KR101825716B1 - Earthquake-proof support - Google Patents

Abstract

The present invention provides an earthquake-proof support which can stably support a high weight structure even when an earthquake occurs and can achieve an effective vibration decrease effect with a relatively simple structure. According to an embodiment of the present invention, the earthquake-proof support comprises: an upper block assembly; a lower block assembly separated from the upper block assembly in a vertical direction; a main elastic part interposed between the upper block assembly and the lower block assembly; and an auxiliary elastic part located at an outer side around the main elastic part, having one end connected to the upper block assembly, and having the other end connected to the lower block assembly.

Description

Earthquake Support {EARTHQUAKE-PROOF SUPPORT}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an earthquake-resistant support, and more particularly, to an earthquake-resistant support capable of stably supporting a heavy structure even when an earthquake occurs.

In a large-scale power demand center such as apartment complexes and factories, a distribution board is installed to monitor or control the high-voltage electricity supplied from the substation. The switchboards constructed in such large-scale power consumers include various heavy-weight electrical apparatuses such as an automatic load transfer switch (ALTS), a meter transformer (MOF), a vacuum breaker (VCB), and the like. The switchboard is installed in the cabinet to protect the switchboard itself and prevent electric shock by high-voltage electricity.

Conventionally, a conventional distribution box is installed to be spaced apart from the ground by a bracket fixedly installed on the ground in order to prevent a leakage accident caused by leakage of water or the like.

However, when the power distribution box is fixed to the ground via the bracket, the vibration of the ground is directly transmitted to the power distribution box when an earthquake occurs. Thus, there is a problem that the power distribution box itself or various electric devices installed in the power distribution box are damaged or the power distribution box is overturned. Accordingly, a number of seismic resistant supports capable of stably supporting the distribution box in the event of an earthquake have been developed. However, conventional earthquake-resistant supports are difficult to attain an effective vibration damping effect or have a complicated structure, so that they are difficult to manufacture and require a lot of fabrication costs. Therefore, as the frequency of recent earthquakes increases and interest in seismic design increases, research and development of earthquake-resistant supports that can achieve an effective vibration damping effect with a relatively simple structure, It needs to be done continuously.

Korean Patent Registration No. 10-1632867 (2016.06.23,

Embodiments of the present invention can provide an earthquake-resistant support capable of stably supporting a heavy structure even in the event of an earthquake and achieving an effective vibration damping effect with a relatively simple structure.

According to an aspect of the present invention, there is provided an upper block assembly comprising: an upper block assembly; A lower block assembly vertically spaced from the upper block assembly; A main elastic part interposed between the upper block assembly and the lower block assembly; And an auxiliary elastic portion disposed on the outer side of the main elastic portion and having one end connected to the upper block assembly and the other end connected to the lower block assembly.

The vibration proof support includes a first connecting member for connecting one end of the auxiliary elastic part to the upper block assembly; And a second connecting member connecting the other end of the auxiliary elastic part to the lower block assembly.

The first or second linking member may be integrally coupled to the upper or lower block assembly, or may be detachably coupled to the upper or lower block assembly.

An earthquake-proof support is formed at each end of the first and second connecting members and is engaged with one or the other end of the auxiliary elastic portion; And a snap ring coupled to the coupling groove to prevent separation of the auxiliary elastic portion.

The vibration proof support may further include a housing having an accommodation space extending vertically therein for inserting the upper block assembly, the main elastic part, and the lower block assembly.

The housing has a tube shape, and at the upper portion of the housing, a clearance hole or a clearance groove formed to be larger than the cross-sectional surface of the first connecting member to prevent interference between the first connecting member and the housing is formed, A through hole may be formed so that the member can be inserted.

The housing may be made of an elastic material.

The upper block assembly includes: a guide bushing having a first curved portion; And a moving bushing having a second curved portion formed to correspond to the first curved portion.

The upper block assembly is coupled to the object to be seismically protected by the bolts, the platform is located below the lower block assembly, and the lower block assembly is coupled to the platform by the bolts. have.

The vibration proof support may further include a support member disposed on a lower side of the lower block assembly and fixed to the lower block assembly by bolts and including a coupling protrusion protruding downward to be fixed to the platform.

The vibration proof support includes an upper cover coupled to an upper portion of the upper block assembly; A first vibration damping pad interposed between the upper block assembly and the upper cover; A lower cover coupled to a lower portion of the lower block assembly; And a second vibration damping pad interposed between the lower block assembly and the lower cover.

The upper cover and the first anti-vibration pad are coupled to the structure to be seismically-resistant by a bolt inserted into a coupling hole formed through the center of each of the upper cover and the first anti-vibration pad, The platform is located on the lower side, and the lower cover and the second vibration damping pad can be coupled to the platform by the bolts inserted into the coupling holes formed through the centers of the lower covers and the second vibration damping pads.

The upper cover and the lower cover may be spaced apart in the vertical direction.

The upper cover is provided with a clearance hole or a clearance groove formed to be larger than the transverse section of the first linking member to prevent interference between the first linking member and the upper cover and a through hole is formed in the lower cover so that the second linking member can be inserted .

According to another aspect of the present invention, there is provided an upper block assembly comprising: an upper block assembly; A lower block assembly vertically spaced from the upper block assembly; A first spring interposed between the upper block assembly and the lower block assembly; A housing having a first spring inserted therein and disposed on an outer side of the upper block assembly and the lower block assembly; A second spring disposed on the outer side of the housing around the first spring and having one end connected to the upper block assembly and the other end connected to the lower block assembly; And a connecting member for connecting one end or the other end of the second spring to the upper block assembly or the lower block assembly.

According to another aspect of the present invention, A lower block assembly vertically spaced from the upper block assembly; An upper cover coupled to an upper portion of the upper block assembly; A first vibration damping pad interposed between the upper block assembly and the upper cover; A lower cover coupled to a lower portion of the lower block assembly; A second vibration damping pad interposed between the lower block assembly and the lower cover; A first spring interposed between the upper block assembly and the lower block assembly; A second spring disposed on the outer side of the first spring and having one end connected to the upper block assembly and the other end connected to the lower block assembly; And a connecting member for connecting one end or the other end of the second spring to the upper block assembly or the lower block assembly.

The first spring and the second spring may be arranged to be parallel to each other.

According to the embodiments of the present invention, it is possible to realize an earthquake-resistant support capable of stably supporting a high-weight structure even when an earthquake occurs and achieving an effective vibration damping effect with a relatively simple structure.

1 is a perspective view illustrating an anti-vibration support according to an embodiment of the present invention;
2 is an exploded perspective view showing an anti-vibration support according to an embodiment of the present invention;
3 is a cross-sectional view of an anti-vibration support according to an embodiment of the present invention.
4 is a sectional view showing an operation state of an anti-vibration support according to an embodiment of the present invention;
5 is a perspective view illustrating an anti-vibration support according to another embodiment of the present invention.
6 is an exploded perspective view showing an anti-vibration support according to another embodiment of the present invention.
7 is a cross-sectional view showing a state in which an anti-vibration support according to another embodiment of the present invention is installed.
8 is a sectional view showing an operation state of an anti-vibration support according to another embodiment of the present invention.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise.

In the present application, when a component is referred to as "comprising ", it means that it can include other components as well, without excluding other components unless specifically stated otherwise. Also, throughout the specification, the term "on" means to be located above or below the object portion, and does not necessarily mean that the object is located on the upper side with respect to the gravitational direction.

Furthermore, the term " coupled " does not mean that only a physical contact is made between the respective components in the contact relation between the respective components, but the other components are interposed between the respective components, It should be used as a concept to cover until the components are in contact with each other.

The sizes and thicknesses of the respective components shown in the drawings are arbitrarily shown for convenience of explanation, and thus the present invention is not necessarily limited to those shown in the drawings.

The terms first, second, etc. may be used to describe various elements, but the elements should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout. A description thereof will be omitted.

2 is an exploded perspective view illustrating an anti-vibration support according to an embodiment of the present invention. FIG. 3 is a perspective view of an anti-vibration support according to an embodiment of the present invention. As shown in Fig.

1 to 3, an anti-vibration support 10 according to an embodiment of the present invention includes an upper block assembly 100, a lower block assembly 200, a main elastic part 300 and an auxiliary elastic part 400, And may be coupled to a platform 20 mounted on a floor or building floor to support a heavy structure 30, such as a distribution cabinet.

The upper block assembly 100 and the lower block assembly 200 may be formed of a member such as a bushing. The upper block assembly 100 and the lower block assembly 200 may be at least partially made of a metal material or an elastic material. Accordingly, the upper block assembly 100 and the lower block assembly 200 support the load of the seismic isolation structure 30 between the lower platform 20 and the upper seismic isolation structure 30 and are transmitted through the ground It can also absorb the seismic force and attenuate it.

Specifically, the upper block assembly 100 may include a guide bushing 110 and a moving bushing 120. The movable bushing 120 is movable relative to the guide bushing 110 according to an external force.

The guide bushing 110 may be disposed on the upper side of the movable bushing 120 and the first curved surface 111 may be formed on the lower surface thereof. The first curved portion 111 may have a convex or concave curved shape. Referring to FIGS. 2 and 3, the first curved portion 111 is a concave hemispherical curved portion.

The movable bushing 120 may be disposed below the guide bushing 110. A second curved surface portion 121 may be formed on the upper surface of the movable bushing 120 to correspond to the first curved surface 111. [ The second curved surface portion 121 may have a concave or convex curved surface shape corresponding to the first curved surface portion 111. 2 and 3, the second curved surface portion 121 is formed of a convex hemispherical curved surface portion.

In this embodiment, since the first curved surface portion 111 is formed of a concave curved surface portion, the second curved surface portion 121 may be formed of a curved surface portion convex upward. Of course, the opposite case is possible and the same effect can be expected.

The guide bushing 110 is guided on the guided curved surface of the movable bushing 120 in a state where the movable bushing 120 is engaged with the upper end of the main elastic part 130, And the earthquake-proof structure 30 can be mounted on the upper side of the guide bushing 110.

Accordingly, when the earthquake occurs, the movable bushing 120 moves along the guiding curved surface of the guide bushing 110 according to the vertical vibration and the horizontal vibration transmitted through the main elastic part 300, 111, and as a result, most of the vibration is absorbed and attenuated by the main elastic part 300 and the movable bushing 120, so that the destructive force of the vibration is transmitted through the guide bushing 110 So that transmission to the structure 30 can be minimized.

Although the upper block assembly 100 includes the guide bushing 110 and the movable bushing 120 in the present embodiment, the present invention is not limited thereto, and the upper block assembly 100 may include one It may be composed of a single body.

Unlike the upper block assembly 100, the lower block assembly 200 may be constructed as a single bushing. Of course, like the upper block assembly 100, the lower block assembly 200 may also include a guide bushing and a moving bushing.

Referring to the drawings, the upper block assembly 100 and the lower block assembly 200 may be coupled to each other by a main elastic part 300 interposed therebetween.

The bottom surface of the movable bushing 120 may be formed with an annular protrusion 122 protruding outwardly from the main elastic part 300 so as to fix the position of the main elastic part 300.

Another annular detachment protrusion 210 inserted into the main elastic part 300 and fixed to the main elastic part 300 may protrude from the upper surface of the lower block assembly 200 .

Accordingly, the main elastic part 300 can be held in a state of being restrained between the upper block assembly 100 and the lower block assembly 200.

Since the main elastic part 300 is interposed between the upper block assembly 100 and the lower block assembly 200, the load transmitted through the upper block assembly 100 is transferred to the lower block assembly 200. Therefore, the main elastic part 300 is made of a material having sufficient rigidity to withstand the load of the object 30 to be subjected to the earthquake.

The main elastic part 300 supports the load of the earthquake-proof target structure 30 and absorbs and attenuates not only the vertical vibration transmitted through the platform 20 but also the vertical and horizontal vibration in the horizontal direction when the earthquake occurs do. In other words, the main elastic part 300 can not only withstand the compressive force acting in the vertical direction (mainly the vertical direction load) but also can receive vertically and horizontally vibrating vibrations acting at the time of an earthquake, have.

According to the present embodiment, the main elastic part 300 may be constituted by the first spring 310. In addition, the main elastic part 300 may be formed in various shapes as long as it can withstand compressive and tensile forces. For example, the main elastic part 300 may be formed by stacking a plurality of hard rubber pads.

Referring to the drawings, the upper block assembly 100 and the lower block assembly 200 may be constrained to each other by a plurality of auxiliary elastic parts 400 located at upper, lower, right, and left sides with respect to a virtual vertical center axis.

The auxiliary elastic part 400 may be composed of a second spring 410.

The auxiliary elastic part 400 may be disposed outside the main elastic part 300 about the main elastic part 300. In this embodiment, a total of four second springs 410 are disposed one above and below the first springs 310 constituting the main elastic part 300. In this case, the first spring 310 and the second spring 410 may be arranged to be parallel to each other in the vertical direction.

The auxiliary elastic part 400 may play a role of holding the main elastic part 300 in a state of being held in a state of being restrained between the upper block assembly 100 and the lower block assembly 200.

Although the main elastic portion 300 restrains the position of the main elastic portion 300 in this way, even if an excessive external force acts on the upper block assembly 100 due to seismic force or load, It is possible to minimize the deviation from the lower block assembly 200 and the lower block assembly 200.

The auxiliary elastic part 400 assists the role of the main elastic part 300 so as to not only withstand a compressive force (mainly a vertical direction load) acting in a normal vertical direction, but also with vertical and horizontal vibration, It is also acceptable to move up, down, left, and right about the axis. That is, when excessive stress acts on the main elastic part 300, the auxiliary elastic part 400 may also disperse the stress applied to the main elastic part 300.

One end of the auxiliary elastic part 400 may be connected to the upper block assembly 100 and the other end of the auxiliary elastic part 400 may be connected to the lower block assembly 200.

According to the present embodiment, the auxiliary elastic part 400 may be connected to the upper and lower block assemblies 100 and 200 through the connecting member 500. The connecting member 500 may include a first connecting member 510 and a second connecting member 520. The first and second connecting members 510 and 520 may be rod-shaped members, for example. Here, the first connecting member 510 and the second connecting member 520 may have substantially the same shape.

The first connecting member 510 connects one end of the auxiliary elastic part 400 to the upper block assembly 100 and the second connecting member 520 connects the other end of the auxiliary elastic part 400 to the lower block assembly 200. [ .

In this embodiment, four first and second connecting members 510 and 520 are arranged in a "+" shape on the upper, lower, right and left sides of the main elastic part 300 .

Referring to FIG. 3, the upper and lower block assemblies 100 and 200 are each provided with female screw-shaped coupling grooves 112 and 212, and the ends of the first and second connecting members 510 and 520 are formed in a male screw shape The screw portions 512 and 522 may be formed. Accordingly, the first and second connecting members 510 and 520 may be detachably coupled to the upper or lower block assemblies 100 and 200 in a threaded manner. As a result, the workability in assembling or maintenance of the vibration-proofing support 10 can be greatly increased.

Of course, the first linking member 510 and the second linking member 520 may be integrally coupled to the upper or lower block assembly 100, 200.

The coupling grooves 511 and 521 may be formed at the ends of the first and second coupling members 510 and 520, respectively. The coupling grooves 511 and 521 are configured to be engaged with one end or the other end of the auxiliary elastic portion 400. In addition, the snap ring 530 can be coupled to the coupling grooves 511, 521 to prevent the auxiliary elastic part 400 from coming off.

According to the present embodiment, the seismic resistant support 10 includes a receiving space 601 extending vertically therein, so that the upper block assembly 100, the main elastic part 300, and the lower block assembly 200 are sequentially inserted (Not shown).

The housing 600 may include a polygonal columnar shape such as a circular column or a square, and a receiving space 601 is formed therein.

The housing 600 may be formed as a columnar tube whose both ends are opened as shown in the figure. The upper block assembly 100, the lower block assembly 200 and the main elastic part 300 can be inserted into the tubular housing 600 so that they can be mutually constrained by the housing 600. Therefore, it is possible to prevent the main elastic part 300 from being separated from the upper block assembly 100 and the lower block assembly 200.

The upper portion of the housing 600 is provided with a clearance hole (not shown) or a clearance groove 610 formed to be larger than the transverse section of the first connection member 510 to prevent interference between the first connection member 510 and the housing 600, Can be formed. The clearance holes or clearance grooves 610 are formed in the upper and lower block assemblies 100 and 100 so that the first connecting members 510 coupled to the upper block assembly 100 can be moved up and down, And may be formed to be larger than the cross-sectional surface of the first connecting member 510 in order to leave a gap between the connecting members 510.

In the case of this embodiment, the clearance groove 610 is shown as being open in a "U" shape from the top of the housing 600 to the open top of the housing 600.

A through hole 620 may be formed in the lower portion of the housing 600 to allow the second connection member 520 to be inserted therein. The through hole 620 may be formed to have a cross section corresponding to the cross section of the second linking member 520.

In one embodiment, the housing 600 may be made of a rigid material. In this case, a predetermined clearance may be formed between the housing 600 and the structures inserted into the accommodation space 601 thereof. Accordingly, the housing 600 supports the coupling between the upper block assembly 100 and the lower block assembly 200 and allows relative movement between the upper block assembly 100 and the lower block assembly 200 when vibration occurs.

In another embodiment, the housing 600 may be made of an elastic material so as to be deformable by an external force. The housing 600 is made of an elastic material capable of being deformed by an external force so that the lower block assembly 200, the main elastic part 300 and the upper block assembly 100 A part of the sequentially transmitted vibration can be absorbed through self-deformation, and as a result, damage to the structure 30 due to vibration can be minimized.

3, the earthquake-proof structure 30 is located above the upper block assembly 100, and the platform 20 is located below the lower block assembly 200. Referring to FIG. The platform 20 may be installed on the ground or the floor of the building, and the earthquake-proof structure 30 may be, for example, a distribution box.

Referring to the drawings, the upper block assembly 100 is coupled to the coupling member, for example, the bolt B, and the vibration- So that it can be detachably coupled to the earthquake-resistant structure 30. Similarly, the lower block assembly 200 may also be releasably coupled to the platform 20 by a fastening member, for example, a bolt (B). As a result, the manufacture and maintenance of the vibration-proofing support 10 can be facilitated.

Although the upper block assembly 100 and the lower block assembly 200 are illustrated as being coupled to the earthquake-proof target structure 30 and the platform 20 using only the bolts B in the present embodiment, It is also possible to use a combination of bolts (B) and nuts (N) as in the example.

The vibration proof supporter 10 according to the present embodiment is disposed on the lower side of the lower block assembly 200 and fixed to the lower block assembly 200 by the bolts B, And may further include a support member 220 including an engaging projection 221 protruding therefrom.

The support member 220 may be formed in a hollow pillar shape in which the upper end is closed and the lower end is opened. A coupling hole 222 through which the bolt B can be inserted may be formed in the center of the support member 220 so as to pass through the upper and lower portions. The support member 220 can be fixed to the lower block assembly 200 by the bolts B inserted into the engagement holes 222. [

At the lower end of the support member 220, a coupling protrusion 221 protruding downward to be fixed to the platform 20 may be formed. The coupling protrusions 221 may protrude downwardly in an annular shape having an outer diameter smaller than the outer diameter of the support member 220.

The vibration proof support 10 according to the present embodiment can be fixed to the platform 20 by inserting the coupling protrusion 221 of the support member 220 into the coupling hole 21 of the platform 20. As another example, the vibration-proofing support 10 may be directly coupled to the platform 20 with only the bolt B without the support member 220. [ In this case, the coupling hole 21 of the platform 20 may be formed to correspond to the diameter of the bolt B.

Of course, the support member 220 may be integrally formed with the lower block assembly 200.

4 is a cross-sectional view showing an operation state of an anti-vibration support according to an embodiment of the present invention.

4, when the platform 20 vibrates vertically or horizontally due to an earthquake or the like, the first and second blocks 300 and 300 constitute the main elastic part 300 between the upper block assembly 100 and the lower block assembly 200, The spring 310 can primarily absorb and cushion vibrations and shocks. In addition, the second spring 410 of the auxiliary elastic part 400, which is disposed above, below, left, and right of the first spring 310 to restrain the upper and lower block assemblies 100 and 200, It can absorb and cushion impact.

When the upper block assembly 100 includes the guide bushing 110 and the movable bushing 120 as in the present embodiment, the vibration and shock that are primarily attenuated in the first spring 310 can be slidably moved And can be absorbed and buffered thirdarily through the moving bushing 120 and the guide bushing 110 that are coupled to each other.

In the structure in which the upper block assembly 100 and the lower block assembly 200 are inserted into the housing 600 as in the present embodiment, when the housing 600 is made of an elastic material such as urethane and can be deformed by an external force A part of the vibration sequentially transmitted to the lower block assembly 200, the main elastic part 300 and the upper block assembly 100 through the platform 20 can be absorbed through self-deformation, It is possible to minimize the damage of the earthquake-proof structure 30.

Needless to say, although not shown in the drawings, the housing 600 may be omitted as another example.

4, when the horizontal vibration is applied due to an earthquake or the like, when the platform 20 deforms to absorb the vibration, the first spring 310 and the second spring 410 are deformed to absorb the vibration, When the vertical vibration is generated or the platform 20 is tilted to one side, the first spring 310 and the second spring 310 are moved in the horizontal direction, 2 spring 410 is tilted to absorb or cushion the vibration.

6 is an exploded perspective view illustrating an anti-vibration support according to another embodiment of the present invention, and Fig. 7 is an exploded perspective view of an anti-vibration support according to another embodiment of the present invention. As shown in Fig.

In describing the present embodiment, the same or corresponding portions as those of the vibration proof supporter 10 according to the above-described embodiment will not be described in detail, and the description will be focused on a structure different from the above embodiment.

5 to 7, an anti-vibration support 11 according to another embodiment of the present invention replaces the housing 600 of the above-described embodiment, and includes an upper cover (not shown) coupled to an upper portion of the upper block assembly 100, And a lower cover 720 coupled to a lower portion of the lower block assembly 200. The lower cover 720 may further include a first vibration damping pad 810 and a second vibration damping pad 820. [

The upper cover 710 may be formed in a hollow pillar shape in which the upper end is closed and the lower end is opened. Referring to FIG. 6, the upper cover 710 may be a cylindrical cylinder structure having a bottom opened.

A coupling hole 711 through which the bolt B can be inserted may be formed in the center of the upper cover 710 so as to pass through the upper and lower portions. The upper cover 710 can be coupled to the upper block assembly 100 by the bolts B inserted into the coupling holes 711. [

Since the upper cover 710 is interposed between the upper block assembly 100 and the earthquake-proof target structure 30, the coupling hole 101 of the upper block assembly 100 and the coupling hole 711 of the upper cover 710, The bolts B passing through the coupling holes 31 of the structure 30 are coupled with the nuts N so that the bolts B can be detachably coupled to each other.

The lower cover 720 may be formed in the shape of a hollow column whose upper end is open and whose lower end is closed, as opposed to the upper cover 710 described above. Referring to FIG. 6, the lower cover 720 may be a cylindrical cylinder structure having an open upper end.

A coupling hole 721 through which the bolt B can be inserted may be formed in the center of the lower cover 720 through the upper and lower portions. The lower cover 720 can be coupled to the lower block assembly 200 by the bolts B inserted into the coupling holes 721. [

The lower cover 720 is interposed between the lower block assembly 200 and the platform 20 at the bottom so that the coupling hole 201 of the lower block assembly 200 and the coupling hole 721 of the lower cover 720 and the platform The bolts B passing through the coupling holes 21 of the bolts 20 are coupled with the nuts N so that the bolts B can be detachably coupled to each other.

Unlike the single-type housing 600 described in the above-described embodiment, the upper cover 710 and the lower cover 720 are separated from each other and arranged to be vertically spaced apart from each other. The upper cover 710 and the lower cover 720 can be arranged in a substantially symmetrical structure.

In this embodiment, since the upper cover 710 and the lower cover 720 are completely separated from each other, when the main elastic part 300 and the auxiliary elastic part 400 are deformed due to the seismic force, 11 can be prevented in advance. In this case, stresses such as vertical and horizontal vibrations acting in the vertical direction (mainly vertical loads) and vertical and horizontal vibrations acting in the event of an earthquake, and twisting motions in the up, down, left, and right directions are applied to the main elastic portion 300, (400).

Since the upper cover 710 and the lower cover 720 are completely separated from each other, the inner main elastic portion 300, that is, the first spring 310 can be exposed to the outside. This exposure structure is advantageous for assembly and maintenance.

The upper cover 710 is provided with a clearance hole 712 or a clearance groove (not shown) formed to be larger than the cross section of the first connection member 510 to prevent interference between the first connection member 510 and the upper cover 710, Can be formed. The clearance holes 712 or the clearance grooves are formed in the upper block assembly 100 and the upper block assembly 100 so that the first connection member 510 coupled to the upper block assembly 100 can be moved up and down, And may be formed to be larger than the transverse section of the first connecting member 510 in order to leave a gap between the first connecting members 510.

A through hole 722 may be formed in the lower cover 720 so that the second connection member 520 can be inserted. The through hole 722 may be formed to have a cross section corresponding to the cross section of the second linking member 520.

The first vibration damping pad 810 may be interposed between the upper block assembly 100 and the upper cover 710 and the second vibration damping pad 820 may be interposed between the lower block assembly 200 and the lower cover 720. [ As shown in FIG.

The first vibration damping pad 810 and the second vibration damping pad 820 are respectively formed with coupling holes 811 and 821 at the centers thereof so that the bolts B can be inserted. The vibration can be absorbed and attenuated.

Although not shown, the upper cover 710 may be configured to surround the upper block assembly 100 and the first connection member 510 coupled to the upper block assembly 100 from the outside. Similarly, the lower cover 720 may be configured to surround the lower block assembly 200 and the second connection member 520 coupled to the lower block assembly 200 from the outside. Also in this case, the upper cover 710 and the lower cover 720 can be arranged in an overlapping manner so that they can be separated from each other.

8 is a cross-sectional view showing an operation state of an anti-vibration support according to another embodiment of the present invention.

8, when the platform 20 vibrates vertically or horizontally due to an earthquake or the like, the first and second block assemblies 100 and 200 constitute the main elastic part 300 between the upper block assembly 100 and the lower block assembly 200, The spring 310 can primarily absorb and cushion vibrations and shocks. In addition, the second spring 410 of the auxiliary elastic part 400, which is disposed above, below, left, and right of the first spring 310 to restrain the upper and lower block assemblies 100 and 200, It can absorb and cushion impact.

8, when the horizontal vibration is applied due to an earthquake or the like, when the platform 20 is deformed to absorb the vibration by the first spring 310 and the second spring 410, When the vertical vibration is generated or the platform 20 is tilted to one side, the first spring 310 and the second spring 310 are moved in the horizontal direction, 2 spring 410 is tilted to absorb or cushion the vibration.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

10, 11: Seismic Support
20: Platform 21: Coupling hole
30: Earthquake-proof structure 31: Coupling hole
100: upper block assembly 101: engaging hole
110: guide bushing 111: first curved portion
112: coupling groove 120: moving bushing
121: second curved surface portion 122:
200: lower block assembly 201: engaging hole
210: separation preventing protrusion 212: engaging groove
220: support member 221: engaging projection
222: coupling hole 300: main elastic part
310: first spring 400: auxiliary elastic part
410: second spring 500: connecting member
510: first connecting member 511: engaging groove
512: screw portion 520: second connecting member
521: coupling groove 522:
530: snap ring 600: housing
601: accommodation space 610:
620: through hole 710: upper cover
711: Coupling hole 712: Clearance hole
720: lower cover 721: engaging hole
722: through hole 810: first anti-vibration pad
811: Coupling hole 820: Second anti-vibration pad
821: Coupling hole

Claims (17)

1. An earthquake-resistant support for supporting a structure by being coupled to a platform installed on a ground,
An upper block assembly for supporting the structure;
A lower block assembly vertically spaced from the upper block assembly;
A support member disposed below the lower block assembly and including a coupling projection projecting downward to be fixed to the platform;
A first spring interposed between the upper block assembly and the lower block assembly;
A tubular housing capable of receiving the upper block assembly, the first spring, and the lower block assembly therein;
A second spring disposed on the outer side of the housing around the first spring and having one end connected to the upper block assembly and the other end connected to the lower block assembly;
A first connection member protruding from the upper block assembly through the housing in a lateral direction to connect one end of the second spring to the upper block assembly;
A second connection member protruding from the lower block assembly in the lateral direction through the housing to connect the other end of the second spring to the lower block assembly;
An engaging groove formed at an end of each of the first and second connecting members and engaged with one end or the other end of the second spring; And
A snap ring coupled to the coupling groove to prevent disengagement of the second spring;
/ RTI >
Wherein the first spring and the second spring are disposed so as to be parallel to each other,
The upper portion of the tube-shaped housing is formed with a clearance hole or a clearance groove formed to be larger than a cross-sectional surface of the first connection member to prevent interference between the first connection member and the housing,
A through hole is formed in a lower portion of the tube-shaped housing so that the second connection member can be inserted therein,
The upper block assembly
A guide bushing having a hemispherical first curved portion,
And a movable bushing having a second curved surface portion having a hemispherical shape corresponding to the first curved surface portion of the hemispherical shape,
Wherein the guide bushing is slidably mounted on the movable bushing and fixed to the structure by bolts,
And the support member is fixed to the lower block assembly by bolts.
delete The method according to claim 1,
Wherein the first or second connection member is integrally coupled to the upper or lower block assembly or is detachably coupled to the upper or lower block assembly.
delete delete delete delete delete delete delete delete delete delete delete delete 1. An earthquake-resistant support for supporting a structure by being coupled to a platform installed on a ground,
An upper block assembly;
A lower block assembly vertically spaced from the upper block assembly;
An upper cover interposed between the upper block assembly and the structure and in contact with the structure;
A first vibration damping pad interposed between the upper block assembly and the upper cover;
A lower cover interposed between the lower block assembly and the platform and in contact with the platform;
A second vibration damping pad interposed between the lower block assembly and the lower cover;
A first spring interposed between the upper block assembly and the lower block assembly;
A second spring disposed on the outer side of the first spring and having one end connected to the upper block assembly and the other end connected to the lower block assembly;
A first connection member protruding from the upper block assembly through the upper cover in a lateral direction to connect one end of the second spring to the upper block assembly;
A second connecting member projecting from the lower block assembly through the lower cover to extend laterally to connect the other end of the second spring to the lower block assembly;
/ RTI >
Wherein the first spring and the second spring are disposed so as to be parallel to each other,
Wherein the upper cover and the first vibration damping pad are coupled to the structure by bolts inserted into coupling holes formed through the centers of the upper cover and the first vibration damping pad,
Wherein the lower cover and the second vibration damping pad are coupled to the platform by a bolt inserted into a coupling hole formed through the center of the lower cover and the second vibration damping pad,
Wherein the upper cover is formed with a clearance hole or a clearance groove formed to be larger than the transverse section of the first connection member to prevent interference between the first connection member and the upper cover,
A through hole is formed in the lower cover so that the second connection member can be inserted therein,
The upper cover may have a closed upper end and an opened lower end to receive the first vibration damping pad and the upper block assembly through the opened lower end,
Wherein the lower cover has a closed lower end and an opened upper end to receive the second vibration damping pad and the lower block assembly through the opened upper end. delete

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