinforced, they are covered with the haunch portion 8c. The internal length of each of the existing column 1 and the existing beam 2 is shortened by the length of the length. Thus, the rigidity and strength of the existing pillar 1 and the existing beam 2 are improved by shortening each inner length.
Therefore, the existing column 1 and the column reinforcing portion are combined, and the rigidity and strength of the reinforcing column can be greatly improved.

  The second embodiment shown in FIG. 5 is different from the first embodiment in the configuration of the transmission reinforcing bar 14, but the other configurations are the same as those in the first embodiment. Therefore, in the second embodiment, the same components as those in the first embodiment are denoted by the same reference numerals as those in the first embodiment, and detailed descriptions of the respective components are omitted.

  As shown in FIG. 5, in 2nd Embodiment, the frame 8 for cross | intersection parts is provided with the hunch part 8c on both sides of the column opposing part 8a. The transmission reinforcing bars 14 pass through the spaces formed in the haunch portion 8c along the slopes of the left and right haunch portions 8c. Each transmission reinforcing bar 14 is bent at one end in a hook shape and hooked on an anchor bolt 5 provided on the beam 2. Further, each of the transmission reinforcing bars 14 crosses the other end with a pair of axial bars 6 provided in front of the pillar 1.

  In the second embodiment, as in the first embodiment, a space is provided in the interval formed by the column portion frame body 7 and the intersecting portion frame body 8 and the column 1 and the beam 2. Yes. This space is continuous with the space in the haunch portion 8c. These spaces are filled with a filler. In this way, by filling the filler, the anchor bolt 5 and the axial reinforcement 6 and the two transmission reinforcing bars 14 and 14 are embedded, and each of them cooperates to exhibit a transmission function.

When the filler is cured, a column reinforcing portion and a beam reinforcing portion are formed, and the column 1 and the beam 2 are combined with each other to form a reinforcing column and a reinforcing beam. In particular, it acts as a lap joint by intersecting the other ends of the transmission reinforcing bars 14, 14 arranged in front of the column 1, as in the case of the single transmission reinforcing bar 11 of the first embodiment. Function.
Configurations and operational effects other than those described above are the same as in the first embodiment.

The third embodiment shown in FIG. 6 is a reinforcing structure that reinforces only one specific surface side of the existing pillar 1, and the other configuration is the same as that of the first embodiment. Therefore, in the third embodiment, the same components as those in the first embodiment are denoted by the same reference numerals as those in the first embodiment, and detailed descriptions of the respective components are omitted.
In the third embodiment, a specific length of the column 1 is surrounded by a column frame 15 with a predetermined distance from the surface of the column 1 so as to be reinforced.

This column part frame 15 is made up of a pair of L-shaped frames made of a single plate, and the ends thereof are butted together to form a U-shaped cross section. I have to.
In addition, the column part frame body 15 has a required reinforcement length by laminating the column part frame bodies 15 divided in the axial direction. The overlapping portions of the frames arranged in this way and the stacked connection portions are joined by welding.
A plurality of anchor bolts 5 (not shown) are fixed to the pillar 1 and provided so as to protrude from the surface on a specific surface of the pillar 1. And the said pillar 1 and a column reinforcement part are integrated by being filled with a filler.

  On the other hand, the crossing frame 16 shown in FIG. 6 includes a column facing portion 16a, a beam facing portion 16b, and a hunch portion 16c. The column facing portion 16a covers the intersecting portion and the portion of the column 1 that continues downward from the intersecting portion. The beam facing portion 16b covers the beam 2 at the intersection. And the said haunch part 16c is following the said column opposing part 16a, inclining with a fixed gradient from the lower surface of the said beam opposing part 16b.

The intersecting frame 16 is disposed at a predetermined distance from the surfaces of the pillars 1 and the beams 2.
In addition, since the said crossing frame 16 covers only one specific surface of the said pillar 1 and the said beam 2, the position where the said haunch part 16c of the said crossing frame 16 opposes with a predetermined space | interval In addition, a triangular auxiliary frame (not shown) is provided. A slope S1 along the slope is provided between the haunch part 16c of the intersection frame 16 and the reinforcing frame, and is continuous via the slope S1.

In addition, a space is provided between the hunch 16c of the crossing frame 16 and the auxiliary frame, and this space is formed by the crossing frame 16, the column 1 and the beam 2. It is continuous with the space.
Further, the intersecting portion frame body 16 is provided by being laminated at the uppermost end of the column portion frame body 15.

In the third embodiment, the tie bar 12 is not provided between the hunch 16c of the crossing frame 16 and the auxiliary frame facing each other. This is because the effect of reducing the number of anchor bolts 5 cannot be obtained because the opposite side surfaces of the beam 2 are not sandwiched.
In the third embodiment, only the column 1 covers the column frame 15, but when the wall intersects the column 1, the column frame 15 A part of the wall may be covered.
Other configurations are the same as those in the first embodiment.

In the third embodiment, since the column facing portion 16a and the beam facing portion 16b are continuous via the haunch portion 16c, a part of the horizontal seismic force transmitted from the beam 2 is the haunch portion. It is transmitted to the column reinforcement along the inclination of 16c. Since the transmission path for changing the direction of force to 90 degrees as in the conventional reinforcing structure is short-cut using the oblique path of the hunch 16c, the horizontal seismic force is applied to the axial direction of the pillar 1 above. It became easy to change the direction to power.
As described above, since the horizontal seismic force is transmitted obliquely to the column reinforcing portion via the haunch portion 16c, more force is transmitted in the axial direction of the column 1. Therefore, the seismic force is exerted on the column reinforcing portion, and the seismic effect is sufficiently exhibited.

Further, since the transmission reinforcing bars 11 are provided along the inclination in the haunch portion 16c, the horizontal seismic force is transmitted to the column reinforcing portions via the transmission reinforcing bars 11. Thus, since the horizontal seismic force is redirected and transmitted in the axial direction via the transmission reinforcing bar 11, the seismic effect of the column reinforcing portion is sufficiently exhibited.
The transmission reinforcing bar 11 exhibits a transmission function by the anchor bolt 5 and the axial direction line 6 being linked. Therefore, the horizontal force transmitted to the anchor bolt 5 can be reliably transmitted to the axial stripe 6.

In addition, since the axial length of the column 1 of the haunch portion 16c in the column 1 and the horizontal length of the beam 2 of the haunch portion 16c in the beam 2 are reinforced, they are covered with the haunch portion 16c. The internal length of each of the existing column 1 and the existing beam 2 is shortened by the length of the length. Thus, the rigidity and strength of the existing pillar 1 and the existing beam 2 are improved by shortening each inner length.
Therefore, the existing column 1 and the column reinforcing portion are combined, and the rigidity and strength of the reinforcing column can be greatly improved.

  The fourth embodiment shown in FIG. 7 is a reinforcing structure that reinforces a specific surface of the existing column 1, and includes a hunch 16 c that surrounds a corner C between the side surface of the column 1 and the lower surface of the existing beam 2. The other configuration is the same as that of the third embodiment. Therefore, in this 4th Embodiment, while using the same code | symbol as 3rd Embodiment for the same component as 3rd Embodiment, detailed description of each component is abbreviate | omitted.

  As shown in FIG. 7, the hunch portion 16 c is provided at the corner C where the side surface of the column 1 and the lower surface of the beam 2 intersect. At a position corresponding to the corner C, a slope S2 is provided along the slope of the haunch portion 16c. Fixing pieces 17 and 17 for fixing the frame body to the pillar 1 and the beam 2 are provided at a portion where the slope S2 contacts the side surface of the pillar 1 and the lower surface of the beam 2. The fixing pieces 17, 17 are fixed to the surface of the pillar 1 and the surface of the beam 2 with an adhesive. In the fourth embodiment, an adhesive is used as a fixing means for the fixing pieces 17, 17, but it may be mechanically fixed by a bolt or the like.

  In addition, a triangular auxiliary frame (not shown) is provided at a position where the crossing frame 16 is opposed to the hunch 16c of the crossing frame 16. A space is provided in the haunch portion 16c formed in this way. In this space, the transmission reinforcing bar 11 passes along the slope S 2, and the transmission reinforcing bar 11 is hooked on the anchor bolt 5 provided on the beam 2 on both sides of the column 1. Further, the transmission reinforcing bar 11 that has passed through both the hunch portions is provided so as to intersect with the pair of axial bars 6 provided in front of the pillar 1. The space thus configured is filled with a filler.

Thus, since the said entrance corner C is covered with the haunch part 16c, the coupling | bonding force of the said pillar 1 and the said beam 2 improves. For this reason, cracks from the corners C are difficult to enter.
Other configurations and operational effects are the same as those of the third embodiment.

  The fifth embodiment shown in FIG. 8 is an existing building in which an existing beam 2 intersects an existing column 1 in four directions, and a shape in which the crossing frame 18 matches the beam 2 in the four directions. It has become. Other configurations are the same as those of the first embodiment. Therefore, in the fifth embodiment, the same components as those in the first embodiment are denoted by the same reference numerals as those in the first embodiment, and detailed description of each component is omitted.

In the fifth embodiment, an intersecting portion frame 18 stacked on the pillar portion frame 7 surrounds an intersecting portion where the beam 2 intersects the pillar 1 in four directions.
The cross frame 18 is maintained in a shape that can be stacked in the axial direction of the pillar 1 in accordance with the shape of the cross section of the pillar frame 7.

The intersecting portion frame 18 shown in FIG. 8 serves as the column facing portion 8b provided in the first embodiment, and the haunch portion 18c serves as a part thereof. Therefore, in the fifth embodiment, it is only necessary that at least the beam facing portion 18a and the haunch portion 8c can cover the column 1 and the beam 2 as components.
The beam facing portion 18a of the fifth embodiment covers the beam 2 at the intersection. Further, the haunch portion 8c continues to the column facing portion or the uppermost end portion of the column portion frame body 7 while being inclined with a certain gradient from the lower surface of the beam facing portion 18a. And the said column opposing part which is not illustrated has covered the said cross | intersection part and a part of the pillar 1 continued below from this cross | intersection part according to the form to implement.

  The intersecting frame 18 is an L-shaped frame having a front surface provided in parallel to each surface of the beam 2 and a side surface orthogonal to the front surface and kept at a predetermined distance from the surface of the beam 2. The body is a pair. And the front-end | tip of two said frame bodies is joined in the position corresponding to the four corners of the said pillar 1, and the said crossing frame 18 is formed. Four such intersecting frame bodies 18 are combined to surround the intersecting portion, and the haunch portion 18c is provided under each beam 2. Then, the crossing frame bodies 18 are continuous with the opposite surfaces of the beam 2 opposite to each other via the haunch portion 18c.

The crossing frame 18 combined in this way is provided with a fixing piece 9 for fixing the crossing frame 18 to the beam 2 at the edge of the side surface in contact with the surface of the beam 2. It is done. The fixing pieces 9 are fixed to the surface of the beam 2 with bolts 10 respectively.
Configurations and operational effects other than those described above are the same as those in the first embodiment.

In each of the above-described embodiments, the connecting means of each frame is joined by welding, but a fiber sheet containing an adhesive can be attached and joined.
Moreover, although each frame was made to overlap the edge part of adjacent frame bodies, you may make it provide a rib in the edge part of each frame, and may make it combine. When ribs are provided on each frame, the frames can be easily assembled.

  Furthermore, in each embodiment, although each frame uses the steel plate, the material of each frame is not limited. For example, reinforced plastic or the like may be used instead of the steel plate, or precast concrete manufactured in advance in a factory may be used. When this precast concrete is used, the transmission reinforcing bars 11, 14 and the axial direction bars 6 can be embedded in the concrete in advance.

  It is most suitable for the reinforcement structure of existing buildings where columns and beams intersect.

  DESCRIPTION OF SYMBOLS 1 ... Column, 2 ... Beam, 5 ... Anchor bolt, 6 ... Axial streak, 7, 15 ... Column part frame, 8, 16, 18 ... Intersection part frame, 11, 14 ... Transmission reinforcement bar, 12 ... Tie bar, S, S1, S2 ... Slope, C ... Inside corner

Claims (6)

The column part frame that covers the existing pillars and the cross part frame that covers the intersections between the columns and the existing beams are stacked,
This intersecting frame is composed of a column facing portion, a beam facing portion, and a hunch portion.
The column facing portion covers the intersection and the portion of the column that continues downward from the intersection,
The beam facing portion covers the beam at the intersection,
The haunch part continues to the column facing part while inclining with a certain gradient from the lower surface of the beam facing part,
A space is formed between the beam facing portion and the beam,
In this space, a plurality of anchor bolts fixed to the surface of the beam protrude,
A reinforcement structure of an existing building in which at least a pair of axial streaks are provided along the axial direction of the pillar, and the space is filled with a filler.   A transmission reinforcing bar penetrating therethrough is provided along the inclination of the haunch, and one end of the transmission reinforcing bar is linked to an anchor bolt provided on the beam, and the other end of the transmission reinforcing bar is The reinforcement structure of the existing building of Claim 1 linked | related with the axial direction line | wire provided in the pillar. The beam is continuous on both sides of the column,
The crossing frame is provided with the haunch portions on both sides of the column facing portion, and allows the transmission reinforcing bars to pass through both the haunch portions, and the other end side of the transmission reinforcing bars that have passed through both the haunch portions is The reinforcing structure for an existing building according to claim 2, which is linked to each other.   The reinforcement structure of the existing building of any one of Claims 1-3 in which the said haunch part covers the corner of the said pillar and a beam.   The column frame is provided on the column with a predetermined interval around the entire circumference of the column, and the cross frame is provided on both sides of the beam opposite to each other, The reinforcing structure for an existing building according to claim 4, wherein the crossing frame bodies are continuous through the haunch portion. The reinforcing structure for an existing building according to claim 5, wherein a tie bar is provided in the haunch portion of the crossing frame body facing each other, and both ends of the tie bar are projected and fixed from the crossing frame body.

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