KR200256843Y1 - Bridge having pot bearing - Google Patents

Abstract

Disclosed is a teaching device capable of absorbing horizontal, vertical and rotational forces acting on a leg. The bridge device of such a leg is fixed to the bottom of the upper plate and the upper member is formed with a guide groove in the horizontal direction at the lower end, the lower member fixed to the upper surface of the piers, fixed to the upper portion of the lower member, the seating groove on the upper surface Is formed so that the lower end of the upper member is inserted into the middle of the seating groove and the seating groove of the middle member, the guide jaw is formed protruding on the upper surface can slide in the guide groove of the upper member It is coupled to the elastic member for absorbing the vertical force and the rotational force transmitted from the upper member, and at least one damper mounted on the upper portion of the pier is connected to the intermediate member to absorb the horizontal force.

Description

Bridge device {BRIDGE HAVING POT BEARING}

The present invention relates to a bridge device, and more particularly, by forming a guide jaw for guiding a horizontal force in a predetermined direction on an upper portion of the elastic portion, when the rotation force acts on the upper plate, the elastic portion is pressed by the guide jaw. A bridge scaffold device capable of absorbing properly.

In general, a bridge includes a top plate that a vehicle or a person can pass, a plurality of piers supporting the top plate, and a bridge device mounted between the top plate and the piers to absorb shock and displacement.

Such a bridge is designed to withstand deformation loads by transmitting an impact when a vehicle passes or an earthquake occurs. In particular, in recent years, seismic isolation and seismic preparation devices for earthquakes have been developed and installed in bridges.

As shown in FIG. 1, the seismic and seismic legs are mounted on the plurality of piers 2, and the multi-point supports supported by the stabilization device 4 at each piers 2. That's the way. The bridge having the above structure is the top plate 1 is fixed by one of the plurality of bridges (2), preferably by the bridge (3) located in the middle, the bridge device 4 is not fixed to the other bridge piers It has a structure on which it is placed.

Therefore, when an external force such as an earthquake acts on the leg, the vertical force is absorbed by the bridge device 4, and the horizontal force is fixed to the bridge 3 located in the middle of the upper plate. The horizontal force is transmitted to the other piers 2. At this time, since the bottom surface of the upper plate 1 is in sliding contact with the upper surface of the bridge device 4, the horizontal force is absorbed by sliding in one direction about the bridge 3 located in the middle.

As shown in FIG. 2, the chair apparatus 4 includes an upper member 5 attached to the bottom surface of the upper plate 1, a lower member 6 attached to the upper surface of the piers 2, and the upper portion. And an intermediate member (7) mounted between the lower members (5, 6), an elastic member (8) mounted inside the intermediate member (7) to absorb horizontal force by an appropriate elastic force, and to absorb vertical force. It includes a damper (Damper) (9).

Therefore, when the vertical force is applied to the chair device 4, the elastic member 8 contracts to absorb the vertical force.

In addition, when a horizontal force acts on the upper plate 1, the upper plate 1 is placed on the upper surface of the chair device 4, so that the upper plate 1 slides in the horizontal direction to absorb the horizontal force.

At this time, the guide jaw 10 protruding from the bottom of the intermediate member 7 is moved in the horizontal direction along the guide groove (11). Therefore, the upper plate 1 is guided in a predetermined direction by preventing the upper plate 1 from moving in any direction by the horizontal force.

However, when the rotational force acts on the cross-section device other than the horizontal force and the vertical force in the structure of such a structure, the elastic member contracts within a certain range to absorb the rotational force, but when it exceeds the predetermined range, the rigid guide guide It comes into contact with the inside of this guide groove. Therefore, the teaching device is no longer able to absorb the rotational force, there is a problem that the whole of the teaching apparatus can be broken by breaking the guide jaw when excessive rotational force is applied.

An object of the present invention was devised to solve the above problems, the guide jaw pressed by the top plate when the rotation force acts on the top plate of the leg by slidably coupled to the bottom of the top plate by forming the guide jaw on the upper side of the elastic member It is to provide a leg stabilization device that can absorb the rotational force by pressing the elastic member to properly respond to the rotational force as well as the vertical force, horizontal force.

1 is a schematic view showing the structure of a general bridge.

Figure 2 is a side view showing the device of the bridge according to the prior art.

Figure 3 is a side view showing the bridge device of the present invention.

FIG. 4 is a side view of the stapling device of the leg shown in FIG. 3; FIG.

Fig. 5 is a sectional view showing a section 'A-A' shown in Fig. 3;

Figure 6 is an operating state showing a state in which the bridge device of the operation device according to the present invention.

In order to achieve the object of the present invention, a preferred embodiment of the present invention is fixed to the bottom surface of the upper plate and the lower member is formed in the horizontal direction in the guide groove, the lower member fixed to the upper surface of the piers, and the lower member It is fixed to the upper portion of the upper surface of the seating groove is formed so that the lower end of the upper member is inserted into the interior of the seating groove, and the seating groove of the intermediate member is located inside the guide jaw protruding from the upper surface An elastic member which is formed and slidably coupled to the guide groove of the upper member to absorb the vertical force and the rotational force transmitted from the upper member, and at least one absorbing the horizontal force by being attached to the upper portion of the pier and connected to the intermediate member It provides a bridge device including a damper of the.

According to a preferred embodiment of the present invention, the elastic member includes a pad made of a material having an elastic force and laminated in a multi-layer therein, and an upper plate attached to the upper portion of the pad, the guide jaw on the upper surface of the upper plate It is formed to protrude upward.

Protruding jaws are formed on both sides of the intermediate member, and the dampers are mounted between the protruding jaws to absorb external forces in the horizontal direction. The damper is fixed to the lower member and is filled with a fluid filled therein, and is mounted so as to be movable in the interior of the cylinder and both sides are connected to the inner surface of the protrusion of the intermediate member respectively to absorb the horizontal force acting on the intermediate member It includes a piston.

Hereinafter, with reference to the accompanying drawings will be described in detail a bridge device according to a preferred embodiment of the present invention.

3 to 5, the bridge device 50 disclosed in the present invention is the upper member 52 is attached to the bottom surface of the upper plate 51, and the lower member (attached to the upper surface of the piers 53) ( 54), an intermediate member 55 disposed between the upper and lower members 52 and 54, and an elastic member 59 positioned inside the intermediate member 55 to absorb vertical force. In addition, a pair of dampers 60 are mounted on the pier 53 to absorb the horizontal force acting on the intermediate member 55.

The upper member 52 has a cylindrical shape and is fixed to the bottom surface of the upper plate 51 by fixing members 61 such as bolts. In addition, a guide groove 62 having a predetermined depth is formed in a horizontal direction on the bottom surface of the upper member 52, and the guide jaw 58 of the elastic member 59, which will be described later, is formed in the guide groove 62 in the horizontal direction. Are slidably combined.

As shown in FIG. 5, the intermediate member 55 has a 'I' shape plane and a cylindrical mounting groove 63 is formed to a predetermined depth from an upper surface thereof. In addition, an elastic member 59 having appropriate elasticity is mounted inside the seating groove 63. In addition, a lower end of the upper member is positioned above the seating groove 63.

Therefore, when the upper member 52 is pressed downward by the vertical force, the lower end of the upper member 52 is inserted into the seating groove 63 to press the elastic member 59 so that the elastic member As 59 is contracted inside the seating groove 63, the vertical force is absorbed.

The elastic member 59 is a compressed rubber material having a predetermined elastic force, the pad 56 is formed in a multi-layer inside the elastic member 59 is embedded. Therefore, when the vertical force is applied to the upper plate 51, the upper member 52 is moved downward to absorb the vertical force by pressing the elastic member 59.

In addition, the upper portion of the elastic member 59, the flat plate 57 is integrally formed, and the guide jaw 58 protrudes upward from the middle portion of the flat plate 57. A fluororesin plate 64 is attached to both sides of the guide jaw 58. In addition, a stainless steel plate 65 is attached to the bottom of the upper member 52. Therefore, when the upper plate 51 is moved in the horizontal direction by the horizontal force, the fluorine resin plate 64 is prevented from being deteriorated and burned out by frictional contact with the stainless steel plate (65).

In addition, the guide jaw 58 is slidably coupled to the inside of the guide groove 62 of the upper member 52. Therefore, when the horizontal force is applied to the upper plate 51, the guide jaw 58 slides in the horizontal direction along the guide groove 62 to guide the upper plate 51 to slide in a predetermined direction.

In addition, the guide jaw 58 is formed on the upper portion of the elastic member 59 to properly absorb the rotational force acting on the chair device (50). That is, since the guide jaw 58 of the elastic member 59 is coupled to the guide groove 62 of the upper member 52, as shown in FIG. 6, in this state, the direction of the arrow on the upper plate 51 is shown. When the rotational force of 69 is applied, the upper member 52 is inclined at a predetermined angle so that the guide groove 62 is also inclined at a predetermined angle. At this time, the guide jaw 58 of the elastic member 59 is inserted into the guide groove 62 of the upper member 52, the elastic member 59 is inclined at a predetermined angle. Therefore, the inclined one side of the elastic member 59 is pressed, the other side is inflated by the elastic force. As a result, the rotational force acting on the upper plate 51 is absorbed by the elastic member 59.

Meanwhile, in the intermediate member 55, protrusions 66 are formed on both sides of the intermediate member 55, respectively, as shown in FIG. 5, and the damper 60 is formed inside the protrusion 66. Each is equipped.

That is, the dampers 60 are fixed to the upper surface of the piers 53, respectively, and both ends 68 are connected to the protrusions 66 of the intermediate member 55, respectively. Therefore, when the horizontal force acts on the intermediate member 55, the damper 60 is moved in the horizontal direction to absorb the external force.

The damper 60 has a space formed therein so that the cylinder 67 is filled with fluid, and is mounted so as to be movable in the cylinder 67, and both ends thereof are formed on the inner surface of the protrusion 66 of the intermediate member 55. It consists of pistons 69 connected to each. Since a predetermined fluid is filled in the inside of the cylinder 67, when the piston 69 moves by an external impact, the shock is absorbed by the fluid.

As described above, when the vertical force, horizontal force, and rotational force act on the upper plate 51 by the external load, the elastic member 59 absorbs the vertical force and the rotational force, and the pair of dampers 60 are horizontal force. Will absorb. Therefore, the teaching apparatus 50 absorbs horizontal force, vertical force, and rotational force within a predetermined range.

As described above, the chair arrangement of the upper plate according to the preferred embodiment of the present invention has an advantage of efficiently absorbing rotational force when an external load acts on the upper plate by forming the guide jaw on the upper portion of the elastic member.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications can be made within the scope of the utility model registration request and the detailed description of the invention and the scope of the accompanying drawings. Of course, this also belongs to the scope of the present invention.

Claims (4)

An upper member fixed to the bottom of the upper plate and having a guide groove formed in a horizontal direction at a lower end thereof; A lower member fixed to an upper surface of the piers; An intermediate member fixed to an upper portion of the lower member and having a seating groove formed on an upper surface thereof, such that a lower end of the upper member is inserted into the seating groove; An elastic member positioned inside the seating groove of the intermediate member, the guide jaw protruding from the upper member to slidably coupled to the guide groove of the upper member to absorb the vertical force and the rotational force transmitted from the upper member; And And at least one damper mounted on an upper portion of the pier and connected to the intermediate member to absorb horizontal force. According to claim 1, wherein the elastic member is laminated in a multi-layer therein and includes a pad made of a material having an elastic force, and an upper plate attached to the upper portion of the pad, the guide jaw protrudes upward on the upper surface of the upper plate The device of the bridge formed. The bridge assembly of claim 1, wherein the intermediate member has protrusion protrusions formed at both sides thereof, and the damper is mounted between the protrusion protrusions to absorb external force in a horizontal direction. The intermediate member of claim 3, wherein the damper is fixed to the lower member and is filled with a fluid filled therein, and is mounted to be movable in the cylinder, and both sides thereof are respectively connected to an inner surface of the protrusion of the intermediate member. A leg stabilization device comprising a piston that absorbs a horizontal force acting on.