KR20090013246A - Reciprocal pressure spring damper and drop preventing device using thereof - Google Patents

Abstract

A reciprocating type compression spring damper and a fall prevention device of a bridge using the same are provided to prevent the accidental fall of a bridge deck effectively when an earthquake occurs, and to maximize the aesthetic effect of a bridge by using a reciprocating type compression spring damper having excellent outward appearance. A reciprocating type compression spring damper comprises an inner cylinder(110) composed of a front plate(113), a rear plate(114) and a lower plate(115) connecting the front plate and the rear plate integrally, a compression spring(130) installed to an inside space of the inner cylinder, a rectangular tube shaped outer cylinder surrounding the outside of the inner cylinder, a spring compression plate supported elastically to the upper part of the compression spring, an outer cylinder cap coupled to the bottom of the outer cylinder, and an inner cylinder cap(112) coupled to the top of the inner cylinder exposed to the top of the outer cylinder which is not coupled with the outer cylinder cap.

Description

Reciprocal Pressure Spring Damper and Drop Preventing Device using corresponding}

The present invention relates to a reciprocating compression spring damper and a fall prevention device using the same to prevent the loss of valuable human life and property by preventing the fall of the bridge deck due to repeated lateral load during the earthquake.

In the event of an earthquake, lateral pressure acts repeatedly, causing the bridge deck to fail, resulting in the loss of valuable lives and property.

As a device for preventing falling of the top plate, the top plate of the bridge is connected to each other by installing a steel bar with a stopper on the side of the adjacent top plate so as to be slidable. However, when the displacement occurs beyond the allowable displacement, the steel rod is designed to resist the displacement.

However, when an earthquake occurs, the top of the bridge causes a sudden displacement due to the earthquake load, and a large amount of impact energy is applied to the steel bar as soon as the steel rod reaches the time when the steel rod resists displacement of the top of the bridge by a stopper provided in the steel bar. Is momentarily acting to damage the connection part (fastening part) of the steel bar or the steel bar itself, there is a problem that can not properly perform the original function of preventing falling.

The object of the present invention created to solve the above problems is as follows.

First, it is an object of the present invention to effectively prevent the fall of the bridge deck when an earthquake occurs to prevent the loss of valuable lives and properties.

     Second, it is another object of the present invention to maximize the aesthetic effect of the bridge by minimizing unnecessary anxiety composition of the user by using a reciprocating compression spring damper having a relatively beautiful appearance.

Third, it is another object of the present invention to achieve the maximum effect at a minimum cost by reducing the construction cost as well as the construction of the construction by simply attaching to the existing bridges as well as existing bridges.

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

The present invention relates to a compression spring damper that efficiently absorbs an impact such as an earthquake, and includes a front plate 113, a back plate 114, and a lower portion of each of the front plate 113 and the back plate 114. Is coupled to the inner cylinder 110 consisting of a lower plate 115 for integrally connecting the front plate 113 and the back plate 114; A compression spring (130) installed in an inner space of the inner cylinder (110) consisting of the front plate (113), the upper back plate (114), and the lower plate (115); An outer cylinder 120 having a rectangular tube shape surrounding the outside of the inner cylinder 110; Both ends of the inner cylinder 110 may be coupled to an upper portion of the inner surface of the outer cylinder 120 across the space between the front plate 113 and the rear plate 114, and may be elastic on the upper portion of the compression spring 130. Supported spring pressing plate 123; An outer cylinder cap 122 coupled to a lower end of the outer cylinder 120; And an inner cylinder cap 112 coupled to an upper end of the inner cylinder 110 exposed to the upper end of the outer cylinder 120 to which the outer cylinder cap 122 is not coupled. Relates to a spring damper.

In addition, the present invention relates to an anti-falling device using such a reciprocating compression spring damper, the outer cylinder connecting rod 220 coupled to the outer surface of the outer cylinder cap 122 in the longitudinal direction; An inner cylinder connecting rod 210 coupled to the outer surface of the inner cylinder cap 112 in a longitudinal direction; An outer cylinder connecting ring 240 that is pin-coupled to the end of the outer cylinder connecting rod 220 in a vertical direction to be rotatable; An inner cylinder connecting ring 230 pivotally coupled to an end of the inner cylinder connecting rod 210 in a vertical direction; An outer cylinder bracket 260 pinned to the end of the outer cylinder connecting ring 240 in a horizontal direction and attached to a bridge structure; And an inner cylinder bracket 250 rotatably pinned to an end of the inner cylinder connecting ring 230 in a horizontal direction and attached to a bridge structure. .

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

First, it is possible to effectively prevent the fall of the bridge deck during the earthquake, thereby preventing the loss of valuable lives and property.

In other words, if the displacement of the upper plate due to the earthquake immediately compresses the compression spring 130 inside the reciprocating compression spring damper 100 and absorbs seismic energy primarily to prevent damage to the fall prevention device or the upper plate. At the same time, it can effectively block the fall of the tops.

     Second, by providing a reciprocating compression spring damper with a relatively beautiful appearance, it can enhance the aesthetics of the bridge itself, and minimize the unnecessary anxiety composition of the user.

Third, as well as the new bridges can be attached to the existing bridges in a simple way, so that the construction can be reduced as well as the air shortening.

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

FIG. 1 is a perspective view showing an inner cylinder 110 and a compression spring 130 installed therein, a spring support plate 33, and an impact absorbing pad 44, and FIG. 2 is coupled to the inner cylinder 110. As the outer cylinder 120 is shown, the state in which the outer cylinder 120 is cut in order to clearly show the coupling structure is also shown.

The inner cylinder 110 is composed of a front plate 113, a rear plate 114 and a lower plate 115, the lower plate 115 by connecting the lower portion of each of the front plate 113 and the back plate 114 integrally. It has a cross-sectional structure in which the 'c' letter is rotated 90 degrees.

The compression spring 130 is installed in the inner space of the inner cylinder 110 composed of the front plate 113, the rear plate 114, and the lower plate 115.

The outer cylinder 120 has a rectangular tube shape as a whole and is coupled to surround the outside of the inner cylinder 110 as shown in FIG. 2.

The spring pressing plate 123 is coupled to the upper end of the inner cylinder 110 of the outer cylinder 120 by welding or the like, both ends of which cross the space between the front plate 113 and the rear plate 114 of the inner cylinder 110. The upper portion of the compression spring 130 is elastically supported.

If the outer cylinder 120 is provided with a cutout portion 55 for receiving the spring pressing plate 123 as shown in FIG. 2, the spring pressing plate 123 may be more conveniently fixed to the outer cylinder 120. .

In addition, as shown in FIG. 2, the outer cylinder 120 may be made in two pieces, and in the process of assembling on the outside of the inner cylinder 110, it may be manufactured by a method of making it integral with each other. It is also possible to insert a single outer cylinder 120 in the form of a square tube directly coupled to the outside of the inner cylinder.

The spring support plate 33 is installed between the upper portion of the compression spring 130 and the lower surface of the spring compression plate 123, and between the lower portion of the compression spring 130 and the upper surface of the lower plate 115, respectively, the shock absorbing pad 44 is attached to the surface of each of the spring support plate 33 abuts on each of the lower surface of the spring pressing plate 123 and the upper surface of the lower plate 115.

The outer cylinder cap 122 is coupled to the lower end of the outer cylinder 120, the inner cylinder cap 112 is exposed to the upper end of the outer cylinder 120, the outer cylinder cap 122 is not coupled to the inner cylinder 110 Is coupled to the top of the.

When the outer cylinder cap 122 and the inner cylinder cap 112 are pulled from each other in such a state that the compression spring 130 is compressed between the spring compression plate 123 and the lower plate 115, such a compression spring ( The elastic action of 130 is used to absorb seismic energy.

Figure 3 is a specific embodiment of the fall prevention device using the reciprocating compression spring damper 100, showing the case where the fall prevention device is attached to the side of the upper plate of the adjacent bridge.

3, the outer cylinder connecting rod 220 is coupled to the outer surface of the outer cylinder cap 122 in the longitudinal direction, the inner cylinder connecting rod 210 in the longitudinal direction on the outer surface of the inner cylinder cap 112. Combined to form a straight line.

The outer cylinder connecting ring 240 is pinned to be rotatable in a vertical direction (rotation along the ground on the drawing) to the end of the outer cylinder connecting rod 220, the inner cylinder connecting ring 230 is the inner cylinder connecting rod (210) The pin is rotatably pinned in the vertical direction (rotation along the ground on the drawing).

The outer cylinder bracket 260 is attached (fixed) to the bridge structure (the side of any one of the top plate of the adjacent bridge in the drawing) using an anchor bolt, etc., the outer cylinder bracket 260 is the outer cylinder connecting ring 240 It is pivotally pinned to the end of the roller in a horizontal direction (a direction that rotates to protrude above the ground or to dig into the ground).

The inner cylinder bracket 250 is attached (fixed) to the bridge structure (another side of the upper plate of the adjacent bridge in the drawing) using an anchor bolt, etc., the inner cylinder bracket 250 is the inner cylinder connecting ring 230 It is pivotally pinned to the end of the roller in a horizontal direction (a direction that rotates to protrude above the ground or to dig into the ground).

In other words, the outer cylinder connecting ring 240 and the inner cylinder connecting ring 230 have a structure similar to that of the universal joint used for the rotating shaft, respectively.

The outer cylinder linking ring 240 and the inner cylinder linking ring 230 having such a structure are provided to effectively cope with relative displacements (up, down, left and right) of adjacent bridge top plates, and the impact energy caused by the earthquake acts on the bridge top plate. Thus, even if the horizontal vibration and vertical vibration of the top plate occurs repeatedly, the compression spring 130 is compressed to effectively attenuate such seismic energy.

Figure 4 is another specific embodiment of the fall prevention device using the reciprocating compression spring damper 100, when the fall prevention device is installed on the side of the upper portion of the alternating portion and the bridge.

The outer cylinder connecting rod 220 is coupled to the outer surface of the outer cylinder cap 122 in the longitudinal direction, the inner cylinder connecting rod 210 is coupled to the outer surface of the inner cylinder cap 112 in the longitudinal direction to form a straight line.

The structures of the outer cylinder connecting ring 240 and the outer cylinder bracket 260 are the same as in the case of FIG. The outer cylinder bracket 260 is coupled (fixed) by using an anchor bolt or the like on the side of the upper plate adjacent to the alternating portion.

The inner cylinder connecting ring 230 is pivotally coupled to the end of the inner cylinder connecting rod 210 in a vertical direction (rotation along the ground on the drawing).

One end of the connecting screw rod 270 is pivotally pinned to the end of the inner cylinder connecting ring 230 in a horizontal direction (a direction to rotate to protrude above the ground or to penetrate below the ground). The other end of 270 is provided with a thread 271 on the outer circumferential surface.

The other end of the connecting screw rod 270 is installed to penetrate the bridge structure (alternating portions supporting both ends of the bridge), as shown in Figure 4, of the connecting screw rod 270 protruding through the bridge structure The lock nut 272 is fastened to the thread 271 provided at the other end.

In addition, between the lock nut 272 and the bridge structure, a disk-shaped buffer rubber pad 273 having a hollow is further provided to act as a buffer.

A pressure plate 274 of the same type as the cushioning rubber pad 273 may be further provided between the lock nut 272 and the cushioning rubber pad 273 so as to press the cushioning rubber pad as a whole.

In this way, by connecting the alternating part and the bridge top by using the fall prevention device, it is possible to effectively cope with the relative displacements (up, down, left and right) of the bridge top and the alternating part. Even if the vibration and vertical vibration occurs repeatedly, the compression spring 130 is compressed to effectively attenuate such seismic energy.

5 is another specific embodiment of the fall prevention device using the reciprocating compression spring damper 100, the fall prevention device is installed on the lower surface of the upper plate of the bridge adjacent to the bridge.

The outer cylinder connecting rod 220 is coupled to the outer surface of the outer cylinder cap 122 in the longitudinal direction, the inner cylinder connecting rod 210 is coupled to the outer surface of the inner cylinder cap 112 in the longitudinal direction to form a straight line.

The outer cylinder bracket 260 is pinned to be rotatable in a vertical direction (rotational direction along the ground on the drawing) to the end of the outer cylinder connecting rod 220, using an anchor bolt, etc. in the bridge structure (bottom surface of the bridge top plate) Attach it.

The inner cylinder bracket 250 is pivotally pinned to the end of the inner cylinder connecting rod 210 in a vertical direction (rotational direction along the ground on the drawing) and attached to the bridge structure (pier) using anchor bolts or the like.

In this way, by connecting the lower surface of the bridge and the adjacent bridge deck using the fall prevention device, it is possible to effectively cope with the relative displacement (up, down, left and right) of the bridge deck and the bridge, and the impact energy caused by the earthquake acts on the bridge deck. Thus, even if the horizontal vibration and vertical vibration of the top plate occurs repeatedly, the compression spring 130 is compressed to effectively attenuate such seismic energy.

As described above, the technical spirit of the present invention has been described with reference to specific embodiments of the present invention, but the protection scope of the present invention is not necessarily limited to these embodiments, and various modifications may be made without departing from the technical spirit of the present invention. Design changes, additions or deletions of known technology, simple numerical limitations, etc., are also within the protection scope of the present invention. In particular, in the specific embodiments shown in FIGS. 3 to 5, other components are the same and only the inner cylinder 110 is used. Even if only the positions of the outer cylinder 120 and the change in each other there is no difference in the technical configuration or effect of the same invention to be clear that it belongs to the protection scope of the present invention.

1 is a perspective view showing an inner cylinder 110 and a compression spring 130, a spring support plate 33, and an impact absorbing pad 44 installed therein.

2 shows the outer cylinder 120 coupled to the inner cylinder 110, together with the state in which the outer cylinder 120 is cut out to clearly show the coupling structure.

FIG. 3 is a specific embodiment of the fall prevention device using the reciprocating compression spring damper 100 shown in FIG. 2 and shows a case in which it is attached to the side of the upper plate of an adjacent bridge.

Figure 4 is a specific embodiment of the fall prevention device using the reciprocating compression spring damper 100 shown in Figure 2, showing a case of connecting the alternating portion and the top plate.

FIG. 5 is a specific embodiment of the fall prevention device using the reciprocating compression spring damper 100 shown in FIG. 2, and illustrates a case in which a pier and a top plate are connected. In this case, an inner cylinder connecting ring 230 and an outer cylinder are illustrated. The link ring 240 is not used.

6 is a cross-sectional structure showing the operation of the reciprocating compression spring damper 100.

<Description of the symbols for the main parts of the drawings>

100: reciprocating compression spring damper

110: inner cylinder

112: inner cylinder cap

113: front panel

114: back plate

115: bottom plate

120: outer cylinder

122: outer cylinder cap

123: spring press plate

130: compression spring

210: inner cylinder connecting rod

220: external cylinder connecting rod

230: inner cylinder connecting ring

240: outer cylinder connecting ring

250: inner cylinder bracket

260: outside cylinder bracket

270: connecting screw rod

271: screw thread

272 lock nuts

273: cushioning rubber pad

274: Acupressure plate

33: spring support plate

44: Shock absorption pad

55: incision

Claims (6)

The present invention relates to a compression spring damper that efficiently absorbs shock such as an earthquake The front plate 113, the back plate 114, and the lower portion of each of the front plate 113 and the back plate 114 are integrally combined to integrally integrate the front plate 113 and the back plate 114. An inner cylinder 110 composed of a lower plate 115 for connecting; A compression spring (130) installed in an inner space of the inner cylinder (110) including the front plate (113), the back plate (114), and the lower plate (115); An outer cylinder 120 having a rectangular tube shape surrounding the outside of the inner cylinder 110; Both ends of the inner cylinder 110 may be coupled to an upper portion of the inner surface of the outer cylinder 120 across the space between the front plate 113 and the rear plate 114, and may be elastic on the upper portion of the compression spring 130. Supported spring pressing plate 123; An outer cylinder cap 122 coupled to a lower end of the outer cylinder 120; And, An inner cylinder cap 112 coupled to an upper end of the inner cylinder 110 exposed to an upper end of the outer cylinder 120 to which the outer cylinder cap 122 is not coupled; Reciprocating compression spring damper, characterized in that comprising a. In claim 1, A spring support plate 33 installed between an upper portion of the compression spring 130 and a lower surface of the spring compression plate 123 and between a lower portion of the compression spring 130 and an upper surface of the lower plate 115; Is included more, A shock absorbing pad (44) formed on a surface of each of the spring support plates (33) contacting each of the lower surfaces of the spring compression plates (123) and the upper surfaces of the lower plates (115); Reciprocating compression spring damper, characterized in that is further provided. The present invention relates to a fall prevention device using the reciprocating compression spring damper (100) according to any one of claims 1 to 7, An outer cylinder connecting rod 220 coupled to the outer surface of the outer cylinder cap 122 in a longitudinal direction; An inner cylinder connecting rod 210 coupled to the outer surface of the inner cylinder cap 112 in a longitudinal direction; An outer cylinder connecting ring 240 that is pin-coupled to the end of the outer cylinder connecting rod 220 in a vertical direction to be rotatable; An inner cylinder connecting ring 230 pivotally coupled to an end of the inner cylinder connecting rod 210 in a vertical direction; An outer cylinder bracket 260 pinned to the end of the outer cylinder connecting ring 240 in a horizontal direction and attached to a bridge structure; And, An inner cylinder bracket 250 pinned to the end of the inner cylinder connecting ring 230 in a horizontal direction and attached to a bridge structure; Falling prevention device using a compression spring damper, characterized in that comprising a. The present invention relates to a fall prevention device using the reciprocating compression spring damper (100) according to any one of claims 1 to 7, An outer cylinder connecting rod 220 coupled to the outer surface of the outer cylinder cap 122 in a longitudinal direction; An inner cylinder connecting rod 210 coupled to the outer surface of the inner cylinder cap 112 in a longitudinal direction; An outer cylinder connecting ring 240 that is pin-coupled to the end of the outer cylinder connecting rod 220 in a vertical direction to be rotatable; An inner cylinder connecting ring 230 pivotally coupled to an end of the inner cylinder connecting rod 210 in a vertical direction; An outer cylinder bracket 260 pinned to the end of the outer cylinder connecting ring 240 in a horizontal direction and attached to a bridge structure; One end is connected to the end of the inner cylinder connecting ring 230 in a horizontally rotatable pin coupling and the other end is provided with a screw thread (271) on the outer circumferential surface, the connection screw rod 270 is installed to penetrate the bridge structure; A lock nut 272 fastened to a thread 271 provided at the other end of the connecting screw rod 270 protruding through the bridge structure; Falling prevention device using a compression spring damper, characterized in that comprising a. In claim 4, A buffer pad 273 in the form of a hollow having a hollow formed between the lock nut 272 and the bridge structure; Falling prevention device using a compression spring damper, characterized in that is further provided. The present invention relates to a fall prevention device using the reciprocating compression spring damper (100) according to any one of claims 1 to 7, An outer cylinder connecting rod 220 coupled to the outer surface of the outer cylinder cap 122 in a longitudinal direction; An inner cylinder connecting rod 210 coupled to the outer surface of the inner cylinder cap 112 in a longitudinal direction; An outer cylinder bracket 260 pinned to the end of the outer cylinder connecting rod 220 in a vertical direction and attached to a bridge structure; And, An inner cylinder bracket 250 pinned to the end of the inner cylinder connecting rod 210 in a vertical direction and attached to the bridge structure; Falling prevention device using a compression spring damper, characterized in that comprising a.

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