KR102174473B1 - Earthquake-proof expansion joint - Google Patents

Abstract

The present invention is to minimize damage to the expansion joint installed on the bridge even from impacts such as earthquakes, and as a specific means for solving the problems of the above invention, the base plate 2 and the finger plate installed at the end of the bridge ( In the known expansion joint (1) in which 3) is coupled with a bolt (5), the bolt flow hole in a long hole shape through which the bolt (5) is interposed between the finger plate (3) and the bolt (5) ( 41) is formed, and a buffer protrusion 42 is formed inside the bolt flow hole 41 so that the kinetic energy of the finger plate 3 is absorbed when an external shock occurs when the buffer protrusion 42 is caught in the bolt 5 It is characterized in that it includes a buffering means (4) to reduce the damage of the expansion joint by minimizing the external force applied to the expansion joint even if a large force is applied to the bridge such as an earthquake and a sudden change occurs by the present invention. And thus the durability of the expansion joint is increased, the lifespan of the expansion joint is increased, and maintenance costs are reduced, the loss of time and installation costs due to re-installation or repair work of the expansion joint is reduced, and unnecessary working hours are reduced. In short, it is an invention that can expect a number of effects, such as preventing inconvenience caused by vehicle control of a bridge.

Description

Earthquake-proof expansion joint

The present invention is a seismic expansion joint device, and if this is described in more detail, the damage to the expansion joint device installed on a bridge is minimized even in impact such as earthquakes.

Bridges and bridges are installed at the ends of the separately constructed bridges to prevent the bridge from being deformed or damaged by the load and vibration of the vehicle running or expansion and contraction due to the temperature difference due to the change of seasons and day and night. It is the expansion joint device that connects them.

The expansion joint is configured to respond to regular, predictable, and gentle changes in the bridge, and when it is difficult to predict, such as an earthquake, and a large force is applied to the crust, causing rapid changes, the expansion joints cross each other and face each other. There may be situations in which components that are present collide with each other.

In particular, in the case of the finger plates protruding so as to face each other, they become more susceptible to breakage when colliding by an earthquake or the like.

When the finger plates collide with each other without a separate buffering means, the possibility of damage to a part of the finger plate or the bolt on which the finger plate is fixed or the base plate on which the bolt is fixed becomes very high.

If a part of the expansion joint including the finger plate is damaged, it takes a lot of time to perform a re-installation or restoration work afterwards, resulting in a large economic loss, and disturbing the passage of the vehicle, resulting in inconvenience.

Therefore, even if an unexpected large impact is applied to the expansion joint, a technology to minimize damage such as damage is required.

Among the technologies to solve this problem, in the case of an expansion joint installed between the upper plate and the upper plate as published in Korean Patent Registration No. 1287489 (announced on July 18, 2013), the new construction gap is reduced when the oil gap changes due to the expansion of the bridge upper plate. A pair of finger plates that are interlocked with each other with a predetermined distance between the bridge upper plates to secure them, and a support part including a base plate, an anchor structure, and a futa material are used to support and fix the finger plates. In the expansion joint device, a technology is known in which the finger plate is installed so as to be movable along the length of the bridge through a clearance adjusting means with respect to the base plate forming the support part, but the technology is a constriction of the expansion joint or In the event of an oil gap, the purpose is to maintain the installation state without reinstallation, and there is a problem in that there is no configuration that prevents damage by buffering a momentary strong impact caused by an earthquake or the like.

KR 20-1287489 B1 (2013.07.12.)

In the present invention, a new technology was created in order to solve the problems of the prior art. The present invention improves the expansion joint to buffer the impact applied to the expansion joint by earthquake, etc., thereby minimizing damage to the expansion joint and durability. It is an object of the invention to provide a seismic expansion joint device to increase the height.

Along with this, although not separately described, other objects within the range that can be inferred in consideration of the specific content and claims for carrying out the following invention are also included in the entire subject of the present invention.

In the present invention as a specific means for solving the problem of the above invention, in constructing the seismic expansion joint device, the base plate (2) and the finger plate (3) installed at the end of the bridge are coupled with a bolt (5). In the expansion joint (1) of, it is interposed between the finger plate (3) and the bolt (5), a long hole-shaped bolt flow hole (41) through which the bolt (5) is formed, and the bolt flow hole (41) ), the buffer protrusion 42 is formed on the inner side of the bolt 5 so that the buffer protrusion 42 is locked to the bolt 5 to reduce the kinetic energy of the finger plate 3 when an external shock occurs. Characterized by, the buffer protrusion 42 may be formed to face each other inside the bolt flow hole 41 so that the bolt 5 is interposed therebetween, and the bolt flows according to the direction of the force applied to the finger plate 3 A circular fixing surface 33 formed on the finger plate 3 on which the circular buffer means 4 is placed may be further included so that the ball 41 rotates,

An upper protrusion 43 for reducing the kinetic energy of the finger plate 3 by being caught by the head portion 51 of the bolt 5 may be configured to protrude upward on the upper portion of the buffer protrusion 42, and the buffer means 4 ) The upper surface of the bolt flow hole 41 is formed to be curved in the longitudinal direction, the head portion 51 of the bolt 5 is pressed to reduce the kinetic energy of the finger plate (3) (44) It is characterized in that it may be further included.

According to the specific means for solving the above-described problem, even if a large force is applied to the bridge such as an earthquake and a sudden change occurs, the external force applied to the expansion joint is minimized, thereby minimizing the damage of the expansion joint.

Therefore, the durability of the expansion joint is increased, so that the lifespan is lengthened and the maintenance cost is reduced.

It is possible to reduce the loss of time and installation costs due to re-installation or repair work of the expansion joint, and reduce unnecessary work time, thereby preventing inconvenience due to vehicle control of the bridge.

1 is a side cross-sectional view of an expansion joint to which an example of the present invention is applied
Figure 2 is a three-dimensional view showing the main parts of the present invention separated
3 is a plan view to which an example of the present invention is applied
4A to 4B are plan views showing the action of the present invention
5A to 5I are exemplary views showing various embodiments of a buffer means
4 is a side cross-sectional view showing an embodiment of a buffer pad
5 is a three-dimensional view showing another embodiment of the present invention

The present invention is intended to provide a seismic expansion joint, which will be described in more detail with the drawings below, and the accompanying drawings are only examples for easily explaining the content and scope of the technical idea of the present invention, and are limited thereto. The terms used are not intended to be interpreted as being limited to the corresponding terms as well, only to specifically describe the embodiments.

The seismic expansion joint device of the present invention described above is applied to the end of the bridges are interconnected as shown in Figs. 1 to 2, the base plate 2 and the finger plate coupled to the upper portion of the base plate (2) ( In the known technology of the expansion joint (1) in which 3) is coupled with a bolt (5), a buffer means (4) is further provided between the finger plate (3) and the bolt (5).

A mounting surface 32 is provided on the finger plate 3 so that the buffer means 4 is spaced apart from the base plate 2 and placed in the bolt through hole 31 formed in the finger plate 3.

When the cushioning means 4 is placed on the seating surface 32, the fixing surface 33 contacting the circumference of the buffering means 4 so that the buffering means 4 does not flow unnecessarily is the upper part of the seating surface 32. Is formed orthogonal to

The buffer means (4) has an elliptical bolt flow hole (41) formed in the center, so that the position of the bolt (5) moves fluidly within the range of the bolt flow hole (41), but the bolt (5) is the bolt flow As a suppression means for suppressing the bolt 5 from one side of the ball 41 so that it does not easily pass to the other side, one or more buffer protrusions 42 protrude inwardly on the inner surface of the bolt flow hole 41.

A space part 34 is formed on one side of the finger plate 3 so that when the finger plate 3 is pushed outward, the finger plate 3 is damaged or deformed by colliding with other constituent members of the expansion joint 1 You can also prevent it.

The buffer protrusion 42 may be configured to contact the threaded portion 53 on which the bolt 5 is formed and pressurized, but when the buffer protrusion 42 directly contacts the threaded portion 53, it protrudes horizontally. In order to compensate for the problem that the thread of the threaded part 53 may be worn out as the thread of the thread part 53 comes into contact with the buffer protrusion 42 which is in line contact in the vertical direction in a cross-shape, resulting in point contact. , It would be desirable to configure the buffer protrusion 42 to contact the grip part 52 by using a bolt 5 having a cylindrical grip part 52 having no thread under the head part 51 of the bolt 5. .

3 is a plan view showing a seismic expansion joint device of the present invention is installed.

The structure responds to earthquakes in various ways, but in the case of the present invention, it is close to the seismic isolation method, and the buffer means 4 is a seismic isolation structure that absorbs the kinetic energy of the earthquake and suppresses the direct transmission of vibration to the finger plate. .

When a periodic and strong external force is applied from the side of the expansion joint on a plane due to an earthquake or the like as shown in FIG. 4A, the finger plates 3 facing each other correspond to each other according to the direction of the force, so that the facing finger plates 3 open to each other There is little risk of damage, but on the contrary, the case where the finger plates 3 come into contact with each other and collide is a problem.

If the position of the finger plate (3) is fixed, the vibration of the earthquake acts on the finger plate (3) as it is, and thus the finger plate (3) collides with other components and the force that continues to push even after it collides. When transferred to the finger plate 3, there is a very high possibility that at least one of the finger plate 3 or the base plate 2 or the bolt 5 connecting the finger plate 3 and the base plate 2 will be damaged.

Therefore, as constituting the buffering means (4), the finger plate (3) flows within the range of the bolt flow hole (41), so that the external force is distributed and the force acting on the finger plate (3) is reduced, and in particular, the bolt flow hole ( As the external force is further reduced while the grip part 52 of the bolt 5 is applied to the buffer protrusion 42 formed in 41), the impact acting on the finger plate 3 is attenuated, and the finger plate 3 is initially installed at the position Each can be pushed slightly as much as the range of the bolt flow hole 41, but the possibility of damage is greatly reduced.

When the external force is applied in the vertical direction on the plane as shown in FIG. 4B, the bolt flow hole 41 formed in the buffer means 4 by forming each of the buffer means 4 and the fixing surface 33 in a circular shape is By rotating in response to the external force, the finger plate 3 is slightly pushed in the same direction as the external force acts, thereby partially alleviating the impact, and the bolt 5 is attached to the buffer protrusion 42 formed in the bolt flow hole 41. As it gets caught, the external force is greatly reduced.

When the external force is applied in a diagonal direction on the plane, the direction of the force can be divided into upper and lower sides and sideways, and thus, the above motions may be combined to reduce the external force.

As shown in FIG. 5A, only one buffer protrusion 42 can be formed to a minimum in the inside of the bolt flow hole 41 provided with the buffer means 4.

The buffer protrusion may protrude in a gentle arc shape or may protrude in an angled mountain shape.

The bolt 5 is caught by the buffer protrusion 42 while flowing inside the bolt flow hole 41 to reduce an external force acting on the finger plate 3.

As shown in FIG. 5B, buffer protrusions 42 facing each other may be formed inside the bolt flow hole 41.

The pressing force of the buffer protrusion 42 can be evenly applied to the grip portion 52 of the bolt 5, and the suppression force for pressing the bolt 5 can be doubled compared to when the buffer protrusion 42 is only on one side. .

As shown in Fig. 5c, by forming the flow space of the bolt flow hole 41 divided by the buffer protrusion 42 into a longer long hole, before the bolt 5 is pressed against the buffer protrusion 42 and is caught There is an advantage that is useful for adjusting the installation position of the finger plate 3.

As shown in FIG. 5D, the facing buffer protrusion 42 may be formed to be repeated several times in the longitudinal direction of the bolt flow hole 41, and in this case, between the adjacent buffer protrusion 42 and the buffer protrusion 42 If the gap is formed so as to be spaced apart so that the bolt 5 is inserted, since the bolt 5 is suppressed several times on the buffer protrusion 42, there is an effect of significantly reducing an external force acting on the finger plate 3.

As shown in Fig. 5e, the buffer protrusion 42 facing each other is formed in an angled mountain shape, but the buffer protrusion 42 can be formed to be repeated several times in the longitudinal direction of the bolt flow hole 41, and buffer as described above. When forming the protrusion 42, the distance between the adjacent buffer protrusion 42 and the buffer protrusion 42 is tight, thus maximizing the number of suppression of pressing the bolt 5 inside the bolt flow hole 41 having a limited size. can do.

As shown in Figure 5f, the upper surface protrusion 43 can be formed to protrude upward on the upper surface of the buffer protrusion 42 formed inside the bolt flow hole 41, in which case the bolt 5 is the bolt flow hole ( When moving the space of 41), the grip part 52 of the bolt 5 is pressed against the buffer protrusion 42, and at the same time, the head part 51 of the bolt 5 is caught by the upper protrusion 43 so that a double suppression force is generated. can do.

As shown in Fig. 5g, the buffer means 4 may be formed with a concave buffer surface 44 on the upper surface of the buffer means 4 in a direction in which the bolt flow hole 41 is formed long.

When the concave buffer surface 44 is formed, when the bolt 5 moves along the space of the bolt flow hole 41 when an earthquake occurs, the buffer surface 44 pushes the head portion 51 of the bolt 5 upward. Therefore, there is an effect of preventing the bolt 5 from being damaged while the bolt 5 hits the end of the bolt flow hole 41 due to the rapid movement of the finger plate 3.

As shown in FIG. 5H, a convex buffer surface 44 may be formed on the upper surface of the buffer means 4 in the direction in which the bolt flow hole 41 is formed in the buffer means 4.

When the convex buffer surface 44 is formed, the buffer surface 44 pushes the head 51 of the bolt 5 upward when the bolt 5 moves along the space of the bolt flow hole 41 when an earthquake occurs. Therefore, the grip portion 52 of the bolt 5 is pressed against the buffer protrusion 42 and the head portion 51 of the bolt 5 is pressed against the buffer surface 44 to generate a double suppression force.

As shown in Figure 5i, the bolt flow hole 41 of the buffer means 4 can be formed in a curved shape, and this is a plurality of protrusions so that the buffer protrusions 42 alternate with each other in the bolt flow hole 41 of the long hole Is similar to forming

When the bolt flow hole 41 is formed in a wave shape, the bolt flow hole 41 is not straight, so the length of the bolt 5 flowing in the bolt flow hole 41 becomes longer, so that the impact is caused by that length. It will be attenuated.

The bolt flow hole 41 is curved in a wave shape, and when the finger plate 3 receives force from one side, the bolt 5 moves the bolt flow hole 41 in a straight line, the part protruding from the wave shape Since the phosphorus buffer protrusion 45 is caught several times, the kinetic energy of the finger plate 3 is reduced.

As shown in FIG. 6, a buffer pad 35 may be additionally formed between the finger plate 3 and the concrete.

When the buffer pads 35 are added, shocks are attenuated from the rear of the finger plates 3 when the finger plates 3 are pressed against each other to provide additional buffering force to the buffer means 4.

As shown in FIG. 7, a key groove (K1) is formed on each of the buffer means (4) and the fixing surface (33), and key fasteners (K2) such as a key or an additional bolt are fastened to the key groove (K1), By preventing unintentional rotation, it is possible to limit the moving direction of the finger plate 3 when the shock is attenuated by the buffering means 4.

As described above, the most preferred embodiments of the present invention have been described in the detailed description of the present invention, but various modifications may be made within the scope of the technical scope of the present invention. Therefore, the scope of protection of the present invention is not limited to the above embodiments, but the scope of protection should be recognized from the techniques of the claims to be described later and from these techniques to equivalent technical means.

1: Expansion joint
2: Base plate 21: Bolt coupling hole
3: finger plate 31: bolt through hole 32: inner tooth surface 33: fixed surface
34: separation space 35: buffer pad
4: buffering means 41: bolt flow hole 42: cushioning protrusion 43: upper protrusion
44: cushioning surface 45: cushioning protrusion
5: bolt 51: head portion 52: grip portion 53: thread portion
K1: Keyway K2: Key fastener

Claims (7)

In the known expansion joint (1) in which the base plate (2) and the finger plate (3) installed at the end of the bridge are joined with a bolt (5),
Interposed between the finger plate (3) and the bolt (5), a long hole-shaped bolt flow hole (41) through which the bolt (5) passes, and a buffer protrusion (42) is formed inside the bolt flow hole (41). A buffer means (4) for preventing damage or deformation of the finger plate (3) when an external impact occurs by forming the buffer protrusion (42) on the bolt (5);
An upper protrusion 43 configured to protrude upward to reduce the kinetic energy of the finger plate 3 by being engaged with the head portion 51 of the bolt 5 on the upper portion of the buffer protrusion 42;
Seismic expansion joint, characterized in that included.
In the known expansion joint (1) in which the base plate (2) and the finger plate (3) installed at the end of the bridge are joined with a bolt (5),
Interposed between the finger plate (3) and the bolt (5), a long hole-shaped bolt flow hole (41) through which the bolt (5) passes, and a buffer protrusion (42) is formed inside the bolt flow hole (41). A buffer means (4) for preventing damage or deformation of the finger plate (3) when an external impact occurs by forming the buffer protrusion (42) on the bolt (5);
A buffer that reduces the kinetic energy of the finger plate 3 by pressing the head portion 51 of the bolt 5 by forming the upper surface of the buffer unit 4 to be curved in the longitudinal direction where the bolt flow hole 41 is formed. Cotton 44;
Seismic expansion joint device, characterized in that included.
delete delete delete delete delete

Images