KR101028234B1 - Hybrid vibration control apparatus using viscoelasticity and friction - Google Patents

Abstract

PURPOSE: A hybrid vibration control device using visco-elasticity and friction force is provided to improve earthquake-proof reinforcement effect at low costs without a separate vibration control device according to the kind of mechanical vibration source. CONSTITUTION: A hybrid vibration control device using visco-elasticity and friction force comprises a pair of damper bodies(10a,10b), a plurality of high damping rubbers(20), a friction pad pressure plate(30), a sliding plate(40), a plurality of friction pads(50a,50b), and a friction pad fastener. The high damping rubber is respectively installed between a sub side plate(106a) and a main side plate(104a). The sliding plate is inserted between the main side plate and friction pad pressure plate. The friction pad fastener fixes the friction pad pressure plate to the main side plate and generates the frictional resistance by compulsively pushing the friction pad to the friction plate by using a screwing force.

Description

Hybrid vibration control apparatus using viscoelasticity and friction}

The present invention relates to a vibration suppression device manufactured to dissipate vibration energy due to wind or earthquake, and particularly, a high damping rubber that can cope with both wind and design-based earthquakes and a maximum level earthquake larger than design earthquake. (Maximum Considerable Earthquakes) relates to a combination of vibration dampers designed to work in the combined vibration damper.

Vibration control refers to the control of vibrations caused by wind or earthquakes in buildings, and a structure in which a special device or device is installed for vibration control is called a vibration suppression structure. The purpose of vibration suppression is to improve the safety and habitability of the structure by dissipating the vibration energy input to the structure due to wind or earthquake.

In the method of vibration suppression, the structure itself is equipped with a function to detect the vibration from the outside and the vibration of the structure according to the active control and the building to reduce the vibration of the structure by applying a control force corresponding to the vibration of the structure inside or outside the structure. There is a manual control to control the dynamic response of the building by installing additional energy dissipation devices to improve the damping performance of the structure.

Passive vibration dampers can be divided into mass tuning type and energy dissipation type. The former is mainly installed on the top of the building, mainly for the purpose of enhancing the wind habitability, and the latter is mainly installed on each floor to be used for the safety of the earthquake and the wind habitability.

Energy dissipation type vibration suppressors can be divided into displacement-dependent and speed-dependent types. Displacement-dependent devices utilize energy dissipation characteristics due to frictional forces between materials or plastic deformation of metals, and speed-dependent types are used when viscous and viscoelastic materials deform. By generating heat and dissipating vibration energy, the dissipated energy is large in proportion to the speed.

Recently, many high-rise buildings are being constructed, which are considerably taller than their lengths. However, buildings with such large equipments are greatly affected by vibrations, so a vibration damping device is required to cope with various vibrations such as wind and earthquakes. Until now, it has been common to install a vibration damper separately according to the type of vibration source, but it is pointed out as a problem that the cost increase or the limitation of building plan is large.

In particular, in Korea, there are many buildings that were constructed before the seismic design standards were applied and the remodeling of old buildings is active, and the development of passive vibration damping devices that can achieve sufficient seismic reinforcement effect at low cost is required.

The present invention has been made in view of the above circumstances and has the following object.

The present invention does not need to install a separate vibration damper according to the type of vibration source, provides a seismic reinforcement effect that can achieve a sufficient seismic reinforcement effect at low cost when the seismic reinforcement of the building is not applied seismic design and remodeling existing buildings It aims to do it.

According to a preferred embodiment of the present invention, comprising an end steel plate, a main side plate and one or more sub side plates, which are arranged side by side at regular intervals along the width direction of the end steel plate perpendicular to one surface of the end steel plate, respectively, The sub side plate of the other damper body is inserted into the gap between the main side plate and the sub side plate of one damper body, and the damper is inserted into the gap between the main side plate and the sub side plate of the other damper body. Sub-side plate of the body is inserted and a constant gap is formed between each adjacent side plate and the end plate is a pair of damper body is installed to face each other;

A plurality of high damping rubbers provided in a gap between the main side plate and the sub side plate;

A friction pad presser plate disposed on the upper and lower sides of the main side plate to face one side and having a loose fitting hole penetrated at the center thereof;

A sliding plate having a friction plate disposed between the main side plate and the friction pad pressing plate, and a stopper inserted into a loose stop hole of the main side plate by inserting a fitting hole in the center thereof;

A plurality of friction pads respectively disposed between the main side plate and the opposing surfaces of the friction plate and between the opposing surfaces of the friction plate and the friction pad pressing plate to face each other; And

And a friction pad tightening means for forcibly fixing the friction pad pressure plate to the main side plate and simultaneously forcing the friction pad to the friction plate by screwing force.

It absorbs vibration energy by shear deformation of high damping rubber against wind or design earthquake, and dissipates seismic energy by friction between friction plate and friction pad for maximum level earthquake.

According to another suitable embodiment of the present invention, stainless steel plates are provided on both surfaces of the friction plate so as to be in contact with the friction pad to maintain a quantitative frictional resistance value.

According to another suitable embodiment of the present invention, the height of the main side plate is configured to be higher than the height of the sub side plate, so that the sub side plate is positioned at the center of the main side plate.

According to another suitable embodiment of the present invention, the friction pad tightening means includes a fastening bolt uniaxially inserted into the bolt hole of the main side plate, the loose bolt hole of the sliding plate, and the bolt hole of the friction pad pressing plate, and screwing to the fastening bolt. Characterized in that consisting of the nut.

According to another suitable embodiment of the present invention, the assembly clearance gap between the stopper, the stop hole and the fitting space and the assembly clearance gap between the fastening bolt and the bolt space are identically configured.

The composite vibration isolator using the viscoelasticity and friction according to the present invention is a combination of high damping rubber that operates during wind load and design earthquake and friction damper that operates during maximum level earthquake. It can respond.

In other words, the energy dissipation capacity due to shear deformation of high damping rubber for wind load and design earthquake reduces the vibration energy of main structure and minimizes residual deformation. Minimize damage to the main structure.

Therefore, it is possible to cope with one vibration damper without installing a separate vibration damper according to the type of vibration source, so that the cost can be reduced and the freedom of construction planning is improved.

In addition, it is possible to achieve sufficient seismic reinforcement effect at a low cost when remodeling a building and an old building that were constructed before the seismic design criteria were applied.

1 is an exploded perspective view showing a composite vibration suppression apparatus according to an embodiment of the present invention.
Figure 2 is a perspective view showing a composite dust removal apparatus according to an embodiment of the present invention.
Figure 3 is a front view showing a composite dust removal apparatus according to an embodiment of the present invention.
Figure 4 is a plan view showing a composite dust removal apparatus according to an embodiment of the present invention.
5 is a state diagram used in the composite vibration damper according to an embodiment of the present invention.
Figure 6 is a diagram showing the deformation form according to the shear behavior of the pulley beam.

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

1 is an exploded perspective view showing a composite vibration suppression apparatus according to an embodiment of the present invention, Figure 2 is a perspective view, Figure 3 is a front view and Figure 4 is a plan view.

1 to 4, the composite vibration suppression apparatus according to an embodiment of the present invention includes a pair of damper bodies 10a and 10b. The pair of damper bodies 10a and 10b are installed opposite to each other.

The damper body 10a on one side of the main side plate 104a is arranged side by side in the width direction of the end steel sheet 102a at regular intervals perpendicular to the front end surface of the end steel sheet 102a and the end steel sheet 102a. And a sub side plate 106a. On the upper and lower sides of the main side plate 104a, stop holes 114a penetrated in the thickness direction are formed, respectively. The sub side plate 106a may have a thickness relatively smaller than that of the main side plate 104a to reduce the width of the damping portion. The end steel plate 102a, the main side plate 104a, and the sub side plate 106a are all made of steel, joined by welding, or manufactured by casting to form a single body.

The damper body 10b on the other side of the main side plate 104b is arranged side by side in the width direction of the end steel sheet 102b at regular intervals perpendicular to the front end plate 102b and the front surface of the end steel sheet 102b. And the sub side plate 106b. On the upper and lower sides of the main side plate 104b, a plurality of bolt holes 114b penetrated in the thickness direction are formed, respectively. The sub side plate 106b may have a thickness relatively smaller than that of the main side plate 104b to reduce the width of the damping portion. The end steel plate 102b, the main side plate 104b, and the sub side plate 106b are all made of steel, joined by welding, or manufactured by casting to form a single body.

In the present embodiment, the height of the main side plates 104a and 104b is configured to be higher than the height of the sub side plates 106a and 106b, and the sub side plates 106a and 106b are located at the center of the main side plates 104a and 104b. It is configured to be.

A pair of damper body (10a, 10b) configured as described above is the damper body (10b) of the other side in the interval between the main side plate (104a) and the sub side plate (106a) of the damper body (10a) of one side as shown in FIG. The sub side plate 106b is inserted, and the sub side plate 106a of the damper body 10a on one side is spaced between the main side plate 104b of the other damper body 10b and the sub side plate 106b. It is assembled in such a way that there is a constant gap between each neighboring side plate. Accordingly, the pair of damper bodies 10a and 10b are arranged from one side to the other side in the order of the main side plate 104a, the sub side plate 106b, the sub side plate 106a, and the main side plate 104b. The steel sheets 102a and 102b face each other.

The high damping rubber 20 is provided in the gap between the main side plates 104a and 104b and the sub side plates 106a and 106b, respectively. Each high damping rubber 20 is a plate shape having the same size and thickness and has the same height as the sub side plates 106a or 106b. The high damping rubber 20 may be any of the high damping rubbers known in the art, and generally has a constant temperature after adding additives such as fillers, vulcanizing agents, antioxidants and plasticizers to natural rubber or / and carbon black. It is manufactured through vulcanization process under pressure and pressure. The elasticity of the high damping rubber can be adjusted according to the ratio of the additives and the energy dissipation capacity is determined by the elasticity. The high damping rubber 20 has an adhesive or a concave-convex or protrusion shape in addition to a contact surface between the main side plates 104a and 104b and the sub side plates 106a and 106b to secure the fixing force at the installation position. Can be secured.

Friction pad pressing plates 30 are disposed on the upper and lower front surfaces of the main side plate 104b at regular intervals. The friction pad pressing plate 30 is positioned side by side facing the upper and lower front surfaces of the main side plate 104b. The friction pad pressing plate 30 has a loose fitting hole 30a penetrated in the thickness direction at the center, a plurality of bolt holes 30b, and a plurality of friction pad fitting grooves 30c.

A sliding plate 40 is interposed between the main side plate 104b and the friction pad pressing plate 30. The sliding plate 40 is vertically installed in the plate-shaped friction plate 42 and the center of the front surface of the friction plate 42 to insert the fitting hole 30a of the friction pad presser plate 30 and loosely stop the main side plate 104a. A stopper 44 is inserted into the ball 114a. At this time, the stopper 44 has a circular cross section and its diameter is loosely fitted with a constant circular clearance smaller than the inner diameter of the fitting hole 30a of the friction pad pressing plate 30 and the stop hole 114a of the main side plate 104a. . At this time, the inner diameter of the fitting hole (30a) and the stop hole (114a) is configured the same.

The friction plate 42 generates a frictional resistance with the friction pads 50a and 50b to be described later, and functions as a friction damper operating at a maximum considerable earthquake (Maximum Considerable Earthquakes). The friction plate 42 may be made of aluminum or aluminum alloy, cast iron or cast steel, cast iron or non-ferrous cast, stainless steel or stainless alloy steel. Preferably, as shown in the enlarged view of FIG. 1 to maintain contact with the friction pads 50a and 50b, the stainless steel plate 41 may be installed on both sides of the friction plate 42. .

A plurality of friction pads 50a and 50b facing each other are disposed between the main side plate 104b and the opposing surface of the friction plate 42 and between the opposing surface of the friction plate 42 and the friction pad pressing plate 30. . At this time, one side of the friction pad 50a is mounted in the friction pad fitting groove 124b of the main side plate 104b, and the other side of the friction pad 50b is in the friction pad fitting groove 30c of the friction pad pressing plate 30. Is mounted.

The friction pads 50a and 50b are made of an aluminum composite material in which ceramic particles are dispersed and reinforced in aluminum or an aluminum alloy, a carbon-carbon composite material, a semi-metallic friction material using metal fibers, and a metal fiber. And low-steel friction materials using organic / inorganic fibers and non-steel friction materials using only organic / inorganic fibers without using any metal fibers. have. Preferably, in consideration of performance and environmental aspects can be made of Non Asbestos Organism (NAO).

A plurality of friction pad tightening means for fixing the friction pad presser plate 30 to the main side plate 104b and forcibly bringing the friction pads 50a and 50b into the friction plate 42 by screwing force to generate friction resistance It is provided. In the present embodiment, the friction pad tightening means fastens the bolt hole 114b of the main side plate 104b and the bolt hole 42a of the sliding plate 40 and the bolt hole 30b of the friction pad pressing plate 30. The bolt 60 and the nut 62 is screwed to the fastening bolt 50. At this time, the fastening bolt 60 is inserted into the bolt hole 42a with a loose circular clearance, and is inserted with the same diameter as the bolt holes 30b and 114b.

As such, the cross section diameter of the stopper 44 of the sliding plate 40 is smaller than the inner diameter of the stop hole 114a of the main side plate 104a, so that it has a loose circular clearance, so that both wind and design earthquakes The corresponding viscoelastic deformation of the high damping rubber 20 is allowed, and the viscoelastic deformation of the high damping rubber 20 enables vibration absorption and damping.

In the composite vibration damping device configured as described above, the damper bodies 10a and 10b on both sides are disposed to face each other so that one side subside plate 106a is spaced between the main side plate 104b and the subside plate 106b on the other side. Is inserted into

Then, the three high damping rubbers 20 are each spaced between the one main side plate 104a and the other sub side plate 106b, and between the other sub side plate 106b and the one side sub side plate 106a. It is interposed between the space | interval of one side sub side plate 106a and the other main side plate 104b. At this time, the high damping rubber 20 may be installed in a prefabricated or injection method.

Next, the friction pad pressing plate 30 is inserted into the stopper 44 of the sliding plate 40 and then the stopper 44 is inserted into the stop hole 114a of the main side plate 104a. Then, when the friction plate 42 is inserted between the friction pad 50a on one side and the friction pad 50b on the other side, the main side plate 104b and the friction plate 42 and the friction pad pressing plate 30 face side by side. Is placed.

In this state, the bolt hole 30b of the friction pad presser plate 30 having the fastening bolt 60 in a straight line, the bolt hole 42a of the sliding plate 40, and the bolt hole 114b of the main side plate 104b. ) And then tighten the nut 62 to the fastening bolt 60 by screwing. At this time, the friction pads 50a and 50b are pushed to the friction plate 42 by the fastening force of the fastening bolt 60 to generate a static friction force.

In this way, the friction pad presser plate 30 and the sliding plate 40 are assembled in pairs with each other, and the upper and lower portions of the main side plate 104b are positioned at two positions.

The composite vibration isolator according to an embodiment configured and assembled as described above includes a high damping rubber interposed between the side plates 104a, 106b, 106a, and 104b of the damper bodies 10a and 10b when a wind load or a design earthquake is applied. 20) absorbs vibrational energy as it deforms. When the maximum level earthquake load is applied, the seismic energy is dissipated by the frictional resistance between the friction pads 50a and 50b and the friction plate 42. At this time, the stopper 44 is caught by the stop hole 114a, and the sliding plate 40 is stopped, and the friction pads 50a and 50b have a section allowing the clearance between the fitting hole 30a and the stopper 44 to have a friction plate. Friction damping occurs while moving while maintaining forced contact with 42.

Therefore, it can effectively respond to both wind and earthquake. That is, the composite vibration suppression apparatus according to an embodiment of the present invention suppresses vibration during wind or design earthquake and friction damper composed of a sliding plate 40 and friction pads 50a and 50b that dissipate vibration energy during maximum level earthquake. It can be referred to as a vibration damping device in which the high damping rubber 20 is combined into one.

Composite vibration suppression apparatus according to an embodiment of the present invention configured as described above may be installed at various locations of the structure to cope with both wind and earthquake. As an example, it may be installed with the same configuration in the newsletter as known in the patent registration No. 10-0943156. That is, as shown in FIG. 5, the embedded rebar assembly 120 is embedded in the left and right pulleys 100, and the embedded rebar assembly 120 is a bent portion of the pair of U-shaped rebar 121 and the U-shaped rebar 121. Consists of a stirrup reinforcement 123 is coupled to surround the bent steel plate 122 and a pair of U-shaped reinforcement 121, the U-shaped reinforcement 121 of the embedded reinforcing bar assembly 120 of one embodiment of the present invention The damper bodies 10a and 10b side end steel plates 102a and 102b can be fixedly attached by welding.

In the above description, the case in which the sub side plates 106a and 106b of the damper bodies 10a and 10b constituting the composite vibration damping device have been described as one each, but the number of the sub side plates is not limited thereto and is two or more. It can also be configured. In this case, the number of the high damping rubbers 20 installed between the sub side plates also increases correspondingly.

In addition, the present embodiment has a structure in which the friction pad presser plate 30 and the sliding plate 40 are connected to the main side plate 104b of the other side, but on the contrary, the main side plate of the side including the friction pads 50a and 50b is included. It may be configured as a structure connected to the 104a.

In the following, the composite vibration damper according to an embodiment of the present invention has an example installed in a pulley beam, and specifically describes the behavior during the wind and design earthquake action and the maximum level earthquake action.

Figure 6 is a diagram showing the deformation form according to the shear behavior of the pulley beam.

As shown in FIG. 6, when wind or earthquake acts on the structure, shear force is generated in the pulley. As shown in FIG. It is behaved by shear force.

When micro deformation occurs due to wind or design earthquake, the high damping rubber 20 is deformed in response to the shearing behavior to reduce vibration. At this time, the main side plate 104b, the friction pad pressing plate 30, and the sliding plate 40 behave together by the friction plate tightening means, and the stopper 44 has a loose stop hole 114a formed in the main side plate 104a. Friction force does not occur until it contacts 114b).

When the large deformation caused by the maximum level earthquake occurs, the stopper 44 comes into contact with the loose stop hole 114a formed in the main side plate 104a, and thus the friction pad 40 is slid from the friction plate 42. As frictional resistance occurs, it dissipates seismic energy.

On the other hand, the composite vibration damping device according to the present invention has a feature capable of behaving against all deformations in the vertical direction. Therefore, as shown in FIG. 5, the shape may be arranged in the center of the plinth, but the shape may be arranged at both ends. When placed at both ends, it behaves due to the bending moment. In addition, even when installed on a member that receives a compressive force, such as braces, it is possible to behave by the tensile force and the compressive force.

So far, the present invention has been described in detail with reference to the presented embodiments, but those skilled in the art may make various modifications and modifications without departing from the technical spirit of the present invention with reference to the presented embodiments. will be. The invention is not limited by the invention as such variations and modifications but only by the claims appended hereto.

10a, 10b: damper body
102a, 102b: end steel plate
104a, 104b: main side plate
106a, 106b: sub-side plate
114a: Stopper
20: high damping rubber
30: friction pad pressure plate
40: sliding plate
42: friction plate
44: stopper
50a, 50b: friction pad
60: fastening bolt
62: nuts

Claims (5)

At least one sub side surface and the main side plates 104a and 104b arranged side by side at regular intervals along the width direction of the end steel sheet perpendicular to one surface of the end steel sheets 102a and 102b and the end steel plates 102a and 102b. The sub-side plates of the other damper body 10b are provided in the gap between the main side plate 104a of the one damper body 10a and the sub side plate 106a by providing the plates 106a and 106b, respectively. 106b) is inserted, and the subside plate 106a of any one damper body 10a is inserted in the gap between the main side plate 104b and the sub side plate 106b of the other damper body 10b. A constant gap is formed between each adjacent side plate, and the end steel sheets 102a and 102b include a pair of damper bodies 10a and 10b installed to face each other;
A plurality of high damping rubbers 20 provided at a gap between the main side plates 104a and 104b and the sub side plates 106a and 106b;
A friction pad presser plate 30 having upper and lower sides of the main side plate 104b facing one side and having a loose fitting hole 30a penetrated in the center thereof;
A stopper inserted into the loose stop hole 114a of the main side plate 104a by inserting a friction plate 42 disposed between the main side plate 104b and the friction pad pressing plate 30 and a fitting hole 30a at the center thereof. A sliding plate 40 provided with 44;
A plurality of friction pads 50a and 50b disposed between the main side plate 104b and the opposing surfaces of the friction plate 42 and between the opposing surfaces of the friction plate 42 and the friction pad pressing plate 30 to face each other; And
And a friction pad tightening means for forcibly connecting the friction pad presser plate 30 to the main side plate 104b and forcibly bringing the friction pads 50a and 50b into the friction plate 42 with a screw tightening force.
It absorbs vibration energy by shear deformation of high damping rubber 20 against wind or design earthquake and dissipates seismic energy by friction between friction plate 42 and friction pads 50a and 50b for maximum level earthquake. Composite vibration suppression device using viscoelasticity and friction. The method according to claim 1,
Both sides of the friction plate 42 is provided with a stainless steel sheet 41 in contact with the friction pad (50a, 50b) to maintain a quantitative friction resistance value, characterized in that the viscoelasticity and friction using a vibration damping device. The method according to claim 1,
The height of the main side plates 104a and 104b is made higher than the height of the sub side plates 106a and 106b so that the sub side plates 106a and 106b are positioned at the center of the main side plates 104a and 104b. Composite vibration suppression apparatus using viscoelasticity and friction. The method according to claim 1,
Friction pad tightening means,
A fastening bolt 60 uniaxially inserted into the bolt hole 114b of the main side plate 104b and the loose bolt hole 30b of the sliding plate 40 and the bolt hole 30b of the friction pad pressing plate 30; Composite vibration suppression apparatus using viscoelasticity and friction, characterized in that consisting of a nut (62) screwed to the fastening bolt (60). The method according to claim 4,
Composite using the viscoelasticity and friction characterized in that the clearance gap between the stopper 44, the stop hole (114a) and the fitting hole (30a) and the assembly clearance gap between the fastening bolt 60 and the bolt hole (30b) is configured equally Vibration damper.

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