JPH10220063A - Earthquake resistant wall - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an earthquake resistant wall wherein cost increase factors are suppressed while securing the same performance as that before division by dividing steel earthquake resistant element into upper and lower blocks and providing spaces between the opposing end parts of both blocks. SOLUTION: A shearing force applied on a wall at the time of earthquakes is transmitted to an earthquake resistant wall 11 separated into upper and lower parts by upper and lower blocks 12a and 12b by opposing recessed and projecting parts, but its degree is decided by setting the number of long and short panels 13 and 14 and rigidity and a strength are freely adjusted. Also, by forming a space g1 between the upper and lower blocks, no fixing load or loading weight of a building is not transmitted in a lower direction, no vertical direction force by stumbling moment at the time of earthquakes is transmitted and thus no reduction occurs in performance by the buckling of a local part or the entire wall. For this earthquake resistant wall 11, after pluralities of long and sort panels 13 and 14 are mutually connected by bolts, high rigidity and a strength are exerted as the integral upper and lower blocks 12a and 12b.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is installed in a main frame consisting of columns and upper and lower beams of a steel building or the like, and absorbs energy input to the structure during an earthquake as hysteretic energy due to plastic deformation. This is related to a shear wall for reducing plasticity and fatigue damage of a structure.

[0002]

2. Description of the Related Art Conventionally, as a seismic wall installed in a main frame of a steel building or the like to absorb energy input to the building as hysteresis energy and reduce plasticization and fatigue damage of the building, For example, JP-A-6-17557
There is an invention described in Japanese Patent Publication No. The present invention provides a steel yielding wall made of steel by joining (or overlapping) a high yield point steel sheet and a low yield point steel sheet side by side on the same vertical plane, and surrounding the steel wall with a steel frame composed of columns and beams. They are joined.

[0003]

In the above-described conventional earthquake-resistant wall, the performance can be generally achieved by appropriate design. However, in order to efficiently and effectively absorb energy during an earthquake. Has a structural problem and also has a problem that replacement or repair after damage is not assumed. In addition, because the structure around the earthquake-resistant wall is fixed to a steel frame, the manufacturing accuracy of the earthquake-resistant wall material (high yield point steel sheet and low yield point steel sheet) and the construction accuracy of the steel frame (main frame) are required. There is a problem that construction is extremely difficult.

In order to efficiently and effectively absorb energy during an earthquake, (1) to concentrate deformation of a building during an earthquake on a specific portion of a shear wall. (2) A seismic element that generates stable and large plastic deformation is disposed in the portion where the deformation is concentrated.

[0005] In addition, in order to easily perform replacement and repair work, (1) In a general building, an earthquake-resistant element must be large enough to be loaded into an elevator. (2) The size and weight allow removal, reattachment, and horizontal movement of the seismic element to be performed manually or by a simple machine (for example, a lifter). (3) Since the removal and re-installation of seismic elements are performed inside the building, avoid using gas or welding. And other requirements. This is the same at the time of construction at the beginning of installation.

In order to make the unit of the seismic element small and easy to attach and detach, for example, it is easy to conceive that the seismic element is divided into small parts and formed by bolting. Various measures are required to secure the same performance as before the split,
It is inevitable that the cost will increase significantly.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and has as its object to obtain a shear wall made of a steel earthquake-resistant element which has the same performance as before splitting and suppresses cost increase factors. Things.

[0008]

[Means for Solving the Problems]

(1) The earthquake-resistant wall according to the present invention is obtained by dividing a steel earthquake-resistant element constituting the earthquake-resistant wall into an upper block and a lower block, and providing a gap between opposing ends of the upper block and the lower block. is there.

(2) The earthquake-resistant wall according to the present invention is formed by dividing a steel earthquake-resistant element constituting an earthquake-resistant wall into an upper block and a lower block, and forming an uneven shape in which ends of the upper block and the lower block mesh with each other. And a gap is provided between the opposing ends.

(3) Each of the upper block and the lower block of the above-mentioned (1) or (2) is constructed by arranging a plurality of small unit elements in the horizontal direction, and the small units adjacent in the horizontal direction. Fixed elements.

(4) The small unit elements constituting the upper block and the lower block of the above (3) are constituted by a web and flanges provided on both side edges thereof, and the entire area of the web has a yield strength higher than that of ordinary steel. Constructed of low steel plate.

(5) The small unit elements constituting the upper block and the lower block of the above (3) are constituted by a web and flanges provided on both side edges thereof, and a part of the web has a lower yield strength than ordinary steel. An area was provided.

(6) Bending reinforcing members are provided on both sides of the upper block and the lower block (1) or (2).

[0014]

BEST MODE FOR CARRYING OUT THE INVENTION

Embodiment 1 FIG. 1 is a front view showing an example in which an earthquake-resistant wall according to Embodiment 1 of the present invention is installed in a main frame of a steel building. In the figure, 1 is a left and right steel column, 2a is a steel beam on the upper floor (upper beam),
Reference numeral 2b denotes a steel beam (lower beam) on the lower floor. The steel frame 1, the upper beam 2a and the lower beam 2b constitute a main frame 3.

Numeral 11 denotes an earthquake-resistant wall according to the present embodiment, which has a structure in which the steel earthquake-resistant element is divided into upper and lower parts. The upper block 12a constituting the upper earthquake-resistant wall has a long small unit element (hereinafter referred to as a long panel) 13 disposed in the center, and short small unit elements (hereinafter referred to as a short panel) 14 disposed on both sides thereof. The adjacent long panel 13 and short panel 14 are integrally connected by bolts, respectively, to form an inverted convex shape. Also, the lower block 12b constituting the lower earthquake-resistant wall
Has a short panel 14 disposed in the center, and long panels 13 disposed on both sides thereof.
Are integrally connected by bolts to form a concave shape.

Then, the upper block 12a and the lower block 1
2b is attached to the upper beam 2a and the lower beam 2b via the attachment member 21, respectively, and the boundary between the two is opposed to each other so that the convex portion and the concave portion are engaged with each other. A gap g1 of several cm (e.g., ₁ cm to 5 cm) is formed such that contact does not occur even if (deflection) occurs. In the present embodiment, each of the long panels 13 and each of the short panels 14 are formed to have the same length.
Plus a gap g ₁ on the length of the long panel 13 and minor panel 14 is set to be the total height of the shear wall 11.

FIG. 2 shows an example of the long panel 13 and the short panel 14. Each of the panels 13 and 14 is formed in an H-shaped cross section, and a steel plate having a lower yield strength than that of ordinary steel is used for the web 15, and flanges 16 made of ordinary steel are welded to both side edges thereof. The web 15 is formed to have a width W that does not require a stiffener for preventing local buckling, and the width W is equal to the thickness t of the web 15 (for example, 6 mm).
２２22 mm) is set to about 30 to 100 times.

One end of the web 15 protrudes from the flange 16 and is provided with a plurality of bolt insertion holes 17 at that portion. The flange 16 has a plurality of bolt insertion holes 18 on both sides of the web 15. Is provided. On the other end side of the flange 16 of the long panel 13 (the side facing the short panel 14), a plurality of long holes 19 are provided in parallel with the longitudinal direction of the flange 16, respectively. Instead of directly providing the bolt insertion hole 17 in the web 15, an end plate may be attached to the web 15 and the bolt insertion hole may be provided in this.

As shown in FIG. 3 (a), the mounting member 21 includes a T-shaped member 22 comprising a web 23 and a flange 24, which serve as a fixing portion of the web 15 of the long panel 13 and the short panel 14, and a web 23, The web 23 and the plate 25 are provided with a plurality of bolt insertion holes 26, 2 respectively.
7 are provided. FIG. 3B shows another example of the mounting member, in which the plate 25 is joined to the other end of the web 23 and the flange 24 of the mounting member 21 to form the mounting member 21a. . The flange 24
H-shaped steel (see 30 in FIG. 5) instead of
And the plate 25 may be directly attached to this H-beam.

Next, an example of the construction in the case where the earthquake-resistant wall 11 is installed in the main frame 3 of the steel structure by the above-described long panel 13, short panel 14, and the mounting members 21 and 21a will be described. First, the flanges 24 of the mounting members 21 corresponding to the numbers of the long panels 13 and the short panels 14 of the upper and lower blocks 12a and 12b are provided on the lower surface of the upper beam 2a and the upper surface of the lower beam 2b in the main frame 3. They are opposed to each other and fixed to the upper beam 2a and the lower beam 2b by welding or bolting. Note that at this time, one end is
The mounting member 21a shown in FIG.

Next, the plate 2 of the central attaching member 21 in which the end of the web 15 of the long panel 13 is attached to the upper beam 2a.
5 through the bolt insertion hole 17 and the mounting member 2
A bolt is inserted through the bolt insertion hole 26 of the web 23,
Fix it. Further, the ends of the web 15 of the short panel 14 are inserted between the plates 25 of the mounting members 21 and 21a on both sides, and similarly fixed with bolts. In addition, although the long and short panels 13 and 14 and the attachment members 21 and 21a are joined in a single-shear manner in FIG. 1, they may be joined in a two-shear manner.

Similarly, the long panel 13 and the short panel 1
4 is bolted to the mounting members 21 and 21a mounted on the lower beam 2b. At this time, the upper block 12a and the lower block 1
2b between the adjacent long and short panels 13 and 14, and between the long panels 13 of the upper and lower blocks 12a and 12b,
Gap g ₂ corresponding to the thickness of the plate 25 of the mounting member 21,21a is formed, also, the upper and lower blocks 12a,
Between each of the opposed long and short panels 13 and 14 of 12b,
Gap g ₁ is formed.

Next, a bolt insertion hole 18 provided in the flange 16 of each of the long and short panels 13 and 14 of the upper and lower blocks 12a and 12b and a bolt insertion hole 27 provided in the plate 25 of the mounting members 21 and 21b respectively. Bolts are inserted and fixed, and bolts are inserted into bolt insertion holes 18 provided in the flanges 16 of the adjacent long and short panels 13 and 14, respectively, and fixed. At this time, the adjacent long, the gap g ₂ formed between the short panel 13, may be inserted liner 29. Thereby, the upper block 12a
And the lower block 12b.

[0024] At this time, the upper block 12a and lower block 12b via a gap g ₁ are opposed in a state of meshing uneven, also, of the blocks 12a, long panel 13 is a convex portion of 12b flange 16 is opposed via a gap g _2. As shown in FIG. 4, a bolt 20 is inserted through the long hole 19 provided in the flange 16 of the adjacent long panel 13, and the two are movably connected in the vertical direction.

As a result, the upper block 12a and the lower block 12b are integrally connected to each other to form the upper beam 2a and the lower beam 2a.
b, and both blocks 12a, 12b are movably connected in the vertical direction, and the installation of the earthquake-resistant wall 11 in the main frame 3 is completed.

When a large earthquake or the like occurs, the earthquake-resistant wall 11 configured as described above yields the web 15 of each of the long and short panels 13 and 14 having a low yield strength before yielding before a frame such as a steel building. By absorbing the hysteresis energy, plasticization and fatigue damage of the main frame 3 can be reduced to maintain a healthy state. Hereinafter, the operation and effect of the present embodiment will be described in more detail.

(1) With respect to the shearing force acting on the wall during an earthquake, the shearing force is transmitted to the earthquake-resistant wall 11 vertically separated by the upper block 12a and the lower block 12b by the concavo-convex portions facing each other. Is long and short panel 1
Since it can be determined by setting the number of 3, 14, the rigidity and strength can be freely adjusted.

(2) Upper block 12a and lower block 12
b and gap g ₁ is formed between the, Therefore,
Since the fixed load and the loaded load of the building are not transmitted downward and the vertical force due to the overturning moment during the earthquake is not transmitted, the performance is not degraded due to buckling of the local area or the entire wall.

(3) Since the plurality of long and short panels 13 and 14 (small unit elements) are bolted to each other, the earthquake-resistant wall 11 has high rigidity as an integrated upper block 12a and lower block 12b after the bonding. And strength. (4) The width of each of the long and short panels 13 and 14 is set so as not to cause local buckling (shows a stable history even if local buckling occurs). Edge flange 1
6 has a buckling reinforcing function at the same time as the purpose for bolt connection, so that it is not necessary to separately provide a stiffener.

[0030] (5) for shear walls 11 is divided into two upper and lower, and a structure in which a gap g ₁ between its upper and lower,
Even if the inner walls of the upper and lower beams 2a and 2b do not have exactly the same or exact dimensions, the earthquake-resistant wall 11 can be constructed.
For this reason, since there is no problem even if the construction accuracy is low, the construction is easy.

(6) Since the long and short panels 13 and 14 are all bolted and are relatively lightweight small unit elements, even if they undergo large plastic deformation due to a large earthquake, they can be used in a building. Easily removed by human power or simple tools,
And can be moved.

(7) A conventional method in which the entire wall is composed of a single steel seismic element and the stiffener is attached vertically and horizontally and the periphery is joined to columns and beams, or the earthquake-resistant wall is divided into small units and mutually connected Compared with the bolting method, the former is simpler in reinforcement and the like, and the latter requires fewer joints, and in any case, the manufacturing cost can be reduced. (8) Due to the simplicity of the above (5) and (6), installation, replacement and repair costs can be significantly reduced.

(Example) In the first embodiment,
Yield point of about 70~150 ^N / mm ^2, 60cm width
A flange 16 made of a common steel plate was welded to both edges of a web 15 made of a steel plate having a length of 150 cm to form a long panel 13 and a short panel 14 having a length of 100 cm.
The long panel 13 is located at the center and the short panels 1
4 and attached to the mounting members 21 and 21a, the adjacent flange 16 and the flanges 16 at both ends and the mounting member 2
The upper block 12a was formed by integrally joining the plates 25 of the base plates 1 and 21a with bolts, and the lower block 12b was similarly formed by disposing the short panel 14 at the center and the long panel 13 on both sides. At this time, the upper block 12a and the lower block 12b which are opposed to each other so as to mesh with each other in an uneven state.
Between the, gaps g ₁ of 3.0cm it was formed.

Embodiment 2 FIG. 5 is a front view of Embodiment 2 of the present invention. The same or corresponding parts as in the first embodiment are denoted by the same reference numerals,
Description is omitted. In the present embodiment, a long panel 13 is provided at the center of the upper block 12a constituting the earthquake-resistant wall 11, and a short panel 14 is provided at the center of the lower block 12b opposed thereto. The panels arranged on both sides of the panel 14 were constituted by panels 13a of the same length (hereinafter referred to as a panel in the description).

The lower wall of the upper beam 2a and the upper surface of the lower beam 2b have the same strength as the upper beam 2a and the lower beam 2b,
A block-shaped waist wall member 30 made of an H-section steel having a length substantially equal to the width of the upper block 12a is attached to the waist wall member 30 via mounting members 21 and 21a. And a lower block 12b. In the present embodiment, so that a gap g ₁ is added to the sum of the length of the long panel 13 and minor panel 14, and further plus the thickness of the spandrel wall member 30 is the overall height of the shear wall 11 Is set to

The present embodiment constructed as described above can provide substantially the same functions and effects as those of the first embodiment. However, the upper and lower waist wall members 30 are provided to provide a relatively rigid region. As a result, the bending moment and the shearing force acting vertically during an earthquake can be concentrated on the central portion of the earthquake-resistant wall 11. In addition, since the waist wall member 30 is provided, the length of the earthquake-resistant wall 11 in the vertical direction can be shortened by that amount.
The material cost of a relatively expensive steel plate having a low yield strength that constitutes the 3a and the short panel 14 can be reduced. The waist wall member 30 can also be provided in the first embodiment.

Third Embodiment FIG. 6 is a front view of a third embodiment of the present invention. The same or corresponding parts as those in the first and second embodiments are denoted by the same reference numerals, and description thereof will be omitted. In the present embodiment, the long panels 13 and the short panels 14 having the same length are alternately arranged so that
The upper block 12a and the lower block 12b composed of the small unit elements are configured.

Further, a bending reinforcing member 31 made of steel or H-shaped steel having substantially the same strength as the waist wall member 30 is connected to the waist wall member 31.
And the upper beam 2a and the lower beam 2b are joined by welding or the like, and are bolted and integrated with the flanges 16 of the long panel 13 and the short panel 14 arranged on both sides of the upper block 12a and the lower block 12b. Things.

In this case, as shown in FIG.
The left and right sides of the upper panel 12 are extended, the ends of the bending reinforcing members 31 are joined to the extended sections by welding or the like, and the flanges 16 of the long panel 13 and the short panel 14 provided on both sides of the upper block 12a and the lower block 12b You may integrate by joining a bottle.

A bending moment and a shearing force act on the upper and lower sides of the earthquake-resistant wall and a shearing force mainly acts on the central portion due to a shearing force due to an earthquake or the like.
Upper and lower waist wall members 30 and upper and lower blocks 12a,
Bending reinforcing members 31 are arranged on both sides of 12b to form a region having high rigidity, and an earthquake-resistant wall 11 as an element for absorbing seismic energy is arranged in an intermediate portion, and an upper block 12a
And the lower block 12b are configured to transmit only the shearing force, so that the shearing force acting on the earthquake-resistant wall 11 becomes dominant, and the shear deformation can be concentrated.

Fourth Embodiment In the first to third embodiments, the upper block 1 of the earthquake-resistant wall 11 is used.
A long panel 13, a middle panel 13a and a short panel 14, which are small unit elements constituting the lower block 2a and the lower block 12b, are provided with flanges 16 made of ordinary steel on both side edges of a web 15 made of a steel plate having a lower yield strength than ordinary steel. Although the case of joining is shown, in the present embodiment, the long panel 13, the middle panel 13a, and the short panel 14 are configured as follows.

FIG. 8A shows the long panel 13 and the middle panel 13.
FIG. 2A is a plan view of a short panel 14 (hereinafter, these are collectively referred to as small unit elements 13 in the description of the present embodiment). In this example, the small unit element 13 is roll H
The web 15 is provided with an opening 35 at one end (opposite side) of the web 15 at an end thereof, and the opening 35 has a yield strength lower than the yield strength of the rolled steel, for example, a roll H-shaped steel. A steel sheet having a lower yield point (hereinafter referred to as a low yield strength steel sheet) 36 is joined. Such a low yield strength steel sheet 36 is obtained by butt welding as shown in (a) of FIG. 8B, single-sided fillet welding as shown in (b) and (d), and as shown in (c). Is joined to the opening 35 of the web 15 by double-sided fillet welding or the like.

FIG. 9A shows a window-shaped opening 3 at one end of a web 15 of a small unit element 13 made of a rolled H-section steel.
5a, and a low yield strength steel plate 36 is joined to the opening 35a as described above.

In the example shown in FIG. 9B, a plurality of window-shaped openings 37 are provided at one end of the small unit element 13 made of rolled H-section steel, whereby the yield strength is provided at the end of the small unit element 13. Is formed.

In the example shown in FIG. 9C, small units 13 are formed by joining flanges 16 made of ordinary steel to both side edges of a web 15 made of ordinary steel, and open at one end of the web 15 to the end. An opening 35 is provided, and a low yield strength steel plate 36 is joined to the opening 35 as described above.

Although the embodiment of the small unit element 13 according to the present invention has been described above, the small unit element 13 according to the present invention is described.
The present invention is not limited to this, and has a structure in which at least a part has a low yield strength, and in the event of an earthquake, seismic energy can be concentrated near the vertical center of the earthquake-resistant wall 11 and subjected to shear deformation. Should be fine. Note that a stiffener may be provided on one end side (opposing portion side) of the small unit element 13 as necessary.

Fifth Embodiment FIG. 10 is a front view of a fifth embodiment of the present invention. Note that the same or corresponding parts as those in the first to third embodiments are denoted by the same reference numerals, and description thereof will be omitted. 11 is an earthquake-resistant wall, and the upper block 1
2a and a lower block 12b.
Is a convex-shaped web 40a made of a low-yield strength steel plate having a convex portion 41a at the center and concave portions 42a formed on both sides thereof, and a flange 16 made of ordinary steel joined to both side edges thereof. And is constituted by.

The lower block 12b has a concave portion 4 in the center.
2b, a web 40b made of a single low-yield strength steel plate having a concave shape and provided with convex portions 41b on both sides thereof, and a flange 16 made of ordinary steel joined to both side edges thereof. I have.

In this embodiment having the above-described earthquake-resistant wall 11, the web 40a of the upper block 12a is bolted to the web 23 of the mounting member 21a mounted on the upper beam 2a, and the flange 16 is connected to the mounting member 21a. It is bolted to the plate 25. Similarly, the lower block 12
b is bolted to the mounting member 21a. At this time, the protrusions 41a, 41b of the upper block 12a and the lower block 12b
The recesses 42a, 42b are opposed in a state of meshing with each other, in the vertical direction of both the gap g ₁ is formed, also, between the protrusions 41a and 41b, gap g ₂ is formed with .

Numeral 43 designates two patch plates each having an elongated hole 44. The patch plates 43 are provided for the upper and lower blocks 12a, 12b.
, Respectively, and one side thereof is joined to, for example, the projection 41a by welding or the like.
Then, a bolt is inserted from the elongated hole 44 into a bolt insertion hole (not shown) provided in the convex portion 41b, and the upper and lower blocks 12 are inserted.
a and 12b are connected so as to be movable in the vertical direction, and are prevented from moving in a direction perpendicular to the wall surfaces of the projections 41a and 41b. In addition, this connection means is not limited to this, and other means may be used,
Further, this connecting means may be provided between the opposed convex portions 41a, 41b and concave portions 42a, 42b.

In the present embodiment configured as described above, substantially the same effects as those in the first embodiment can be obtained. Also in this embodiment, the waist wall member 30 may be provided as in the case of the second embodiment, and the waist wall member 30 and the bending reinforcing member 3 may be provided as in the case of the third embodiment.
1 may be provided. Furthermore, as shown in Embodiment 4, the upper block 12a and the lower block 12b may be made of a normal steel plate, and a part thereof may be provided with a region having a low yield strength. In the present embodiment, the upper and lower blocks 12a, 1
Since each of the flanges 40a and 40b of 2b is made of one low yield strength steel plate, one or more stiffeners may be provided.

Embodiment 6 FIG. 11 is a front view of Embodiment 6 of the present invention. Note that the same or corresponding parts as those in the first to third embodiments are denoted by the same reference numerals, and description thereof will be omitted. 11 is an earthquake-resistant wall, and the upper block 1
2a and a lower block 12b. 45 is a small unit element constituting the upper and lower blocks 12a and 12b. One end of the web 46 is formed of a steel plate having a lower yield strength than ordinary steel formed in an uneven shape by a convex portion 47 and a concave portion 48. And a flange 16 made of joined ordinary steel.

The small unit element 45 configured as described above is
Attachment members 21 and 21 that attach the web 46 to the upper beam 2a
1a, and the flange 16 is bolted to the plate 25 of the mounting members 21 and 21a.
Are joined together by bolts to form the upper block 12a. Similarly, the lower block 12
b.

[0054] At this time, the convex portion 47 and concave portion 48 of the upper block 12a and lower block 12b is opposed in a state of meshing with each other, a gap g ₁ is formed in the vertical direction of both also adjacent between the flanges 16 of the projections 47, gap g ₂ is formed. In this state, a bolt is inserted into a long hole provided in the flange 16 of the convex portion 47, and the two are movably connected in the vertical direction. As described in the fifth embodiment, the space between the webs 46 of the upper and lower small unit elements 45 is
Both may be connected so as to be movable in the vertical direction by connecting means such as the contact plate 43.

In the present embodiment configured as described above, substantially the same operation and effect as in the first embodiment can be obtained. In this embodiment, the waist wall member 30 may be provided as in the case of the second embodiment, or the waist wall member 30 and the bending reinforcing member 31 may be provided as in the third embodiment. Further, the small unit elements 45 constituting the upper block 12a and the lower block 12b are made of a normal steel plate,
A configuration as shown in the fourth embodiment may be adopted, for example, by providing a region having a low yield strength in a part thereof. In addition, each small unit element 4
5 may be provided with a stiffener at the end.

[0056]

【The invention's effect】

(1) In the earthquake-resistant wall according to the present invention, the steel earthquake-resistant element constituting the earthquake-resistant wall is divided into an upper block and a lower block, and a gap is provided between opposing ends of the upper block and the lower block. Since the fixed load and the loaded load of the object are not transmitted downward and the vertical force due to the overturning moment at the time of the earthquake is not transmitted, the performance is not degraded due to buckling of the local area or the entire wall. Further, it is possible to prevent a large concentrated load from acting on the lower beam.

The earthquake-resistant wall is divided into upper and lower parts, and
Since the structure has a gap between the upper and lower portions, it can be constructed even if the earthquake-resistant wall does not have exactly the same or exact dimensions as the inner spacing between the upper beam and the lower beam. For this reason, there is no problem even if the construction accuracy is low, and the construction is easy. Furthermore, compared to a conventional earthquake-resistant wall in which the entire wall is made of steel seismic elements, and stiffeners are attached vertically and horizontally and the surroundings are joined to columns and beams, reinforcement and other features are simpler. Construction costs can be reduced.

(2) In the earthquake-resistant wall according to the present invention, the steel earthquake-resistant element constituting the earthquake-resistant wall is divided into an upper block and a lower block, and the edges of the upper block and the lower block are engaged with each other. Since the gap is provided between the opposed end portions, the effect of the above (1) is obtained, and the shear force at the time of the earthquake can be reliably transmitted by the uneven portions that mesh with each other.

(3) The upper block and the lower block of (1) or (2) are configured by arranging a plurality of small unit elements in the horizontal direction, and connecting the small unit elements adjacent in the horizontal direction to each other. Since it is fixed, it has the above-mentioned effects (1) and (2), and its rigidity and strength can be freely adjusted by appropriately setting the number of small unit elements. Also,
Since the upper and lower blocks are composed of a plurality of small unit elements arranged side by side, even if they undergo large plastic deformation due to a large earthquake, they can be removed and moved in the building by human power or simple tools. it can. For this reason, construction, replacement and repair are easy, and costs can be reduced.

(4) The small unit elements constituting the upper block and the lower block of (3) are constituted by the web and the flanges provided on both side edges thereof, and the entire area of the web has a lower yield strength than ordinary steel. Since it is made of a steel plate, the above-mentioned effect (3) can be obtained, and the upper block and the lower block can be integrally formed by bolting adjacent small unit elements via the flange, thereby achieving high rigidity. Strength is obtained. Also, when a large earthquake occurs, small unit elements with low yield strength yield before the frame of the steel building and absorb the hysteretic energy, so plastic columns and the upper and lower beams are subject to plasticization and fatigue damage. It can be reduced and maintained in a healthy state.

(5) The small unit elements constituting the upper block and the lower block in (3) above are constituted by the web and flanges provided on both side edges thereof, and a part of the web has a lower yield strength than ordinary steel. (3), (4)
The same effect as described above can be obtained.

(6) Since the bending reinforcing members are provided on both sides of the upper block and the lower block of the above (1) and (2), the effects of the above (1) and (2) can be obtained. The upper and lower and both sides of the block were regions of high rigidity. Thereby, the shearing force acting on the earthquake-resistant wall can be concentrated at the center.

[Brief description of the drawings]

FIG. 1 is a front view of a first embodiment of the present invention.

FIG. 2 is a perspective view of a small unit element of FIG. 1;

FIG. 3 is a perspective view of the mounting member of FIG. 1;

FIG. 4 is a perspective view of a main part of FIG. 1;

FIG. 5 is a front view of a second embodiment of the present invention.

FIG. 6 is a front view of a third embodiment of the present invention.

FIG. 7 is a front view of another example of the third embodiment.

FIG. 8 is an explanatory diagram of Embodiment 4 of the present invention.

FIG. 9 is a front view of a fourth embodiment of the present invention.

FIG. 10 is a front view of a fifth embodiment of the present invention.

FIG. 11 is a front view of a sixth embodiment of the present invention.

[Explanation of symbols]

 Reference Signs List 1 steel column 2a upper beam 2b lower beam 3 main frame 11 earthquake-resistant wall 12a upper block 12b lower block 13 long panel (small unit element) 13a middle panel (small unit element) 14 short panel (small unit element) 15, 40a, 40b , 46 web 16 flange 21, 21 a mounting member 30 waist wall member 31 bending reinforcing member 36 low yield strength steel plate 35, 35 a, 37 opening 41 a, 41 b, 47 convex 42 a, 42 b, 48 concave 43 plate

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Haruhito Okamoto 1-2-1, Marunouchi, Chiyoda-ku, Tokyo Nihon Kokan Co., Ltd. (72) Inventor Nobuyuki Nakamura 1-2-1, Marunouchi, Chiyoda-ku, Tokyo Sun (72) Inventor Minoru Hirota 1-2-2 Marunouchi, Chiyoda-ku, Tokyo Japan Tube Co., Ltd.

Claims (6)

[Claims] 1. An earthquake-resistant wall in a building, wherein a steel earthquake-resistant element constituting the earthquake-resistant wall is divided into an upper block and a lower block, and a gap is provided between opposing ends of the upper block and the lower block. An earthquake-resistant wall characterized by that. 2. An earthquake-resistant wall in a building, wherein a steel earthquake-resistant element constituting the earthquake-resistant wall is divided into an upper block and a lower block, and ends of the upper block and the lower block are formed in an uneven shape so as to mesh with each other. An earthquake-resistant wall characterized by having a gap between opposing ends. 3. An upper block and a lower block each comprising a plurality of small unit elements arranged side by side in the horizontal direction, and small unit elements adjacent in the horizontal direction being fixed. The earthquake-resistant wall described in 2. 4. The small unit element constituting the upper block and the lower block is constituted by a web and flanges provided on both side edges thereof, and the entire area of the web is constituted by a steel plate having a lower yield strength than ordinary steel. The earthquake-resistant wall according to claim 3, characterized in that: 5. The small unit element constituting the upper block and the lower block is constituted by a web and flanges provided on both side edges thereof, and a part of the web is provided with a region having a lower yield strength than ordinary steel. The earthquake-resistant wall according to claim 3, characterized in that: 6. A bending reinforcing member is provided on both sides of the upper block and the lower block.
Or the earthquake-resistant wall described in 2.