KR102523632B1 - Shear key for bridge capable of spacing adjustment and displacement measurement - Google Patents

Abstract

The present invention relates to a shear key for a bridge capable of adjusting a spacing and measuring displacement. In the shear key installed between an upper part structure and a lower part structure of the bridge, the shear key for the bridge capable of adjusting the spacing and measuring the displacement of the present invention comprises: an upper part plate (100) provided with an upper part guide protrusion (110) downward; a lower part plate (200) provided with a guide installation groove (210); and a pair of lower part guide protrusions (300) installed in the guide installation groove (210), an installation gap of which can be adjusted in the direction perpendicular to the longitudinal direction of the guide installation groove (210). An objective of the present invention is to provide the shear key for the bridge capable of adjusting the spacing and measuring the displacement, which can easily and precisely adjust the spacing.

Description

Shear key for bridge capable of spacing adjustment and displacement measurement}

The present invention relates to a shear key for a bridge installed between an upper structure and a lower structure of a bridge in order to prevent the bridge superstructure from falling or the bridge bearing from being damaged during an earthquake.

More specifically, a guide installation groove is provided in the lower plate constituting the shear key, the position of the lower guide protrusion installed in the guide installation groove can be easily adjusted, and a displacement indicator capable of measuring displacement is provided, so that the displacement can be easily and easily performed. It relates to a shear key for bridges capable of quickly measuring spacing and displacement.

Seismic loads generated during earthquakes have the greatest impact on the safety, usability and durability of bridges. Therefore, when designing a bridge, various measures are taken to improve the seismic performance of the bridge.

When the shear force generated in the bridge bearing due to an earthquake or the like exceeds the resistance capability that the bridge bearing can resist, the bridge bearing cannot resist any longer and cannot provide the necessary horizontal stability to the bridge.

Accordingly, a shear key is installed between the bridge superstructure and the substructure to suppress the horizontal shear force.

The shear key is installed so that a certain distance is formed between the opposing positions of the upper projection of the upper plate and the lower projection of the lower plate. In this case, the restraining wedge of the bridge bearing bears all the horizontal force, resulting in fracture.

Therefore, in order for the shear key to perform its function and respond effectively to the earthquake load, it is necessary to accurately set and install the distance between the upper and lower projections. In the conventional shear key, it was difficult to adjust the exact distance between the lower plate and the upper plate in the field. However, the distance between both sides of the upper projection must match, but it was very difficult to match it exactly at the construction site.

In addition, there has been a prior art in which a displacement measuring means for measuring displacement has been applied to a bridge bearing, but since a separate displacement measuring device must be installed on the bridge bearing, the device is complicated and inefficient, parts are increased, and additional installation costs are incurred. There was a problem with the time required.

Therefore, it was necessary to develop a shear key for bridges that can easily adjust the distance between the upper plate and the lower plate and has an efficient structure that can easily measure the displacement by a simple structure.

Korea Patent No. 10-2376758

In order to improve the above problems of the prior art, in the present invention, the purpose of providing a shear key for bridges capable of adjusting the distance and measuring the displacement that can easily and precisely adjust the distance between the upper guide projection and the lower guide projection at the construction site do.

An object of the present invention is to provide a shear key for bridges capable of adjusting spacing and measuring displacement, which can easily measure displacement without adding a separate special device.

An object of the present invention is to provide a shear key for bridges capable of adjusting the distance and measuring the displacement that can be applied in a fixed end format by restricting the relative displacement between the upper guide projection and the lower guide projection.

In the present invention, in the shear key installed between the upper structure and the lower structure of the bridge, the upper plate 100 is provided with an upper guide projection 110 downward; A lower plate 200 provided with a guide installation groove 210; It is installed in the guide installation groove 210, and includes a pair of lower guide protrusions 300 capable of adjusting the installation interval in the longitudinal direction and the vertical direction of the guide installation groove 210, spacing adjustment and displacement measurement. Provides a shear key for bridges that can do this.

The lower guide protrusion 300 includes a lower member 310 and a vertical member 320, and the width w2 of the guide installation groove 210 is greater than the width w1 of the lower member 310. characterized by

A reaction arm 220 is provided in the guide installation groove 210, and a spacing control plate 400 is provided between the reaction arm 220 and the lower member 310.

A bolt tap 211 is provided in the guide installation groove 210, and a bolt fastening hole 311 penetrating vertically is provided in the lower member 310, and a fastening bolt 240 is provided with the bolt fastening hole 311. ), and by fastening to the bolt tap 211, it is characterized in that the lower guide projection 300 is installed.

A reinforcing member 230 having a long hole 231 is fixed to an end of the lower plate 200, and a bolt tap 301 is provided to an end of the lower guide protrusion 300, and fastened with the long hole 231. It is characterized in that the bolt 250 is passed through and fastened to the bolt tap 301.

A displacement indicator 500 attached to the upper plate 100 is further included, and the lower guide protrusion 300 is provided with a scale 510.

The displacement indicating unit 500 includes a fixing part 511 and an indicating part 512, the fixing part 511 and the indicating part 512 form an L shape, and the fixing part 511 is the upper plate ( 100) and/or includes a fixing part 521 and an indicating part 522, wherein the fixing part 521 and the indicating part 522 form a T-shape, and the fixing part 521 It is characterized in that it is attached to the side or bottom surface of the upper plate (100).

A through hole 1111 is formed in the upper guide protrusion 110, a through hole 321 is formed in the vertical member 320, and a fixing inserted into the through hole 1111 and the through hole 321 together. A member 600 is further included.

In normal times, the longitudinal displacement of the upper guide projection 110 and the lower guide projection 300 is limited by the fixing member 600, and when the horizontal force caused by an earthquake exceeds a certain level, the fixing member 600 shears and fractures. Thus, displacement in the longitudinal direction of the upper guide projection 110 and the lower guide projection 300 is allowed, and the magnitude of the horizontal force caused by the earthquake that causes the fixing member 600 to break is the shear strength of the fixing member 600 , It is characterized in that it is adjustable by the cross-sectional size and quantity.

The spacing control plate 400 is characterized in that one or more are provided and installed to meet the required spacing.

The shear key for bridges capable of spacing adjustment and displacement measurement of the present invention has the following effects.

First, it is possible to easily adjust the installation distance of the lower guide protrusions 300 by properly providing the distance adjusting plate 400 between the reaction arm 220 and the lower member 310 at the bridge construction site. In particular, if the thickness of the spacing control plate is thin, very precise spacing adjustment is possible.

Second, simply by inserting the gap control plate 400 between the reaction arm 220 and the lower member 310 and fastening the lower guide protrusion with a fastening bolt, the distance adjustment operation is completed, so installation and disassembly of the shear key , maintenance and replacement are very easy.

Third, a plurality of spacing control plates 400 may be provided, and by having various thicknesses of the spacing control plates 400, both time reduction and precise spacing control of the spacing adjustment operation are possible.

Fourth, since the lower member 310 penetrates vertically and is provided with a bolt fastening hole 311 and is fastened by passing the fastening bolt 240 through the bolt fastening hole 311, the bolt fastening hole 311 It is easy to adjust the position of the lower guide protrusion and fasten it.

Fifth, by attaching the L-shaped displacement indicator to the end of the upper plate 100 or by attaching the T-shaped displacement indicator to the side or lower surface of the upper plate, the displacement can be easily checked with the naked eye.

Sixth, by the fixed member passing through the upper guide projection and the lower guide projection together, it can be applied as a shear key of a fixed end type, and when an earthquake load is applied, the fixed member is sheared and fractured, and it is possible to change to a movable end. At this time, the magnitude of the seismic load at which the fixing member is broken can be determined by adjusting the strength, cross-sectional size, quantity, etc. of the fixing member to shear and fracture when the seismic load is applied.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a perspective view (with a spacing control plate) of one embodiment of the present invention.
Figure 2 is a perspective view (without a spacing control plate) of one embodiment of the present invention.
Figure 3 is a front view and a perspective view of the top plate of the present invention.
Figure 4 is a front view and a perspective view of the lower plate of the present invention.
5 is a front view and a perspective view of a lower guide protrusion of the present invention.
6 is a front view and a perspective view of the spacing control plate of the present invention.
7 to 10 show an embodiment for adjusting the installation interval of the lower guide projections.
11 is a perspective view (with a spacer control plate) of another embodiment of the present invention.
12 is a perspective view (without a spacing control plate) of another embodiment of the present invention.
13 is a perspective view of a lower plate of another embodiment of the present invention.
14 is a perspective view of a lower guide projection of another embodiment of the present invention.
15 is a front view of a displacement indicator of the present invention.
16 is a perspective view showing an embodiment of a displacement indicator.
17 is a cross-sectional view in which a fixing member is installed.

Hereinafter, embodiments of the present invention will be described in detail so that those skilled in the art can easily practice with reference to the accompanying drawings. However, the present invention may be embodied in many different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification. Throughout the specification, when a certain component is said to "include", it means that it may further include other components without excluding other components unless otherwise stated. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention relates to a shear key for a bridge installed between an upper structure and a lower structure of a bridge to improve seismic performance of the bridge.

The description of the embodiment of the present invention is based on the fact that the upper guide projection and the lower guide projection are installed in the axial direction. However, the technical concept of the present invention can be applied even when the upper guide projection and the lower guide projection are installed in a direction perpendicular to the bridge axis.

In the description of the present invention, the inside of the shear key points toward the center with respect to the direction perpendicular to the cross axis, and the outside of the shear key points away from the center in the direction perpendicular to the cross axis.

The shear key for bridges capable of adjusting spacing and measuring displacement of the present invention includes an upper plate 100, a lower plate 200, a lower guide protrusion 300, and a spacing adjusting plate 400, and includes a displacement indicator 500, a fixing member ( 600) may be further included.

The upper plate 100 may be fixed to a sole plate (not shown) fixed to the upper structure by bolts or welding, and the lower plate 200 may be fixed to the lower structure by anchor bolts (not shown).

An upper guide protrusion 110 is provided on the lower portion of the upper plate 100 in the axial direction. It is preferable to be integrally provided.

The upper guide protrusion 110 and the lower guide protrusion 300 are formed long along the throttling direction, and the upper guide protrusion 110 is positioned between the lower guide protrusions 300 to accommodate the displacement of the upper structure in the throttling direction, , it resists the horizontal force acting in the direction perpendicular to the bridge axis.

Sliding plates (not shown) may be fixed to opposite sides of the upper guide projection 110 and the lower guide projection 300 . That is, a sliding plate (not shown) is fixed to the inner side of both sides of the upper guide projection 110 and both sides of the lower guide projection 300 to smoothly absorb the displacement of the upper and lower structures in normal times. make it possible

The lower plate 200 has a configuration for installing and supporting a pair of lower guide protrusions 300, and is provided with a guide installation groove 210 in the bridge axis direction. A pair of the guide installation grooves 210 may be provided side by side.

A pair of lower guide protrusions 300 are installed in the guide installation groove 210, and it is a special technical feature of the present invention that the installation distance in the direction perpendicular to the bridge axis can be easily adjusted.

The guide installation groove 210 is formed by forming a groove downward in the lower plate 200, and a pair of reaction arm 220 is provided along the throttling direction by the groove.

The reaction arm 220 is a wall formed on the outer side of the guide installation groove 210 in the axial direction.

When an earthquake occurs, the reaction arm 220 resists the horizontal force transmitted to the lower guide protrusion 300 .

A bolt tap 211 for fastening the lower guide protrusion 300 is provided in the guide installation groove 210 . It is preferable that two or more bolt tabs 211 are provided for firm fastening.

The lower guide protrusion 300 includes a lower member 310 and a vertical member 320 provided vertically upward from one end of the lower member 310 . A pair of lower guide protrusions 300 are provided in an axisymmetric shape.

Preferably, the lower member 310 and the vertical member 320 are integrally provided.

The lower member 310 is provided with a bolt fastening hole 311 penetrating vertically, and the fastening bolt 240 passes through the bolt fastening hole 311 and is fastened to the bolt tap 211, thereby lowering the guide. The protrusion 300 is fastened and installed.

In order to easily adjust the distance between the lower guide protrusions in the direction perpendicular to the bridge axis, the bolt fastening holes 311 are preferably formed longer in the direction perpendicular to the bridge axis than in the direction of the bridge axis when viewed from a plan view.

When the fastening bolt 240 is passed through the bolt fastening hole 311 of the lower member 310 and fastened to the bolt tap 211, between the reaction arm 220 and the lower member 310, By inserting the spacing control plate 400 suitable for the required spacing and completely fastening the fastening bolts 240, it is possible to adjust the installation spacing of the lower guide protrusion 300 in the direction perpendicular to the bridge axis. At this time, the spacing control plate 400 may not be inserted according to the required spacing.

In order to properly adjust the distance, the width w2 of the guide installation groove 210 is greater than the width w1 of the lower member 310.

The size difference between the width w2 of the guide installation groove 210 and the width w1 of the lower member 310 is determined in consideration of the specifications of the components constituting the entire shear key, the distance adjustment range, and the limit displacement of the bridge support.

A rectangular flat plate having a certain thickness may be used as the spacer adjusting plate 400, and it is preferable that the area is the same as that of the reaction arm.

The distance is adjusted by the total thickness of the distance control plate 400 provided between the reaction arm 220 and the lower member 310.

Therefore, the thickness of one spacing adjusting plate 400 is thin (eg, 0.1 mm, 0.2 mm, 0.5 mm, 1 mm or more), and the spacing can be adjusted very precisely by providing a plurality of them.

However, when the thickness of all the spacing control plates is thin, the efficiency of the spacing adjustment operation is reduced and it may take a lot of time, so it may be effective to have various thicknesses of the spacing control plates.

7 to 10, it is shown that the distance between the upper guide projection and the lower guide projection is equalized on both sides by adjusting the installation distance of the lower guide projection.

7 shows that between the reaction arm 220 and the lower member 310, the gap control plate 400 is inserted, and the lower guide protrusion is installed as far as possible inside.

8 shows that the lower guide protrusion is installed as far as possible between the reaction arm 220 and the lower member 310 without inserting the spacing control plate 400.

In FIG. 9 , a pair of lower guide protrusions are installed on the left side as much as possible by inserting the spacing control plate 400 only between the right reaction arm 220 and the lower member 310 in the drawing.

10 shows that a pair of lower guide protrusions are installed on the right side as much as possible by inserting the spacing control plate 400 only between the reaction bar 220 and the lower member 310 on the left side of the drawing.

Since the width w2 of the guide installation groove 210 is greater than the width w1 of the lower member 310, after the lower guide protrusion is installed in the guide installation groove 210, the lower member 310 and the guide installation groove The inner space of 210 may be an empty space (the inner space of both lower members 310 in FIG. 8, the inner space of the lower left member 310 in FIG. 9, and the inner space of the lower right member 310 in FIG. 10). medial space).

However, it does not matter even if there is an empty space because the force acts only on the reaction arm not only during normal times but also during the earthquake load, and the force does not act on the inner wall of the guide installation groove.

The embodiments shown in FIGS. 7 to 10 are intended to explain typical examples of adjusting the spacing, and in addition to these, it will be possible to adjust the spacing in a myriad of forms within the scope of the technical idea of the present invention.

A reinforcing member 230 may be further provided to reinforce the bearing capacity against the horizontal force caused by the seismic load and to resist the large horizontal force.

The reinforcing member 230 is fixed to an end portion of the lower plate 200 in the axial direction, and a long hole 231 is provided in the reinforcing member 230 . The reinforcing member 230 may be fixed to both ends of the lower plate 200 in the axial direction, or to only one end.

To integrate the reinforcing member 230 and the lower guide projection 300, a bolt tap 301 is provided at the end of the lower guide projection 300, and the fastening bolt 250 passes through the long hole 231, , It can be fastened to the bolt tap 301.

At this time, since the lower guide protrusion 300 should be able to adjust the installation interval in the direction perpendicular to the bridge axis, it is preferable that the long hole 231 is formed longer in the direction perpendicular to the bridge axis than in the vertical direction when viewed from the front. For robust fastening of the fastening bolt 250, it is preferable that the length of the long hole 231 in the vertical direction is equal to or slightly larger than the diameter of the fastening bolt 250.

In the present invention, a displacement indicator 500 and a scale unit 510 may be further included in order to measure displacement in the throttle direction occurring between the upper plate and the lower plate.

The displacement indicator 500 may be attached to the upper plate 100, and the graduation part 510 may be provided on the lower guide protrusion 300.

The displacement indicator 500 of the present invention can be described in two embodiments.

The first embodiment includes a fixing part 511 and an indicating part 512, the fixing part 511 and the indicating part 512 form an L shape, and the fixing part 511 is the upper plate 100 It is attached to the end in the throttle direction and measures the displacement in the throttle direction by checking the graduation indicated by the indicator 512 (FIG. 15 (a)).

The second embodiment includes a fixing part 521 and an indicating part 522, the fixing part 521 and the indicating part 522 form a T shape, and the fixing part 521 is the top plate 100 ) and is attached to the side or bottom surface of the axial direction displacement by checking the scale indicated by the indicator 522 (FIG. 15 (b)).

Since the fixing part 511 and the fixing part 521 are attached to the top plate 100, the displacement indicator 500 and the top plate move together.

Attachment of the fixing part 511 and the fixing part 521 to the upper plate 100 may be permanently fixed by welding or the like, and in some cases may be provided so as to be detachable using a bracket, magnet, bolt, etc. means that it can

In the case of being detachably provided, the fixed position of the displacement indicator 500 may be changed during use.

Either one of the two embodiments of the displacement indicator 500 may be applied, or both may be applied to one shear key.

A scale may be displayed on the scale unit 511, and colors may be different for each section. That is, for a range of a certain displacement or more, messages such as caution and warning may be displayed by painting in yellow or red.

In order to be able to use the shear key of the present invention as a fixed end type, a fixing member 600 for restraining the upper guide protrusion 110 and the pair of lower guide protrusions 300 in the axial direction may be further included.

The fixing member 600 may be a steel bar having a circular or polygonal cross section.

By means of a fixing member penetrating both the upper guide projection and the lower guide projection, it can also be used as a fixed-end shear key that limits displacement in normal times.

To install the fixing member 600, a through hole 1111 is formed in the upper guide protrusion 110, a through hole 321 is formed in the vertical member 320, and the fixing member 600 is It is inserted into the through hole 1111 and the through hole 321 together.

In normal times, the displacement is limited, but when an earthquake load of a certain magnitude or more acts in the throttle direction, the fixing member 600 is sheared and fractured, and is changed to a one-way movable end in the throttle direction.

It may be provided by adjusting the shear strength, cross-sectional size, quantity, etc. of the fixing member to meet the required seismic load.

In the above, an embodiment in which two guide installation grooves 210 are provided side by side has been described, but the two guide installation grooves 210 may be communicated. That is, instead of forming two grooves so that the guide installation grooves 210 described above become a pair, one guide installation groove having a width wide enough to accommodate a pair of lower guide protrusions may be implemented. .

In addition, in the previous embodiment, the upper guide projection and the lower guide projection are installed in the direction of the bridge axis, but the technical idea of the present invention is applicable even when the upper guide projection and the lower guide projection are installed in the direction perpendicular to the bridge axis. . That is, if the foregoing contents described above are applied with horizontal rotation of 90 degrees based on installation in the bridge axis direction, even when the upper guide projection and the lower guide projection are installed in the direction perpendicular to the bridge axis, the special effects and objects of the present invention can be achieved as they are.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is only exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom.

Therefore, the true technical scope of protection of the present invention should be determined by the technical spirit of the appended claims.

100. Top plate
110. Upper guide protrusion 1111. Through hole
200. Lower plate
210. Guide installation groove 211. Bolt tap
220. Reaction Arm
230. Reinforcing member 231. Long hole
240. fastening bolt 250. fastening bolt
300. Lower guide protrusion
310. Lower member 311. Bolt fastening hole
320. Vertical member 321. Through hole
301. Bolt tap
400. Gap adjustment plate
500. Displacement indicator
511. Fixed part 512. Indicating part
521. Fixed part 522. Indicating part
530. Graduation
600. Fixing member: round bar
w1. Width of lower member w2. Width of guide installation groove

Claims (10)

In the shear key installed between the upper structure and the lower structure of the bridge,
An upper plate 100 provided with an upper guide protrusion 110 downward;
A lower plate 200 provided with a guide installation groove 210;
It includes a pair of lower guide projections 300 installed in the guide installation groove 210,
The lower guide protrusion 300 includes a lower member 310 and a vertical member 320,
The width w2 of the guide installation groove 210 is greater than the width w1 of the lower member 310,
The guide installation groove 210 is provided with a reaction arm 220,
A spacing control plate 400 is provided between the reaction arm 220 and the lower member 310,
The pair of lower guide protrusions 300 are characterized in that the installation interval in the direction perpendicular to the longitudinal direction of the guide installation groove 210 can be adjusted
A shear key for bridges capable of spacing adjustment and displacement measurement. delete delete According to claim 1,
The guide installation groove 210 is provided with a bolt tap 211,
The lower member 310 is provided with bolt fastening holes 311 penetrating vertically,
Characterized in that the lower guide projection 300 is installed by passing the fastening bolt 240 through the bolt fastening hole 311 and fastening to the bolt tap 211
A shear key for bridges capable of spacing adjustment and displacement measurement. According to claim 4,
A reinforcing member 230 having a long hole 231 is fixed to an end of the lower plate 200,
A bolt tap 301 is provided at an end of the lower guide protrusion 300,
Characterized in that the fastening bolt 250 is passed through the long hole 231 and fastened to the bolt tap 301
A shear key for bridges capable of spacing adjustment and displacement measurement. The method of any one of claims 1, 4 and 5,
Further comprising a displacement indicator 500 attached to the upper plate 100,
Characterized in that the lower guide projection 300 is provided with a scale 530
A shear key for bridges capable of spacing adjustment and displacement measurement. According to claim 6,
The displacement indicator 500,
It includes a fixing part 511 and an indicating part 512, the fixing part 511 and the indicating part 512 form an L shape, and the fixing part 511 is attached to the end of the top plate 100 and/or
It includes a fixing part 521 and an indicating part 522, the fixing part 521 and the indicating part 522 form a T shape, and the fixing part 521 is on the side or bottom surface of the upper plate 100. characterized in that it is attached
A shear key for bridges capable of spacing adjustment and displacement measurement. The method of any one of claims 1, 4 and 5,
A through hole 1111 is formed in the upper guide protrusion 110,
A through hole 321 is formed in the vertical member 320,
Further comprising a fixing member 600 inserted into the through hole 1111 and the through hole 321
A shear key for bridges capable of spacing adjustment and displacement measurement. According to claim 8,
In normal times, the longitudinal displacement of the upper guide projection 110 and the lower guide projection 300 is limited by the fixing member 600,
When the horizontal force caused by the earthquake is greater than a certain level, the fixing member 600 is sheared and fractured, allowing longitudinal displacement of the upper guide projection 110 and the lower guide projection 300,
The magnitude of the horizontal force caused by the earthquake that causes the fracture of the fixing member 600 is adjustable by the shear strength, cross-sectional size and quantity of the fixing member 600.
A shear key for bridges capable of spacing adjustment and displacement measurement. The method of any one of claims 1, 4 and 5,
Characterized in that one or more spacing control plates 400 are provided and installed to meet the required spacing
A shear key for bridges capable of spacing adjustment and displacement measurement.

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