KR101329420B1 - Energy dissipation system of vertical slit shear wall - Google Patents

Abstract

The present invention provides a system for distributing energy by vertically forming a slit on wall in order to maximize earthquake control properties by forming a vibration control system in a core of a pillar type structure which is not a wall structure of an apartment house. The system for distributing the energy by vertically forming the slit on the wall forms an opening unit vertically penetrating the front surface of a concrete core wall of the apartment building and having a regular width. The system for distributing the energy by vertically forming the slit on the wall installs one or more vibration control devices for a safety lintel in the opening at every predetermined height and forms the slit having narrower gap in a vertical direction than the width of the opening unit on the rear surface of the core wall. A damping unit is installed in the slit and is composed on a slit shear wall.

Description

Energy dissipation system of vertical slit shear wall

The present invention relates to an energy dissipation system that is designed to dissipate vibration energy due to wind or earthquake, and in particular, it is possible to maximize the seismic control ability by constructing a vibration suppression system in the core of the column structure instead of the wall structure of the apartment house. To a wall vertical segmented energy dissipation system.

Existing multi-family houses have a wall structure, and have developed and applied an isolating type vibration damping device to improve seismic performance.

That is, in the case of a multi-family house with a wall structure, considering the fact that securing the variability of the plane is a very important factor in the damping design, it is suitable for heavy earthquake earthquake areas such as Korea, and it is economical and sufficient seismic effect that can achieve sufficient seismic effect (SF). ) Dampers have been developed. The friction damper is excellent in terms of energy dissipation efficiency, durability, and maintenance, and by installing the damper in the pulverizing beam position, the friction damper is integrated with surrounding shear walls (Coupling Effect) and has the advantage of showing the maximum performance.

As such, the wall structure that bears the seismic load and the gravity load at the same time can be applied to the damping device in the pulley beam.

However, when constructing a multi-family house with a ramen structure that can be easily remodeled, it is difficult to apply a room-type vibration damping device. Therefore, the slit shear wall is required to apply the pulsation damping device to the core of the ramen type apartment house and maximize the effect.

As a background technology of the present invention, Korean Laid-Open Patent Publication No. 10-2011-0041079, comprising: In a flue gas increased shear wall system; A buried part having one side embedded in the shear wall and the other side buried in the plinth, a slit damper main body connected to the buried part and buried in the plinth and made of I-shaped steel or H-shaped steel, and both ends of the slit damper main body The present invention proposes a ductile increased shear wall system comprising a slit damper joint connected to each other. Therefore, when a lateral load of more than the design load is applied, the slit damper joint absorbs energy to prevent concentration of damage to a specific layer, and prevents damage at the coupling beam and shear wall joint, as well as reduction and reinforcement of the cross section of the coupling beam. Cost reduction by reducing the amount of abs.

However, the background art is advantageous to the wall structure in which the entire wall bears the support load, but there is a problem that the core wall is difficult to apply to the columnar structure in which most of the support load is dedicated.

Korea Patent Registration No. 10-1150237 Korea Patent Registration No. 10-0952232

It is an object of the present invention to provide a wall vertical segmented energy dissipation system configured to maximize the seismic control ability by configuring the vibration suppression system in the core of the column structure, not the wall structure of the apartment house.

Wall vertical segmented energy dissipation system according to a preferred embodiment of the present invention,

An opening is formed in the front surface of the concrete core wall wall of the multi-family house with a certain width and penetrates in the vertical direction. Forming a slit having a gap relatively narrower than the width of the slit, characterized in that the construction was synthesized by the slit shear wall through the damping means via the slit.

In addition, the two sides of the damping means is characterized in that the steel plate which is provided with a plurality of stud bolts on each side is bonded.

In addition, the cross-sectional shape of the slit shear wall is characterized in that any one of the complete separation type, reinforcing bar separation type, reinforcing bar connection type.

In addition, the pulverization damping device is characterized in that any one of the bending yield type friction damper using the tension of the friction pad and bolt, the shear yielding steel damper using the shear plastic deformation of the steel, viscoelastic damper, viscous damper.

In addition, the damping means,

A steel plate having a plurality of stud bolts installed on opposite sides of the slit wall, and a plurality of stud bolts disposed on the rear surface thereof; An inner vertical plate disposed at right angles to the front surface of the steel sheet and interposed between the outer vertical plates and having a plurality of long holes, and interposed between the outer vertical plates and the inner vertical plates, It includes a fastening bolt for forcing the stainless steel plate and the pad to be in close contact with each other by inserting the outer vertical plate and the stainless steel plate, the fastening bolt can be moved in the long hole formed up and down at the same position of the inner vertical plate and the stainless steel sheet during the damping operation It is characterized in that configured to.

In addition, the damping means,

Steel plates that are installed opposite to each other on the slit wall and are provided with a plurality of stud bolts on their back surfaces, an inner vertical plate disposed at right angles to the front surface of one steel plate, and disposed at right angles to the other steel plate front surface, It characterized in that it comprises an outer vertical plate having a plurality of bridges continuously connected along the side to the end of the straight plate, and a fastening bolt for forcibly close the bridge to the inner vertical plate.

According to the wall vertical segmented energy dissipation system of the present invention, after forming the front and rear shear walls having an opening in the front wall of the core wall and the slit in the rear wall, the pneumatic guard damping device and the damping means are respectively installed in the opening and the slit. In the event of wind load or earthquake, the core wall of the apartment house behaves in parallel to dissipate the vibration energy by the friction or hysteresis characteristics of the damping means and the vibration energy by the viscoelastic deformation of the damping means.

Therefore, the present invention is not a wall structure in which all the walls in the generation of the multi-family house bear the earthquake load and the gravity load at the same time according to the stiffness, the earthquake load is all or most of the core, and the non-core frame is the ramen frame supporting only the gravity load. Applicable to the structure.

In addition, the vibration suppression apparatus of the present invention can maximize the efficiency of seismic control capability by intensively arranged around the core as well as the core.

The following drawings, which are attached in this specification, illustrate the preferred embodiments of the present invention, and together with the detailed description thereof, serve to further understand the technical spirit of the present invention. It should not be construed as limited.
1 is a schematic construction state of the wall vertical segmented energy dissipation system according to the present invention.
FIG. 2 is a view of the core wall of FIG. 1 from another angle. FIG.
Figure 3 is a plan view of Figure 2;
4 is a front view and a partially enlarged view showing a state in which the steel sheet is bonded to the damping means applied to the present invention.
Figure 5 is a plan view showing a core portion to which the wall vertical segmented energy dissipation system according to the present invention is applied.
6 is a graph showing the hysteresis curve of the damping means.
7 is a cross-sectional view of various slit shear walls to which the wall vertical segmented energy dissipation system of the present invention is applied;
8A and 8B are front views and cross-sectional views taken along line AA as a state diagram of a bending yield type friction damper;
9A is a perspective view of a shear yielding steel damper;
9B and 9C are front views and top views of the installation state of FIG. 9A.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto.

In the wall vertical segmented energy dissipation system according to the present invention, a ramen core wall 20 is columnarly constructed on the enlarged base 10 as in FIGS. 1 to 3. For example, the core wall 20 may be configured in the elevator core portion 2 of the columnar apartment 1 as shown in FIG. The core wall 20 is made of reinforced concrete.

In the core wall 20, an opening 210 having a predetermined width and penetrating in the vertical direction is formed on the front wall 21, and one or more pulverizing damping devices 30 are installed in the opening 210 at predetermined heights. do. In this embodiment, a room-proof vibration suppression apparatus is installed on each floor, and the installation position thereof may be an upper side-portion guard at the entrance of the elevator.

The pulverization damping device is a known device. For example, a bending yield damper (SF) damper that dissipates seismic energy into friction energy by using tension of a friction pad and a bolt, and shear using plastic shear deformation of steel. Stable steel damper (SS) damper, viscoelasticity (GSF) damper using energy-absorbing capacity of speed-dependent viscous materials, viscosity using response-reducing ability due to vibration acting on impact load using speed-dependent viscous fluid It can be any of the (coupling) dampers.

The slits 220 having a gap t relatively narrower than the width of the opening 210 in the vertical direction are formed in the rear wall 22 of the core wall 20, and the damping means 40 is interposed in the slits 220. And synthesized in the slit shear wall. The damping means 40 may be, for example, a high damping rubber in the form of a band having a thickness corresponding to the slit 220 and a length corresponding to the height of the core wall 20. The high damping rubber has a hysteresis curve as shown in FIG. 6 to absorb and dissipate vibration energy by viscoelastic deformation. In this case, as shown in FIG. 4, steel sheets 42 and 42 having a plurality of stud bolts 421 installed on both surfaces of the high damping rubber may be joined to the slit wall. Therefore, the high damping rubber is integrated with the steel sheets 42 and 42 to form an integrated body.

Accordingly, the core wall 20 is in a state where the walls of the slit 220 are synthesized through the high damping rubber.

As another example of the damping means 40, as illustrated in FIGS. 8A and 8B, the steel plates 80a and 80b are disposed on the wall surfaces of the slits 220 so as to face each other and are provided with a plurality of stud bolts on the rear surfaces thereof. A pair of outer vertical plates 81 and 81 that are disposed at right angles to the front surface of the steel sheet 80a and are integrated at regular intervals, and are disposed at a right angle to the front surface of the other steel sheet 80b to form an outer vertical plate ( Stainless steel interposed between the inner vertical plate 82 inserted between the 81 and 81 and having a plurality of long holes, and the outer vertical plate 81 and the inner vertical plate 82; Fastening bolts 85 for forcibly adhering the stainless steel plate 83 and the pad 84 to each other by inserting the steel plate 83 and the pad 84, the inner and outer vertical plates 82, 81, and the stainless steel plate 83. ), And the fastening bolts 85 are formed at the same position of the inner vertical plate 82 and the stainless steel plate 83 during the damping operation. In the long hole (82a, 83a) that can be configured to allow for movement. The fastening bolt 85 is tightened with the nut to generate a forced adhesion between the stainless steel plate 83 and the pad 84. Therefore, the damping means of FIG. 8 performs a damping role by dissipating the earthquake load with friction energy according to the relative movement of the stainless steel plate 83 and the pad 84 during a wind load or an earthquake.

As another example of the damping means 40, as shown in Figs. 9a to 9c, the steel plates 90a and 90b which are installed to face each other on the wall surface of the slit 220 and are provided with a plurality of stud bolts on the rear surfaces thereof, The inner vertical plate 92 disposed at right angles to the front surface of one steel plate 90a, and the inner vertical plate 92 disposed at right angles to the front surface of the other steel plate 90b, and are continuously connected to the end portions of the inner vertical plate 92 along the side surface. The outer vertical plates 91 and 91 each having a plurality of bridges 91a and a fastening bolt 95 for forcibly bringing the bridge 91a into close contact with the inner vertical plate 92 may be included. The fastening bolt 95 is fixed by being tightened with a nut. Accordingly, the damping means of FIG. 9 performs a damping role by dissipating the earthquake load through plastic deformation of the bridge 91a when the wind load or the earthquake occurs.

The cross-sectional shape of the slit shear wall may be any one of a fully separated type, a separated steel type, and a reinforcing bar type type, as shown in (a), (b) and (c) of FIG. 7. In this case, when there is no horizontal reinforcing bar and concrete in the slit section, it is divided into a completely separate type as shown in (A), and when there is a horizontal reinforcing bar 23 in the slit section, (c) ) Are divided into rebar separation type.

As described above, since the pulverization-type vibration suppression apparatus 30 and the damping means 40 are installed on the core wall 20, the common house performs vibration suppression on the core wall 20 when a wind load or an earthquake occurs.

Therefore, the present invention is not a wall structure in which all the walls in the generation of the multi-family house bear the earthquake load and the gravity load at the same time according to the stiffness, the earthquake load is all or most of the core, and the non-core frame is the ramen frame supporting only the gravity load. Applicable to the structure.

At this time, the vibration damping apparatus of the present invention can maximize the efficiency of seismic control capability by intensively arranged around the core as well as the core.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the above teachings. will be. The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

20: core wall
210: opening
220: slit
30: Pulsating damping device
40: damping means
42: steel sheet
421 stud bolt

Claims (7)

An opening 210 having a predetermined width and penetrating in the vertical direction is formed in the front surface 21 of the concrete core wall 20 of the multi-family house, and the opening 210 has one or more pulverization type vibration suppressing devices 30 at predetermined heights. ) And a slit 220 having a gap relatively narrower than the width of the opening 210 in the direction perpendicular to the core wall 20, the wall rear surface 22 thereof, and damping means (S) in the slit 220. 40) Wall vertical segmental energy dissipation system, characterized in that the construction was synthesized to the slit shear wall via. The method of claim 1,
Wall vertical segmental energy dissipation system, characterized in that the two sides of the damping means (40) are joined to each of the steel plates (42, 42) are provided with a number of stud bolts (421) on each side. The method of claim 1,
A vertical wall segmental energy dissipation system, characterized in that the cross-sectional shape of the slit shear wall is any one of a fully separated type, a separated steel type, and a reinforcing bar type. The method of claim 1,
The pulverization damping device 30 is a flexural yield type friction (SF) damper using the tension of the friction pad and the bolt, a shear yielding steel damper using the shear plastic deformation of the steel, and a viscoelastic (GSF) Wall vertical segmental energy dissipation system, characterized in that any one of a damper, a viscous damper. The method of claim 1,
And the damping means is a high damping rubber. The method of claim 1,
Damping means 40,
Steel plates 80a and 80b, which are installed to face each other on the wall surface of the slit 220 and are provided with a plurality of stud bolts, respectively, are disposed at right angles on the front surface of any one steel plate 80a, and are integrated at regular intervals. A plurality of long vertical holes are inserted between the pair of outer vertical plates 81 and 81 and the front plates of the other steel plate 80b at right angles and inserted between the outer vertical plates 81 and 81. Inner vertical plate 82, stainless steel plate 83 and pad 84 interposed between outer vertical plate 81, 81 and inner vertical plate 82, and inner and outer vertical plates 82 (81) and the stainless steel sheet (83) by inserting a bolt (85) for forcibly contacting the stainless steel sheet (83) and the pad (84) mutually, the fastening bolt 85 is the inner vertical plate during the damping operation Even if it is possible to move in the long holes (82a, 83a) formed vertically long at the same position of the 82 and the stainless steel sheet (83) Wall vertical segmented energy dissipation system, characterized in that it is configured. The method of claim 1,
Damping means 40,
Steel plates 90a and 90b, which are installed to face the slits 220 and face each other and are provided with a plurality of stud bolts on their rear surfaces, and an inner vertical plate 92 disposed perpendicular to the front surface of any one of the steel plates 90a. ) And outer vertical plates 91 and 91 each having a plurality of bridges 91a disposed at right angles to the front surface of another steel plate 90b and continuously connected to the ends of the inner vertical plates 92 along the sides thereof. And a fastening bolt (95) for forcibly bringing the bridge (91a) into close contact with the inner vertical plate (92).

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