KR102234265B1 - Extended footbridge with improved walking stability - Google Patents

Abstract

The present invention relates to an extended footbridge, which comprises: a main member fixed to the outside of an existing structure not installed with a sidewalk; an auxiliary member fixed to an upper side of the main member, and having a bottom plate and a handrail post on an upper part; an upper bracket fixed to a lower part of the auxiliary member; a lower bracket fixed to an upper part of the main member; and a vibration attenuating unit installed between the upper and lower brackets to attenuate vibration. According to the present invention, structural safety is secured by securing the rigidity of a branch point by treating a side cross section of the main member, a pad made of an elastic pad and the like absorbs a transmission force of an upper live load as energy to efficiently distribute a load with high flexibility and elasticity so as to have excellent walking stability. Also, vibration transmission is minimized by using at least one of the pad and an elastic body against a shock load to reduce the fatigue life of the auxiliary member so as to have structurally excellent safety. In addition, a reinforcement plate is applied to a base plate to improve resistance to shearing and bending.

Description

Extended footbridge with improved walking stability {EXTENDED FOOTBRIDGE WITH IMPROVED WALKING STABILITY}

The present invention relates to an extended footbridge with improved walking stability, and more particularly, to a footbridge that is efficiently extended and installed outside a structure without an existing footpath.

In general, a bridge is recognized as a civil engineering structure such as an overpass constructed on railroads and roads, or a bridge constructed across a river. It is composed of structures.

In addition, bridges are divided into simple bridges, continuous bridges, gerber bridges, truss bridges, slab bridges, arch bridges, ramen bridges, suspension bridges and cable-stayed bridges, depending on the type of the upper structure.

Among them, slab bridges are constructed in the form of placing slabs (for example, concrete decks) between piers with short spans.

On the other hand, such a conventional slab bridge is also installed with a sidewalk for not only vehicle passage, but also for the passage of general pedestrians, and the sidewalk installed on such a bridge is not installed by a separate method, but simply a roadway for vehicle passage, In other words, a part of the edge of the slab top is partitioned with handrails, etc. and used as a sidewalk.

In addition, it is intended to improve the convenience of pedestrians by forming such an extended guideway on the outer retaining wall of the existing road where only the roadway is formed.

Such a footbridge-related technology has been proposed in Korean Patent Publication No. 2013-0082052.

However, Patent Document 1 is limited to changing the structure of the connecting bar in order to prevent deformation from vibration and impact force caused by the traffic of bicycles or pedestrians, so there is a limit to the deformation prevention.

Korean Patent Publication No. 2013-0082052 (2013.07.18)

The present invention was conceived in consideration of the above points, and the problem of the present invention is to install an upper bracket and a lower bracket for reinforcement on the outside of a structure without an existing sidewalk, and a vibration damping part between the upper bracket and the lower bracket. Its purpose is to provide an extended footbridge that improves pedestrian performance by attenuating the vibration caused by installation, and improves the walking stability that can restore the structure to a circular shape by giving post tension in case of deformation, sag, or abnormality due to continuous repeated load after construction.

An extended footbridge with improved walking stability according to the present invention for achieving the above object includes: a main member including a base plate integrated with the existing structure outside the existing structure in which the sidewalk is not installed; A couple member fixed to the upper side of the main member and provided with a bottom plate and a railing post thereon; An upper bracket fixed to the upper part of the main member; A lower bracket fixed to the lower portion of the couple member; And a vibration attenuating unit installed between the upper and lower brackets to attenuate vibration.

The couple member may be provided to cover the outer wall of the structure or the upper part of the structure, and the base plate of the main member may be provided with a reinforcing plate to integrate with the existing structure.

The vibration damping unit may be at least one of a pad and an elastic body.

The couple member may be provided with a tension providing unit capable of adjusting pre-tension and post-tension between the fixed plate fixed therein and the outer wall.

The tension providing unit may be any one of a post tension steel bar or a steel wire that reinforces sagging.

The tension providing unit may be installed in a horizontal or diagonal direction.
The extended footbridge with improved walking stability according to the present invention includes a main member 110 including a base plate integrated with the existing structure outside the existing structure in which the sidewalk is not installed; A couple member 120 fixedly provided on the upper side of the main member 110 so as to protrude outside the end of the main member 110 by a predetermined length, and provided with a bottom plate and a railing post on the upper side; A lower bracket 114 provided on the upper portion of the main member 110; An upper bracket 122 provided under the couple member 120; A vibration damping unit 130 installed between the upper bracket 122 and the lower bracket 114 to attenuate the vibration; And a tension providing unit that generates a tensile force in order to prevent sagging or vibration of the couple member 120 caused by the length of the couple member 120 protruding outside the end of the main member 110 by a predetermined length ( 840); includes, a pad 1320 for attenuating vibration is provided between the lower bracket 114 and the upper bracket 122, and the vibration attenuating part 130 includes the upper bracket 122 and It is installed in a structure that penetrates all of the lower bracket 114, and the vibration damping unit 130 has an elastic body 1310 penetrating both the upper bracket 122 and the lower bracket 114, and both ends of the elastic body 1310 It includes an upper cap and a lower cap that are fixed by bolting while being wrapped, and the vibration damping unit 130 includes an upper bracket 122 and a lower bracket 114 having a pad 1320 therebetween without spaced apart from each other. It is provided in a meshing manner, and the tension providing unit 840 includes a fixing plate 821 provided at a central point of the sub-member 120 corresponding to the end of the main member 110 and the end of the sub-member 120 It is characterized in that the structure is fixed to both outer walls of the fixing unit 842 provided in the.

According to the present invention, structural safety is secured by securing the stiffness of the branch portion by treatment of the main member side surface, and the pad made of an elastic pad absorbs the transmission power of the upper live load as energy, thereby effectively distributing the load with high flexibility and elasticity. It is excellent in walking stability and minimizes vibration transmission by using at least one of a pad and an elastic body against the shock load generated on the upper part, thereby reducing the fatigue life of the sub-materials, thus providing excellent structural safety, and a reinforcing plate is applied to the base plate. This improves resistance to shear and warpage.

In addition, there is an effect of improving resistance to end sagging by installing a tension providing unit on the sub-member.

In addition, the pad made of a material such as synthetic rubber is composed of a fine air layer inside the material, so it has excellent buffering function and elasticity, and is excellent in resistance to deformation for a long period of time, so it has excellent glass management.

In addition, the standardized sub-materials are manufactured in a batch factory to assemble a ready-made main member and on-site bolts, so construction is easy, and the production period is shortened by using a ready-made main member, which saves time.

1 is a side cross-sectional view showing a state installed in a structure when an extended footbridge with improved walking stability of the present invention is a general type.
2 is a plan view showing upper and lower brackets when the extended footbridge with improved walking stability of the present invention is a general type.
3 is a front view showing a base plate when the extended footbridge with improved walking stability of the present invention is a general type.
4 is an explanatory view showing a vibration damping unit provided in an extended footbridge with improved walking stability according to the present invention.
5 is a plan view showing upper and lower brackets when the extended footbridge with improved walking stability of the present invention is a reinforced type.
6 is a front view showing a base plate when the extended footbridge with improved walking stability of the present invention is a reinforced type.
7 is a plan view showing upper and lower brackets when the extended footbridge with improved walking stability of the present invention is an upper reinforcement type.
8 is a front view showing a base plate when the extended footbridge with improved walking stability of the present invention is an upper reinforcement type.
9 is a plan view showing upper and lower brackets when the extended footbridge having improved walking stability of the present invention is a first slope type.
10 is a front view showing a base plate when the extended footbridge having improved walking stability of the present invention is a first slope type.
11 is a plan view showing upper and lower brackets when the extended footbridge having improved walking stability according to the present invention is a second slope type.
12 is a front view showing a base plate when the extended footbridge having improved walking stability of the present invention is a second slope type.
13 is a plan view showing upper and lower brackets when the extended footbridge with improved walking stability according to the present invention is a first retaining wall type.
14 is a front view showing a base plate when the extended footbridge with improved walking stability of the present invention is a first retaining wall type.
15 is a plan view showing upper and lower brackets when the extended footbridge with improved walking stability of the present invention is a second retaining wall type.
16 is a front view showing a base plate when the extended footbridge with improved walking stability of the present invention is a second retaining wall type.
17 is a plan view showing upper and lower brackets when the extended footbridge with improved walking stability of the present invention is a steel wire reinforcement type.
18 is a front view showing a base plate when the extended footbridge with improved walking stability of the present invention is a steel wire reinforcement type.
19 is a front view showing a base plate when the extended footbridge with improved walking stability of the present invention is a steel wire reinforcement type.
FIG. 20 is an enlarged view illustrating part A of FIG. 17.

The above objects, features, and other advantages of the present invention will become more apparent by describing in detail a preferred embodiment of the present invention with reference to the accompanying drawings. Hereinafter, with reference to the accompanying drawings will be described in detail an extended footbridge with improved walking stability according to an embodiment of the present invention.

1 to 3, the extended footbridge 100 with improved walking stability of the present invention illustrates a case of a general type, and includes a main member 110, a couple member 120, and a vibration damping unit 130 .

As shown in FIG. 1, the main member 110 is fixed in a cantilevered structure outside the structure 1 in which the sidewalk is not installed, and is formed in the shape of a beam having an "I" structure.

At this time, the main member 110 is fixed to the outer wall of the structure 1 by a base plate 112 installed at the end with a bolt (B1).

Here, the base plate 112 has a plurality of fastening holes for fastening bolts on the outer wall of the structure 1, as shown in FIG. 3, and reinforcing plates 113 are provided on both sides of the main member 110 so as to be sheared and bent. Improves resistance to

Moreover, the base plate 112 is provided with a plurality of reinforcing plates embedded in the existing structure 1 and integrated into the rear surface.

And the main member 110 is provided with a lower bracket 114 on the upper portion.

The lower bracket 114 has a plurality of through-holes 114a formed therethrough so that the elastic body 1310 of the vibration attenuating part 130 penetrates.

The couple member 120 is fixed to the upper side of the main member 110 in a cantilevered structure, and a polygonal steel pipe 124 is disposed on the upper side at each set interval, and a bottom plate 126 such as synthetic wood or the like is disposed on the steel pipe 124 It is provided, the section steel 128 is fixed in the longitudinal direction at the end, and the railing support 129 is provided on the upper surface of the section steel 128.

At this time, the couple member 120 can secure structural safety by securing the stiffness of the branch portion by processing the side surface.

In addition, the couple member 120 is provided with an upper bracket 122 at the bottom.

The upper bracket 122 has a plurality of through-holes 122a formed therethrough so that the elastic body 1310 of the vibration attenuating part 130 penetrates.

Vibration attenuating unit 130 is installed between the upper and lower brackets 122 and 114 to improve pedestrian performance by attenuating vibrations, and when a civil complaint about the width of use occurs after construction, only the upper bracket 122 is changed to enable rapid civil complaint processing. It is possible.

At this time, at least one of the elastic body 1310 and the pad 1320 is applied to the vibration attenuating unit 130, and in the present invention, it is exemplified that both the elastic body 1310 and the pad 1320 are used.

This is achieved by installing a pad 1320 between the upper and lower brackets 122 and 114, and overlapping the through hole 114a of the lower bracket 114 and the through hole 122a of the upper bracket 122. The elastic body 1310 is installed through the holes 114a and 122a.

The elastic body 1310 is closed with upper and lower caps, and has an open type (refer to Fig. 4(a)) for convenient level control through a vibration reduction effect and an adjustment bolt, and an internal sponge to reduce vibration due to horizontal force, and a vibration reduction effect. And it is divided into a convenient sealed type [see Fig. 4(b)] for level control through the adjustment bolt.

On the other hand, the elastic body 1310 is excellent in structural safety by minimizing the transmission of vibration by using an impact spring bolt against the impact load generated on the upper portion to shape the fatigue life of the sub-material 120.

The pad 1320 is made of a material such as an elastic pad, and has a large support load per unit area and has strong acid resistance, oil resistance, and heat resistance (see FIG. 4(c)).

In addition, the pad 1320 absorbs the transmission power of the upper live load as energy, so that the effect of distributing the load is efficiently achieved with high flexibility and elasticity, and is excellent in walking stability.

In addition, the pad 1320 is composed of a fine air layer inside the material, has excellent buffering function and elasticity, and is excellent in resistance to deformation for a long period of time, so that glass management is excellent.

As described above, a process of installing the extended footbridge 100 having improved walking stability of the present invention to the structure 1 will be described as follows.

First, in a state in which the base plate 112 of the main member 110 is in close contact with the installation surface of the structure 1, the base plate 112 is fixed to the installation surface of the structure 1 through bolts.

Next, the pad 1320 is seated on the lower bracket 114 of the main member 110.

Next, the upper bracket 122 of the sub-material 120 is seated on the pad 1320.

Next, the elastic body 1310 is installed through the through holes 114a and 122a in a state in which the through holes 114a of the lower bracket 114 and the through holes 122a of the upper bracket 122 are overlapped.

Next, a polygonal steel pipe 124 is disposed on the upper portion of the couple member 120 at each set interval, and a bottom plate 126 such as synthetic wood or the like on the steel pipe 124, and a railing support 129 at the end (128) Fix it on the top surface.

In this way, the pad 1320 and the elastic body 1310 are installed between the lower bracket 114 of the main member 110 and the upper bracket 122 of the subsidiary member 120 to prevent impact from being transmitted to the joint portion. Can be obtained.

5 and 6, the extended footbridge 200 having improved walking stability of the present invention illustrates a case of a reinforced type, but includes a main member 210, a couple member 220 and a vibration damping part 230, and , Unlike the previous general type, which does not fix the sub-material 120 to the outer wall of the structure 1, only the point of reinforcing the sub-material 220 to the outer wall of the structure 1 with bolts (B2) is different, so a detailed description will be omitted. do.

Here, unexplained reference numeral 212 is a base plate, 213 is a reinforcing plate, 214 is a lower bracket, 214a, 222a are through holes, 222 is an upper bracket, 224 is a steel pipe, 226 is a bottom plate, 228 Is a section steel, 229 is a railing post, and B1 is a bolt.

7 and 8, the extended footbridge 300 having improved walking stability of the present invention illustrates a case of an upper reinforcement type, but includes a main member 310, a couple member 320, and a vibration damping part 330 And, since the sub-material 320 is partially superimposed on the upper surface of the structure 1 and fixed with a bolt B3 to reinforce it, a detailed description will be omitted.

Meanwhile, since the upper bracket 322 extends to the upper surface of the structure 1, the through hole 322a is formed through the portion extending to the upper surface of the structure 1.

Here, unexplained reference numeral 312 is a base plate, 313 is a reinforcing plate, 314 is a lower bracket, 314a is a through hole, 322 is an upper bracket, 324 is a steel pipe, 326 is a bottom plate, and 328 is a section steel. , 329 is a railing post, and B1 is a bolt.

9 and 10, the extended footbridge 400 having improved walking stability of the present invention illustrates a case of the first slope type, but the main member 410, the couple member 420, and the vibration attenuating part 430 Including, and unlike the previous general type, the structure 1 differs only in the outer wall of the first side surface, and the rest of the configuration is the same, so a detailed description thereof will be omitted.

Here, unexplained reference numeral 412 is a base plate, 413 is a reinforcing plate, 414 is a lower bracket, 414a, 422a are through holes, 422 is an upper bracket, 424 is a steel pipe, 426 is a bottom plate, and 428 Is a section steel, 429 is a railing post, and B1 is a bolt.

11 and 12, the extended footbridge 500 having improved walking stability of the present invention illustrates the case of the second slope type, but the main member 510, the couple member 520, and the vibration attenuating part 530 Including, and the sub-member 520 is partially overlapped on the upper surface of the second side surface portion of the structure 1 and fixed with bolts B3 to reinforce it, so a detailed description thereof will be omitted.

Meanwhile, since the upper bracket 522 extends to the upper surface of the second side surface portion of the structure 1, the through hole 522a is formed through the portion extending to the upper surface of the structure 1.

Here, unexplained reference numeral 512 is a base plate, 513 is a reinforcing plate, 514 is a lower bracket, 514a is a through hole, 522 is an upper bracket, 524 is a steel pipe, 526 is a bottom plate, and 528 is a section steel. , 529 is a railing post, and B1 is a bolt.

13 and 14, the extended footbridge 600 having improved walking stability of the present invention illustrates the case of the first retaining wall type, but the main member 610, the couple member 620, and the vibration attenuating part 630 It includes, and unlike the previous general type, the structure 1 is different only that the outer wall of the first retaining wall portion, and the rest of the configuration is the same, so a detailed description thereof will be omitted.

Here, unexplained reference numeral 612 is a base plate, 613 is a reinforcing plate, 614 is a lower bracket, 614a, 622a is a through hole, 622 is an upper bracket, 624 is a steel pipe, 626 is a bottom plate, 628 Is a section steel, 629 is a railing post, and B1 is a bolt.

15 and 16, the extended footbridge 700 having improved walking stability of the present invention illustrates the case of the second retaining wall type, but the main member 710, the couple member 720, and the vibration attenuating part 730 Including, since the sub-material 720 is partially overlapped on the upper surface of the second retaining wall portion of the structure 1 and fixed with bolts B3 to reinforce it, so detailed description thereof will be omitted.

Meanwhile, since the upper bracket 722 extends to the upper surface of the second retaining wall portion of the structure 1, the through hole 722a is formed through the portion extending to the upper surface of the structure 1.

Here, unexplained reference numeral 712 is a base plate, 713 is a reinforcing plate, 714 is a lower bracket, 714a is a through hole, 722 is an upper bracket, 724 is a steel pipe, 726 is a bottom plate, and 728 is a section steel. , 729 is a railing post, and B1 is a bolt.

17 to 19, the extended footbridge 800 having improved walking stability of the present invention illustrates a case of a steel wire reinforcement type, but the main member 810, the couple member 820, the vibration attenuating part 830 and the tension Since the providing unit 840 is included, and the tension providing unit 840 is further included, unlike the general type, only different portions will be described.

The base plate 812 is fixed to the outer wall of the structure 1 with bolts B1 and B2, respectively, while the adjacent ends of the main member 810 and the couple member 820 are fixed to the base plate 812.

At this time, the tension providing unit 840 is applied to the fixing plate 821 and a steel bar or a steel wire installed at both ends of the outer wall of the tension providing unit 840 opposed thereto, and can be fixed in a horizontal or oblique direction.

Moreover, when the tension providing unit 840 is a steel bar, the fixing unit 842 is fixed to the end exposed to the outer wall side of the tension providing unit 840 in a helical fastening method.

The tension providing unit 840 includes a pre-tension for pre-tensioning between the fixing plate 821 fixed to the inside of the couple member 820 and the outer wall, and the tension providing unit 840 is a steel material. When sagging occurs in the tension providing unit 840, it is provided to enable the adjustment of the post tension by further tightening the fixing unit 842 screwed to the tension providing unit 840.

That is, the tension providing unit 840 is a component that generates a tensile force to prevent sagging or vibration that may occur when the length of the sub-member 820 is increased.

Therefore, it is possible to apply to a footbridge having a large fatigue load or a working load by maintaining the tension on the couple member 820 by the tension providing unit 840, and the first part where sagging or structural fragility may occur due to fatigue. It is possible to give pre-tension to the device and to give it a post-tension when sagging occurs to bring it to the initial installation position.

Referring to FIG. 20(a), when the tension providing part 840 is a steel bar in the horizontal direction, the anchor nut 842 is an anchor nut at the exposed end through the anchor plate 844 fixed to the outer wall of the sub-material 820. Then, the fixing unit 842 is closed with a protective cap 846.

Referring to FIG. 20(b), when the tension providing part 840 is a horizontal steel wire, the anchor head 848 and the anchor at the exposed end through the anchor plate 844 fixed to the outer wall of the sub-material 820. It is fixed using a cap (849).

Referring to FIG. 20(c), when the tension providing part 840 is a steel bar in an oblique direction, the anchor nut 842 is an anchor nut at the exposed end through the anchor plate 844 fixed to the outer wall of the sub-material 820. Then, the fixing unit 842 is closed with a protective cap 846.

Referring to FIG. 20(d), when the tension providing unit 840 is a steel wire in an oblique direction, the anchor head 848 and the anchor at the exposed end through the anchor plate 844 fixed to the outer wall of the sub-material 820. It is fixed using a cap (849).

In this case, when the tension providing unit 840 is a steel bar or a steel wire in an oblique direction, the outer surface of the anchor plate 844 is formed with an inclined surface to have a direction orthogonal to the center of the tension providing unit 840.

Here, unexplained reference numeral 813 is a reinforcing plate, 814 is a lower bracket, 814a is a through hole, 822 is an upper bracket, 824 is a steel pipe, 826 is a bottom plate, 828 is a section steel, and 829 is a railing post. And B1 is a volt.

Meanwhile, although not shown in the drawings, the tension providing unit can be selectively applied to the previous structure, and detailed descriptions are omitted.

Embodiments of the present invention have been described above with reference to the accompanying drawings, but those of ordinary skill in the art to which the present invention pertains can be implemented in other specific forms without changing the technical spirit or essential features. You will be able to understand. Therefore, it should be understood that the embodiments described above are illustrative and non-limiting in all respects.

1: structure
100, 200, 300, 400, 500, 600, 700, 800: extended footbridge
110, 210, 310, 410, 510, 610, 710, 810: main member
114, 214, 314, 414, 514, 614, 714, 814: lower bracket
120, 220, 320, 420, 520, 620, 720, 820: subsidiary material
122, 222, 322, 422, 522, 622, 722, 822: upper bracket
130, 230, 330, 430, 530, 630, 730, 830: vibration damping unit
1310, 2310, 3310, 4310, 5310, 6310, 7310, 8310: elastic body
1320, 2320, 3320, 4320, 5320, 6320, 7320, 8320: pad

Claims (6)

A main member 110 including a base plate integrated with the existing structure outside the existing structure in which the sidewalk is not installed;
A couple member 120 fixedly provided on the upper side of the main member 110 so as to protrude outside the end of the main member 110 by a predetermined length, and provided with a bottom plate and a railing post on the upper side;
A lower bracket 114 provided on the upper portion of the main member 110;
An upper bracket 122 provided under the couple member 120;
A vibration damping unit 130 installed between the upper bracket 122 and the lower bracket 114 to attenuate the vibration; And
A tension providing unit 840 that generates a tensile force to prevent sagging or vibration of the sub-member 120 caused by the length of the sub-member 120 protruding outside the end of the main member 110 by a predetermined length. ); includes,
A pad 1320 for attenuating vibration is provided between the lower bracket 114 and the upper bracket 122,
The vibration damping part 130 is installed in a structure that penetrates both the upper bracket 122 and the lower bracket 114,
The vibration damping unit 130 includes an elastic body 1310 penetrating both the upper bracket 122 and the lower bracket 114, and an upper cap and a lower cap fixed by bolting while surrounding both ends of the elastic body 1310. Includes,
The vibration attenuating unit 130 is provided in a manner that aligns the upper bracket 122 and the lower bracket 114 provided with the pad 1320 therebetween without spaces apart from each other,
The tension providing unit 840 includes a fixing plate 821 provided at a central point of the sub-member 120 corresponding to the end of the main member 110 and the fixing unit 842 provided at the end of the sub-member 120. An extended footbridge with improved walking stability, characterized in that the structure is fixed to both outer walls.
The method of claim 1,
The couple member is provided to cover an outer wall of the structure or an upper portion of the structure,
An extended footbridge with improved walking stability, characterized in that the base plate of the main member is provided with a reinforcing plate so as to be integrated with the structure.
delete delete The method of claim 1,
The extension footbridge with improved walking stability, characterized in that the tension providing unit is any one of a post-tension steel bar or a steel wire for reinforcing sagging.
The method of claim 5,
The extension footbridge with improved walking stability, characterized in that the tension providing unit is installed in a horizontal or oblique direction.

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