KR100385007B1 - Aseismatic reinforcing device - Google Patents

Abstract

The present invention is to provide a seismic reinforcement mechanism for the purpose of attaching and reinforcing to joints of building structural materials such as foundations, columns, beams, and purlins so as not to collapse even when a strong vibration is applied to a wooden house due to an earthquake or typhoon. will be. The present invention is a seismic reinforcing mechanism for joining three-dimensional cross-building structural members (A, A), and the first reinforcing base material (1) for bending a plate made of high-strength steel 90 ° to fix to one building structural member (A) and And a second reinforcing base material 2 fixed to the other building structural member A disposed symmetrically through the first reinforcing base material 1 and the hinge 4, and the second reinforcing base material 2 The plate made of high strength steel is bent at 90 ° and a rubber elastic cushioning member 3 is attached to various portions of the bent portion, and the cushioning member 3 is sandwiched between the building structural members A and A. It is set so that it may be fixed to the other building structural material A, and the said other building structural material A is joined to the said one building structural material A, It is characterized by the above-mentioned.

Description

Earthquake-resistant reinforcement mechanism {ASEISMATIC REINFORCING DEVICE}

The present invention relates to an earthquake-resistant reinforcement mechanism for the purpose of attaching and reinforcing to joints of building structural materials such as foundations, columns, beams, and purlins so as not to collapse even when a strong vibration is applied to a wooden house by an earthquake, typhoon or the like.

Conventionally, as a method of reinforcing the joint of a wooden building structural member, various methods have been adopted, such as providing a brace or an angle brace beam, attaching a clamp, or an L-shaped mechanism. .

However, in the above method, the reinforcing effect when a strong vibration is loaded by an earthquake, typhoon, etc. is not sufficient, the structural material is transferred or damaged at the joint, and the wooden building is destroyed at the joint, or collapses in severe cases. There was also a concern.

Therefore, the reinforcement mechanism 61 shown in the perspective view in FIG. 5 is devised and used to withstand the strong vibration caused by an earthquake, a typhoon, and the like.

The reinforcing mechanism 61 is a L-shaped base material 62 in which a plate member made of high-strength steel is bent into an L-shape, and at the same time, the bending protrusions 63a and 63b are formed to be bent inward in the middle portions of the both ends 62a and 62b. ) To fix the reinforcing member 64, which is a sheet of high tensile steel, bent to the bent edge portion 62c of the L-shaped base material 62 by welding, and is absorbed in various places of the L-shaped base material 62. The shock absorbing member 65 made of rubber or the like is joined.

According to this, the entire L-shaped base material 62 and its bent protrusions 63a and 63b can absorb the strong vibrations in both the vertical and horizontal directions, thereby restoring the deformation of the L-shaped base material 62, so that the strong vibration is applied to the load. Even so, wooden structures are less likely to be destroyed or collapsed at the joints.

However, the reinforcing mechanism 61 is an L-shaped base material 62, and both ends of the base material 62 join structural members that are perpendicular to each other in structure, and have a function of three-dimensionally joining building structural materials. It is not.

Further, the reinforcing member 64 is fixed to the L-shaped base material 62 by welding, and the bent edge portion 62c of the L-shaped base material 62 and the bent edge portion 64c of the reinforcing member 64 are brought into close contact with each other. Therefore, the amount of elastic deformation was small, and the effect of restoring the deformation of the L-shaped base material 62 was also insufficient.

The present invention has been made to solve the above problems, and absorbs vibrations in the vertical and horizontal directions and fluctuations in the vertical direction so that three-dimensional crossover construction does not collapse even when a strong vibration is applied to a wooden house by an earthquake or typhoon. An object of the present invention is to provide an earthquake-resistant reinforcing mechanism for further improving the seismic performance by fixing the reinforcing base material between the structural members.

1 is a perspective view showing a mounting state of one embodiment of the present invention,

2 is a plan view showing a mounting state of one embodiment of the present invention,

3 is an exploded perspective view showing each member used in an embodiment of the present invention;

4 is a perspective view showing another embodiment of the present invention,

5 is a perspective view showing a conventional example.

* Description of the symbols for the main parts of the drawings *

1: first reinforcing base material 11: fixing part

111: long hole 12: loop bearing portion

2: second reinforcing base material 21: fixing piece

211: fixing hole 22: cylindrical bearing portion

23: curved protrusion 231: circular arc surface

24: bending protrusion 241: flat surface

25: cushion round 3: cushion member

4: hinge 41: shaft center bolt

411 pin hole 412 fixed pin

42: spring 43: nut

5: fixture A: building structural material

A-1: column structural member A-2: beam, purlin structural member

This invention solves the said subject and achieves the objective, The objective is the earthquake-proof reinforcement mechanism which joins three-dimensional cross-building structural members together, and it bends a board | plate material by 90 degrees, and fixes it to one building structural material. The first reinforcing base material and the second reinforcing base material which is fixed to the other building structural material arranged symmetrically through the first reinforcing base material and the hinge, the second reinforcing base material, the plate is 90 ° bent and bent A rubber elastic shock absorbing member is attached to various parts of the part, and the shock absorbing member is sandwiched between the building structural members to be fixed to the other building structural member, and the other building structural member is joined to the one building structural member. It is a seismic reinforcement mechanism characterized by the above-mentioned.

Then, the middle portion of the second reinforcing base material is bent outward to form a curved protrusion, or the middle portion is bent outwards several times to form a bending protrusion.

When the plate is made of high tensile strength steel, the tensile strength, weldability, notch toughness, workability and corrosion resistance are excellent, which is more preferable.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of the earthquake-resistant reinforcement mechanism of this invention is described concretely with reference to drawings.

1 is a perspective view showing a mounting state of one embodiment of the present invention, Figure 2 is a plan view showing a mounting state of one embodiment of the present invention, Figure 3 is an exploded view showing each member used in one embodiment of the present invention 4 is a perspective view showing another embodiment of the present invention.

The present invention is a seismic reinforcing mechanism for fixing three-dimensionally intersecting building structural members (A, A) as shown in the perspective views of FIGS. 1, 3, and 4, and also in the plan view of FIG. It is fixed to the first reinforcing base material 1 that is bent and fixed to one building structural material A, and the other building structural material A that is symmetrically arranged through the first reinforcing base material 1 and the hinge 4. The second reinforcing base material (2) is made, the second reinforcing base material (2), the plate is bent 90 °, the upper end of the bent portion of the rubber member cushioning member (3) is attached, A structure in which the shock absorbing member 3 is sandwiched between the building structural members A and A to be fixed to the other building structural member A, and the other building structural member A is bonded to the one building structural member A. I did it.

Then, the curved protrusion 23 having the arc surface 231 is formed by bending the middle portion of the second reinforcing base material 2 outward, or the bending protrusion portion having the flat surface 241 by bending the middle portion outwards several times. 24 is formed and the cushion round 25 can be formed in the substantially center of the curved protrusion 23 or the bending protrusion 24 of the said 2nd reinforcement base material 2 as needed.

According to the present invention, the curved to bent protrusions 23 and 24 are formed on the outer side of the middle portion of the second reinforcing base material 2, and at various places of the fixing pieces 21 and 21, the cushioning member having rubber elasticity ( 3) and a hinge 4 for elastically axially supporting and connecting the first reinforcing base material 1 and the second reinforcing base material 2 in the vertical direction, and the vibration in the vertical direction and the horizontal direction, and the vertical direction. The oscillating force is absorbed and at the same time, there is a restoring force, and even when a strong vibration is applied to a wooden house by an earthquake, typhoon or the like, the counter force against being pulled or twisted to one side is increased. , 24) The cushioning effect 25 can be further improved by forming the cushion round 25 almost in the middle.

As shown in FIG. 1, FIG. 2, and FIG. 4, this invention installs over the column structural material A-1, beam, and purlin structural material A-2 which intersect, for example, a three-dimensionally intersecting building construction material A. FIG. As a seismic reinforcing mechanism, the first reinforcing base material 1 fixed to the column structural member A-1, and the beam and purlin structural material A arranged symmetrically through the first reinforcing base material 1 and the hinge 4. It consists of the 2nd reinforcement base material 2 fixed to -2).

The first reinforcing base material 1 bends a plate made of a steel material having flexibility and rigidity such that the bending angle θ-1 is 90 °, and fixes both ends along the column structural member A-1 surface. Long holes 111 are formed in each of them, and a k-shaped loop bearing portion 12 is formed in the bent corner. Although not shown, a cylindrical bearing part may be provided in place of the loop bearing part 12.

The second reinforcing base material 2 bends a plate made of a steel material having flexibility and rigidity such that the bending angle θ-2 is 90 °, and a cylindrical bearing portion 22 is formed at the bending edge portion. And at the same time, both ends are fixed to the fixing piece (21, 21) to be fixed to the purlin structural member (A-2), the middle portion of each of the fixing piece (21, 21) is curved outward to the arc surface (231) A curved protrusion 23 having a flat surface or a bending protrusion 24 having a flat surface 241 by bending the intermediate portion of the fixing pieces 21 and 21 to the outside several times, and the curved to bent protrusion 23 as necessary. At about the center of, 24, a cushion round 25 is formed.

In addition, the fixing holes 211 are formed in various places of the fixing pieces 21 and 21 of the second reinforcing base material 2, respectively, and the shock absorbing member having rubber elasticity in accordance with the formation position of the fixing holes 211. (3) is attached.

The shock absorbing member 3 to be attached to the fixing pieces 21 and 21 of the second reinforcing base material 2 is made of a reduced pressure rubber having elastic properties and rubber elasticity with good durability. ), A long hole is formed on the contact surface in contact with the fixing hole 211 formed in various places of the fixing pieces 21, 21 of the second reinforcing base material 2, so that the second reinforcing base material 2 The holding part which encloses the fixing piece 21 of the 2nd reinforcement base material 2 is formed in the surface side while enabling attachment fine adjustment.

It is preferable to employ structural steel as the steel material, and particularly to employ high tensile steel. High tensile steel is a low carbon steel, which is a small amount of alloying elements such as manganese, silicon, nickel, chromium, molybdenum, and the like added in small amounts. It is excellent in corrosion resistance.

As shown in FIG. 3, the hinge 4 for elastically axially supporting the first reinforcing base material 1 and the second reinforcing base material 2 in the vertical direction is bent in the first reinforcing base material 1. From the pin-shaped loop bearing part 12 formed in the corner part to the cylindrical bearing part 22 formed in the bending edge part of the 2nd reinforcement base material 2, the shaft center bolt 41 is loosened from an arrow direction. The nut 43 is screwed through the spring 42 with the shaft center bolt 41 projecting from the bottom of the cylindrical bearing portion 22, and immediately below the nut 43, the It is formed by inserting and fixing the fixing pin 412 in the pin hole 411 formed in the lower part of the axial center bolt 41. As shown in FIG.

Hereinafter, the procedure to attach the reinforcement mechanism of this invention to the building structural material A is described.

As shown in FIGS. 2 and 3, first, the fixing portion 11 of the first reinforcing base material 1 is connected to the column structure member A using a fixing tool 5 such as a screw or a nail through the long hole 111. After temporarily fixing to -1), the cylindrical bearing part 22 of the fixing piece 21 of the 2nd reinforcing base material 2 is matched with the loop bearing part 12 of the 1st reinforcing base material 1, The shaft center bolt 41 is loosely fitted, and the nut 43 is screwed through the spring 42 with the shaft center bolt 41 protruding from the bottom of the cylindrical bearing part 22, and at the same time, the fixing pin 412 is fixed to the pin hole 411.

Then, the fixing piece 21 of the second reinforcing base material 2 is beamed using the fixing tool 5 through the fixing hole 211 and the long hole of the shock absorbing member 3, and the purlin structural material A-2. At the same time, the fastener 5 temporarily fixed to the pillar structural member A-1 is reliably fixed to complete the attachment construction to the building structural member A of the present invention.

According to the present invention, a spring 42 is provided between the first reinforcing base material 1 fixed to the column structural member A-1 and the second reinforcing base material 2 fixed to the beam and purlin structural member A-2. The vibration in the vertical direction is absorbed by the hinge 4 elastically supporting the shaft in the up and down direction through the cross section), and the second reinforcing base material 2 has the curved to bent protrusions 23 and 24 and the cushion round ( In addition to the formation of 25), the fixing piece 21 is fixed to the beam and the purlin structural member A-2 through the rubber elastic cushioning member 3, whereby vibration in the horizontal direction is absorbed and there is a restoring force. Even when a strong vibration is loaded in the vertical or horizontal direction of a wooden house by an earthquake or typhoon, the counter force against being pulled or twisted to one side is increased.

Since this invention consists of the said structure, it has the following effects.

That is, according to the present invention, since the vibration in the vertical or horizontal direction and the vertical direction applied to the building structural material are absorbed and the restoring force is amplified, even when a strong vibration is applied to the wooden house by an earthquake or the like, the counter force increases and the seismic performance is improved. Demonstrates further improved action.

Claims (4)

As a seismic reinforcement mechanism to join three-dimensional cross building structural materials together, A first reinforcing base material which is bent by 90 ° and fixed to one building structural material, and a second reinforcing base material fixed to the other building structural material symmetrically disposed through the first reinforcing base material and a hinge, To the second reinforcing base material, a plate member is bent by 90 degrees and a rubber elastic cushioning member is attached to the bent portions. And the shock absorbing member is sandwiched between the building structural members to be fixed to the other building structural member so as to bond the other building structural member to the one building structural member. The seismic reinforcing mechanism according to claim 1, wherein a curved protrusion is formed by bending an intermediate portion of the second reinforcing base material outward. The seismic reinforcing mechanism according to claim 1, wherein a bending protrusion having a flat surface is formed by bending the middle portion of the second reinforcing base material outwards several times. The seismic reinforcing mechanism according to any one of claims 1 to 3, wherein the plate is high tensile steel.