KR20210041813A - Girder Joint - Google Patents

Abstract

The present invention relates to a girder joint, which absorbs an impact of a girder and fixated to a support. More specifically, the present invention comprises: the support composed of an abutment and a pier fixated to the ground; the girder mounted in an upper portion of the support and allowing slab to be installed in an upper portion thereof; and the joint connecting the support and the girder and absorbing vibration of the girder.

Description

Girder Joint

The present invention is directed to a girder joint that absorbs the impact of a girder and is fixed to a support.

Patent Document 001 is a base plate in which a fall-off prevention facility is provided with a plate seated on the upper surface of a bridge coping and fixed through an anchor bolt, and two fastening frames with fastening holes face each other with respect to the center of the plate and are spaced apart so that they are erected. And, a rolling bearing installed inside the fastening frame of the base plate, and one end of the box-shaped girder end of the bridge upper plate is fixed through bolting, and a contact surface in contact with the rolling bearing is formed at the other end, thereby forming the girder. The support frame and the support frame of the base plate are supported on the rolling bearing so as to be rollable and have a fastening hole positioned on the same line with the fastening hole of the base plate, and a fastening hole communicating with the fastening holes. It connects the base plate and the support frame while simultaneously connecting the base plate and the support frame while simultaneously penetrating the bellows-type elastic member that is intervened and expands and contracts according to the expansion and contraction of the bridge upper plate, and the fastening hole formed in the fastening frame and the support frame and the elastic member intervening therebetween. It is presenting a technology with a possible structure of fasteners.

Patent document 002 discloses that a truss bridge capable of absorbing vibration is a truss, a pier that supports the load of the truss, a bridge that transmits the load of the truss to the pier, a first buffering means provided between the truss and the pier, and an adjacent truss. Consisting of a second buffering means, the first buffering means, the elastic body, a pair of plates spaced apart from the inside of the elastic body by a predetermined distance, a buffer member including a spring provided between the plates, and a bottom surface of the truss It proposes a technology consisting of a housing installed in and in which a part of the buffer member is inserted.

Patent document 003 relates to a bridge lifting device, in which the bracket part is installed so as to be spaced laterally from each other in contact with the upper surface of the bridge substructure, but extends past the fracture front surface of the upper edge of the bridge substructure. Both horizontal support plates are installed so that the locking holes formed at the bottom of one end are caught in the locking groove formed on the upper surface of the bridge substructure, and vertically installed so as to be fixed with anchor bolts on the side of the bridge substructure by extending downward to the bottom of the other ends of the horizontal support plates. Support plate; And a horizontal fixing plate in the form of a horizontal plate extending in the transverse direction on the front top of the vertical support plate and having a support hole for the impression jack receiving the impression jack on the center upper surface.

Patent Document 004 includes upper and lower plates fixed to the upper side of the abutment and the upper side of the bridge and the lower end of the girder under the railroad rail, and absorbing the axial force and seismic resistance of the railroad rail by including an elastic member between the upper and lower plates. It relates to a bridge seating device for a bridge in which the upper plate is individually flowed to support and absorb expansion and contraction, and a lower plate provided on the upper side of the abutment and the pier and fixed by a binding member to the lower side, and provided at both ends of the lower plate Is provided with left and right guides protruding upward to have a predetermined height, an elastic member provided on the upper surface of the lower plate and provided between the left and right guides and having a predetermined thickness, and at least one penetrating portion penetrating the upper and lower surfaces of the elastic member And a fixing member that is inserted and fixed to the through part to fix the upper and lower sides of the elastic member, respectively, and a guide groove of a predetermined length covering the upper surface of the elastic member and having both sides of the left and right guides inserted therein to have left and right gaps. Provides a technology in which the upper plate is fixed to the upper side of the left and right guides and has a length toward the upper plate and has a fixing block having a predetermined gap with the upper plate, and the upper plate is coupled to the girder of the lower part of the railroad rail. Are doing.

KR 10-0647523 B1 (November 13, 2006) KR 10-0965236 B1 (June 14, 2010) KR 10-1066837 B1 (September 16, 2011) KR 10-0610586 B1 (August 2, 2006)

The present invention is directed to a girder joint that absorbs loads and impacts acting on a girder and is fixed to a support.

It is to solve the problems of the prior inventions, the present invention is a support 100 formed of an alternating bridge and pier fixed to the ground;, a girder which is seated on the upper portion of the support 100, and the slab 10 is installed thereon (200);, A joint 300 that connects the support 100 and the girder 200 and absorbs the vibration of the girder 200; consists of a configuration including.

The present invention is an invention for a girder joint, the support 100 presented above;, girder 200;, joint 300; in the invention consisting of; the girder 200 is seated on the support 100, A point portion 210 formed in a box shape and filled with concrete therein; A span portion 220 formed between the branch portions 210 and formed of a plurality of eye (I)-shaped structures is added.

The present invention is an invention for a girder joint, and the support 100 presented above;, girder 200;, joint 300; in the invention consisting of the joint 300 is seated on the upper portion of the support 100 A seating portion 310;, an absorption portion 320 formed inside the seating portion 310 and absorbing the vibration of the girder 200; is added.

The present invention is an invention for a girder joint, and the support 100 presented above;, girder 200;, joint 300; is coupled to the invention consisting of a detachable side of the seating portion 310, the A departure prevention plate 400 for preventing separation of the girder 200; is added.

In the present invention, the girder is seated and can support the load acting on the girder.

The girder of the present invention is formed by a combination of a box and an eye (I) type structure, which reduces its own weight, thereby reducing the maximum amount of deflection of the girder.

The present invention proposes the size of the double composite part and the branch part, which generates an optimized amount of deflection in the environment of structural and boundary conditions.

The present invention can absorb the impact as the girder is seated in the absorbing portion having elastic force.

The present invention can flexibly cope with the load acting on the girder as the hemispherical fastening portion is seated on the absorbent portion.

In the present invention, the fixture is coupled to the separation prevention plate so that the girder is not separated from the joint and can be rotated at a predetermined angle.

1 is a front view of a bridge in which the girder of the present invention is installed.
Figure 2 is a plan view of a bridge in which the girder of the present invention is installed.
Figure 3 is a cut perspective view showing the girder of the present invention.
Figure 4 is a side view of the joint of the present invention.
5 is a plan view of the joint of the present invention.
Figure 6 is a side view showing a seat according to another embodiment of the present invention.
Figure 7 is a perspective view showing the absorber of the present invention.
Figure 8 is an operation state diagram of the absorber of the present invention.
Figure 9 is a construction flow chart showing a state in which the girder is seated in the joint of the present invention.

Hereinafter, in order to describe in detail enough that a person of ordinary skill in the art can easily implement the present invention, the most preferred embodiment of the present invention will be described in detail.

The numbers cited in the following examples are not limited only to the object of reference, and may be applied to all examples. Objects that exhibit the same purpose and effect as the configuration presented in the examples correspond to equivalent substitutional objects. The upper concept presented in the examples includes the object of the lower concept that is not described.

(Example 1-1) In the present invention, in a girder joint, a support 100 formed of an alternating bridge and a pier fixed to the ground;, a slab 10 is installed on the upper part of the support 100 A girder 200;, and a joint 300 that connects the support 100 and the girder 200 and absorbs the vibration of the girder 200.

(Example 1-2) In the girder joint of the present invention in Example 1-1, the support 100 is a support 110 that is seated on the ground; is formed on the upper portion of the support 110, and the joint Includes; a fixed plate 120 to which 300 is fixed.

(Example 1-3) In the girder joint of the present invention in Example 1-2, the fixing plate 120 includes a plurality of fastening holes to which anchor bolts are fastened.

The present invention relates to a girder 200 installed on a bridge consisting of at least two spans, and a joint 300 of piers and abutments, and specifically, vibration generated by the load and impact generated on the girder 200 It absorbs and can respond to various stresses such as shear force and deflection. The girder joint of the present invention absorbs the load acting on the girder 200 by supporting the girder 200 connecting the upper part of the bridge and pier installed in rivers, rivers, farmland, and the like. In general, in the girder 200, the slab 10 is installed on the upper part, so that vibration and load are generated as the vehicle and the train move, and bending and sagging are generated by the wind load. In order to overcome this, in the conventional inventions, a stopper is formed at a position where the girder 200 and the pier and the abutment contact each other to prevent rotation and separation of the girder 200 and at the same time reduce vibration. In addition, the stopper is formed as a hinge to induce the girder 200 to rotate at regular intervals so as to have fluidity by the load.

In this way, the support 100 on which the girder 200 is seated is preferably formed alternately with a pier, and is fixed to the ground to prevent the girder 200 from being separated. Such a support 100 is formed with a support 110 that is seated on the ground, and a fixing plate 120 is formed on the upper portion of the support 110 so that the joint 300 is coupled. The support 110 is formed in various shapes, bridges and alternately formed. The fixing plate 120 is formed in a plate shape, and as it is formed of a steel material, the joint 300 is formed by welding or a plurality of fastening holes are formed to fasten the anchor bolts.

Therefore, the girder joint of the present invention has a feature of fixing the girder 200 to the upper part of the pier and the abutment, and reducing the load and impact of the upper part.

(Example 2-1) The present invention relates to a girder joint, and in Example 1-1, the girder 200 is seated on the top of the support 100, formed in a box shape, and filled with concrete therein. A branch portion 210; And a span 220 formed between the branch portions 210 and formed of a plurality of eye (I)-shaped structures.

(Example 2-2) In Example 2-1, the girder joint of the present invention is formed at the lower end of the branch part 210 and includes a fastening part 230 that is fastened to the joint 300. .

(Example 2-3) In Example 2-2, the girder joint of the present invention includes a spacer 240 connecting a plurality of I-type structures.

The present invention relates to a girder 200, and specifically, the girder 200 may be installed between a plurality of piers and abutments, or a plurality of girders 200 may be combined to be seated on an abutment and an upper part of the pier. Each girder 200 is formed with a branch portion 210 on both sides, and a span 220 is formed between the branch portion 210 and the branch portion 210. A positive moment is applied to the branch part 210 and a positive moment is applied to the span part 220. The branch part 210 is located on an abutment or on the pier, and is formed in a box shape. In addition, the span 220 is located between the branch portions 210 and is formed of an eye (I) type structure. In this eye (I) type structure, three plates are joined by welding or the like to form an eye (I) shape, or an I type standard steel material may be used. In the span 220, two eye (I)-type structures are arranged in parallel, and in order to improve the bending and torsional stiffness of the girder 200, the spacer 240 is disposed between the two eye (I)-type structures. Are combined. The spacers 240 are arranged at regular intervals, and the intervals are formed uniformly or non-uniformly.

In addition, the branch part 210 has a fastening part 230 formed at the lower end, and the fastening part 230 is coupled to the joint 300 installed on the pier and the upper part of the abutment. The fastening part 230 is formed in a hemispherical shape, and the angle is variously adjusted at the joint 300. This is to allow the girder 200 to be fluidly variable by the load and impact acting on the girder 200.

Therefore, in the girder 200 of the present invention, the fastening part 230 that is seated on the upper part of the support 100 is formed, and the branch part 210 formed on the upper part of the fastening part 230 is formed in a box shape, so that the shear force It may correspond to, and sagging such as bending may be prevented by the span 220 connecting the plurality of point portions 210.

(Example 2-4) The girder joint of the present invention in Example 2-3, wherein the branch portion 210 is a plate-shaped upper branch plate 211;, forming a horizontal surface with the upper branch plate 211 And a lower branch plate 212 spaced apart from each other; and a vertical branch plate 213 formed between the upper branch plate 211 and the lower branch plate 212 and formed of two plates.

(Example 2-5) In Example 2-4, the girder joint of the present invention includes a double composite part 214 formed in a part of the inside of the box of the branch part 210 and in which concrete is poured below; It is located inside the double composite portion 214, is formed in a grid, and a deformed reinforcement to which the reinforcing bar is reinforced; includes.

The present invention relates to the point portion 210, specifically the point portion 210 is formed in a box shape and is seated on the upper portion of the support (100). In order to implement the branch portion 210 in a box shape, the upper branch plate 211 and the lower branch plate 212 are parallel. And two vertical branch plates 213 are inserted into the upper and lower branch plates 212, and a space is formed between the upper branch plate 211, the lower branch plate 212, and the vertical branch plate 213, and the overall appearance is It is formed in the shape of a square box. In addition, the branch portion 210 is formed on the upper portion of the support 100 formed as an alternating and piercing, and is coupled by the fastening portion 230. Since the boundary condition of the girder 200 takes the form of high information at both ends, the maximum amount of the center of the girder 200 (the center of the span 220) is smaller than that of a simple support beam.

In addition, the branch portion 210 may improve the rigidity of the box-shaped branch portion 210 to increase the deformation resistance of the girder 200. This can obtain the effect of increasing the length of the girder 200, it is possible to increase the gap between the abutment and pier, and the pier and pier. This can improve workability and shorten construction time. In addition, the double-composite portion 214 may pour concrete into the entire point portion 210 or only under the point portion 210. Alternatively, concrete may not be poured. Or it can be replaced with a plurality of metal reinforcing members. At this time, the concrete poured under the branch part 210 generates the greatest compressive stress in the lower part when bending deformation occurs. The floor slab 10 causes cracks. In order to prevent this, a deformed reinforcing bar is formed inside the concrete, and the deformed reinforcing bar prevents the concrete compression deformation, thereby preventing cracking. In addition, a deformed reinforcing bar is used to fix the stable point portion 210 of the concrete.

Therefore, it is possible to minimize the moment of the branch part 210.

(Example 2-6) In the girder joint of the present invention in Example 2-2, the fastening portion 230 is formed in a hemispherical shape, and a mounting hole 231 that is seated on the joint 300;, the It includes; is formed on both sides of the mounting hole 231, a fixture 232 fixed to the joint 300.

The present invention relates to the fastening portion 230, is specifically formed to protrude from the lower end of the point portion 210, is formed in a hemispherical shape to be seated on the joint 300. The fastening part 230 of the present invention is a seating hole 231 formed in a hemispherical shape to be seated on the joint 300 and flexibly rotated at a predetermined angle according to the movement of the girder 200. In detail, the mounting hole 231 is formed in a hemispherical shape and is mounted on the joint 300 to be described later, and the girder 200 is at a predetermined angle due to impacts such as the upper load and the wind load of the girder 200. When rotating, the fastening part 230 moves flexibly. This prevents the normal girder 200 to which the girder 200 and the support 100 are fixed from being damaged by impact, and prevents plastic destruction from occurring as the girder 200 flexibly adjusts the angle. In addition, the fixture 232 is formed on both sides of the mounting hole 231 formed in a hemisphere, and is coupled to a joint 300 to be described later. At this time, the fixture 232 is coupled to the joint 300, but is not in close contact, so that when the angle of the girder 200 is flexibly rotated by the mounting hole 231, the girder 200 is prevented from being separated. Specifically, the fixture 232 is coupled to the joint 300 so that the angle at which the girder 200 is separated from the joint 300 or rotated by an external impact is kept constant. The fixture 232 is formed by extending downward from the side of the mounting hole 231 and then extending from the end to the outside. At this time, the fixing body 232 is formed to correspond to each other and is coupled to the departure prevention plate 400 to be described later.

Therefore, the fastening part 230 rotates at a predetermined angle in the joint 300 by the mounting hole 231, and the fastening part 230 and the girder 200 are prevented from being separated by the fixture 232. I can.

(Example 3-1) The present invention relates to a girder joint, and in Example 2-1, the joint 300 is a seating portion 310 that is seated on the upper portion of the support 100; and the seating portion. It is formed in the interior of the (310), the absorber 320 for absorbing the vibration of the girder 200; includes.

(Example 3-2) In the girder joint of the present invention in Example 3-1, the mounting portion 310 is formed of a plate, and a mounting plate 311 fixed to the upper portion of the support 100;, Side plates 312 extending upward from both sides of the seating plate 311, respectively; include.

(Example 3-3) In the girder joint of the present invention in Example 3-1, the seating plate 311 is a plurality of through holes 313 through which anchor bolts fixed to the support base 100 pass; Includes.

(Example 3-4) The girder joint of the present invention in Example 3-1, wherein the side plate 312 has an upper portion formed in an oblique line; includes.

The present invention relates to the joint 300, specifically, the girder 200 is seated to absorb the load and impact to prevent damage of the girder 200. The joint 300 of the present invention is mounted on the upper portion of the support 100 to fix the girder 200, and the seating portion 310 and the seating portion 310 fixed by an anchor bolt on the upper portion of the support 100 The absorber 320 is formed inside and absorbs vibration and shock of the girder 200. In addition, the mounting portion 310 has a plurality of through holes 313 through which the anchor bolts installed to be fixed to the upper portion of the support 100 are fixed, and the through holes 313 are formed at equal intervals. In addition, the seating portion 310 is formed of a plate material to form a seating plate 311 in which the through hole 313 is formed, and the seating plate 311 is welded to the fixing plate 120 formed on the upper portion of the support 100 And an anchor bolt. In this case, when the absorption part 320 is provided on the fixing plate 120, the mounting plate 311 may be omitted. And side plates 312 surrounding the fastening part 230 of the girder 200 are formed on both sides of the incheok plate as it rises upward. The side plate 312 is coupled to the mounting plate 311 by welding to prevent the fastening part 230 from being separated from the side, and as the fastening part 230 and the mounting plate 311 are fixed by a brace, the fastening part It is possible to more effectively prevent the departure of (230). In addition, as the upper portion of the side plate 312 is formed in a diagonal line having different heights on one or both sides, the girder 200 is flexibly induced to rotate by the load. In addition, the absorbing part 320 is formed inside the seating part 310 and formed of a rubber material to absorb the vibration of the girder 200.

Therefore, the joint 300 secures the flexibility of the girder 200 and prevents separation.

(Example 3-5) In the girder joint of the present invention in Example 3-2, the absorbent part 320 is formed inside the seating part 310, and the elastic body on which the fastening part 230 is seated. (321); It is formed to surround one surface of the elastic body 321, a shock absorber 330 for preventing the impact of the elastic body 321; includes.

(Example 3-6) The girder joint of the present invention in Example 3-5, wherein the elastic body 321 is formed in a curved surface so that the hemispherical fastening portion 230 contacts; includes.

The present invention relates to the absorbing portion 320, specifically the absorbing portion 320 is in contact with the fastening portion 230, and absorbs the shock and vibration acting on the girder 200. The absorbent part 320 of the present invention is formed inside the seating part 310 and is formed in plural to surround the fastening part 230. In detail, the fastening part 230 is formed in a hemispherical shape, and the absorbing part 320 is formed to be in contact with the slope of the fastening part 230 in order to prevent separation of the fastening part 230. In general, as the girder 200 moves horizontally, the absorbent part 320 is formed at a position where the girder 200 moves much. In this case, the size of the absorber 320 is the same, but the absorber 320 facing each other may be formed differently when they cross each other. The absorbent part 320 has an elastic body 321 formed of synthetic rubber such as styrene butadiene (SBR), acrylonitrile butadiene (NBR), silicone (VMQ), urethane, and Teflon, and the fastening part 230 ) The surface in contact with the curved surface is formed to be more closely contacted with the hemispherical fastening portion 230. In addition, the elastic body 321 is formed to be wrapped by the shock absorber 330, and the shock absorber 330 has elasticity in the elastic body 321 more effectively by a spring 333 or the like.

Accordingly, the absorbing unit 320 is disposed to surround the slope of the fastening unit 230 and absorbs a load acting on the upper portion by elasticity and an impact caused by the impact.

(Example 3-7) In the girder joint of the present invention in Example 3-4, the shock absorber 330 includes a fastening plate 331 surrounding the elastic body 321; An elastic plate 332 formed to be spaced apart from the fastening plate 331 and fixed to the mounting plate 311; And a spring 333 formed between the fastening plate 331 and the elastic plate 332 and applying elasticity to the fastening plate 331.

(Example 3-8) In Example 3-7, the girder joint of the present invention is formed on the mounting plate 311, and a guide rail 314 for guiding the horizontal movement of the fastening plate 331; Includes.

The present invention relates to a shock absorber 330, and specifically applies more effective elasticity to the elastic body 321 by vibration and impact. The shock absorber 330 of the present invention is formed with a fastening plate 331 surrounding the elastic body 321. The fastening plate 331 is formed to surround the rear and lower surfaces of the elastic body 321, and a guide protrusion that is guided horizontally and moved horizontally is formed at the lower part by being coupled to the guide rail 314 formed on the seating plate 311. And the fastening plate 331 is fixed to the spring 333 at the rear, the spring 333 is formed on the elastic plate 332 formed to be spaced apart from the fastening plate 331. The elastic plate 332 is fixed to the seating plate 311 and the other end of the spring 333 is fixed.

Accordingly, the shock absorber 330 is formed with a spring 333 to increase the elastic force to the elastic body 321 when a load and an impact are applied to the fastening part 230.

(Example 4-1) The present invention relates to a girder joint, and in Example 3-1, it is detachably coupled to the side surface of the seating portion 310 and prevents separation of the girder 200 Includes; prevention plate 400.

(Example 4-2) In the girder joint of the present invention in Example 2-2 or Example 4-1, the separation prevention plate 400 includes a coupling plate 410 to which the fastening portion 230 is coupled; , A support plate 420 fixed to the lower end of the coupling plate 410 and fixed to the seating portion 310; And a reinforcing plate 430 connecting the coupling plate 410 and the support plate 420 to each other.

(Example 4-3) The girder joint of the present invention in Example 4-2, wherein the support plate 420 is fixed to the seating portion 310 by welding and anchor bolts; includes.

The present invention relates to the departure prevention plate 400, specifically, the fixing body 232 of the fastening portion 230 is coupled to adjust the rotation angle of the fixing body 232 or prevent separation. The separation prevention plate 400 of the present invention has a coupling plate 410 formed so that the fixing bodies 232 protruding downward from both sides of the fastening part 230 are coupled, and the coupling plate 410 is the fixing body 232 A coupling protrusion 411 extending from one surface to at least one is formed so as to be inserted. Specifically, the coupling protrusion 411 extends from the upper end of the coupling plate 410 toward the fixture 232 and is formed at least one such as spaced apart from the upper end and the lower end of the coupling plate 410. In addition, the coupling protrusions 411 are formed so that the fixing body 232 is not in close contact with each other to rotate at a predetermined angle, so that the plurality of coupling protrusions 411 are spaced apart from each other. In addition, the coupling plate 410 is provided with a support plate 420 in the lower part so as not to be damaged by the fastening part 230 or separated from the seating part 310. The support plate 420 is formed by extending the coupling protrusion 411 and the other surface, and the coupling plate 410 and the support plate 420 are coupled by welding. In addition, the support plate 420 and the coupling plate 410 are formed with a reinforcing plate 430, and the reinforcing plate 430 is formed in a triangular shape to prevent the coupling plate 410 from being damaged by the fastening portion 230. . In addition, the support plate 420 is formed by welding so as not to be separated from the seating portion 310 or fixed by an anchor bolt to be fixed to the support 100 by a through hole 313 of the seating portion 310.

Accordingly, the separation prevention plate 400 prevents the separation of the fastening part 230, and has a characteristic of adjusting the angle when the fastening part 230 rotates at a predetermined angle due to vibration and impact.

10: slab 100: support
110: support 120: fixing plate
200: girder 210: branch
211: upper branch plate 212: lower branch plate
213: vertical branch plate 214: double composite part
220: span part 230: fastening part
231: mounting hole 232: fixture
240: spacer 300: joint
310: seat 311: seat plate
312: side plate 313: through hole
314: guide rail 320: absorber
321: elastic body 330: shock absorber
331: fastening plate 332: elastic plate
333: spring 400: departure prevention plate
410: coupling plate 411: coupling protrusion
420: support plate 430: reinforcement plate

Claims (4)

Support 100 formed of an alternating bridge and pier fixed to the ground;,
A girder 200 that is seated on the upper part of the support 100 and on which the slab 10 is installed;,
A girder joint comprising a; a joint 300 that connects the support 100 and the girder 200 and absorbs the vibration of the girder 200.
The method according to claim 1,
The girder 200 is mounted on the support 100, a point portion 210 formed in the form of a box and filled with concrete therein;
A girder joint including; a span 220 formed between the branch portions 210 and formed of a plurality of eye (I)-type structures.
The method according to claim 2,
The joint 300 is a seating portion 310 that is seated on the upper portion of the support 100;,
A girder joint comprising; an absorption part 320 formed inside the seating part 310 and absorbing the vibration of the girder 200.
The method of claim 3,
A girder joint comprising a; separation prevention plate 400 that is detachably coupled to a side surface of the seating portion 310 to prevent separation of the girder 200.

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