KR20110028478A - Slit plate hybrid damper and earthquake energy damping device using thereof - Google Patents

Abstract

PURPOSE: A hybrid damper for a slit plate and an earthquake energy damping device using the same are provided to semi-permanently use the damper by minimizing the influence by the change of season or climate. CONSTITUTION: A hybrid damper for a slit plate comprises a central slit plate(110), an intersection plate(120), a first flat plate(410), a second flat plate(420), a central load transmission plate(210), an outer load transmission plate(220), and a connection plate(230), and a third flat plate(430). Linear cut parts(11) are horizontally formed in the central slit plate. The intersection plate is coupled to the central slit plate. The bottom end of central load transmission plate is coupled to the top of the second flat plate. The outer load transmission plate is protruded from the top of the central load transmission plate. The third flat plate is coupled to the top end of the outer load transmission plate.

Description

Slit plate hybrid damper and earthquake reinforcing device using same

The present invention relates to a composite structure damper that absorbs and attenuates seismic energy step by step using frictional heat and the yield (deformation) of the slit steel sheet due to frictional motion, and a seismic reinforcing device using the same.

Recently, earthquakes that occur frequently in countries close to Korea have caused a lot of loss of lives and property. Fortunately, many years ago, earthquake-resistant reinforcement works have been actively conducted to secure the safety of existing facilities in the event of an earthquake.

As a seismic reinforcement technique of existing facilities, a vibration seismic reinforcement technique using a steel frame and a brace, a vibration reinforcement technique such as a viscous or oil damper, a slit steel damper, and a friction damper combined with a steel frame and a toggle are used.

(1) Earthquake-resistant reinforcement technology using steel frame and brace is mainly a technology to reinforce the strength of existing facilities, and the ability to control the displacement of the target structure during earthquake is insufficient, causing partial destruction of existing facilities. As a result, there is a risk of loss of life and property, there is a problem that creates a sense of unnecessary discomfort to users of the existing facilities because the aesthetics are rough.

(2) Viscous or oil dampers are mainly used in places where earthquakes occur frequently, such as Japan, and there is no need to replace the viscous or oil dampers even after an earthquake, and the strength of seismic energy (for example, strong, medium or weak). scale is a step-by-step response capacity is proportional to the earthquake) is relatively solid, but an expensive installation costs, may be the environment, excessive reinforcement, such as a country, especially viscous fluid, or a change in viscosity and oil and the viscosity of the oil due to seasonal temperature changes Maintenance work such as checking the loss of the liquid is required regularly, but since the viscous liquid or oil is contained in the sealed cylinder, such a check and maintenance work is difficult and a significant cost is generated .

(3) The friction damper does not need to replace the friction damper even after the earthquake occurs, and it has the ability to stably absorb and damp the seismic energy during the earthquake, and the installation cost is relatively low. There is no need to worry about, the friction damper itself is exposed to the outside installed and easy to check and maintenance work, and almost semi-permanent durability. However, these friction dampers do not generate frictional motion of the friction dampers until they reach the seismic energy intensity applied in the damper design, and remain almost in the elastic region. In the case of friction dampers designed for strong earthquake, Damping effect It does not occur, there is a problem that can lead to partial destruction phenomenon of the target facilities (structures).

(4) The slit steel damper has excellent ability to stably absorb and attenuate seismic energy during an earthquake, install cost is relatively low, and there is no need to worry about deterioration of energy absorption due to temperature change in four seasons. The steel damper itself is exposed to the outside and is easy to check and maintain, and has almost semi-permanent durability. However, the slit steel damper has a problem in that the slit steel damper needs to be replaced when the slit steel sheet is yielded due to seismic energy. In the case of slit steel dampers designed for strong earthquake, there is a problem that , in the event of weak earthquake, the absorption power of seismic energy is insignificant , leading to partial destruction of the target facility (structure) .

Technical problem of the present invention created to solve the above problems is as follows.

First, it is an object of the present invention to provide a semi-permanent seismic energy damper that can minimize the effects of seasonal or climate changes.

Second, another object of the present invention is to provide a damper for damping seismic energy, which is capable of stably absorbing and damping seismic energy by operating step by step according to the strength of seismic energy even when an earthquake with irregular intensity is generated.

Third, another object of the present invention is to provide a damper for damping new earthquake energy that does not require replacement of a damper even after an earthquake occurs.

Fourthly, another object of the present invention is to provide a damper for damping earthquake energy, which is inexpensive and has excellent molding beauty.

Technical composition of the present invention created to achieve the above object is as follows.

The present invention is a central slit plate 110 is formed with a plurality of straight cutout portion 11 in the horizontal direction; A cross plate 120 having a central portion integrally coupled to cross the center of the central slit plate 110 and having a lower end protruding downward from the central slit plate 110; A pair of central slit plate buckling prevention reinforcing plates (130) integrally coupled to both left and right end surfaces of the central slit plate (110); A pair of cross plate buckling prevention reinforcing plates 140 which are integrally coupled to both left and right end surfaces of the cross plate 120 and have a lower end protruding downward from the center slit plate 110; A first flat plate 410 integrally coupled to a lower end of the cross plate 120 and the cross plate buckling reinforcement plate 140; A second flat plate 420 integrally coupled to an upper end of the central slit plate 110 and the central slit plate buckling prevention reinforcing plate 130; A center load transfer plate 210 having a plurality of straight cutouts 11 formed in a vertical direction and having a lower end integrally coupled to an upper surface of the second flat plate 420; A plurality of bolt holes 22 are formed at positions corresponding to the linear cutouts 11 of the central load transfer plate 210, and closely contact the front and rear surfaces of the central load transfer plate 210 by bolts and nuts. A pair of external load transfer plates 220 protruding to an upper portion of the central load transfer plate 210; A pair of connecting plates 230 integrally coupled to both left and right end surfaces of the central load transfer plate 210 and having a lower end integrally coupled to an upper surface of the second flat plate 420; And a third flat plate 430 integrally coupled to an upper end of the pair of external load transfer plates 220 protruding to an upper portion of the central load transfer plate 210. Present steel composite damper.

In addition, the present invention the upper horizontal steel member 610 is installed in a horizontal direction; A lower horizontal steel member 620 spaced apart from the upper horizontal steel member 610 and installed side by side; A pair of vertical steel members 630 connecting both ends of the upper horizontal steel member 610 and the lower horizontal steel member 620 to each other; And the first toggle 510 at three of four inner four corners of a rectangular steel frame frame formed of the upper horizontal steel member 610, the lower horizontal steel member 620, and the pair of vertical steel member 630. ), The second toggle 520, and the toggle pin hole 44 provided at the other end of each of the third toggle 530, each of the slit steel composite damper 100 is coupled to the coupling pin 33; It proposes a seismic reinforcing device using the slit steel composite damper characterized in that the.

Technical effects of the configuration of the present invention are as follows.

First, it is possible to provide a semi-permanent seismic energy damper that can minimize the effects of seasonal and climate changes.

In other words, by using only the structure by mechanical bonding without using oil or viscous liquid, it is possible to ignore the effects of seasonal or climate change, and semi-permanent use.

Second, even if an earthquake with an irregular intensity occurs, it works step by step according to the strength of the seismic energy, so that stable seismic energy absorption and attenuation are possible.

In other words, when the earthquake load of the weak or medium magnitude scale acts, frictional motion occurs between the central load transfer plate 210 and the external load transfer plate 220 to absorb and attenuate the seismic energy, and the earthquake load of the magnitude of the earthquake scale. When this action occurs, the friction movement between the central load transfer plate 210 and the external load transfer plate 220 occurs first, and then the yield (deformation) of the central slit plate 110 occurs step by step to stabilize the seismic energy. Absorb and attenuate.

Third, the damper does not need to be replaced after the earthquake occurs.

In other words, the frictional movement between the center load plate and the external load transfer plate causes frictional heat to be absorbed and attenuated using the heat generated from the frictional load. It is prevented from being destroyed or deformed and can be reused only by retightening the bolts.

Fourth, it is possible to provide a damper for earthquake energy damping which is inexpensive and excellent in shaping.

1 is a specific embodiment of the present invention.
FIG. 2 is a perspective view and a side view showing a state of use of the specific embodiment shown in FIG.
3 is another specific embodiment of the present invention.
4 is a perspective view and a side view showing a state of use of the specific embodiment shown in FIG.
5 and 6 are specific embodiments of the seismic reinforcing device using the slit steel composite damper.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1, a specific embodiment of the present invention is shown.

The center slit plate 110 is a plate material in which a plurality of straight cut portions 11 are formed in a horizontal direction (width direction), and the straight cut portions 11 cut in the horizontal direction are arranged in two rows. It is not limited to the column array, and the specific type or arrangement of the incision can be changed.

The center portion of the cross plate 120 intersects to cross the center of the center slit plate 110 in the vertical direction, and the cross plate 120 and the center slit plate 110 are integrally coupled by a method such as welding.

The lower end of the cross plate 120 protrudes to the bottom of the center slit plate 110.

The pair of central slit plate buckling reinforcement plate 130 is integrally coupled to the left and right both end surfaces of the central slit plate 110, respectively, mainly a welding coupling method is used. The upper end of the central slit plate buckling reinforcement plate 130 and the upper end of the central slit plate 110 maintain the same height in a coupled state.

A pair of cross plate buckling reinforcement plate 140 is integrally coupled to the left and right both ends of the cross plate 120, respectively, the lower end of the cross plate buckling reinforcement plate 140 is the same as the lower end of the cross plate 120. Protrude to the bottom of the central slit plate 110 to maintain the same height. The coupling between the cross plate 120 and the cross plate buckling reinforcement plate 140 is also mainly used for the welding coupling method.

The first flat plate 410 is integrally coupled to the lower end of the cross plate 120 and the cross plate buckling reinforcement plate 140 by welding or the like.

The second flat plate 420 is integrally coupled to the upper end of the central slit plate 110 and the central slit plate buckling reinforcement plate 130 by welding or the like.

The central load transfer plate 210 has a plurality of straight cutouts 11 are formed in the vertical direction (length direction), and the lower end of the central load transfer plate 210 is welded to the upper surface of the second flat plate 420, or the like. It is combined integrally in a way.

The pair of external load transfer plates 220 are formed with a plurality of bolt holes 22 at positions corresponding to the straight cutouts 11 of the center load transfer plate 210, and the center load transfers by bolts and nuts. The front and rear surfaces of the plate 210 are in close contact with each other, and the upper end of the external load transfer plate 220 is coupled to protrude to the upper portion of the central load transfer plate 210.

The friction pads 240 are respectively installed between the central load transfer plate 210 and the external load transfer plate 220, and the friction pads 240 correspond to the straight cuts 11 formed on the central load transfer plate 210. A straight cut 11 is provided. The material of the friction pad 240 may be a general non-asbestos friction pad or a friction pad made of a metallic material.

The pair of connecting plates 230 are integrally coupled to the left and right both end surfaces of the central load transfer plate 210 by welding, or the like. The lower end of the connecting plate 230 is connected to the upper surface of the second flat plate 420. It is combined integrally by welding or the like.

The third flat plate 430 is integrally coupled to the upper ends of the pair of external load transfer plates 220 protruding to the upper portion of the central load transfer plate 210 by welding or the like.

2 is a perspective view and a side view showing a state of use of the specific embodiment shown in FIG.

When the earthquake load of the magnitude or the magnitude of the earthquake is applied, friction movement occurs between the central load transfer plate 210 and the external load transfer plate 220, and absorbs and damps seismic energy by frictional heat. No deformation occurs. If the seismic load of the magnitude of the magnitude of the earthquake is applied, first, the frictional movement between the central load transfer plate 210 and the external load transfer plate 220 occurs first, and then the yield (deformation) of the central slit plate 110 is stepwise. Occurs, stably absorbs and attenuates seismic energy. Because before the yield (deformation) of the central slit plate 110 occurs, the central load transfer plate 210 and the external load transfer so that friction movement occurs first between the central load transfer plate 210 and the external load transfer plate 220. This is because the fastening force between the plates 220 is adjusted.

3 shows another specific embodiment of the present invention.

Center slit plate 110, cross plate 120, center slit plate buckling reinforcement plate 130, cross plate buckling reinforcement plate 140, the first flat plate 410, the second flat plate 420 and the friction pad The coupling structure of 240 is the same as in the case of FIG.

The central load transfer plate 210 has a plurality of straight cutouts 11 formed in a vertical direction (length direction), and a connection pin hole 211 is provided at an upper end of the central load transfer plate 210.

The pair of external load transfer plates 220 are formed with a plurality of bolt holes 22 at positions corresponding to the straight cutouts 11 of the center load transfer plate 210, and the center load transfer plate by bolts and nuts. In close contact with each of the front and rear surfaces 210, the lower portion of the central load transfer plate 210 protrudes.

The lower end of the external load transfer plate 220 is integrally coupled to the upper surface of the second flat plate 420 by a welding method or the like.

4 is a perspective view and a side view showing a state of use of another specific embodiment of the present invention shown in FIG.

In the case of FIG. 4, as in FIG. 2, when the earthquake load of the weak or medium scale action is applied, frictional motion is generated between the central load transfer plate 210 and the external load transfer plate 220 while absorbing and damping seismic energy by frictional heat. And the deformation of the central slit plate 110 does not occur. If the seismic load of the magnitude of the magnitude of the earthquake is applied, first, the frictional movement between the central load transfer plate 210 and the external load transfer plate 220 occurs first, and then the yield (deformation) of the central slit plate 110 is stepwise. Occurs, stably absorbs and attenuates seismic energy.

5 or 6, the first toggle 510, the second toggle 520, and the third toggle 530 may be combined with each other.

The specific embodiment shown in FIG. 3 is mainly used together with the first toggle 510, the second toggle 520, and the third toggle 530 in this manner, but this is not necessarily the case. In the case of the embodiment is applied in the same manner as the specific embodiment shown in Figure 3 when integrally coupling the connecting member having a toggle pin hole or a connecting pin hole that can be rotatably coupled to the upper surface of the third flat plate 430 This is possible.

The first toggle 510 is a length member provided with a toggle pin hole 44 at both ends, and the second toggle 520 is a length member provided with a toggle pin hole 44 at both ends, and the first toggle 510 is provided. A toggle pin hole 44 provided at one end of the toggle pin hole 44 provided at one end of the second toggle 520 is pivotally coupled to the connection pin hole 211 of the central load transfer plate 210. 33).

One end of the third toggle 530 is integrally coupled to the lower surface of the first flat plate 410, and the toggle pin hole 44 is provided at the other end of the third toggle 530.

As such, when the first toggle 510, the second toggle 520, and the third toggle 530 are used together, the first toggle 510, the second toggle 520, and the third toggle 530 are easily installed in a rectangular steel frame as shown in FIG. It is possible to make a finished product.

5 and 6 show a specific embodiment of the seismic reinforcing device using the slit steel composite damper, it is possible to install a variety of forms not shown in the accompanying drawings.

The upper horizontal steel member 610 is installed in the horizontal direction serves as an upper frame.

The lower horizontal steel member 620 is spaced apart from the upper horizontal steel member 610 and installed side by side and serves as a lower frame.

The pair of vertical steel member 630 connects both ends of the upper horizontal steel member 610 and the lower horizontal steel member 620 and serves as a vertical frame.

The upper horizontal steel member 610, the lower horizontal steel member 620 and the vertical steel member 630 are integrally coupled by a method such as welding or bolt to form a rectangular frame.

5 is a case where one slit steel composite damper is used.

The seismic reinforcing apparatus shown in FIG. 5 includes a first horizontal steel member 610, a lower horizontal steel member 620, and a pair of four inner four corners of a rectangular steel frame edge formed of a pair of vertical steel members 630. The toggle pin hole 44 provided at the other end of each of the toggle 510, the second toggle 520, and the third toggle 530 is coupled to the coupling pin 33.

In the case of Figure 6 is a rectangular steel frame frame is stretched in the horizontal direction, the case where two slit steel composite dampers are used. The rectangular steel frame can be installed in a similar way even if it is long in the vertical direction.

The slit steel composite damper 1 (101) is any two of the four inner four corners of the rectangular steel frame edge consisting of the upper horizontal steel member 610, the lower horizontal steel member 620, and a pair of vertical steel member 630 and Toggle pin holes 44 provided at the other end of each of the first toggle 510, the second toggle 520, and the third toggle 530 inside the central portion of the upper horizontal steel member 610 are combined pins 33, respectively. Are combined.

The slit steel composite damper 2 (102) is the remaining two of the four inner four corners of the rectangular steel frame frame consisting of the upper horizontal steel member 610, the lower horizontal steel member 620, and a pair of vertical steel member 630 and Toggle pin holes 44 provided at the other end of each of the first toggle 510, the second toggle 520, and the third toggle 530 inside the central portion of the upper horizontal steel member 610 are combined pins 33. Are combined.

Although not separately illustrated in the accompanying drawings, if necessary, the toggle pin hole 44 may be coupled to the center portion of the lower horizontal steel member 620, unlike FIG. 6.

As such, when the slit steel composite damper is installed using the first toggle 510, the second toggle 520, and the third toggle 530 inside the rectangular steel frame, the upper horizontal steel member 610 when an earthquake occurs. The amount of movement of the point where the connection pin hole 211 is located is amplified in comparison with the lateral shaking of the slit, and the amplified movement is made to have stable absorption and attenuation through the slit steel composite damper. In this process, the slit steel composite damper is operated step by step according to the strength of the seismic load, as already discussed.

As described above, specific embodiments of the present invention have been described with reference to the accompanying drawings, but the scope of protection of the present invention is not necessarily limited to these embodiments, and various design changes and disclosures are made without departing from the technical spirit of the present invention. In the case of addition or deletion of technology, and simple numerical limitations, it is obvious that the scope of the present invention is included.

100: slit steel composite damper
101: slit steel composite damper 1
102: slit steel composite damper 2
110: center slit board
120: intersection
130: center slit plate buckling prevention reinforced plate
140: Crossing plate buckling prevention stiffening plate
210: center load transfer plate 211: connecting pin hole
220: external load transfer plate
230: connecting plate
240: friction pad
410: first reputation
420: second reputation
430: third reputation
510: first toggle
520: second toggle
530: third toggle
610: upper horizontal steel member
620: lower horizontal steel member
630: vertical steel member
11: straight incision
22: Bolt hole
33: coupling pin
44: toggle pinhole

Claims (6)

A center slit plate 110 in which a plurality of straight cutouts 11 are formed in a horizontal direction;
A cross plate 120 having a central portion integrally coupled to cross the center of the central slit plate 110 and having a lower end protruding downward from the central slit plate 110;
A pair of central slit plate buckling prevention reinforcing plates (130) integrally coupled to both left and right end surfaces of the central slit plate (110);
A pair of cross plate buckling prevention reinforcing plates 140 which are integrally coupled to both left and right end surfaces of the cross plate 120 and have a lower end protruding downward from the center slit plate 110;
A first flat plate 410 integrally coupled to a lower end of the cross plate 120 and the cross plate buckling reinforcement plate 140;
A second flat plate 420 integrally coupled to an upper end of the central slit plate 110 and the central slit plate buckling prevention reinforcing plate 130;
A center load transfer plate 210 having a plurality of straight cutouts 11 formed in a vertical direction and having a lower end integrally coupled to an upper surface of the second flat plate 420;
A plurality of bolt holes 22 are formed at positions corresponding to the linear cutouts 11 of the central load transfer plate 210, and closely contact the front and rear surfaces of the central load transfer plate 210 by bolts and nuts. A pair of external load transfer plates 220 protruding to an upper portion of the central load transfer plate 210;
A pair of connecting plates 230 integrally coupled to both left and right end surfaces of the central load transfer plate 210 and having a lower end integrally coupled to an upper surface of the second flat plate 420; And,
A third flat plate 430 integrally coupled to an upper end of the pair of external load transfer plates 220 protruding to an upper portion of the central load transfer plate 210;
Slit steel composite damper, characterized in that comprising a. A center slit plate 110 in which a plurality of straight cutouts 11 are formed in a horizontal direction;
A cross plate 120 having a central portion integrally coupled to cross the center of the central slit plate 110 and having a lower end protruding downward from the central slit plate 110;
A pair of central slit plate buckling prevention reinforcing plates (130) integrally coupled to both left and right end surfaces of the central slit plate (110);
A pair of cross plate buckling prevention reinforcing plates 140 which are integrally coupled to both left and right end surfaces of the cross plate 120 and have a lower end protruding downward from the center slit plate 110;
A first flat plate 410 integrally coupled to a lower end of the cross plate 120 and the cross plate buckling reinforcement plate 140;
A second flat plate 420 integrally coupled to an upper end of the central slit plate 110 and the central slit plate buckling prevention reinforcing plate 130;
A center load transfer plate 210 having a plurality of straight cutouts 11 formed in a vertical direction and having a connection pin hole 211 at an upper end thereof; And,
A plurality of bolt holes 22 are formed at positions corresponding to the linear cutouts 11 of the central load transfer plate 210, and closely contact the front and rear surfaces of the central load transfer plate 210 by bolts and nuts. A pair of external load transfer plates 220 protruding below the central load transfer plate 210;
It is configured to include,
The lower end of the external load transfer plate 220, the slit steel composite damper, characterized in that integrally coupled to the upper surface of the second flat plate (420). The method of claim 1 or 2,
Installed between the central load transfer plate 210 and the external load transfer plate 220, the straight cut portion 11 of the shape corresponding to the straight cut portion 11 formed on the central load transfer plate 210, respectively. Friction pad 240 is provided;
Slit steel composite damper, characterized in that it further comprises. In claim 2,
A first toggle 510 which is a length member provided with toggle pin holes 44 at both ends;
A second toggle 520 which is a length member provided with a toggle pin hole 44 at both ends; And,
A third toggle 530 having one end integrally coupled to a lower surface of the first flat plate 410 and a toggle pin hole 44 provided at the other end;
More,
The toggle pin hole 44 provided at one end of the first toggle 510 and the toggle pin hole 44 provided at one end of the second toggle 520 are connected to the pin hole of the central load transfer plate 210. 211) Slit steel composite damper, characterized in that coupled to the rotatable coupling pin (33). An earthquake-resistant reinforcement apparatus using the slit steel composite damper according to claim 4,
An upper horizontal steel member 610 installed in a horizontal direction;
A lower horizontal steel member 620 spaced apart from the upper horizontal steel member 610 and installed side by side;
A pair of vertical steel members 630 connecting both ends of the upper horizontal steel member 610 and the lower horizontal steel member 620 to each other; And,
The first toggle 510 in three of the four inner four corners of the rectangular steel frame frame consisting of the upper horizontal steel member 610, the lower horizontal steel member 620, and the pair of vertical steel member 630, A slit steel composite damper 100 having a toggle pin hole 44 provided at the other end of each of the second toggle 520 and the third toggle 530 coupled to the coupling pin 33, respectively;
Seismic reinforcement device using a slit steel composite damper, characterized in that consisting of. An earthquake-resistant reinforcement apparatus using the slit steel composite damper according to claim 4,
An upper horizontal steel member 610 installed in a horizontal direction;
A lower horizontal steel member 620 spaced apart from the upper horizontal steel member 610 and installed side by side;
A pair of vertical steel members 630 connecting both ends of the upper horizontal steel member 610 and the lower horizontal steel member 620 to each other;
The upper horizontal steel member 610, the lower horizontal steel member 620, and any two of the four inner sides of the rectangular steel frame frame consisting of the pair of vertical steel member 630 and the upper horizontal steel member ( 610 or a toggle provided at the other end of each of the first toggle 510, the second toggle 520, and the third toggle 530 inside the central portion of any one of the lower horizontal steel members 620. The slit steel composite damper 1 (101) to which the pin holes 44 are coupled to the coupling pins 33, respectively; And,
The other two of the four inner sides of the rectangular steel frame frame consisting of the upper horizontal steel member 610, the lower horizontal steel member 620, and the pair of vertical steel member 630 and the upper horizontal steel member ( 610 or a toggle provided at the other end of each of the first toggle 510, the second toggle 520, and the third toggle 530 inside the central portion of any one of the lower horizontal steel members 620. A slit steel composite damper 2 102 in which the pinholes 44 are respectively coupled to the coupling pins 33;
Seismic reinforcement device using a slit steel composite damper, characterized in that consisting of.

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