KR100555248B1 - The bridge construction method of having used an steel i beam girder to which rigidity increased and this - Google Patents

Abstract

According to the present invention, the constant moment portion in the continuous bridge is utilized as the existing steel I beam, and the parent moment portion expands and reinforces the upper and lower flanges in the transverse direction, and additionally installs one or more pairs of reinforcement plates on the left and right sides of the existing abdomen, After installation on the piers, the upper and lower flanges are interconnected in the lateral direction to increase the cross-section stiffness of the parent cement section to control the parent cement and increase the cross-section stiffness that enables the construction of long beam steel I beam bridges. The purpose is to provide a steel I beam and a bridge construction method using the same.

Steel I beam with increased cross-sectional rigidity according to the present invention for achieving the above object is composed of the upper, lower flange and the abdomen, the general steel I beam disposed on the left and right; It is disposed between the general steel I beam, and consists of an upper, lower flange and the abdomen, the predetermined width and length from the outer end of the upper flange, lower flange or upper, lower flange than the general steel I beam integrally Expanded reinforcing steel I beam; In order to connect the general steel I beam and the reinforcing steel I beam, high tension bolts or welding are coupled to one side of the upper and lower flanges of the general steel I beam, and high tension bolts or one side of the upper and lower flanges of the reinforced steel I beam. It is characterized by consisting of a connecting plate that is welded.

In addition, the bridge construction method using the steel I beam with the increased cross-sectional rigidity according to the present invention for achieving the above object comprises the steps of manufacturing a steel I beam with increased cross-sectional rigidity; Installing steel I beams having increased cross-sectional rigidity on alternating and piers; The upper and lower flanges of the reinforcing steel I beam for the reinforcement of the parent portion of the steel I beam having the increased cross-section stiffness provided on the alternating and piers are characterized in that the step of interconnecting via a connecting plate in the transverse direction.

Sectional Rigidity, Steel I Beam, Bridge Construction Method

Description

The bridge construction method of having used an steel I beam girder to which rigidity increased and this}

1 is a perspective view showing a steel I beam with increased cross section rigidity for continuous bridges according to the present invention;

Figure 2 is a plan view showing a steel I beam with increased cross-sectional rigidity of the continuous bridge according to the present invention,

3 is a cross-sectional view taken along the line A-A of FIG.

4 is a cross-sectional view taken along the line B-B of FIG.

Figure 5 is a side view showing a continuous bridge is installed steel I beam with increased cross-sectional rigidity according to the present invention,

6 is a cross-sectional view taken along the line A-A of FIG.

7 is a cross-sectional view taken along the line B-B of FIG.

8 is a plan view showing a continuous bridge provided with a steel I beam with increased cross-sectional rigidity according to the present invention;

9 is a front view showing a constant moment portion of a continuous bridge provided with a steel I-beam mold with increased cross-sectional rigidity according to the present invention;

FIG. 10 is a front view illustrating the constant moment part mold of FIG. 9; FIG.

11 is a front view showing a parent portion of a continuous bridge provided with a steel I beam mold having increased cross-sectional rigidity according to the present invention;

12 is a front view showing the parent cement portion mold of FIG.

Figure 13 is a perspective view showing a steel I beam with increased cross-sectional rigidity for simple bridges in accordance with the present invention,

14 is a plan view showing a steel I beam with increased cross-sectional rigidity for simple bridges in accordance with the present invention,

15 is a cross-sectional view taken along the line A-A of FIG. 14;

16 is a cross-sectional view taken along the line B-B of FIG. 14;

17 is a side view showing a simple bridge in which steel I beams having increased cross-sectional rigidity according to the present invention are installed;

18 is a cross-sectional view taken along the line A-A of FIG. 17;

19 is a cross-sectional view taken along the line B-B of FIG. 17;

20 is a plan view illustrating a simple bridge provided with a steel I beam having increased cross-sectional rigidity according to the present invention;

21 is a front view showing both ends of the positive moment portion of a simple bridge provided with a steel I-beam mold with increased cross-sectional rigidity according to the present invention;

FIG. 22 is a front view illustrating a mold of both side ends of the constant moment part of FIG. 21;

23 is a front view showing a central portion of a simple bridge provided with a steel I-beam mold with increased cross-sectional rigidity according to the present invention;

24 is a front view showing the mold of the center portion of the constant moment portion of FIG.

25 is a plan view showing the upper and lower flanges of the abdominal three columnar shape, the parent flange portion, the lower flange integrally;

FIG. 26 is a cross-sectional view taken along the line A-A of FIG. 25;

27 is a cross-sectional view taken along the line B-B of FIG. 25;

28 is a plan view showing the upper and lower flanges of the abdominal three-template with openings formed on the parent portion and the lower flange;

29 is a cross-sectional view taken along the line A-A of FIG. 28;

30 is a cross-sectional view taken along the line B-B of FIG. 28;

31 is a plan view showing the upper and lower flanges of the three abdominal shape of the abdominal triangular upper flange is integrally formed with an opening in the lower flange;

32 is a cross-sectional view taken along the line A-A of FIG. 31;

33 is a cross-sectional view taken along the line B-B of FIG. 31;

34 is a plan view showing the upper and lower flanges of the abdominal two-mould, wherein the upper and lower flanges are integral.

35 is a cross-sectional view taken along the line A-A of FIG. 34;

36 is a cross-sectional view taken along the line B-B of FIG. 34;

FIG. 37 is a plan view 1 showing the upper and lower flanges of an abdominal two-mould having an opening formed on a parent cement portion and a lower flange;

38 is a cross-sectional view taken along the line A-A of FIG. 37;

39 is a cross-sectional view taken along the line B-B of FIG. 37;

40 is a plan view showing the upper and lower flanges of the abdominal two main molds having an opening formed in the lower flange of the upper portion of the parent cement portion;

41 is a cross-sectional view taken along the line A-A of FIG. 40;

42 is a cross-sectional view taken along the line B-B of FIG. 40;

43 is a plan view showing the upper and lower flanges of the abdominal two-mould having an opening formed on the parent cement portion and the lower flange;

44 is a cross-sectional view taken along the line A-A of FIG. 43;

45 is a cross-sectional view taken along the line B-B in FIG. 43;

Explanation of symbols on the main parts of the drawing

10: general steel I beam 12: upper flange

14: lower flange 16: abdomen

20: reinforcing steel I beam 22: upper flange

24: lower flange 26: abdomen

28: crossbeam 29: opening

30: connecting plate A: shift

B: Bridge G: Steel I beam with increased cross-sectional rigidity

P: Pier

The present invention relates to a steel I beam having an increased cross-sectional rigidity and a bridge construction method using the same. In particular, in a continuous bridge, the constant moment portion is used as an existing steel I beam, and the parent moment portion is enlarged and reinforced in the horizontal direction of the upper and lower flanges. Steel I-beam with increased cross-sectional stiffness, which is interconnected to the parent and the lower flange, after installation of one or more pairs of abdomen on the left and right sides of the existing abdomen It is about a construction method.

In general, in order to structurally improve the performance of the steel I beam, a method of improving the structural rigidity by attaching the PS steel to the side of the steel I beam and then prestressing the PS steel or preflexing the load However, the manufacturing process is complicated, there is a disadvantage that must be accompanied by precision construction.

In addition, the conventional steel I-beam is constructed by adjusting the thickness and width of the flange in order to construct a bridge between low and high long diameters, but in the I-shaped cross section, there is a limit to increase the rigidity of the parent part in the continuous bridge. There is this.

Therefore, increasing the rigidity of the parent section of the continuous bridge is a key issue for achieving low height and long span in continuous bridges.

Therefore, the present invention has been made to solve the problems described above, in the continuous bridge, the constant moment portion is used as the existing steel I beam, the parent moment portion is expanded and reinforced in the horizontal direction, the lower flange, After additionally installing one or more pairs of reinforcement plates on the left and right side of the abdomen, and then installing them on the alternating and piers, by connecting the upper and lower flanges in the lateral direction to increase the cross section rigidity of the parent section, It is an object of the present invention to provide a steel I-beam with an increased cross-section stiffness and a bridge construction method using the same for constructing a low-profile high-long steel I-beam bridge.

Steel I beam with increased cross-sectional rigidity according to the present invention for achieving the above object is composed of the upper, lower flange and the abdomen, the general steel I beam disposed on the left and right; It is disposed between the general steel I beam, and consists of an upper, lower flange and the abdomen, the predetermined width and length from the outer end of the upper flange, lower flange or upper, lower flange than the general steel I beam integrally Expanded reinforcing steel I beam; In order to connect the general steel I beam and the reinforcing steel I beam, high tension bolts or welding are coupled to one side of the upper and lower flanges of the general steel I beam, and high tension bolts or one side of the upper and lower flanges of the reinforced steel I beam. It is characterized by consisting of a connecting plate that is welded.

In addition, the bridge construction method using the steel I beam with the increased cross-sectional rigidity according to the present invention for achieving the above object comprises the steps of manufacturing a steel I beam with increased cross-sectional rigidity; Installing steel I beams having increased cross-sectional rigidity on alternating and piers; The upper and lower flanges of the reinforcing steel I beam for the reinforcement of the parent portion of the steel I beam of the cross-section stiffness provided on the alternating and piers are characterized in that the step of interconnecting through the connecting plate in the transverse direction.

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

1 to 4 are views showing the steel I-beam with increased cross-sectional rigidity for continuous bridges according to the present invention, Figures 5 to 8 show the continuous bridge with steel I-beam with increased cross-sectional rigidity according to the present invention 9 and 10 are views showing a constant moment of a continuous bridge provided with a steel I-beam mold with increased cross-sectional rigidity according to the present invention.

11 and 12 are views showing the parent portion of the continuous bridge in which the steel I beam mold with increased cross-sectional stiffness according to the present invention, and FIGS. 13 to 16 show increased cross-sectional stiffness for simple bridges according to the present invention. FIGS. 17 to 20 are diagrams illustrating simple bridges in which steel I beams having increased cross-sectional stiffness according to the present invention are installed.

21 and 22 are views showing both end portions of the positive moment portion of the simple bridge provided with the steel I-beam mold with increased cross-sectional rigidity according to the present invention, and FIGS. 23 and 24 show increased cross-sectional rigidity according to the present invention. FIG. 25 to FIG. 27 are views illustrating upper and lower flanges of an upper abdomen and an abdominal three mold of a parent cement part.

28 to 30 are views showing upper and lower flanges of an abdominal three columnar shape having openings on the parent cement portion and the lower flange, and FIGS. 31 to 33 are upper flanges of the parent cement portion and the lower flange is integrally formed. FIGS. 34 to 36 are views illustrating upper and lower flanges of an abdominal two-template, which are integral with the lower flange and on lower parent portions, of the upper and lower flanges.

37 to 39 are views showing upper and lower flanges of an abdominal two main mold having an opening formed on a parent cement portion and a lower flange, and FIGS. 40 to 42 are an upper flange of the parent cement portion and an opening of the lower flange. Figures showing the upper and lower flanges of the abdominal two-template formed.

43 to 45 are views illustrating upper and lower flanges of an abdominal two-pillar shape having openings formed on upper and lower flanges of a parent cement part.

As shown in these drawings, the steel I-beam with increased cross-sectional rigidity according to the present invention is composed of upper and lower flanges 12 and 14 and the abdomen 16, and the general steel I-beam 10 disposed on the left and right sides. and; It is disposed between the normal steel I beam 10, and consists of upper, lower flanges 22, 24 and the abdomen 26, compared to the upper steel I beam 10, the upper flange 22, the lower flange (24) or a reinforcing steel I beam 20 in which a predetermined width and length are integrally enlarged from the outer ends of the upper and lower flanges 22 and 24; In order to connect the general steel I beam 10 and the reinforcing steel I beam 20, high tension bolts or welds are coupled to one side of the upper and lower flanges 12 and 14 of the general steel I beam 10 and reinforced. The upper plate of the steel I beam 20, the lower flanges 22, 24 of one side of the high tension bolt or welded coupling plate 30 is composed of.

Here, the reinforcing steel I-beam 20 is a continuous bridge, the lower flange (22, 24) extends both ends of the constant moment portion, the abdomen 26 is at least two or more rows, in simple bridges The upper and lower flanges 22 and 24 portions of the center portion of the cement portion extend from both end portions and the abdomen 26 has two or more rows.

That is, the steel I beam having increased cross-sectional rigidity according to the present invention has a structure in which the general steel I beam 10, the reinforcing steel I beam 20, and the connecting plate 30 are organically combined.

Here, the general steel I beam 10 is an I beam consisting of the upper flange 12, the lower flange 14, and the abdomen 16, which are commonly used in the continuous bridge of the present invention mainly used in the constant moment portion do.

In addition, the reinforced steel I-beam 20 increases the stiffness of the parent portion when installed on the bridge (B) by extending the width of the upper and lower flanges 12, 14 of the general steel I-beam 10 in the transverse direction. At least one general steel I beam 10 is welded in the width direction.
As shown in FIG. 8, when the beam connecting the reinforcing steel I beam to the general steel I beam is installed in the bridge B, another side of the reinforcing steel I beam 20 adjacent to the side of the reinforcing steel I beam 2 is provided. It is a structure connected in the width direction by using the side part and steel plate

The reinforcing steel I beam 20 has a structure in which at least one pair of cross beams 28 are provided on the abdomen 26 between the upper flange 22 and the lower flange 24 to cross the abdomen 26.
Installing the at least one pair of cross beams 28 on the abdomen 26 of the reinforcing steel I beam 20 is to install the reinforcing steel I beam 20 adjacent to the bridge and the adjacent reinforcing steel I beam Between the abdomen (26) of the (20) is to install one or more pairs of crossbeams 28 to interconnect.
Here, the cross beam 28 is installed to prevent buckling due to the compressive force applied to the reinforcing steel I beam (20).

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In addition, the reinforcing steel I-beam 20 is formed of both the upper and lower flanges 22 and 24 integrally, or the opening 29 is formed in each of the upper and lower flanges 22 and 24, or the upper flange ( 22) is formed integrally, it is noted that the lower flange 24 may be variously formed in a structure in which the opening 29 is formed.
In order to form all of them integrally, it means to install the cross section which extended the width for forming the reinforcing steel I beam 20 in both the upper and lower flanges.
This manufactures the reinforcing steel I beam 20 in one-piece or opening as necessary to increase the rigidity of the desired parental portion with a minimum amount of steel against the external force applied to the parental portion in the continuous bridge.

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In addition, it is noted that when the general steel I beam 10 and the reinforcing steel I beam 20 are connected, one side may be formed in a structure having the same continuous smooth surface.
When the continuous smooth surface is connected to the general steel I beam 10 and the reinforcing steel I beam 20, each one side is continuously connected, that is, the connection surface is formed without a step, the other side connection step This is to create a good view by arranging the connection surface without a step so that passers-by can see.
This is to promote the aesthetics of continuity or simple school.

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On the other hand, the connecting plate 30 uses a conventional steel plate.

Hereinafter, the construction of the bridge using the steel I-beam with increased cross-sectional stiffness according to the present invention having the above configuration will be described.

Bridge construction method using the steel I-beam with increased cross-sectional rigidity according to the present invention comprises the steps of manufacturing a steel I-beam (G) with increased cross-sectional rigidity; Installing steel I beams G having increased cross-sectional stiffness on alternating A and pier P; The upper and lower flanges 22 and 24 of the reinforcing steel I beam 20 of the parent portion of the steel I beam G having the increased cross-sectional stiffness provided on the alternating portions A and pier P in the transverse direction. It is made of a step of interconnecting via the connecting plate 30.

That is, the bridge construction method using the steel I beam with increased cross-sectional stiffness according to the present invention, first, after manufacturing the reinforced steel I beam 20, and then the reinforced steel I beam 20 and the general steel I beam ( After placing 10 in parallel, connecting plates 30 on the upper flanges 12 and 22 and the lower flanges 14 and 24 of the general steel I beam 10 and the reinforced steel I beam 20. After positioning, when the connecting plate 30 is joined by high tension bolts or welding, steel I beams G having increased cross-sectional rigidity are manufactured, and steel I beams G having increased cross-sectional rigidity are alternately manufactured. After installation on (A) and pier (P), the connecting plate 30 of the upper and lower flanges 22 and 24 of the reinforcing steel I beam 20 of the parent portion in the transverse direction by a high-tensile bolt or welding When interconnected, bridge B is completed.

Therefore, the steel I-beam with increased cross-sectional stiffness according to the present invention composed of the above-described configuration and construction utilizes the constant moment portion as the existing steel I beam 10 in the continuous bridge, and the parent portion is the steel I beam for reinforcement. The upper and lower flanges 22 and 24 of the 20 are enlarged and reinforced in the lateral direction, and the cross beams 28 are formed on the abdomen 16 and 26 of the existing steel I beam 10 or the reinforced steel I beam 20. After installing one or more pairs of additional reinforcement, and then installed on the alternating (A) and pier (P), the upper and lower flanges 22, 24 of the reinforcement type steel I beam 20 of the parent cement portion laterally interconnected As a result, the cross stiffness of the parent portion is increased to control the parent cement.

In addition, in the present invention, only the parent part of the continuous bridge is reinforced by the reinforcing steel I beam 20, so that maintenance is easy without a large increase in construction cost, and the bridge of the low-profile, long-span steel I beam G (B). There is an effect that can be constructed.

In addition, the fabrication of the steel I beam G having the increased cross-sectional stiffness may be applied to both the conventional rolled steel I beam 10 and the steel sheet I beam, and the steel I beam 10 may have the same cross-section and sides. Applicable to both cross sections.

On the other hand, in the case of a simple bridge, by adopting a method of reinforcing the reinforcing steel I-beam 20 to the parent moment of the continuous bridge as described above, the low-profile, steel I-beam easy to maintain without increasing the construction cost (G) Bridge (B) There is an effect that can be built.

As described above, the steel I-beam and the bridge construction method using the increased cross-sectional rigidity according to the present invention has the following effects.

First, in the present invention, the constant moment portion in the continuous bridge is utilized as the existing steel I beam, the parent moment portion is expanded and reinforced the upper and lower flanges in the lateral direction, and after the reinforcement of one or more pairs of the abdomen to the left and right side After installing on the alternating and pier, the upper and lower flanges are interconnected in the lateral direction to increase the cross-sectional stiffness of the parent cement section to control the parent cement. have.

Second, the present invention has the advantage that it is possible to construct a low-rise, long span steel beam I beam bridge easy to maintain without a large increase in construction cost by reinforcing only the parent portion in the construction of a continuous bridge.

Third, in the construction of a continuous bridge, the present invention not only can apply I beam fabrication to both conventional rolled steel I beams or steel plate fabrication I beams, but also I beams can be applied to both equilateral and side cross sections. There is an advantage.

Fourth, the present invention uses the method of reinforcing the parent moment portion of the continuous bridge as described above in the case of a simple bridge, there is an advantage that it is easy to maintain low-rise, steel I-beam bridge construction without a large increase in construction cost .

Claims (17)

 A general steel I beam 10 including upper and lower flanges 12 and 14 and an abdomen 16 and disposed at left and right sides thereof;      It is disposed between the general steel I beam 10, and consists of upper and lower flanges 22 and 24 and the abdomen 26,       Reinforcement steel I-beams integrally abused with a predetermined width and length from outer ends of the upper flange 22, the lower flange 24, or the upper and lower flanges 22 and 24, compared to the general steel I beam 10. 20;       In order to connect the general steel I beam 10 and the reinforcing steel I beam 20, high-strength bolts or welds are coupled to one side of upper and lower flanges 12 and 14 of the general steel I beam 10. In the steel I beam having an increased cross-sectional rigidity consisting of a high tension bolt or a connecting plate 30 welded to one side of the upper and lower flanges 22 and 24 of the steel I beam 20,     The reinforcing steel I beam 20 is a continuous bridge, the upper and lower flanges 22, 24 of the parent portion portion is extended at both ends of the positive moment portion, the abdomen 26 is at least two rows, In the simple bridge, the upper and lower flanges (22, 24) portion of the center portion of the moment is extended than both side end portion portion, the steel I-beam with increased cross-sectional stiffness, characterized in that the abdomen 26 is two or more rows. delete The method of claim 1, The general steel I beam 10 and the reinforcing steel I beam 20 are steel I beams having increased cross-sectional stiffness, characterized in that at least one side is configured to have a continuous smooth surface. The method of claim 1, The reinforcing steel I beam 20 is steel I beam with increased cross-sectional rigidity, characterized in that at least one welded to the general steel I beam 10 in the width direction. The method according to any one of claims 1, 3, and 4, The reinforcing steel I beam 20 is characterized in that at least one pair of cross beams 28 are installed across the abdomen 26 in the abdomen 26 between the upper flange 22 and the lower flange 24. Steel I beam with increased cross-sectional rigidity. The method according to any one of claims 1, 3, and 4, The reinforcing steel I beam 20 is a steel I beam with increased cross-sectional rigidity, characterized in that all of the upper, lower flanges (22, 24) are integrally formed. The method according to any one of claims 1, 3, and 4, The steel I beam for reinforcing steel I beam having an increased cross-sectional rigidity, characterized in that the opening 29 is formed in each of the upper and lower flanges (22, 24). The method according to any one of claims 1, 3, and 4, The reinforcing steel I beam 20 has an upper flange 22 integrally formed, and the lower flange 24 has an opening 29 formed therein. Manufacturing a steel I beam (G) having increased cross-sectional rigidity;      Installing steel I beams (G) having increased cross-sectional stiffness on alternating and piers (P);      The upper and lower flanges 22 and 24 of the reinforcing steel I beam 20 of the reinforcement of the parent portion of the steel I beam G having the increased cross-sectional stiffness installed on the alternating and piers P are connected in the transverse direction ( In the bridge construction method consisting of the steps of interconnecting via 30),    Steel I beam (G) having increased cross-sectional rigidity is composed of upper and lower flanges (12, 14) and the abdomen (16), the general steel I beam (10) disposed on the left and right sides;      It is disposed between the general steel I beam 10, and consists of upper and lower flanges 22, 24 and the abdomen 26, the upper flange 22, lower than the general steel I beam 10 Reinforcing steel I beam 20 formed integrally with a predetermined width and length from the outer ends of the flange 24 or the upper and lower flanges 22 and 24; In order to connect the general steel I beam 10 and the reinforcing steel I beam 20, high-strength bolts or welds are coupled to one side of upper and lower flanges 12.14 of the general steel I beam 10 and reinforced steel I Bridge construction method using steel I-beam with increased cross-sectional stiffness, characterized in that it consists of a high tension bolt or connecting plate 30 welded to one side of the upper and lower flanges 22, 24 of the beam 20 delete The method of claim 9, The reinforcing steel I-beam 20 is a continuous bridge, the lower flanges 22, 24 on both sides of the constant moment portion of the lower flange (22, 24) is extended, the abdomen 26 is at least two rows, In the simple bridge, the bridge construction using the steel I-beam with increased cross-sectional rigidity, wherein the upper and lower flanges 22 and 24 portions of the center portion of the constant moment portion extend more than both side end portions and the abdomen 26 has two rows or more. Way. The method of claim 9, The general steel I beam (10) and the reinforcing steel I beam (20) is a bridge construction method using the steel I beam with increased cross-sectional rigidity, characterized in that at least one side is configured to have the same smooth surface. The method of claim 9, The reinforcing steel I beam 20 is a bridge construction method using the steel I beam with increased cross-sectional rigidity, characterized in that at least one welded to the general steel I beam (10) in the width direction. The method according to any one of claims 12 and 13, The reinforcing steel I beam 20 is characterized in that at least one pair of cross beams 28 are installed across the abdomen 26 in the abdomen 26 between the upper flange 22 and the lower flange 24. Bridge construction method using steel I beam with increased cross-sectional rigidity. The method according to any one of claims 12 and 13, The reinforcing steel I beam 20 is a bridge construction method using the steel I beam with increased cross-sectional rigidity, characterized in that all of the upper, lower flanges (22, 24) are integrally formed. The method according to any one of claims 12 and 13, The reinforcing steel I beam (20) is a bridge construction method using the steel I beam with increased cross-sectional rigidity, characterized in that the opening 29 is formed in each of the upper, lower flanges (22, 24). The method according to any one of claims 12 and 13, The reinforcing steel I beam 20 has an upper flange 22 integrally formed, and the lower flange 24 has an opening 29 formed therein. .

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