KR20100011527A - Bearing apparatus for structure - Google Patents

Abstract

PURPOSE: A bearing apparatus for structures is provided to restore relative position of the structures and protect the structures from external forces by guiding relative sliding between the upper and lower support plates using a plurality of guide pins. CONSTITUTION: A bearing apparatus for structures comprises an upper support plate(3), a lower support plate(5), a plurality of sliding pads(50), guide pins(10), and a sliding guide part(30). The guide pins are accepted and roll in the sliding guide part and guides the relative sliding motion of the upper and lower support plates while rolling.

Description

Bearing device for structures {BEARING APPARATUS FOR STRUCTURE}

The present invention relates to a bearing device for a structure, and more particularly, to a bearing device for a structure interposed between the upper structure and the lower structure to protect the upper and lower structures from vibrations of the ground and other external forces such as wind loads. It is about.

In general, a bearing device for a structure is a facility that prevents the structure from being damaged by an external force such as an earthquake or wind power. The bearing device for the structure must support the load of the structure in the direction of gravity, and the ability to dissipate the energy transmitted by the deformation and vibration caused by the vibration when the vibration occurs in the direction of gravity or ground (sea level) is required. do.

On the other hand, lead bearings or friction type port bearings are widely used in conventional bearing devices for structures. Bearing devices for structures such as lead bearings and frictional pot bearings have the ability to dissipate vibrational energy in the direction of gravity.

By the way, since the seismic waves transmit the horizontal and vertical vibration energy of P wave (primary wave) and S wave (secondary wave) at the same time, the conventional bearing device for structure dissipating vibration energy in the gravity direction, vibration energy in the ground direction There is a vulnerable problem.

In addition, even when there is no earthquake, since the moving object transmits force not only in the gravity direction but also in the moving direction, vibrations in the ground direction also occur in bridges with many vehicles or in complex buildings with many movements. The bearing device for the structure also has a problem vulnerable to vibration in the ground direction.

Accordingly, an object of the present invention is to provide a bearing device for a structure that can absorb and attenuate the vibration energy in the direction of gravity and ground caused by an external force such as an earthquake or wind power to prevent breakage of the structure due to the external force. .

According to the present invention, there is provided a bearing device for a structure disposed between an upper structure and a lower structure, the upper support plate and the lower support plate which are respectively installed at a predetermined distance to the upper structure and the lower structure; A plurality of sliding pads interposed between the upper support plate and the lower support plate and relatively sliding the upper support plate and the lower support plate in a plate surface direction of the upper support plate and the lower support plate; A guide pin provided in a horizontal direction of any one of the upper support plate and the lower support plate; A sliding guide part provided on the other of the upper support plate and the lower support plate to receive the guide pin, wherein the guide pin is accommodated in the sliding guide part to guide the relative sliding movement of the upper support plate and the lower support plate. It is made by a bearing device for a structure, characterized in that the rotating contact with the sliding guide.

Here, the guide pin, the support pin coupled in the transverse direction of any one of the upper support plate and the lower support plate plate direction; It may include a bearing portion accommodated in the sliding guide, rotatably coupled to the support plate to rotate along the inner surface of the sliding guide.

The plurality of sliding pads may include a first sliding pad made of a rigid material coupled to one of the upper support plate and the lower support plate, and a fluorine resin material coupled to the other of the upper support plate and the lower support plate. It may include two sliding pads.

The apparatus may further include a support pad interposed between the sliding pad and the lower support plate to support the load from the upper support plate.

The support pad is preferably provided with an elastic force in the transverse direction of the support pad plate surface direction.

On the other hand, coupled to the lower support plate, it may further include a stopper for preventing the separation of any one of the plurality of sliding pads and the support pad stacked on the lower support plate.

Therefore, according to the above solution, since the vibration energy in the gravity direction and the ground direction generated by the external force acting between the upper structure and the lower structure can be effectively absorbed and damped, thereby restoring the position between the structures It is possible to provide a bearing device for a structure that can prevent damage to them.

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

As shown in Figures 1 to 3, the bearing device 1 for a structure according to the present invention is the upper support plate 3 and the lower support plate 5, and the guide pin 10 is coupled to the lower support plate 5 and , A sliding guide part 30 provided on the upper support plate 3 to receive the guide pin 10, and a pair of sliding pads 50 interposed between the upper support plate 3 and the lower support plate 5. . In addition, the bearing device for the structure 1 is a support pad 60 for supporting the sliding pad 50 of the present invention, any one of the pair of sliding pads 50 and the support pad laminated on the lower support plate (5) It further includes a stopper 70 for preventing the separation of the 60.

The upper support plate 3 is installed on an upper structure (not shown). In addition, the lower support plate 5 is installed on the lower structure (not shown) to face the upper support plate 3. Here, the lower support plate 5 is formed with a coupling hole 7 to be engaged with the coupling portion 74 of the stopper 70 to be described later and a pin coupling hole 8 to engage with the guide pin 10.

On the other hand, the upper support plate 3 and the lower support plate 5 is provided with a plurality of anchor bolts 9 toward the upper structure and the lower structure, respectively. As one embodiment of the present invention, the anchor bolts 9 are provided on the plate surface of the upper support plate 3 and the lower support plate 5, respectively. However, the number of anchor bolts 9 may be less than four or more than four, depending on design changes. The anchor bolt 9 is embedded in the upper structure and the lower structure, and fixedly supports the upper support plate 3 and the lower support plate 5 to the upper structure and the lower structure, respectively. The anchor bolt 9 is detachably coupled to the upper support plate 3 and the lower support plate 5.

As shown in FIG. 4, the guide pin 10 is provided in the transverse direction of any one of the upper support plate 3 and the lower support plate 5. Guide pin 10 is an embodiment of the present invention, is inserted and coupled to the pin coupling hole (8) of the lower support plate (5). The guide pin 10 includes a support pin 12 inserted into and coupled to the pin coupling hole 8 of the lower support plate 5, and a bearing portion 14 contacting and rotating along the inner surface of the sliding guide 30. . Guide pin 10 serves to guide, ie guide the relative sliding movement of the upper support plate 3 and the lower support plate (5).

The support pin 12 is provided in a cylindrical shape as an embodiment of the present invention. One end of the support pin 12 is inserted into the pin coupling hole 8 of the lower support plate 5, and the other end is coupled to the bearing portion 14. In one embodiment, the support pin 12 has a smaller diameter at the other end to which the bearing portion 14 is coupled than a diameter at one end inserted into the pin coupling hole 8 of the lower support plate 5.

The bearing portion 14 is rotatably coupled with respect to the support pin 12 at one end of the support pin 12 accommodated in the sliding guide 30. The bearing part 14 is accommodated in the sliding guide 30 so that when an external force such as an earthquake is applied to the upper structure and the lower structure, the sliding guide part so that the upper support plate 3 and the lower support plate 5 move relative slidingly ( Rotate along the inner surface of 30). That is, the bearing portion 14 coupled to the support pin 12 rotates along the inner surface of the sliding guide portion 30 when the upper support plate 3 and the lower support plate 5 are moved by an external force. ) And to guide the relative movement of the lower support plate (5).

Here, the bearing portion 14 includes an outer portion 14a in contact with the inner surface of the sliding guide portion 30 and an inner portion 14b coupled to the support pin. The outer portion 14a is made of a material such as rubber having elastic force to withstand the wear caused by the contact of the sliding guide 30 and to absorb the impact caused by the contact on the inner surface of the sliding guide 30. The inner portion 14b is made of a metal bearing structure such that the bearing portion 14 is rotatable with respect to the support pin 12. It is preferable that lubricating oil is supplied between the bearing portion 14 and the engaging surface of the support pin 12 to prevent wear due to the rotation of the bearing portion 14 with respect to the support pin 12.

Next, as shown in FIG. 5, the sliding guide part 30 is provided on the other of the upper support plate 3 and the lower support plate 5. That is, the sliding guide part 30 is provided on the side where the guide pin 10 is not coupled to the upper support plate 3 and the lower support plate 5. As an embodiment of the present invention, the guide pin 10 is provided on the upper support plate 3 is not coupled as shown in the figure. The sliding guide 30 is recessed toward the upper structure from the plate surface of the upper support plate 3 adjacent to the guide pin 10.

The sliding guide 30 is provided in a circular shape as an embodiment of the present invention. That is, the sliding guide portion 30 is provided in a circular shape so that the bearing portion 14 is in contact rotation along the circumferential direction, so that the upper support plate 3 and the lower support plate 5 sufficiently secure the relative slide movement range.

On the other hand, the sliding guide 30 may be provided in an elliptical shape such that the relative sliding movement range of the upper support plate 3 and the lower support plate 5 in one direction is larger according to the external force range of the upper structure and the lower structure when designing. It may be. However, the sliding guide 30 is preferably provided in a circular shape such that the relative sliding movement range of the upper support plate 3 and the lower support plate 5 is the same.

Next, the sliding pad 50 is interposed between the upper support plate 3 and the lower support plate 5, and the upper support plate 3 and the lower support plate 5 along the plate surface direction of the upper support plate 3 and the lower support plate 5. ) Relative sliding.

The sliding pad 50 includes, as an embodiment of the present invention, a first sliding pad 52 coupled to the upper support plate 3 and a second sliding pad 54 coupled to the lower support plate 5. Here, it is preferable that the contact surface of the first sliding pad 52 and the second sliding pad 54 has a small coefficient of friction so that the first sliding pad 52 and the second sliding pad 54 can move relative to each other.

The first sliding pad 52 corresponds to the shape of the first pad body 52a forming the exterior of the first sliding pad 52 and the sliding guide part 30 in the center region of the first pad body 52a. The through hole 52b is formed through. The first sliding pad 52 is made of a rigid material.

The second sliding pad 54 includes a second pad main body 54a forming an appearance of the second sliding pad 54 and a support pin 12 of the guide pin 10 in the center region of the second pad main body 54a. ) Includes a through hole 54b formed to correspond to the cross-sectional shape. The second sliding pad 54 is made of a fluorine resin material. However, the second sliding pad 54 may be made of a material such as synthetic resin having a small coefficient of friction.

The support pad 60 is interposed between the second sliding pad 54 and the lower support plate 5. The support pad 60 includes a support pad body 62 forming an outer portion of the support pad 60 and a pad formed so that the support pin 12 of the guide pin 10 penetrates through the center region of the support pad body 62. The through hole 62 is included. The support pad 60 supports the second sliding pad 54 to prevent the second sliding pad 54 from being damaged by the load of the upper structure while at the same time smoothing the relative sliding movement with the first sliding pad 52. do.

Here, the support pad 60 is provided with an elastic rubber material as an embodiment of the present invention. However, the support pad 60 may be made of any material known as long as it is a material having elastic force such as rubber. The support pad 60 is provided with an elastic force in the transverse direction of the plate surface direction. That is, since the support pad 60 has elastic force in itself, the support pad 60 can be flexibly elastically deformed with respect to external force in the contact direction between the upper support plate 3 and the lower support plate 5.

The stopper 70 is coupled to the lower support plate to prevent separation of any one of the plurality of sliding pads 50 and the support pad 60 stacked on the lower support plate. The stopper 70 prevents the separation of the support pad 60 stacked on the lower support plate 5 and the second sliding pad 54 stacked on the support pad 60 in one embodiment of the present invention.

The stopper 70 is provided in a frame shape and surrounds the second sliding pad 54 and the support pad 60. The stopper 70 includes a stopper body 72 made of a frame and a plurality of coupling parts 74 protruding downward from the stopper body 72 to the lower support plate 5 and inserted into the coupling holes 7 of the lower support plate 5. ). The stopper 70 prevents the second sliding pad 54 from being separated from the lower support plate 5 by the frictional force caused by the relative sliding movement of the first sliding pad 52 and the second sliding pad 54.

Looking at the assembly process and operation process of the structure bearing device 1 of the present invention according to such a configuration as follows.

First, the anchor bolts 9 are respectively coupled to the upper support plate 3 and the lower support plate 5. The stopper 70 is coupled to the opposite surface of the plate surface of the lower support plate 5 to which the anchor bolt 9 is coupled. In addition, the support pad 60 and the second sliding pad 54 are stacked in the inner region of the stopper 70.

Guide pin 10 is inserted into the lower support plate (5). That is, the support pin 12 of the guide pin 10 penetrates the through hole 54b of the second sliding pad 54 and the pad through hole 62 of the support pad 60 to pin the lower support plate 5. It is coupled to the coupling hole (8).

The bearing portion 14 of the guide pin 10 is accommodated in the sliding guide portion 30 provided in the upper support plate (3).

On the other hand, the upper support plate 3 and the lower support plate 5 installed on the upper structure and the lower structure, respectively, relative movement by the external force. For example, when an external force acts in the direction of the ground, the sliding pin 50 interposed between the upper support plate 3 and the lower support plate 5 and the guide pin 10 rotates in contact with the sliding guide part 30. By operation the vibration energy transmitted to the superstructure and substructure is dissipated.

On the other hand, when the external force acts in the gravity direction, the vibration energy in the gravity direction transmitted to the upper structure and the lower structure by the elastic force provided to the support pad 60 is dissipated. Of course, even when a complex vibration energy is transmitted in the ground direction and the gravity direction can be dissipated.

Therefore, it is possible to effectively absorb and attenuate the vibration energy in the gravity direction and the ground direction generated by the external force acting between the upper structure and the lower structure, thereby restoring the position between the structures and at the same time to prevent damage of the structures. have.

1 is an exploded perspective view of a bearing device for a structure according to the present invention;

Figure 2 is a perspective view of the combination of the bearing device for the structure shown in Figure 1,

3 is a cross-sectional view taken along line III-III of the bearing device for a structure shown in FIG.

4 is an exploded perspective view of a guide pin of a bearing device for a structure according to the present invention;

5 is an operation plan view of a bearing device for a structure according to the present invention.

Explanation of symbols on the main parts of the drawings

3: upper support plate 5: lower support plate

10: guide pin 12: support pin

14: bearing portion 30: sliding guide portion

50: sliding pad 52: the first sliding pad

54: second sliding pad 60: support pad

70: stopper

Claims (6)

In the structure bearing device disposed between the upper structure and the lower structure, An upper support plate and a lower support plate respectively installed at predetermined intervals on the upper structure and the lower structure; A plurality of sliding pads interposed between the upper support plate and the lower support plate and relatively sliding the upper support plate and the lower support plate in a plate surface direction of the upper support plate and the lower support plate; A guide pin provided in a horizontal direction of any one of the upper support plate and the lower support plate; A sliding guide provided on the other of the upper support plate and the lower support plate to receive the guide pin, The guide pin is accommodated in the sliding guide portion, bearing structure for the structure, characterized in that the sliding contact to the sliding guide portion to guide the relative sliding movement of the upper support plate and the lower support plate. The method of claim 1, The guide pin, A support pin coupled in a horizontal direction of any one of the upper support plate and the lower support plate; And a bearing part accommodated in the sliding guide part and rotatably coupled to the support plate to rotate along an inner surface of the sliding guide part. The method of claim 1, The plurality of sliding pads, A first sliding pad made of a rigid material coupled to any one of the upper support plate and the lower support plate; And a second sliding pad made of a fluorine resin material coupled to the other of the upper support plate and the lower support plate. The method according to claim 2 or 3, And a support pad interposed between the sliding pad and the lower support plate to support a load from the upper support plate. The method of claim 4, wherein The support pad is a bearing device for a structure, characterized in that the elastic force is provided in the horizontal direction of the support pad plate direction. The method of claim 5, It is coupled to the lower support plate, the bearing device for a structure, characterized in that it further comprises a stopper for preventing the separation of any one of the plurality of sliding pads and the support pad laminated on the lower support plate.

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