KR102320562B1 - Temporary bridge with inserted bent upper parts and construction method thterefor - Google Patents

Abstract

The present invention relates to a temporary bridge with a temporary vent inserted and accommodated therein and a construction method thereof, which can secure the bending negative moment support performance of a bridge point at which a girder is connected to the upper surface of a temporary vent, and optimize the girder depth to sufficiently secure structural performance. The temporary bridge with a temporary vent inserted and accommodated therein comprises: a steel girder having an insertion accommodation part formed on a lower portion thereof in a concave groove shape; and a temporary vent having a cuboid shape, formed by using a vertical member and a horizontal member, and having a temporary vent head and a temporary vent lateral part formed on an upper portion thereof to perpendicularly cross each other in a T-shaped cross section to insert the temporary vent head and the temporary vent lateral part of a T-shaped cross section into the insertion accommodation part to be strongly coupled to the steel girder. The steel girder and the temporary vent lateral part function as a horizontal grid structure (B).

Description

TEMPORARY BRIDGE WITH INSERTED BENT UPPER PARTS AND CONSTRUCTION METHOD THTEREFOR}

The present invention relates to a temporary bridge into which a temporary vent is inserted and a construction method thereof. More specifically, it is possible to secure the bending moment support performance of the continuous point of the bridge where the girder is connected to the upper surface of the temporary vent, while the shape height can be optimized to ensure sufficient structural performance. It is about the construction method.

1A is a construction diagram of a temporary bridge using a conventional temporary vent.

That is, the temporary vent 30 is formed by connecting the steel beams in multiple layers to form a rectangular parallelepiped at a constant height, and corresponds to a bridge substructure that serves as a pier and an abutment of the temporary bridge.

Accordingly, both ends of the steel girder 10 are supported between the upper surfaces of the temporary vent 30, and the steel girder 10 is manufactured as an I-shaped cross-section formed of an upper flange, an abdomen, and a lower flange. it can be seen that there is

Accordingly, the steel girder 10 of the I-shaped cross-section is manufactured to have bending rigidity to resist this, since a constant bending moment with respect to the neutral axis is formed the largest in the central portion.

Accordingly, the reinforcing beam 20 is attached to the steel girder 10 by using the brackets 24 and 25 at both ends on the bottom surface of the steel girder 10 to secure sufficient flexural rigidity while maintaining the shape as it is. It can be seen that they are doing

Accordingly, it can be seen that the cross-sectional height is increased by the cross-sectional height of the reinforcing beam 20 while allowing the installation position of the steel girder 10 to be maintained as it is, so that bending rigidity can be additionally secured.

However, this method does not increase the flexural rigidity at the point where both ends of the steel girder 10 are located, but it is known that there is a limit in that the surface of the passage is reduced as the reinforcing beam 20 is installed. can

Figure 1b shows a construction diagram of a temporary bridge located in a conventional continuous point portion.

The continuous branch part of the temporary bridge is installed so that the approximate central part of the steel girder 10 is supported on the upper surface of the temporary vent 30, and since a bending negative moment is relatively large in this continuous branch part, the steel girder 10 of the continuous branch part It can be seen that the cross-sectional height h1 of ) is formed to be larger than the cross-sectional height of the steel girder 10 on both sides of the continuous point portion.

However, since the steel girder 10 having a large cross-sectional height is mounted on the upper surface of the temporary vent 30 as it is, it can be seen that there is a problem in that the mold height increases as much as the formed cross-sectional height h1.

It can be seen that, in the end, the temporary vent 30 is used as it is, but there is a limit in efficiently increasing the structural performance because it is approached by adjusting only the cross-sectional height of the steel girder 10 .

0001) Republic of Korea Patent No. 10-0891924 (Title of the invention: side section type type fulcrum beam for temporary bridge, publication date: April 08, 2009) 0002) Republic of Korea Registered Utility Model No. 20-0360711 (Title of the invention: Structure of a temporary bridge according to the construction method combining H and T-beams that increase the section modulus and secondary moment of section of the temporary bridge housing, publication date: September 01, 2004)

Accordingly, the present invention provides a new combination of a temporary vent and a steel girder so as not to affect the shape height according to the increase in the cross-sectional height (h1) of the steel girder in the continuous point of the temporary bridge, so that the structurally better performance is excellent while It is a technical task to solve the provision of a temporary bridge in which a temporary vent is inserted and accommodated in an economical temporary bridge construction and its construction method.

In the temporary bridge into which the temporary vent of the present invention is inserted and accommodated for achieving the above object, the temporary bridge 100 is constructed as an intermediate temporary vent 120 of the continuous point part A between the temporary vents 120 on both sides. In a temporary bridge in which a temporary vent in which a negative moment occurs greater than the positive bending moment between the continuous point part (A) is inserted and accommodated, the cross-sectional height (h2) between the side temporary vent 120 and the intermediate temporary vent 120 The steel girder 110 is formed in the longitudinal direction, and the insertion receiving portion 130 is formed in the form of a concave groove at the bottom; and a rectangular parallelepiped shape, formed using a vertical member and a horizontal member, and the upper part is formed so that the temporary bent head and the temporary bent lateral part cross each other at right angles to each other in a T-shaped cross section, and the temporary bent head of the T-shaped cross section is formed in the insertion receiving part and a temporary vent to be inserted and a temporary vent transverse part is inserted to be rigidly connected to the steel girder; including, the steel girder and the temporary vent transverse part function as a horizontal grid structure (B), and the steel of the continuous point part (A) The cross-sectional height (h1) of the girder 110 is formed to be larger than the cross-sectional height (h2) of the steel girder 110 on both sides of the continuous point portion (A), and the insertion receiving portion 130 of the continuous point portion (A). ), so that the height of the temporary bridge can be lowered by the insertion depth h3 of the temporary vent 120 inserted and accommodated.

In addition, the temporary bridge construction method in which the temporary vent of the present invention is inserted and accommodated for achieving the above object is the construction of the temporary bridge 100 with the intermediate temporary vent 120 of the continuous point part (A) between the temporary vents 120 on both sides. In the construction method of a temporary bridge in which a temporary vent is inserted and accommodated, in which the bending negative moment is greater than the bending positive moment between the continuous points (A) In the upper part, installing a plurality of temporary vents formed so that the temporary vent head and the temporary vent lateral part cross each other orthogonally in a T-shaped cross-section in a longitudinal direction spaced apart from each other; b) a steel girder 110 formed in the longitudinal direction with a cross-sectional height h2 between the side temporary vents 120 and the intermediate temporary vent 120, and having the insertion receiving part 130 formed in the form of a concave groove at the bottom providing; and (c) inserting the temporary bent head of the T-section into the insertion receiving part of the steel girder at the continuation point part (A) and making the temporary bent head and the temporary bent transverse part to be rigidly connected; including, the steel girder and the temporary bent transverse The direction part functions as a horizontal grid structure (B), and the cross-sectional height (h1) of the steel girder 110 of the continuous point part (A) of the step (b) is the steel girder 110 on both sides of the continuous point part (A). ) to be formed larger than the cross-sectional height (h2), and the height of the temporary bridge can be lowered by the insertion depth (h3) of the temporary vent 120 inserted and accommodated in the insertion receiving part 130 of the continuous point part (A). will make it

According to the present invention, it is possible to solve the problem of deterioration in constructability and economic feasibility of the temporary bridge due to the increase in the height by excluding the factor of increase in the height at the continuous point of the temporary bridge.

In addition, according to the present invention, since the head of the temporary vent is constructed in a state coupled to the steel girder, it is possible to construct a temporary bridge without installing a bridge support, etc. on the temporary vent.

In addition, according to the present invention, it is possible to resist the bending negative moment of the continuous point part by using the head of the temporary vent at the continuous point part of the temporary bridge, so that the temporary bridge with the temporary vent head which is advantageous for shape height adjustment is inserted and accommodated, and its construction method provision becomes possible.

1a is a construction diagram of a temporary bridge using a conventional temporary vent;
Figure 1b is a construction diagram of a temporary bridge located in a conventional continuous point part;
2a and 2b are a configuration and construction perspective view of a temporary bridge in which the temporary vent head of the present invention is inserted and accommodated;
3A and 3B are flowcharts of a construction method for a temporary bridge in which a temporary vent head of the present invention is inserted and accommodated.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art can easily implement them. However, the present invention may be embodied in many different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Throughout the specification, when a part "includes" a certain element, it means that other elements may be further included, rather than excluding other elements, unless otherwise stated.

[ Temporary bridge 100 in which the temporary vent 120 of the present invention is inserted and accommodated ]

2a and 2b show the configuration and construction perspective view of the temporary bridge 100 into which the temporary vent 120 of the present invention is inserted and accommodated.

As for the temporary bridge (100, temporary bridge) in which the temporary vent is inserted and accommodated, the temporary vent 120 is first constructed at a position where the temporary bridge is to be constructed, and the steel girder 110 is connected to the upper surface of the temporary vent 120. The temporary vent head 123 and the temporary vent transverse part 124 of the temporary vent 120 are inserted and accommodated in the lower part of the steel girder 110, that is, the insertion receiving part 130, so that the steel girder 110 and the temporary vent are inserted. (120) will be tightened to each other.

Accordingly, the mold height can be lowered by the insertion depth h3 of the temporary vent 120 inserted and accommodated in the lower portion of the steel girder 110, and as the temporary vent 120 is strengthened with the steel girder 110, the continuation point of the temporary bridge It is possible to construct a temporary bridge safely by ensuring sufficient rigidity performance against the bending moment occurring in the part (A).

Accordingly, the temporary bridge 100 is constructed with a temporary vent 120 as a bridge lower structure, and a steel girder 110 is used as the bridge upper structure, and the temporary vent 120 is manufactured and constructed as a steel structure, and is constructed of steel. The girder 110 is made of a steel beam of I-shaped section, but the cross-sectional height h1 at the continuous point part (A) of the temporary bridge 100 is higher than the cross-sectional height h2 at other than the continuous point part (A). The larger one will be used.

As a result, it can be seen that the temporary bridge 100 into which the temporary vent of the present invention is inserted includes a steel girder 110 , a temporary vent 120 , and an insertion receiving part 130 as shown in FIGS. 2A and 2B .

First, the steel girder 110, as shown in Figs. 2a and 2b, may be used that is formed of a steel beam including an upper flange, an abdomen and a lower flange.

In particular, in the continuous point portion (A) of the temporary bridge 100, the bending moment is greater than the positive bending moment between the continuous point portions (A). It can be seen that the cross-sectional height (h1) is formed to be larger than the cross-sectional height (h2) of both sides of the continuous point portion (A).

Accordingly, it can be seen that in the continuous point portion (A), the upper flange is maintained as it is, and the cross-sectional height of the abdomen 112 is gradually extended downward, and the lower flange is formed at the lower end of the abdomen.

As a result, it is possible to additionally secure the bending rigidity of the steel girder 110 as the cross-sectional height of the abdomen 112 extends downward and becomes larger, so that it is possible to effectively resist the bending moment of the continuous point portion (A). .

At this time, it can be seen that the lower flange 113 and the abdomen 112 are formed with an insertion receiving part 130 to be described later in the form of a concave groove dug upward with a certain depth based on the lower flange 113 .

This steel girder 110 is formed with a cross-sectional height (h2) in sections other than the continuous point portion (A) (both sides of the continuous point portion (A)), the amount of the steel girder 110 of the continuous point portion (A) It is formed by connecting with the end.

That is, when the temporary bridge 100 is constructed as an intermediate temporary vent 120 corresponding to the pier of the continuous point part A between the side temporary vents 120 corresponding to both abutments,

Both side steel girder 110 formed with a cross-sectional height h2 between the side temporary vent 120 and the intermediate temporary vent 120 is installed, and the central part is located in the intermediate temporary vent 120. Both ends of the girder 110 are connected to each other with the steel girder 110 on both sides.

Next, as shown in FIGS. 2A and 2B , the temporary vent 120 is manufactured such that a steel frame member extends upward from the ground G at a certain height as a lower structure of the temporary bridge 100 .

Accordingly, according to FIGS. 2A and 2B, the vertical member 121 and the horizontal member 122 are assembled in a rectangular parallelepiped shape using a steel beam, and the upper surface is the upper end of the vertical member 121 and protrudes into the temporary vent head 123. It can be seen that it has been formed.

The temporary vent head 123 protruding upward is combined with the temporary vent lateral part 124 horizontally in the lateral direction to form a T-shaped cross-section.

Accordingly, the present invention accepts the insertion of the steel girder 110 of the temporary vent head 123 and the temporary vent lateral direction part 124 and the coupling site of the continuous point part (A) coupled to each other in a T-shaped cross section, as shown in FIG. 2b. After being inserted and accommodated in the part 130, they are integrated with each other.

As such, if the temporary vent head 123 is connected to the steel girder 110 in the vertical direction, it is hypothesized that the insertion receiving part 130 of the steel girder 110 is connected in the transverse direction orthogonal to the steel girder 110 . It may be referred to as the vent transverse direction portion 124 .

As such, the temporary vent head 123 extending to the vertical member 121 is combined with the temporary vent lateral part 124 to form a T-shaped cross-section member, and the temporary vent head 123 and the temporary vent lateral part 124 are formed. ) as the steel girder 110 having the insertion receiving part 130 accommodated extends in the longitudinal direction, the steel girder 110 and the temporary vent transverse section 124 function as a horizontal grid structure (B) to serve as a steel girder (110) While resisting the load transmitted by the duplex plate 140 installed on the upper door, it is finally transferred to the lower part of the temporary vent 120.

Accordingly, according to FIGS. 2a and 2b, it can be seen that the four temporary vent heads 123 and the two temporary vent lateral parts 124 can vertically support the two steel girder 110 at the bottom, It can be seen that the temporary vent 120 may also be formed in response thereto according to the number of installations in the transverse direction of the steel girder 110 .

Accordingly, the vertical member 121 and the horizontal member 122 are used as the temporary vent 120 in the lower part of the temporary vent head 123 and the temporary vent lateral direction part 124 to function as a lower structure of the temporary bridge in the form of a rectangular parallelepiped. do.

Next, the insertion receiving portion 130 is, as shown in FIGS. 2a and 2b, the temporary vent head 123 of the temporary vent 120 and the integrated temporary vent transverse section 124 of the steel girder 110 to pass through. It is a concave groove formed in the lower part.

The insertion receiving portion 130 is formed as a concave groove extending vertically to accommodate the temporary vent lateral portion 124, and the temporary vent head 123 is formed in the concave groove in the temporary vent lateral direction portion 124. By extending downward from the, it is possible to be formed.

The temporary vent head 123 and the temporary vent transverse part 124 inserted into and penetrating the insertion receiving part 130 act integrally with respect to the bending moment generated by tightening each other by a bolt fastening method, such as a steel girder ( While it is possible to secure the bending rigidity of 110), in addition, the height of the cross-sectional height (h3) of the temporary vent head 123 and the temporary vent transverse direction part 124 that is inserted and accommodated in the insertion receiving part 130 is increased. It has a function that prevents it from shrinking.

[The construction method of the temporary bridge 100 into which the temporary vent 120 of the present invention is inserted]

3a and 3b show a flow chart of the construction method of the temporary bridge 100 into which the temporary vent 120 of the present invention is inserted.

In the construction method of the temporary bridge 100 in which the temporary vent head is inserted and accommodated, the temporary vent 120 is first constructed, and the intersection of the temporary vent head 123 and the temporary vent lateral part 124 of the temporary vent 120 is To be accommodated in the lower flange of the steel girder 110 and the insertion receiving part 130 formed in the lower abdomen of the steel girder 110, the temporary vent 120 is formed in a grid shape with each other, and the steel girder 110 ) can be said to be installed on the upper surface.

Accordingly, the temporary vent 120 is constructed on the ground (G) as shown in FIG. 3A.

Although it is divided into both side temporary vent 120 and intermediate temporary vent 120, the intermediate temporary vent 120 is a continuous point part (A), as a whole in the form of a rectangular parallelepiped, a vertical member 121 and a horizontal member 122. It can be seen that the upper part is formed so that the temporary vent head 123 and the temporary vent lateral part 124 cross each other in a T-shaped cross section orthogonal to each other.

At least one intermediate temporary vent 120 between both side temporary vents 120 may be installed, and both side temporary vents 120 do not correspond to the continuous point portion A, so the vertical member 121 and A normal temporary vent using the horizontal member 122 may be used.

Next, as shown in Figure 3b, the steel girder 110 is rigidly fixed to the intermediate temporary vent 120 corresponding to the continuous point portion (A).

That is, after the intersecting portion of the temporary vent head 123 and the temporary vent lateral portion 124 is inserted and accommodated in the lower flange of the steel girder 110 and the insertion receiving portion 130 formed in the abdomen, the fastening bolt and Finally, they are integrated with each other by means of a nut or the like.

In both sides of the steel girder 110 installed in the intermediate temporary vent 120 , the ends of the steel girder 110 , one end of which is supported by both side temporary vents 120 , are connected to each other, and thus the steel girder 110 ) can maintain the cross-sectional height (h1) of the steel girder 110 at the continuous point part (A) as it is, and the cross-sectional height (h2) of the steel girder 110 on both sides of the continuous point part (A) It can be seen that formed

In addition, in the continuous point portion (A), the upper part of the temporary vent 120 is cut from the bottom surface of the steel girder 110, adding flexural rigidity to the bending negative men without affecting the shape height by the cross-sectional height (h3) can be obtained with

Accordingly, two steel girder 110 is shown in the transverse direction, but when a plurality of temporary vent transverse portions 124 of the temporary vent 120 are connected and installed to extend further in the transverse direction, a plurality of steel girder 110 is installed. It can be installed, and the final multi-layered plate 140 is installed on the upper surface of the steel girder 110 to complete the temporary bridge.

In addition, the present invention can be applied to a permanent bridge as well as a temporary bridge.

The above description of the present invention is for illustration, and those of ordinary skill in the art to which the present invention pertains can understand that it can be easily modified into other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive. For example, each component described as a single type may be implemented in a dispersed form, and likewise components described as distributed may be implemented in a combined form.

The scope of the present invention is indicated by the following claims rather than the above detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention. do.

100: Temporary bridge in which temporary vents are inserted
110: steel girder 112: abdomen
113: lower flange 120: temporary vent
121: vertical member 122: horizontal member
123: temporary vent head 124: temporary vent lateral direction
130: insertion receiving unit 140: ventral plate
A: continuation point
B: Horizontal grid structure

Claims (7)

The temporary bridge 100 is constructed with the intermediate temporary vent 120 of the continuous point part (A) between the side temporary vents 120, so that the bending negative moment is greater than the bending positive moment between the continuous point parts (A) In the temporary bridge in which the generated temporary vent is inserted and accommodated,
A steel girder 110 formed in the longitudinal direction with a cross-sectional height h2 between the side temporary vents 120 and the intermediate temporary vent 120, and having an insertion receiving portion 130 formed in the form of a concave groove at the bottom thereof; and
As a rectangular parallelepiped shape, it is formed using a vertical member 121 and a horizontal member 122, and the upper part is formed such that the temporary bent head 123 and the temporary bent lateral part 124 cross each other at right angles to each other in a T-shaped cross section. , The temporary vent head 123 and the temporary vent lateral part 124 of the T-section in the insertion receiving part 130 are inserted into the temporary vent 120 to be rigidly connected to the steel girder 110; Including; The steel girder 110 and the temporary vent transverse section 124 function as a horizontal grid structure (B), and the cross-sectional height h1 of the steel girder 110 of the continuous point part (A) is a continuous point part ( A) to be formed larger than the cross-sectional height (h2) of the steel girder 110 on both sides, and the insertion depth (h3) of the temporary vent 120 inserted and accommodated in the insertion receiving portion 130 of the continuous point portion (A) ), a temporary bridge in which a temporary vent is inserted to lower the height of the temporary bridge. The method of claim 1,
The steel girder 110 is
At the continuous point portion (A), the cross-sectional height of the abdomen 112 from the upper flange gradually extends downward, and a lower flange is formed at the lower end of the abdomen, from the lower flange 113 to the lower flange to the abdomen 112. A temporary bridge in which a temporary vent is inserted and accommodated so that the insertion receiving part 130 is formed in the form of a concave groove dug upward with reference to (113). delete The method of claim 1,
A plurality of temporary vent transverse portions 124 of the temporary vent 120 are connected to be installed to extend further in the transverse direction, and a plurality of steel girder 110 is installed in the transverse direction to install the multilayer plate 140 in the steel girder 110. A temporary bridge with a temporary vent installed on the upper surface to construct a temporary bridge. delete The temporary bridge 100 is constructed with the intermediate temporary vent 120 of the continuous point part (A) between the side temporary vents 120, so that the bending negative moment is greater than the bending positive moment between the continuous point parts (A) In the temporary bridge construction method in which the generated temporary vent is inserted and accommodated,
(a) as a rectangular parallelepiped shape, formed using a vertical member 121 and a horizontal member 122, the upper part of the temporary vent head 123 and the temporary vent lateral portion 124 cross each other at right angles to each other in a T-section Installing a plurality of temporary vents 120 formed to be spaced apart in the longitudinal direction;
(b) a steel girder 110 formed in the longitudinal direction with a cross-sectional height h2 between the side temporary vent 120 and the intermediate temporary vent 120, and having the insertion receiving part 130 formed in the form of a concave groove at the bottom (110) providing a; and
(c) inserting the temporary vent head 123 and the temporary vent lateral part 124 of the T-shaped cross-section into the insertion receiving part 130 of the steel girder 110 at the continuous point part (A) so as to be stiffened ; Including, the steel girder 110 and the temporary bent transverse section 124 are to function as a horizontal grid structure (B), and the steel girder 110 of the continuous point section (A) of the step (b). The cross-sectional height (h1) is formed to be larger than the cross-sectional height (h2) of the steel girder 110 on both sides of the continuous point portion (A), and is inserted and accommodated in the insertion receiving portion 130 of the continuous point portion (A). A temporary bridge construction method in which a temporary vent is inserted and accommodated so that the height of the temporary bridge can be lowered by the insertion depth (h3) of the temporary vent 120. delete

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