KR102453222B1 - Reinforced girder and bridge using the same - Google Patents

Abstract

The present invention provides a reinforced girder (A) having a steel plate reinforced part (200) which comprises a main body (201) of a steel pipe structure having a circular or polygonal cross section, and a reinforcing steel plate (202) installed longitudinally inside the main body (201) and having both edges welded to the inner surface of the steel pipe so as to be positioned biased upwardly or downwardly. Therefore, excellent appearance and structural stability can be achieved without increasing the overall diameter and thickness of the steel pipe.

Description

Reinforcement girder with steel plate reinforcement and bridge using the same

The present invention relates to the field of construction, and more particularly, to a reinforcing girder having a steel plate reinforcing part.

Existing reinforced concrete bridges, even when long spans are required, have limitations in span length due to shape space, excessive foundation construction costs, and in the case of Ramen bridges, construction cost and aesthetics due to the disadvantages of road vertical alignment as the height increases. It was very unfavorable in that respect.

Steel pipe girder or composite girder bridges compensate for the shortcomings of reinforced concrete bridges as described above, and various types of construction methods are being developed because they have a low shape and are advantageous for river passageways and lower space.

In the case of a bridge using steel pipe as a girder among existing steel products, the aesthetics is excellent, but the sectional stiffness is smaller than that of an I-type or H-section girder (secondary moment of section is about 65%). There is a problem in that it is disadvantageous to economic feasibility because the diameter and thickness of the must be increased as a whole.

The present invention was derived to solve the above problems, and it is to present a reinforcing girder and its construction method that have excellent aesthetics and achieve excellent structural stability without increasing the diameter and thickness of the steel pipe as a whole. The purpose.

In order to solve the above problems, the present invention provides a body 201 of a steel pipe structure having a circular or polygonal cross section, installed along the longitudinal direction in the interior of the body 201, and positioned to be biased upward or downward, both edges provides a reinforcing girder (A) comprising a; a steel plate reinforcing part 200 having a reinforcing steel plate 202 welded to the inner surface of the steel pipe.

Preferably, the steel plate reinforcing part 200 has a circular cross-sectional structure, and the reinforcing steel plate 202 has a curved structure to protrude toward the center of the steel pipe.

Preferably, the steel plate reinforcing part 200 has a rectangular cross-sectional structure, and the reinforcing steel plate 202 has a flat structure.

The steel plate reinforcement part 200 includes a lower steel plate reinforcement part 210 disposed in the positive moment section of the bridge, and the reinforcement steel plate 202 of the lower steel plate reinforcement part 210 is the steel plate reinforcement part 200. It is preferable to be installed on the inner lower side of the

The steel plate reinforcement part 200 includes an upper steel plate reinforcement part 220 disposed in the negative moment section of the bridge, and the reinforcement steel plate 202 of the upper steel plate reinforcement part 220 is the steel plate reinforcement part 200. It is preferable to be installed on the inner upper side of the.

It is preferable that the lower steel plate reinforcing part 210 and the upper steel plate reinforcing part 220 are alternately arranged.

A steel pipe structure having a circular or polygonal cross section, and a general steel pipe part 30 formed in the same structure as the steel plate reinforcement part 200, and the general steel pipe part 30 is the lower steel plate reinforcement part 210 and it is preferably disposed between the upper steel plate reinforcing part 220 .

The steel plate reinforcing part 200 includes a thin plate part 101 formed by bending a relatively thin steel plate, and a thick plate part 102 formed by bending a thick steel plate compared to the thin plate part 101. Including, it is preferable that the thin plate portion 101 and the thick plate portion 102 are welded to each other, and both edges of the reinforcing steel plate 202 are welded to the center or both edges of the thick plate portion 102 .

It is preferable that the steel plate reinforcing part 200 has a circular cross-sectional structure, and the thin plate part 101 and the thick plate part 102 have an arc-shaped cross-sectional structure.

It is preferable that the steel plate reinforcing part 200 has a rectangular cross-sectional structure, and the thin plate part 101 and the thick plate part 102 have a "C"-shaped cross-sectional structure.

The steel plate reinforcing part 200 has a rectangular cross-sectional structure, the reinforcing steel plate 202 has a "C"-shaped bent structure, and both ends of the reinforcing steel plate 202 are welded to the center of the inner surface of the thick plate part 102. desirable.

The present invention is a bridge using the reinforcement girder (A), a plurality of piers (10); The reinforcement girder (A) installed on the upper portion of the plurality of piers (10); The upper plate 20 installed on the upper part of the reinforcing girder (A); including, the lower steel plate reinforcement part 210 is disposed in the positive moment section, the upper steel plate reinforcement part 220 is disposed in the negative moment section A bridge characterized by

The present invention provides a reinforcing girder and its construction method that have excellent aesthetics and achieve excellent structural stability without increasing the overall diameter and thickness of a steel pipe.

1 shows an embodiment of the present invention,
1 is a cross-sectional view of a first embodiment of a steel plate reinforcing part.
Figure 2 is a cross-sectional view of a second embodiment of the steel plate reinforcement.
3 is a perspective view of a first embodiment of a reinforcing girder;
4 is a cross-sectional view of a third embodiment of the steel plate reinforcement.
5 is a cross-sectional view of a fourth embodiment of a steel plate reinforcing part.
6 is a perspective view of a second embodiment of a reinforcing girder;
7 is a side view of a first embodiment of a bridge;
8 is a side view of a second embodiment of the bridge;
9 is a perspective view of a third embodiment of a reinforcing girder;
Fig. 10 is a perspective view of a third embodiment of a reinforcing girder;
11 is an exploded perspective view of a third embodiment of a reinforcing girder;
12 is a cross-sectional view of a fifth embodiment of a steel plate reinforcing part.
13 is a cross-sectional view of a third embodiment of the bridge;
14 is a perspective view of a third embodiment of the bridge;
15 is a cross-sectional view of a sixth embodiment of a steel plate reinforcing part.
16 is a cross-sectional view of a fourth embodiment of the bridge;
17 is a perspective view of a fourth embodiment of the bridge;
18 is a perspective view of a fifth embodiment of the bridge;
19 is a cross-sectional view of a seventh embodiment of a steel plate reinforcing part.
20 is a cross-sectional view of an eighth embodiment of a steel plate reinforcing part.
21 to 27 are cross-sectional views of a first embodiment of a steel plate reinforcing part.
28 to 33 are cross-sectional views of a second embodiment of a steel plate reinforcing part.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1, the reinforcing girder (A) according to the present invention is provided with a steel plate reinforcing part 200, the steel plate reinforcing part 200 is a body 201 of a steel pipe structure having a circular or polygonal cross section. And, installed along the longitudinal direction in the interior of the body 201, and take a structure provided with a reinforcing steel plate 202, both edges of which are welded to the inner surface of the steel pipe so as to be inclined upward or downward.

It is installed inside the steel plate reinforcement part 200 of the steel pipe structure to increase the resistance (strength) to the maximum moment, and it is possible to efficiently reinforce the necessary parts without increasing the overall diameter or thickness of the steel pipe, Since it is not installed over the entire area of the inside of the reinforcing girder (A), but only in some areas that require reinforcement, there is an advantage in that the burden of welding work on the inside of the steel pipe is not large.

When the steel plate reinforcing part 200 has a circular cross-sectional structure, it is preferable that the reinforcing steel plate 202 is formed in a curved structure to protrude toward the center of the steel pipe in order to increase the reinforcing effect (FIGS. 1 to 3).

When the steel plate reinforcing part 200 has a rectangular cross-sectional structure, the reinforcing steel plate 202 is formed in a flat structure (Figs. 4 to 6).

The steel plate reinforcement part 200 is configured to include a lower steel plate reinforcement part 210 disposed in the positive moment section of the bridge, and an upper steel plate reinforcement part 220 disposed in the negative moment section of the bridge. (Figs. 3 and 6) ,7,8)

Since the maximum moment occurs in the lower part of the positive moment section of the girder installed on the bridge (the section between the pier 10 and the pier 10), the lower steel plate reinforcement part 210 has the reinforcement steel plate 202. It resists the maximum moment (Fig. 1, 4).

When the steel plate reinforcing part 200 has a circular cross-sectional structure, the reinforcing steel plate 202 is positioned to the lower side and is curved to protrude toward the upper side, which is the center of the steel plate reinforcing part 200, thereby resisting the maximum moment. (Fig. 1)

Since the maximum moment is generated in the upper part of the negative moment section (the upper section of the pier 10) of the girder installed on the bridge, the upper steel plate reinforcing part 220 resists the maximum moment as the reinforcing steel plate 202 is located biased upward. .(Fig. 2,5)

When the steel plate reinforcing part 200 has a circular cross-sectional structure, the reinforcing steel plate 202 is positioned to the upper side and is curved to protrude toward the lower side, which is the center of the steel plate reinforcing part 200, thereby resisting the maximum moment. (Fig. 2)

The reinforcing girder (A) according to the present invention is configured to include a lower steel plate reinforcing part 210 and an upper steel plate reinforcing part 220 as described above. The girder supported by the plurality of piers 10 has a positive moment section and a parent. Since the ment section is repeated, it is preferable to basically adopt a structure in which the lower steel plate reinforcing part 210 and the upper steel plate reinforcing part 220 are alternately arranged. (FIG. 7)

In some cases, when the above structure becomes an overreinforced structure, using the general steel pipe part 30 formed in the same structure as the steel plate reinforcement part 200 as a steel pipe structure having a circular or polygonal cross section, this general steel pipe part It is efficient to arrange 30 between the lower steel plate reinforcing part 210 and the upper steel plate reinforcing part 220 (FIG. 8).
In order to prevent an overreinforced structure, the general steel pipe part 30 has a hollow structure. (FIG. 11)

Since the lower steel plate reinforcing part 210 and the upper steel plate reinforcing part 220 have a vertical symmetrical structure, the load conditions (positive moment section or negative moment section) of the installed bridge after manufacturing a plurality of steel plate reinforcing parts 200 of the same structure ), since the reinforcing girder (A) can be manufactured, the advantage of excellent manufacturing convenience is added.

Hereinafter, an embodiment in which the thick plate portion 102 is added will be described.

The steel plate reinforcing part 200 includes a thin plate part 101 formed by bending a relatively thin steel plate, and a thick plate part 102 formed by bending a thick steel plate compared to the thin plate part 101, and , the thin plate part 101 and the thick plate part 102 are welded to each other, and both edges of the reinforcing steel plate 202 may take a structure in which both edges of the thick plate part 102 are welded to each other. (FIGS. 9 to 11)

That is, the thin plate part 101 and the thick plate part 102 are manufactured by bending steel plates having different thicknesses, and the steel plate reinforcement part 200 of the steel pipe structure having a circular or polygonal cross section as a whole is manufactured by welding them together. can

It is preferable in terms of aesthetics that the step structure caused by the difference in thickness of the thin plate part 101 and the thick plate part 102 is formed inside the steel plate reinforcing part 200 so that the stepped structure is not visible from the outside. .

Since the steel plate reinforcing part 200 has a greater strength than the thin plate part 101 in comparison with the thin plate part 101, the lower part of the girder installed in the positive moment section of the bridge or the upper part of the girder installed in the negative moment section As such, when the upper plate part 102 is disposed at a position where a greater stress is generated compared to other parts, it is possible to efficiently resist external force by the large strength of the thick plate part 102, the thin plate part 101 ), the material can be saved due to the fact that it is a structure formed by welding the thin plate part 101 and the thick plate part 102. It has advantages such as ease of operation.

When the steel plate reinforcing part 200 has a circular cross-sectional structure, the thin plate part 101 and the thick plate part 102 are formed in an arc-shaped cross-sectional structure (Figs. 12 and 15).

In the case of the lower steel plate reinforcing part 210 installed in the positive moment section where the maximum moment occurs in the lower part, the thin plate part 101 is disposed on the upper part, the thick plate part 102 is disposed on the lower part, and the reinforcing steel plate 202 is disposed on the lower part. is positioned to the lower side and takes a curved structure to protrude toward the upper side, which is the center of the steel plate reinforcing part 200 (Figs. 12 to 14).

In the case of the upper steel plate reinforcing part 220 installed in the negative moment section where the maximum moment is generated, the thick plate part 102 is disposed on the upper part, the thin plate part 101 is disposed on the lower part, and the reinforcing steel plate 202 is disposed on the lower part. is positioned to the upper side and takes a curved structure to protrude toward the lower side, which is the center of the steel plate reinforcing part 200 (Figs. 15 to 17).

When the steel plate reinforcing part 200 has a rectangular cross-sectional structure, the thin plate part 101 and the thick plate part 102 are each formed in a "C"-shaped cross-sectional structure ( FIGS. 19 and 20 ).

In the case of the lower steel plate reinforcing part 210 installed in the positive moment section where the maximum moment occurs in the lower part, the thin plate part 101 of the "C"-shaped cross-section structure is disposed on the upper part, and the thick plate part of the "C"-shaped cross-sectional structure is provided. (102) is disposed on the lower side, the reinforcing steel plate 202 is located inclined to the lower side. (FIG. 19)

In the case of the upper steel plate reinforcing part 220 installed in the negative moment section where the maximum moment occurs at the top, the thick plate part 102 of the "C"-shaped cross-sectional structure is disposed on the upper part, and the thin plate part of the "C"-shaped cross-sectional structure is provided. 101 is disposed at the lower portion, and the reinforcing steel plate 202 is located at an upward bias. (FIG. 20)

Hereinafter, an embodiment of the manufacturing method of the lower steel plate reinforcing part 210 among the reinforcing girder of a circular cross section according to the present invention will be described.

A thin plate portion 101 is formed by bending a thin steel plate (FIG. 21).

The thick plate part 102 is formed by bending a steel plate thicker than the thin plate part 101, and both ends are taper-processed (Figs. 22 and 23).

The reason for forming the tapered part 102a at both ends of the thick plate part 102 is for stable welding connection with the thin plate part 101 having a thinner thickness than the thick plate part 102 .

A reinforcing steel plate 202 is formed by bending a thin steel plate or a thick steel plate, and both ends thereof are welded to the inner surface of the thick plate part 102 ( FIGS. 24 and 25 ).

With respect to both ends of the bent thin plate part 101, both ends of the thick plate part 102 to which the reinforcing steel plate 202 is bonded are welded together. (Figs. 26 and 27)

When the welding operation is difficult because the space between the reinforcing steel plate 202 and the thick plate portion 102 is narrow, the present embodiment can easily utilize the wide space between the thin plate portion 101 and the reinforcing steel plate 202 in spite of this. It has the advantage of being able to perform welding work.

Hereinafter, an embodiment of the manufacturing method of the lower steel plate reinforcement part 210 among the reinforcement girder of the rectangular cross section according to the present invention will be described.

A thin steel plate is bent into a "C"-shaped cross-sectional structure to form the thin plate part 101 (FIG. 28).

The thick plate part 102 is formed by bending a steel plate thicker than the thin plate part 101 into a "C"-shaped cross-sectional structure, but the both ends are taper-processed (FIGS. 29 and 30).

The reason for forming the tapered part 102a at both ends of the thick plate part 102 is for stable welding connection with the thin plate part 101 having a thinner thickness than the thick plate part 102 .

A reinforcing steel plate 202 is formed by bending a thin steel plate or a thick steel plate into a "C"-shaped cross-sectional structure, and both ends thereof are welded to the center of the inner surface of the thick plate part 102 (FIG. 31).

Both ends of the thick plate part 102 to which the reinforcing steel plate 202 is bonded are welded to both ends of the thin plate part 101 bent with a "C"-shaped cross-sectional structure. (FIGS. 32 and 33)

In spite of this embodiment, there is an advantage that welding can be easily performed by utilizing a wide space between the thin plate portion 101 and the reinforcing steel plate 202 .

Since the above has only been described with respect to some of the preferred embodiments that can be implemented by the present invention, the scope of the present invention as noted above should not be construed as being limited to the above embodiments, and It will be said that the technical idea and the technical idea with the root are all included in the scope of the present invention.

A : Reinforcement girder 10 : Pier
20: top plate 30: general steel pipe part
101: thin plate part 102: thick plate part
200: steel plate reinforcement part 201: body
202: reinforcing steel plate 210: lower steel plate reinforcement
220: upper steel plate reinforcement part

Claims (12)

A body 201 of a steel pipe structure having a circular or polygonal cross section, and
A steel plate reinforcing part 200 provided with a reinforcing steel plate 202 installed in the longitudinal direction inside the main body 201 and having both edges welded to the inner surface of the steel pipe so as to be located at an upward or downward bias. do,
The steel plate reinforcement part 200,
The lower steel plate reinforcement 210 disposed in the positive moment section of the bridge;
The upper steel plate reinforcement 220 disposed in the negative moment section of the bridge;
A steel pipe structure having a circular or polygonal cross section, and a general steel pipe part 30 formed in the same structure as the steel plate reinforcement part 200;
The reinforcing steel plate 202 of the lower steel plate reinforcing part 210 is installed on the inner lower side of the steel plate reinforcing part 200,
The reinforcing steel plate 202 of the upper steel plate reinforcing part 220 is installed on the inner upper side of the steel plate reinforcing part 200,
The lower steel plate reinforcing part 210 and the upper steel plate reinforcing part 220 are alternately arranged,
The general steel pipe part 30 is disposed between the lower steel plate reinforcement part 210 and the upper steel plate reinforcement part 220,
Reinforcement girder (A), characterized in that the general steel pipe portion 30 has a hollow structure in order to prevent overreinforcement structure. According to claim 1,
The steel plate reinforcement 200 has a circular cross-sectional structure,
The reinforcing steel plate 202 is a reinforcing girder (A), characterized in that it has a curved structure to protrude toward the center of the steel pipe. According to claim 1,
The steel plate reinforcing part 200 has a rectangular cross-sectional structure,
The reinforcing steel plate 202 is a reinforcing girder (A), characterized in that it has a flat structure. delete delete delete delete According to claim 1,
The steel plate reinforcing part 200 includes a thin plate part 101 formed by bending a relatively thin steel plate, and a thick plate part 102 formed by bending a thick steel plate compared to the thin plate part 101. including,
The thin plate portion 101 and the thick plate portion 102 are welded to each other,
Reinforcement girder (A), characterized in that both edges of the reinforcing steel plate (202) are welded to the center or both edges of the thick plate (102). 9. The method of claim 8,
The steel plate reinforcement 200 has a circular cross-sectional structure,
The thin plate part 101 and the thick plate part 102 are reinforcing girder (A), characterized in that it has an arc-shaped cross-sectional structure. 9. The method of claim 8,
The steel plate reinforcing part 200 has a rectangular cross-sectional structure,
Reinforcement girder (A), characterized in that the thin plate portion 101 and the thick plate portion 102 have a "C"-shaped cross-sectional structure. 9. The method of claim 8,
The steel plate reinforcing part 200 has a rectangular cross-sectional structure,
The reinforcing steel plate 202 has a "C"-shaped bent structure,
Reinforcement girder (A), characterized in that both ends of the reinforcing steel plate (202) are welded to the center of the inner surface of the thick plate (102). As a bridge using the reinforcing girder (A) of any one of claims 1 to 3 and 8 to 11,
a plurality of piers (10);
The reinforcement girder (A) installed on the upper portion of the plurality of piers (10);
Including; the upper plate 20 installed on the upper part of the reinforcing girder (A);
A bridge, characterized in that the lower steel plate reinforcing part 210 is disposed in the positive moment section, and the upper steel plate reinforcing part 220 is disposed in the negative moment section.

Images