KR20220048276A - Girdir and railway bridge using the same - Google Patents

Abstract

Provided is a girder (100). The girder of the present invention comprises: a body unit (110) having a trapezoidal cross-section formed so that a width of a lower part is gradually increased compared to a width of an upper part; and an upper flange (120) formed on an upper end of the body unit (110). According to the present invention, compared to an I-type girder (10) of the same height, a height of a neutral axis is formed at a lower position. Therefore, an efficient and economical structure is obtained to match specificity of a railway bridge in which a train runs on a certain route, unlike a vehicle.

Description

GIRDIR AND RAILWAY BRIDGE USING THE SAME

The present invention relates to the field of construction, and more particularly, to a girder and a railway bridge.

1 is a cross-sectional view of a conventional railway bridge.

As shown, a plurality of I-shaped girder 10 is installed on the pier (not shown), the upper plate 20 is installed thereon, and the ballast 30 and rail 40 are installed thereon. .

However, the conventional railway bridge as above has the following problems.

First, in the case of a general road bridge on which a vehicle operates, a number of I-type girders are arranged for safety on the premise that a uniformly distributed load is applied on the deck, since the vehicle does not travel on a fixed path on the deck, which is the case of a railway bridge. It is not an efficient structure.

Second, basically, since the I-type girder is formed at a position where the height of the neutral axis is high, there is a risk of overturning during construction, so the workability is not good.

Third, since it is difficult to arrange the tension member on the abdomen of the I-type girder, it is common to arrange the tension member on the lower flange, which is not an efficient structure.

The present invention has been derived to solve the above problems, and the purpose of the present invention is to present a girder of an efficient and economical structure and a railroad bridge using the same, so as to match the specificity of a railway bridge in which a train runs on a predetermined route unlike a vehicle. do.

In order to solve the above problems, the present invention provides a body portion 110 having a trapezoidal cross section formed so that the width of the lower portion is gradually increased compared to the width of the upper portion; The upper flange 120 formed on the upper end of the body 110; and including, compared to the I-shaped girder 10 of the same height, the girder 100, characterized in that formed at a position where the height of the neutral axis is low do.

A plurality of tension members 130 for post-tension are disposed inside the body part 110 in a longitudinal direction, and the plurality of tension members 130 are arranged in a row in the vertical direction, and the plurality of tension members 130 are arranged in a vertical direction. ) of the upper tension member 131 is preferably arranged in a curved shape such that both ends are positioned on the upper portion of the body part 110 , and the central part is positioned on the lower part of the body part 110 .

It is preferable that the side surface of the central part of the body part 110 be concavely curved inwardly.

The lower side of the body 110 preferably has a flat structure along the vertical direction.

A lower tension member 133 is disposed on the lower portion of the body 110, and an adjustable tension member capable of adjusting the tension on both sides of the upper end of the body 110 so as to control the swell due to the tension of the lower tension member 133. It is preferable that 140 is disposed.

Both ends of the adjustable tension member 140 are formed at both ends of the body 110 so that the self-weight of the upper structure of the girder 100 and the compression force by the adjustable tension member 140 are not greater than the tensile force by the lower tension member 133 . It is preferable to be fixed at positions spaced inward from both ends.

The present invention is a railway bridge using the girders 100, a plurality of girders 100 installed in a row along the width direction; A railroad bridge comprising; a ballast 30 and a rail 40 installed on the plurality of girders 100 is provided.

It is preferable that the pair of rails 40 on which one train runs is installed on the upper portion of the pair of girders 100 installed adjacently.

It is preferable that the center C1 of the pair of rails 40 is installed between the centers C2 and C3 of each of the pair of girders 100 .

The present invention provides a construction method of the railway bridge, comprising the steps of manufacturing and lifting the girder 100 and mounting it on the pier; Tensioning and fixing the lower tension member 133 and the adjustment tension member 140 of the girder 100; Installing the upper structure on the upper part of the girder (100); The method of constructing a railway bridge comprising: additionally tensioning the adjustment tension member 140 or releasing some tension to minimize the bulge or sag of the girder 100 is provided.

The present invention provides a girder of an efficient and economical structure and a railroad bridge using the same to match the specificity of a railroad bridge in which a train runs in a certain route, unlike a vehicle.

1 is a cross-sectional view of a conventional railway bridge. 2 shows an embodiment of the present invention, Fig. 2 is a longitudinal sectional view of a first embodiment of a girder; 3 is a perspective view of a first embodiment of a girder; 4 is a cross-sectional view of a first embodiment of a girder; 5 is a cross-sectional view of a railway bridge. 6 is a perspective view of a railway bridge. Fig. 7 is a longitudinal sectional view of a second embodiment of a girder; Fig. 8 is a longitudinal sectional view of a third embodiment of a girder; 9 is a cross-sectional view of a second embodiment of a girder;

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

As shown in Figure 2 or less, the girder 100 according to the present invention is basically a body portion 110 of a trapezoidal cross section formed so that the width of the lower portion is gradually increased compared to the width of the upper portion; and an upper flange 120 formed on the upper end of the body 110 .

For this reason, compared to the I-type girder 10 of the same height, the height of the neutral axis is formed at a lower position.

That is, in the conventional I-type girder, the web and the lower flange are transformed into the body part 110 of a trapezoidal cross section, so that the height of the neutral axis is formed at a low position.

A railway bridge using such a girder 100 includes a plurality of girders 100 installed and opened along the width direction; A plurality of girders 100 are installed on the top 30 and the rail 40; is configured to include (Figs. 5 and 6).

This has the following effects.

First, it is possible to achieve an efficient structure suitable for the specificity of the railway bridge.

Unlike vehicles, trains run only along a certain path along rails, so there is no need to form a structure on the premise that a railroad bridge is subjected to a uniformly distributed load like a general road bridge on which vehicles operate.

In a railway bridge, since the load of the train is intensively distributed only on the lower part of the rail and ballast, when the girder 100 of the same structure as the present invention is installed at that location, the number of girders compared to the case of using the conventional I-type girder It is possible to form an efficient and stable support structure while reducing the amount (FIG. 5).

Second, since the girder 100 according to the present invention is formed at a position where the height of the neutral axis is lower than that of the I-type girder 10 of the same height, the risk of overturning during construction is low and the workability is excellent.

Third, since the girder 100 according to the present invention has a large cross-section of the body (abdomen), sufficient space for arranging the tension member is ensured, so that the efficient curved arrangement of the tension member is possible.

Fourth, since the girder 100 according to the present invention has a larger overall cross-section than the I-type girder, vibratory usability against dynamic loads can be sufficiently secured.

Fifth, the girder 100 according to the present invention generates a small stress at the lower part of the girder when a working load is applied, and has a larger cross-section than the I-type girder. And it can be effectively applied even when it is necessary to secure a mold space.

Sixth, when the tension force for girder production is introduced, tensile stress is generated in the upper part of the girder. can be prevented

Hereinafter, examples related to the specific structure of the present invention will be described.

A plurality of tension members 130 for post-tensioning may be disposed inside the body portion 110 of the girder 100 along the longitudinal direction, and the plurality of tension members 130 may be arranged in a row in the vertical direction. there is.

Since the body 110 of the girder 100 according to the present invention has a trapezoidal cross-sectional structure formed so that the width of the lower part is gradually increased compared to the width of the upper part, a plurality of tension members 130 can be disposed, and the upper part Compared to the lower portion, a larger number of tension members 130 may be disposed (FIG. 2).

Among the plurality of tension members 130 , the upper tension member 131 is preferably arranged in a curved shape such that both ends are positioned on the upper portion of the body part 110 , and the central part is positioned on the lower part of the body part 110 for structural efficiency. (Fig. 4).

That is, since the body portion 110 of the girder 100 according to the present invention has a cross section of a sufficient size in the lower portion, the upper tension member 131, the central tension member 132, and the lower tension member 133 among the plurality of tension members 130. ) can be arranged so that all of the central portions are located at the lower portion of the body part 110 , which has the effect that curved arrangement of the upper tension member 131 and the central tension member 132 is possible.

The side surface of the central portion of the body 110 may have a flat structure, but in the case of taking a structure concavely curved inward, there is an advantage in that it can reduce its own weight by reducing parts other than the cross-section required for disposing the tension member.

Even with the above structure, it is preferable for the side of the lower portion of the body 110 to have a flat structure along the vertical direction for ease of manufacture, storage, and transport.

Hereinafter, an embodiment of a railway bridge using a girder 100 according to the present invention will be described.

This is basically a plurality of girders installed along the width direction (100); A plurality of girders 100 are installed on the top 30 and the rail 40; is configured to include (Figs. 5 and 6).

In order to efficiently transmit the load transmitted and distributed to the lower part of the pair of rails 40 to the lower structure, it is most preferable that a pair of girder 100 according to the present invention is installed under the pair of rails 40 (Fig. 5).

That is, it is preferable that the pair of rails 40 on which one train 1 operates are installed on the upper portion of the pair of girders 100 installed adjacently.

However, since the railroad bridge requires a space in which not only rails but also auxiliary facilities such as railings and soundproof walls are installed, the center of the pair of rails 40 is precisely positioned at the center of the upper part of the pair of girder 100. it's difficult.

However, since another adjacent pair of girders 100a is installed on one side of the pair of girders 100, the load of the train 1 can also be distributed on such an adjacent pair of girders 100a, If the center (C1) of the rail 40 is located between the centers (C2, C3) of each of the pair of girders 100 installed in the lower part, the stable distribution of the load and the load on the pier 200 transmission is possible.

Hereinafter, an embodiment of the construction method of the railway bridge using the girder 100 according to the present invention will be described.

Raising (camber) occurs in the girder to which tension is applied, and due to the characteristics of railway bridges, the rise must be minimized to manage the alignment of the rail (track).

To this end, in the present embodiment, in the girder 100 , the lower tension member 133 is disposed at the lower portion of the body part 110 , and the body part 110 of the girder 110 controls the bulging by the tension force of the lower tension member 133 . An adjustable tension member 140 capable of adjusting the tension is disposed on both sides of the upper end (the lower portion of the upper flange 120). (FIGS. 7 and 8)

Since this adjustment tension member 140 generates a compressive stress in the upper part of the girder 100, even if the tension force of the lower tension member 133 is increased (even if a large tensile stress is generated in the lower part of the girder 100) of the girder 100 Since it is possible to prevent damage to the upper part, there is an advantage that the height (type height) of the girder 100 can be reduced.

In addition, both ends of the adjusting tension member 140 are provided with the body part 110 so that the self-weight of the upper structure (ballast, rail) of the girder 100 and the compression force by the adjustable tension member 140 are not greater than the tensile force by the lower tension member 133 . ) is preferably fixed at positions spaced inward from both ends. (FIG. 9)

The adjustable tension member 140 may have a structure embedded in the body portion 110 of the girder 100 ( FIG. 7 ) or may have a structure protruding outside the body portion 110 ( FIG. 8 ). )

In the former case, the fixing unit of the adjustable tension member 140 may have a block-out structure, thereby adjusting the tension of the adjustable tension member 140 .

In this case, of course, the above-described upper tension member 131 and the central tension member 132 may be additionally installed as needed.

The construction method of the railway bridge according to this embodiment is made by the following process.

The girder 100 is manufactured and lifted and mounted on the pier, and the lower tension member 133 and the adjustment tension member 140 of the girder 100 are tensioned and fixed.

The above two processes may be changed before and after depending on the manufacturing, transport, mounting and other construction conditions of the girder 100 .

Install the upper structure (ballast, rail) on the upper part of the girder (100).

In this state, the alignment of the rail (track) is managed by additionally tensioning the adjustment tension member 140 or releasing some tension to minimize the rise or deflection of the girder 100.

That is, when the girder 100 rises in a state where the upper structure is installed on the girder 100, it is possible to reduce the rise by additional tensioning the adjustment tension member 140, and conversely, the sagging of the girder 100 occurs. In this case, it is possible to reduce the sagging by releasing some tension of the adjustment tension member 140 .

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

30: image 40 : rail 100 : girder 110: body 120: upper flange 130: tension material 131: upper tension member 140: adjustable tension material

Claims (10)

The body portion 110 of a trapezoidal cross section formed so that the width of the lower portion is gradually increased compared to the width of the upper portion; The upper flange 120 formed at the upper end of the body portion 110; Including, I-type girder of the same height ( 10), the girder 100, characterized in that the height of the neutral axis is formed in a low position. According to claim 1, Inside the body portion 110, a plurality of tension members 130 for post-tension is disposed along the longitudinal direction, The plurality of tension members 130 are arranged in open along the vertical direction, The upper tension member 131 among the plurality of tension members 130 is a girder, characterized in that both ends are positioned on the upper portion of the body part 110 and the central part is arranged in a curved shape such that the central part is positioned on the lower part of the body part 110 . (100). The girder (100) of claim 1, wherein a side surface of the central portion of the body (110) is concavely curved inwardly. The girder (100) of claim 3, wherein the lower side of the body (110) has a flat structure along the vertical direction. According to claim 1, A lower tension member (133) is disposed on the lower portion of the body (110), Tension force on both sides of the upper end of the body (110) so as to control the swell due to the tension of the lower tension member (133) The girder 100, characterized in that the adjustable tension member 140 is disposed. According to claim 5, So that the self-weight of the upper structure of the girder (100) and the compression force by the adjustable tension member (140) are not greater than the tensile force by the lower tension member (133), both ends of the adjustable tension member (140) are A girder (100), characterized in that it is fixed at positions spaced inward from both ends of the body (110). As a railway bridge using the girder 100 of any one of claims 1 to 6, the plurality of girders 100 installed to be opened along the width direction; The ballast 30 installed on the plurality of girders 100, and Rail (40); Railroad bridge comprising a. The railway bridge according to claim 7, wherein the pair of rails (40) on which one train operates are installed on top of the pair of girders (100) installed adjacently. The railway bridge according to claim 8, wherein the center (C1) of the pair of rails (40) is installed between the centers (C2, C3) of each of the pair of girders (100). As a construction method of a railway bridge using the girder 100 of claim 5 or 6, manufacturing and lifting the girder 100 and mounting the girder 100 on the pier; The lower tension member 133 of the girder 100 and the adjustment tension member ( Tensioning and fixing 140); Installing the superstructure on the upper part of the girder 100; By additionally tensioning the adjustment tension member 140, or releasing some tension, the girder 100 rises or Minimizing the deflection; Construction method of a railway bridge comprising the.

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