KR102739857B1 - support structure of girder construction for side walk or bridge - Google Patents

Abstract

The present invention relates to a support structure for girder construction intended for sidewalks or bridges. The support structure positions a main girder with high structural strength and significant weight and size at the center of a cantilever. It also positions an outer girder, which has lower structural strength and less weight and size than the main girder, around the cantilever. This arrangement aims to lighten the overall weight of the cantilever (coping) and facilitate its construction with reduced costs. The support structure of the girder method includes multiple pillars (10), a main cantilever (20), a main girder connecting member (30), an outside girder connecting member (40), a main girder (50), an outside girder (60), a secondary cantilever (70), and a longitudinal direction supporting member (80).

Description

{support structure of girder construction for side walk or bridge}

The present invention relates to a structure using a girder method for supporting a deck road for forming a hiking trail or walking trail at the foot of a mountain, on a hill, near a waterway, etc. The present invention relates to a structure using a girder method for supporting a cantilever-type deck road, which effectively forms a hiking trail or walking trail, a skywalk, a tree-top road, a bridge, a pedestrian bridge, or a bicycle path by utilizing a girder method using a circular steel pipe and beam on the upper part of a support.

Recently, as interest in the environment has increased, deck roads using flat or inclined wooden decks are being installed and utilized in various places such as hiking trails, walking paths in parks, sidewalks formed along lakesides, and terraces of country houses or pensions.

These deck roads refer to walkways, etc., made by continuously arranging and installing block-shaped decks, which are mainly made using synthetic wood, natural wood, or various synthetic resins.

Deck roads like this are mainly installed on pedestrian bridges that are built to add a separate sidewalk outside the roadway of a bridge, or on footbridges built exclusively for pedestrians, or on hiking trails or walking paths in mountains or parks.

These conventional deck load systems are generally composed of a yoke frame that is installed in two rows in a balanced manner and has connecting frames formed at regular intervals, a deck plate installed on top of the yoke frame, a handrail member installed on top of the deck plate, and a support that supports the yoke frame at a certain height from the ground, and each component is mainly configured to be fastened using direct-drilling screws.

In such a deck load system, the support is typically provided downward on each of the two rows of yoke frames on both sides, as shown in the “deck load equipped with a block frame” (Korean Patent Publication No. 10-1793243, Patent Document 1), and thus also takes on a two-row arrangement.

However, there are cases where it is difficult to arrange two rows of columns for various reasons, such as when the deck road is installed at the foot of a mountain, near a waterway, or when the installation height is high from the ground.

In addition, for existing landscaping installed in these locations, the maintenance and management cycle is becoming shorter, which is causing difficulties in budget execution due to increased maintenance costs for each local government.

As part of an effort to resolve these problems, a "deck-joint support-type pedestrian bridge with pile reinforcement cap and anti-loosening bolt applied" (Korean Patent Publication No. 10-2491293, Patent Document 2) discloses a structure in which a steel coping is installed on the upper part of a support installed vertically on the ground, a girder is installed on the upper part of the steel coping, a pipe is placed on top of it, and then a deck plate is installed on top of the pipe.

The above-mentioned patent document 2 has a cantilever structure in which the outer edges of the coping are extended to both sides of a central support firmly installed in the ground, and girders are arranged on top of it, so that the structural stability is high and the durability is excellent, which can lead to a reduction in maintenance and management costs compared to the past.

This patent document 2 can be said to be a support-type pedestrian bridge using steel coping combined with a deck road. However, in the case of patent document 2, there is a problem that the initial construction cost increases because it has a structure similar to a support-type pedestrian bridge on which vehicles, etc. pass, and the construction cost is similar to that of a large support-type pedestrian bridge.

Specifically, in terms of girder placement, they are necessarily placed on both the left and right sides of the coping, and are also placed in the central area as needed. This structure requires a structural design that enables the coping to support the load of the girder applied to both left and right ends, which results in an increase in weight.

This provides an unnecessary structure for deck loads that are intended for people rather than vehicles, and as the weight increases, it also increases manufacturing and installation costs.

In addition, compared to a support-type bridge for vehicle traffic, in the case of a deck road, the length between supports can be increased to induce cost reduction, but a structure such as Patent Document 2 has a problem in that it is difficult to increase the distance between supports because the girders placed on the coping are made of the same standard.

KR 10-1793243 (2017.10.27) KR 10-2491293 (2023.01.18)

The support structure of the girder method for a bridge or a walkway of the present invention is intended to solve the problems occurring in the above-mentioned conventional technology, by arranging a main girder with high structural strength and large weight and size at the center of a cantilever, and arranging an outer girder with lower structural strength and smaller weight and size than the central main girder at the outer periphery of the cantilever, thereby reducing the weight of the overall cantilever (coping) and facilitating the construction of the cantilever at a lower construction cost.

In addition, by providing auxiliary cantilevers supported by the main girder between the main cantilevers installed on each support, the distance between the supporters can be lengthened while allowing the load of the deck load to be evenly distributed and transmitted to the lower part, thereby enabling the installation and construction of the deck load at a low cost.

In addition, the outer girder cover member, into which the outer girder connecting member connecting the outer girders is inserted, is made to protrude above the upper coping so as to directly support the metal mesh body that supports the deck material, so that the support of the deck material through the metal mesh body can be continuously maintained.

In addition, unlike the structure in which the girder is installed on the coping, the structure in which the girder is butted together and connected through a girder connecting member inserted into the coping minimizes the need for a connecting member that connects the girders laterally, thereby further minimizing the load burden applied to the cantilever (coping) and ensuring ease of construction.

In addition, by installing a metal mesh that can evenly support and transmit the load of the deck material, even if partial damage to the deck material occurs, the phenomenon of the deck material falling out is prevented, thereby temporarily ensuring the safety of pedestrians before repairs.

In order to solve the above-mentioned problem, the support structure of the girder method for a bridge or a pavement of the present invention comprises a plurality of supports (10) having a lower part inserted into the ground where the deck rod is to be installed, an upper part protruding upward above the ground, and installed spaced apart from each other along the length direction of the deck rod; A lower coping (21) in which the lower part is fixed on the upper part of each support (10) and connected to the support (10) and has a main girder lower insertion groove (21a) formed in the upper center, and a lower coping (21) that is detachably connected to the lower coping (21) through bolts, and a main girder upper insertion groove (22a) is formed at a position corresponding to the upper part of the main girder lower insertion groove (21a), and a lower part is formed to extend upwardly and slantedly to the left and right sides based on the main girder upper insertion groove (22a), and has a flat upper surface, and an upper coping (22) in which an outer girder lower insertion groove (22b) is formed on both left and right sides, and is connected to the upper coping (22) by bolting or welding at a position corresponding to the upper part of the outer girder lower insertion groove (22b), and an outer girder upper insertion groove (23a) is formed at the lower part. A main cantilever (20) composed of an outer girder cover member (23); a main girder connection member (30) having a lower portion fitted into the main girder lower insertion groove (21a), an upper portion fitted into the main girder upper insertion groove (22a), and having flange portions (31) for bolt connection formed at both ends; an outer girder connection member (40) having a lower portion fitted into the outer girder lower insertion groove (22b), an upper portion fitted into the outer girder upper insertion groove (23a), and having flange portions (41) for bolt connection formed at both ends; a main girder (50) having main flange portions (51) formed at both ends to butt and bolt-connect with the flange portions (31); an outer girder (60) having outer flange portions (61) formed at both ends to butt and bolt-connect with the flange portions (41); A first upper coping (71) and a first outer girder cover member (72) having the same shape as the upper coping (22) and the outer girder cover member (23) are provided between adjacent main cantilevers (20), and the outer girder (60) passes through the first upper coping (71) and the first outer girder cover member (72), and the lower part of the main girder (50) is inserted into the central main girder upper insertion groove (22a) and is supported by the main girder (50); A longitudinal support member (80) that is secured to the upper surface of the upper coping (22) of the main cantilever (20) and the auxiliary upper coping (51) of the auxiliary cantilever (70) and extends along the longitudinal direction of the deck rod; It is configured to include a metal mesh body (90) installed on the upper part of the longitudinal support member (80) and supporting the lower part of the deck material (A).

In the above configuration, the main girder connecting member (30) is made of a circular steel pipe with a high-strength structural member (32) inserted therein and connected to the inner surface through the connecting member (33), and the flange portion (31) of the end is made of a plate shape that blocks the inside of the circular steel pipe, and the main girder upper insertion groove (22a) of the auxiliary cantilever (70) is made in an angular shape, and when the main girder (50) has an angular cross-sectional shape, the main girder upper insertion groove (22a) of the auxiliary cantilever (70) has the same shape as the upper cross-sectional shape of the main girder (50), and when the main girder (50) has a circular cross-sectional shape, an anchoring auxiliary member (73) is provided that fills the gap between the main girder (50) and the main girder upper insertion groove (22a).

According to the present invention, a main girder having high structural strength and large weight and size is arranged at the center of a cantilever, and an outer girder having lower structural strength and smaller weight and size than the central main girder is arranged at the outer periphery of the cantilever, thereby reducing the weight of the overall cantilever (coping), and making it easy to construct the cantilever at a lower construction cost.

In addition, by providing auxiliary cantilevers supported by the main girder between the main cantilevers installed on each support, the distance between the supporters can be lengthened while the load of the deck load can be evenly distributed and transmitted to the lower part, enabling the installation and construction of the deck load to be performed at a low cost.

In addition, the outer girder cover member, into which the outer girder connecting member connecting the outer girders is inserted, is made to protrude above the upper coping and directly support the metal mesh body that supports the deck material, so that the deck material can be continuously supported through the metal mesh body.

In addition, unlike the structure where the girder is installed on the coping, the structure where the girder is butted together and connected through a girder connecting member inserted into the coping minimizes the need for a connecting member that connects the girders laterally, further minimizing the load burden applied to the cantilever (coping) and ensuring ease of construction.

In addition, by providing a metal mesh that can evenly support and transmit the load of the deck material, even if partial damage to the deck material occurs, the phenomenon of the deck material falling out is prevented, thereby temporarily ensuring the safety of pedestrians even before repairs are made.

Figure 1 is a plan view showing a support structure of a girder method for a bridge or a pavement of the present invention, a cross-sectional view of a cantilever, and an exploded cross-sectional view.
FIG. 2 is a drawing showing a state in which the main cantilever is connected to a support and the auxiliary cantilever is mounted on the main girder in the present invention.
Figure 3 is a drawing showing the assembly state of the lower coping and upper coping of the main cantilever in the present invention.
FIG. 4 is a drawing showing various examples of grooves into which girder connecting members are fitted in accordance with the shape of the girder in the present invention.
Figure 5 is a drawing showing an example of assembling a girder connecting member and a girder in the present invention.
Figure 6 is an exploded perspective view showing an assembly example of the main cantilever in the present invention.
Figure 7 is an exploded cross-sectional view showing an example of anchoring a girder with a circular cross-section to an auxiliary cantilever using an anchoring auxiliary member in the present invention.
Figure 8 is a drawing showing an example of a girder connecting member in the present invention being a circular steel pipe with a structural member inserted therein to be reinforced.

Hereinafter, the supporting structure of the girder method for a pavement or bridge of the present invention will be described in detail through the attached drawings.

The support structure of the girder method for a bridge or a pavement of the present invention is largely composed of a support (10), a main cantilever (20), a main girder connecting member (30), an outer girder connecting member (40), a main girder (50), an outer girder (60), an auxiliary cantilever (70), a longitudinal supporting member (80), and a metal mesh body (90).

The support (10), which is a component of the present invention, is composed of a plurality of pieces spaced apart from each other along the length direction of the deck rod, and the lower part is inserted into the ground itself where the deck rod is to be installed, or is connected to a foundation inserted into the ground, and the upper part protrudes upward above the ground.

These supports (10) can be applied to supports made of various materials such as metal, concrete, and reinforced concrete.

The main cantilever (20), which is a component of the present invention, is composed of a lower coping (21), an upper coping (22), and an outer girder cover member (23), as shown in Fig. 1.

The lower coping (21) is secured to the upper part of each support (10) and connected to the support (10) through bolts, and a main girder lower insertion groove (21a) is formed in the upper center so that the lower part of the main girder connecting member (30) can be inserted and supported.

In order for the lower coping (21) to be easily attached to the support (10) and connected, the lower part of the lower coping (21) is configured such that at least two walls extend downward to enable a fitting connection with the upper part of the support (10), and the two walls and the upper part of the support (10) fitted thereto are bolted in a horizontal direction so that they can be easily connected.

Referring to the drawing of Fig. 6 to explain the lower coping (21), a horizontally extending plate-shaped abutment portion (21b) is formed at both ends of the main girder lower insertion groove (21a) so as to be bolt-joined while being flush with the outer bottom portion of the upper coping (22).

In addition, a wall portion (21c) is formed long and downward from the boundary point between the rounded bottom surface forming the main girder lower insertion groove (21a) and the mating portion (21b), and the lower end of the wall portion (21c) is connected to the floor portion (21d).

In addition, the rounded bottom surface forming the main girder lower insertion groove (21a) and the bottom portion (21d) are connected by a reinforcing rib (21e) to support the load, and the lower portion of the wall portion (21c) forms an elongated extension portion (21f), and bolt installation holes forming a straight line in the horizontal direction are formed in at least two extension portions (21f), so that the support (10) can be bolted after being fitted.

In the drawing, the main girder lower insertion groove (21a) is formed in a circular shape, assuming that the main girder connecting member (30) and the main girder (50) are shaped like a circular steel pipe or steel bar. If the main girder (50) has a cross-sectional shape such as an H shape or a square shape, it is obvious that it can be formed in a corresponding shape as shown in Fig. 4.

In addition, it is obvious that the shapes of the grooves below into which the upper or lower portions of the main girder (50) and the outer girder (60) are inserted, in addition to the main girder lower insertion groove (21a), can also be implemented in various embodiments.

The upper coping (22) is detachably connected to the lower coping (21) via a bolt, as shown in FIG. 1 and FIG. 6.

In addition, a main girder upper insertion groove (22a) is formed at a position corresponding to the upper portion of the main girder lower insertion groove (21a) so that the upper portion of the main girder connecting member (30) is fitted therein.

That is, the adjacent left and right bottom surfaces of the main girder upper insertion groove (22a) are made of a flat bottom flat plate (22c) and are bolted to the lower coping (21) while being in contact with the abutting portion (21b).

In addition, a bottom slanted portion (22d) extending upwardly from both ends of the bottom flat portion (22c) toward the outer side is formed.

Meanwhile, the upper surface of the upper coping (22) is formed as a flat upper plate portion (22e) as shown in the drawing, and an outer girder lower insertion groove (22b) is formed on both left and right sides of the upper plate portion (22e) so that the lower part of the outer girder connecting member (40) can be inserted.

At this time, a central reinforcing rib (22f) is installed between the wall surface forming the inner surface of the main girder upper insertion groove (22a) and the upper flat plate portion (22e), and an outer reinforcing rib (22g) may be provided between the upper flat plate portion (22e) and the lower inclined portion (22d), and between the inner surface forming the outer girder lower insertion groove (22b) and the lower inclined portion (22d).

At this time, the outer reinforcing rib (22g) may not be extended completely to the low slope (22d) but may be extended only a certain distance from the top.

In addition, a wall surface and a low slope portion (22d) forming the inner surface of the main girder upper insertion groove (22a) constituting the lower part of the upper coping (22) and a wall portion (22h) interconnecting the inner surface forming the outer girder lower insertion groove (22b) and the upper flat portion (22e) may be provided.

The parts forming the skeleton of the upper coping (22) are not limited by the attached drawing, and various embodiments are possible with the main girder upper insertion groove (22a) and the outer girder lower insertion groove (22b) formed.

However, an embodiment such as Fig. 6 is effective because it can transmit the load from the outer girder connecting member (40) to the lower coping (21) while evenly distributing the load while reducing the weight of the upper coping (22) as much as possible.

As shown in FIG. 1 and FIG. 6, the outer girder cover member (23) is fastened to the upper coping (22) by bolting or welding at a position corresponding to the upper portion of the outer girder lower insertion groove (22b), and an outer girder upper insertion groove (23a) is formed at the bottom.

As described above, in the above configuration, various shapes, such as square, rather than the illustrated semicircular shape, are possible depending on the shape of the girder connecting members.

The outer girder cover member (23) may be configured to be level with the surface of the upper coping (22) unlike in the drawing, but it is more preferable that it protrudes upward from the upper flat plate portion (22e).

At this time, the protruding outer girder cover member (23) is positioned between the longitudinal support members (80), so that the metal mesh body (90) is supported not only through the longitudinal support members (80) but also through the outer girder cover member (23), thereby further suppressing deformation of the metal mesh body (80).

In particular, the main cantilever (20) has superior strength and durability compared to the longitudinal support member (80) on its upper side. If the longitudinal support member (80) is corroded or deformed by an upper load, the deck material (A) supported by it may be damaged or deformed. However, if the outer girder cover member (23) protrudes and supports a part of the metal mesh body (90), even if the longitudinal support member (80) is deformed or damaged, the deck material (A) can be supported smoothly through the metal mesh body (90), thereby maintaining the safety of pedestrians until repairs are made after damage or deformation.

As shown in FIGS. 1 and 6, the main girder connecting member (30), which is a component of the present invention, is configured such that the lower part is fitted into the main girder lower insertion groove (21a), the upper part is fitted into the main girder upper insertion groove (22a), and a flange part (31) for bolt connection is formed at both ends, so that it is bolt-connected to the main girder (50).

The main girder connecting member (30) may be connected to the main girder (50) after the upper coping (22) is installed on the lower coping (21) during the construction process, or may be connected before the upper coping (22) is installed.

Alternatively, the main girder (50) may be installed on the lower coping (21) in a pre-connected state, and the installation time can be adjusted according to convenience in construction.

In the drawing, the main girder connecting member (30) has a circular cross-sectional shape. As described above, this can be implemented in various forms depending on the cross-sectional shape of the main girder (50) being constructed.

As shown in FIGS. 1 and 6, the outer girder connecting member (40), which is a component of the present invention, has a lower portion that is fitted into the outer girder lower insertion groove (22b), an upper portion that is fitted into the outer girder upper insertion groove (23a), and a flange portion (41) for bolt connection is formed at both ends.

The installation of the outer girder connecting member (40) can be performed after the upper coping (22) is installed and assembled on the lower coping (21), and like the main girder connecting member (30), the outer girder (60) can be selectively connected and constructed.

As shown in the drawing, the main girder (50), which is a component of the present invention, has a main flange portion (51) formed at both ends and is bolted to the flange portion (31) while facing each other, and can be made of various types of structural materials such as a circular steel pipe, a circular steel bar, an H-shaped steel, a square pipe, or a square bar.

As shown in the drawing, the outer girder (60), which is a component of the present invention, has an outer flange portion (61) formed at both ends and is bolted to the flange portion (41) while facing each other. The shape can be of various shapes, similar to the main girder (50).

At this time, the outer girder (60) may be composed of a member having smaller structural strength, weight, and size than the main girder (50), as shown in the drawing.

That is, it would be sufficient if the deck material (A) had sufficient bearing capacity to support the load applied from both outer sides.

On the other hand, since the central main girder (50) must be able to transfer the upper load transmitted through the outer girder (60) to each support (10), it is desirable to have a relatively larger structural strength, weight, and size than the outer girder (60).

The auxiliary cantilever (70), which is a component of the present invention, is positioned between adjacent main cantilevers (20) as shown in FIGS. 1 and 2, and has a first upper coping (71) and a first outer girder cover member (72) having the same shape as the upper coping (22) and the outer girder cover member (23), and the component corresponding to the lower coping (21) is excluded, so that the support (10) is not connected to the lower portion.

That is, the load of the deck material (A) etc., which is installed on the main girder (50) and transmitted from above, is transmitted to the adjacent main cantilever (20) through the main girder (50), causing the support (10) to bear the load.

Specifically, the outer girder (60) penetrates between the first upper coping (71) and the first outer girder cover member (72), and the lower part of the main girder (50) is inserted into the central main girder upper insertion groove (22a) and is supported by the main girder (50).

In order to ensure that the upper load including the deck material (A) is smoothly transferred through the auxiliary cantilever (70), it is preferable that the main girder connecting member (30) and the main girder (50), and the outer girder connecting member (40) and the outer girder (60) have the same cross-sectional shape and size.

It is obvious that the installation of these auxiliary cantilevers (70) is performed after the installation of the main girder (50) connecting adjacent main cantilevers (20), and it is preferable that the installation of the outer girder (60) is performed after the installation of the auxiliary cantilevers (70).

However, before the installation of the outer girder (60) and the first outer girder cover member (72), the auxiliary cantilever (70) may easily rotate left and right and fall to the ground if the main girder (50) is circular as shown in the drawing.

In light of this, it is desirable that at least the main girder (50) and the main girder connecting member (30) following its shape have an angular shape rather than a circular cross-section so that the auxiliary cantilever (70) has a shape that does not rotate during the construction process.

However, if the main girder upper insertion groove (22a) at the center of the lower part of the auxiliary cantilever (70) has a semicircular shape (if the main girder has a circular cross-section) similar to the main girder upper insertion groove (22a) at the center of the lower part of the main cantilever (20), a different measure is required.

To this end, as shown in Fig. 7, the main girder upper insertion groove (22a) at the center of the lower part of the auxiliary cantilever (70) has an angular shape.

The lower part corresponds to the circular shape of the upper part of the main girder (50), and the upper part is provided with a fixing auxiliary member (73) corresponding to the angled main girder upper insertion groove (22a), so that before fixing the auxiliary cantilever (70), the fixing auxiliary member (73) can be fixed to the upper part of the main girder (50) by using a bolt (not shown) or applying a welding method, and then the auxiliary cantilever (70) can be fixed to the upper part of the fixing auxiliary member (73).

These auxiliary cantilevers (70) do not rotate or move laterally after the outer girders (60) on both left and right sides are installed on top of the first upper coping (71) and the first outer girder cover member (72) is installed on top of them.

From this point of view, the main girder (50) and the two outer girders (60) on both sides can be said to be essential components in the present invention.

In addition, considering the convenience of construction, when the main girder connecting member (30) is positioned between the lower coping (21) and the upper coping (22) for assembly work, and when the outer girder connecting member (40) is positioned on the outer sides of the upper coping (22) for assembly work, the girder connecting member (30, 40) is easy to assemble because of its circular shape.

The cross sections of the main girder (50) and outer girder (60) that are connected by facing each other with these girder connecting members (30, 40) are in fact applied in a flange manner, so they can be made of members of various shapes.

However, the aforementioned anchoring auxiliary member (73) only needs to be utilized when installing the aforementioned auxiliary cantilever (70).

In addition, the flange portions of the girder connecting members (30, 40) are configured in a plate shape with a closed interior rather than a hollow tube shape as shown in the drawing, so that girders of various shapes can be easily connected.

In summary of these viewpoints, as illustrated in Fig. 7, when forming a main girder connecting member (30), the outer surface is formed in the shape of a circular steel pipe, a highly rigid structural member (32) such as a shaped steel is inserted inside, and a connecting member (33) connecting the structural member (32) and the steel pipe is formed, and the flange portion (31) of the end is formed in the shape of a plate that blocks the inside of the steel pipe and can be formed by welding and fixing it to the steel pipe.

In this case, as described above, the main girder connecting member (30) can be easily positioned and secured on the lower coping (21), and the upper coping (22) can be guided and positioned properly on top of it, and can be easily bolted together against a main girder (50) of various cross-sectional shapes.

In addition, when the auxiliary cantilever (70) is installed on the main girder (50), if the main girder (50) has an angular shape, it is inserted into the angular main girder upper insertion groove (22a) to prevent left-right movement, and if the main girder (50) is circular, it can be installed while preventing left-right movement by utilizing the aforementioned installation auxiliary member (73).

Even if the main girder (50) has an angular shape, if there is a difference in size with the main girder upper insertion groove (22a), the fixing auxiliary member (73) can be installed using a shape corresponding to the amount of clearance.

The longitudinal support member (80), which is a component of the present invention, is mounted on the upper surface of the upper coping (22) of the main cantilever (20) and the auxiliary upper coping (51) of the auxiliary cantilever (70) and is extended along the longitudinal direction of the deck load to serve as a yoke of a typical deck load.

At this time, as described above, in the case where the outer girder cover member (23) and the first outer girder cover member (72) protrude from the upper surface of the upper coping (22) of the main cantilever (20) and the upper coping (71) of the auxiliary cantilever (70), it is preferable to configure them so that the upper surfaces have the same height.

These longitudinal support members (80) are depicted as square pipes in the drawing, but are not limited thereto and may be composed of various structural members that serve as a yoke.

As shown in the drawing, the metal mesh body (90), which is a component of the present invention, is installed on the upper part of the longitudinal support member (80), and the deck material (A) is installed on the upper part.

The installation of this metal mesh body (90) prevents damage to the deck material (A) installed via bolts, clips, etc. in a direction perpendicular to the longitudinal support member (80) and thus prevents the risk of pedestrians falling due to damage before repair or replacement.

In addition, since the deck material (A) is supported at points other than the connection point with the longitudinal support member (80), deformation of the deck material (A) is suppressed as much as possible, thereby improving the durability of the deck material (A).

The construction of a support structure for a girder method for a sidewalk or bridge configured as described above involves first installing a support (10), then attaching a lower coping (21) to the support (10), placing a main girder connecting member (30) on top of the lower coping (21), then placing an upper coping (22) on top of it, and then bolting it to the lower coping (21).

At this time, the arrangement of the main girder connecting member (30) and the arrangement of the upper coping (22) are such that the main girder lower insertion groove (21a) and the main girder upper insertion groove (22a) are located, so that installation using a crane or the like can be accomplished very easily.

Then, the main girder (50) is positioned between adjacent main girder connecting members (30) and subjected to bolt welding, and then the auxiliary cantilever (70) described above is positioned on the main girder (50).

After positioning the outer girder connecting member (40) in the outer girder lower insertion groove (22b) of the upper coping (22), the outer girder (60) is connected to both sides of the adjacent outer girder connecting member (40), and then the outer girder cover member (23) and the first outer girder cover member (72) are covered over the upper part of the outer girder (60) and then fastened by welding or bolting.

In this way, the installation work of the auxiliary cantilever (70) is also completed.

Then, a longitudinal support member (80) is placed on the upper part of each cantilever (20, 70) and fixed by welding or other methods, and then a metal mesh body (90) is placed and fixed, thereby completing the construction of the support structure of the present invention.

Above that, a deck road consisting of deck materials, railing columns, and railings is constructed.

10: Support 20: Main cantilever
21: Lower coping 22: Upper coping
21a: Main girder lower insertion groove 21b: Butt joint
21c: Wall section 21d: Floor section
21e: Reinforcing rib 21f: Extension
22a: Main girder upper insertion groove 22b: Outer girder lower insertion groove
22c: Low-level flat part 22d: Sloped part
22e: Upper plate 22f: Central reinforcing rib
22g: Outer reinforcing rib 22h: Wall section
23: Outer girder cover member 23a: Outer girder upper insertion groove
30: Main girder connecting member 31: Flange part
32: Structural member 33: Connecting member
40: Outer girder connecting member 41: Flange part
50: Main girder 51: Main flange
60: Outer girder 61: Outer flange
70: Auxiliary cantilever 71: First upper coping
72: First outer girder cover member 73: Anchoring auxiliary member
80: longitudinal support member 90: metal mesh body

Claims (2)

In the support structure,
A plurality of support posts (10) having a lower portion inserted into the ground to be installed, an upper portion protruding upward above the ground, and installed spaced apart from each other along the length direction;
A lower coping (21) in which the lower part is fixed on the upper part of each support (10) and connected to the support (10) and has a main girder lower insertion groove (21a) formed in the upper center, and a lower coping (21) that is detachably connected to the lower coping (21) through bolts, and a main girder upper insertion groove (22a) is formed at a position corresponding to the upper part of the main girder lower insertion groove (21a), and a lower part is formed to extend upwardly and slantedly to the left and right sides based on the main girder upper insertion groove (22a), and has a flat upper surface, and an upper coping (22) in which an outer girder lower insertion groove (22b) is formed on both left and right sides, and is connected to the upper coping (22) by bolting or welding at a position corresponding to the upper part of the outer girder lower insertion groove (22b), and an outer girder upper insertion groove (23a) is formed at the lower part. A main cantilever (20) composed of an outer girder cover member (23);
A main girder connecting member (30) having a lower portion fitted into the main girder lower insertion groove (21a), an upper portion fitted into the main girder upper insertion groove (22a), and a flange portion (31) for bolt connection formed at both ends;
An outer girder connecting member (40) whose lower part is fitted into the outer girder lower insertion groove (22b), whose upper part is fitted into the outer girder upper insertion groove (23a), and whose flange part (41) for bolt connection is formed at both ends;
A main girder (50) having a main flange portion (51) formed at both ends and bolted to the flange portion (31);
An outer girder (60) having an outer flange portion (61) formed at both ends and bolted to the flange portion (41);
A first upper coping (71) and a first outer girder cover member (72) having the same shape as the upper coping (22) and the outer girder cover member (23) are provided between adjacent main cantilevers (20), and the outer girder (60) passes through the first upper coping (71) and the first outer girder cover member (72), and the lower part of the main girder (50) is fitted into the central main girder upper insertion groove (22a) and is supported by the main girder (50).
It is composed of a longitudinal support member (80) that is extended along the longitudinal direction and is secured to the upper surface of the upper coping (22) of the main cantilever (20) and the auxiliary upper coping (51) of the auxiliary cantilever (70).
A support structure of girder construction for a pavement or bridge.
In paragraph 1,
The above main girder connecting member (30) is made of a circular steel pipe connected to the inner surface through a connecting member (33) with a high-strength structural member (32) inserted inside, and the flange portion (31) of the end is made of a plate shape that blocks the inside of the circular steel pipe.
The main girder upper insertion groove (22a) of the above auxiliary cantilever (70) is formed in an angular shape,
When the above main girder (50) has an angular cross-sectional shape, the main girder upper insertion groove (22a) of the auxiliary cantilever (70) has the same shape as the upper cross-sectional shape of the main girder (50).
In the case where the above main girder (50) has a circular cross-sectional shape, it is characterized in that a fixing auxiliary member (73) is provided that fills the gap between the main girder (50) and the main girder upper insertion groove (22a).
A support structure of girder construction for a pavement or bridge.