KR100755946B1 - Composite temporary bridge - Google Patents

Abstract

A composite temporary bridge is provided to perform construction work economically by increasing the stiffness of a main girder installed on a support effectively and optimizing a cross section of a main girder installed on a span. A composite temporary bridge for a temporary bridge for increasing the stiffness of a main girder installed on a support(A) effectively contains an I-shaped main girder(100) for a support formed by composing an upper steel and a lower steel to an upper flange and a lower flange in the longitudinal direction, a cross beam(200) installed between a main girder for a support and a main girder for a span in the horizontal direction, a deck plate(300) for a support supported to the upper side of the cross beam and extended adjacently to the side of the upper steel in the longitudinal direction, and a deck plate(500) for a span installed on a main girder(400) for a span in the horizontal direction to abut on two ends of the deck plate for a support.

Description

Synthetic Temporary Bridge {COMPOSITE TEMPORARY BRIDGE}

1 illustrates a conventional temporary bridge.

2A and 2B show the point mould of the present invention.

Figure 3 shows the installation state diagram of the synthetic temporary bridge of the present invention.

4A and 4B show front and partial side views of the synthetic temporary bridge of the present invention.

<Description of the symbols for the main parts of the drawings>

100: branch casting mold 110: upper flange

120: Abdomen 130: Lower Flange

140: stranded steel (T-shaped steel) 150: fixing plate

160: branch upper part tension material 170: lower stranded steel (T-shaped steel)

200: grouse 210: Bracing material

300: branch cover plate 400: span section mold

500: span section plate 600: span section tension material

The present invention relates to a synthetic hypothesis bridge. More specifically, after installing the mold in the longitudinal direction to the temporary vents, and puts a perforated plate on the mold upper surface relates to a temporary bridge that can temporarily communicate traffic.

The conventional temporary bridge is constructed by a mold and a perforated plate.

That is, as shown in Figure 1, after installing the temporary support structure 10, such as a temporary tent on the ground at a predetermined interval, the mold 20, such as I-type steel in the longitudinal direction on the upper surface of the temporary support structure (10) After the installation, while installing the perforated plate 30 installed on the upper surface of the mold 20 in the transverse direction, by installing a plurality of perforated plates in the longitudinal direction in order to complete the temporary bridge.

At this time, since the perforated plate 30 is simply installed on the upper surface of the mold 20, the mold and the perforated plate are not synthesized and are not designed to resist external loads integrally, but rather the perforated plate only adds its own weight to the mold. It was pointed out that structurally very inefficient mold cross section design had to be achieved.

In addition, the bending moment generated by the external force (traffic load, etc.) in the span section of the temporary bridge is transmitted to the branch part (temporary vent installation part), and eventually researches and experiments on a method for effectively resisting the bending moment of the branch bridge. Although this was necessary, there was a problem that no effective alternative has been proposed in relation to crosslinking.

The present invention is to solve the problems of the prior art,

An object of the present invention is to increase the rigidity of the mold installed in the branch portion more effectively, the hypothesis that such an increase in rigidity can also serve as a perforated plate without complicating the configuration of the mold to enable economic and efficient mold cross-section design It is to provide a bridge construction method.

In order to achieve the above technical problem, the present invention

First, in the mold made of I-type steel extending in the longitudinal direction based on the point portion, the mold is composed of I-shaped cross-section, the upper flange is installed on the upper flange so that the upper strand and the mold is synthesized, The upper stranded steel was also able to play a role of the perforated plate, and also the lower flange of the mold was also installed in the lower stranded steel to be synthesized in the mold to maximize the rigidity of the mold at the point.

Second, unlike the conventional perforated plate, the steel streaked steel installed in the branch part serves as the perforated plate so that the branch part perforated plate extending in both sides based on the branch part is installed in the longitudinal direction, and the branch part in the longitudinal direction is provided. For the installation of the perforated plate, the cross beams can be installed between the point steel and the steel.

Third, in the longitudinal stator steel of the type installed in the point portion is provided with a tension member in the longitudinal direction, so as to more effectively resist the bending moment generated in the point portion, in the case of the span section additional to the lower portion of the mold. The installation allows more effective prestressing to be introduced into the mold.

Hereinafter, the synthetic hypothesis bridge according to the present invention will be described in detail with reference to the embodiment shown in the drawings.

2A and 2B show the point mould of the present invention.

Figure 3 shows the installation state diagram of the point mould, the spot covering plate and the span section slab installed in the upper and lower steel materials installed in the synthetic temporary bridge of the present invention.

4A and 4B show front and partial side views of the synthetic temporary bridge of the present invention.

The synthetic hypothesis bridge of the present invention

In the temporary bridge including a plurality of molds and perforated plate is installed on the temporary support structure including a temporary vent,

Branch cast mold 100 of the I-shaped cross-section is composed of the upper strand is synthesized in the longitudinal direction on the upper flange, the lower strand is further synthesized in the longitudinal direction in addition to the lower flange set to be installed in the site where the perforated plate is to be formed;

A cross beam 200 installed in a transverse direction between the top side of the point mold and the point mold;

A branch part covering plate 300 which is supported on a horizontal beam upper surface and is extended in a longitudinal direction in contact with a side surface of the upper strand steel; And

Includes; span portion plate plate 500 mounted on the span portion mold 400 to be in contact with both end surfaces of the branch portion plate plate in the transverse direction.

Synthetic temporary bridge of the present invention is to be applied to the temporary bridge, the temporary support structure 10, such as a temporary tent is basically installed first, the mold is installed on the upper surface of the temporary support structure, the perforated plate is installed on the mold upper surface . At this time, the site where the temporary vent is installed is structurally formed as a branch (A).

The point portion mold 100 of the present invention is installed in this point portion A, and the center portion of the point portion mold 100 of the present invention is schematically installed based on the point portion A.

2A and 2B, the point portion mold 100 uses a steel mold made of a section steel having an I-shaped cross section.

That is, the upper malleable steel material 140, which is a T-shaped steel, is further installed by welding in the steel formed of the upper flange 110, the abdomen 120, and the lower flange 130.

Since the overall height of the steel is increased by the staging steel 140, the overall rigidity of the steel is significantly increased. This makes it possible to effectively share the bending moment transmitted from the span section.

The upper strand steel 140, which is a T-shaped steel, allows the abdomen 141 to contact the upper flange upper surface, and the upper part 142 to extend horizontally to the abdomen 141, preferably as shown in FIG. 2B It is preferable to minimize the neutral axis upward movement of the steel by the staging steel 140 by making the width D2 of the upper portion of the staging steel material smaller than the flange width D1.

In addition, the stiffener 143 can be vertically installed between the upper 142 and the upper flange 110, the upper stiffener so that the staging steel 140 can be stably synthesized in the steel, and the stiffener is a point portion steel material described later The torsional stiffness of the steel due to the settling of tension increases.

As a result, the upper strand steel 140 and the steel mold is integrated with each other and structurally synthesized, whereby the upper strand steel 140 and the steel mold can be integrally resisted against external force, thereby increasing the overall rigidity of the steel mold.

Furthermore, the upper staging steel 140 of the present invention was to serve as a perforated plate, not merely to increase the rigidity of the steel.

That is, instead of installing the perforated plate additionally on the upper surface of the upper malleable steel 140 as in the related art, as shown in FIG. 3 and FIG. 4B, the malleable steel 140 itself synthesized with the steel can serve as the perforated plate. . As a result, even if the rigidity of the branch casting mold increases, it is not necessary to install an additional perforated plate, and thus it is possible to install a very economical branch perforated plate, and can be easily applied even when there is a space limitation of the mold.

As described above, the upper malleable steel 140 has a role of the perforated plate, and thus, the branch portion of the branched plate 300 is installed in the longitudinal direction in the same manner as the upper malleable steel 140.

That is, while the normal perforated plate 30 is installed on the mold 20 in the transverse direction as shown in FIG. 1, the point portion A in the longitudinal direction as shown in FIG. Extension will be installed.

In addition, the upper strand steel material 140 is further provided with fixing plates 150 on both end surfaces, to arrange the point portion upper tension member 160 between the fixing plate 150, tension the point upper tension member 160, By fixing, the required prestress is introduced into the branch casting mold 100. This makes it possible to more effectively resist the bending parent moment M- generated because the point portion mold 100 is installed in the point portion A. FIG.

However, in installing the upper portion tension member 160, the neutral axis of the steel is in a state that is moved considerably upwards because the upper strand steel 140 is located in the upper portion of the steel. That is, since the eccentric distance between the point injury portion tension material 160 and the neutral shaft of the steel is not large, the eccentric effect is small and may be somewhat inefficient in securing the cross-sectional force of the steel.

Therefore, in the present invention, by further installing the T-type lower stranded steel 170 in the lower flange 130 of the steel composite, by moving the neutral axis of the steel downward, by maximizing the eccentric effect by the point portion upper tension member 160 In the point mold 100, more economical and efficient cross-sectional design was made possible.

In this case, the lower lead steel material 170 also allows the abdomen 171 to contact the lower flange bottom surface, and the lower 172 extends horizontally to the abdomen 171, preferably unlike the upper flange steel 140 It is preferable to maximize the final eccentric effect by minimizing upward movement of the neutral axis of the steel by the upper strand steel 140 by having the width D4 substantially equal to the width D3.

In addition, the stiffener 173 may be vertically installed between the lower 172 and the upper surface of the lower flange 130 so that the lower lead steel 170 may be stably synthesized in the steel mold.

The upper and lower steels 140 and 170 are installed in the upper flange 110 and the lower flange 130, the steel of the synthesized state is increased rigidity can effectively resist external forces, the present invention Is used as the point casting mold 100.

The point portion mold 100 is installed to be fixed to the temporary support structure 10 including the temporary vents by a mechanical fastener such as a bolt, nut, roughly, based on the point (A) Figure 3 It is installed to protrude outwards on both sides (length direction) of the point portion.

Of course, in the point A, a plurality of point molds 100 are installed in parallel in the transverse direction, which may be appropriately selected according to the width of the temporary bridge.

Since the upper malleable steel 140 of the branch portion mold 100 of the present invention extends in the longitudinal direction to serve as a perforated plate, the branch portion overlapping plate 300 is installed in the branch portion A in correspondence to the extension length of the malleable steel. do.

Referring to Figure 3, the branch covering plate 300 is installed to extend in the longitudinal direction on the upper portion of the branch mold 100, for this purpose, a horizontal beam 200 is installed between the branch portion mold and the branch portion mold of the present invention. do.

The horizontal beams 200 are installed between the point portion molds, but are installed such that the upper surface of the horizontal beams 200 is the same height as the upper surface of the upper flange of the steel, as shown in Figure 4b, the bottom surface of the branch covering plate 300 on the upper surface of the horizontal beams To be supported by contact.

This is distinguished from the conventional cross beam is installed in the transverse direction between the abdomen of the mold for preventing the fall of the mold, etc., which can support the branch covering plate 300 of the present invention because it is installed extending in the longitudinal direction This may be because the horizontal beam 200 should be installed to be.

The horizontal beams 200 may be installed in the transverse direction between the point portion mold 100 in the point portion (A), spaced apart from each other in the longitudinal direction over the extension length of the point portion mold (100) Could be.

In addition, the connection portion of the cross beam 200 and the point portion mold 100 is further provided with a bracing material 210 in a diagonal direction, for example, to enable a stable support of the branch covering plate 300 and the point portion mold 100 ) And the lattice structure of the cross beam 200 to be a safer point structure.

Thus, in the state in which the branch part mold 100, the cross beam 200, and the branch parting plate 300 are installed in the branch part A, the span part mold 400 is additionally formed between the branch part and the branch part. ) And the back plate and bolts and nuts to be connected to each other, such that the upper surface of the span portion 400, the normal perforated plate is installed in the transverse direction and can be installed between the span cross mold. The perforated plate installed in the span part mold 400 is referred to as the span part perforated plate 500 in the present invention.

In the case of such a span part plate 500, by matching the height of the point portion plate 300, the jaw is not formed on the upper surface of the temporary bridge.

As the span length 400 extends, the bending constant moment (M +) is inevitably increased as the extension length thereof becomes longer, and thus, there may be a situation in which a large cross-sectional size may be increased due to a large amount of deflection.

In order to prevent such a phenomenon, in the present invention, as shown in FIG. 4A, the span-loading tensioning material 600 is tensioned and fixed to the lower surface of the span-mold mold 400 so that the required prestress is introduced into the span-mold mold.

At this time, the spanning load tensioning material 600 is fixed to the bottom of the spanning mold 400, spaced apart by the fixing unit 610, and then tension or fix both ends of the spanning load tensioning material 600, or one end After fixing, the other end can be tensioned and fixed.

Since the prestress is introduced to resist the bending constant moment (M +), it can be distinguished from the prestress by the point portion upper tension member 160 introduced to resist the bending parent moment (M−) of the point casting mold. Such prestressing refers to a case where all of the prestresses are introduced into the temporary bridge, and is referred to as double prestressing in the present invention.

The prestress by the span load tensioning material 600 can be selectively implemented in the present invention, and it is not necessary to install the span load tensioning material 600 in a temporary bridge having a small span.

By the synthetic hypothesis bridge of the present invention, it is possible to have a more secure structure in the branch portion by using the steel combined with the upper and lower steels so that the rigidity is increased in the branch portion, and relatively The cross-sectional area of the rigid steel between the two sections can be designed economically.

In addition, it is possible to form the branch structure of temporary bridges more economically and efficiently because the staging steel of the branch casting mold can play the role of a perforated plate at the same time.

By allowing the required prestress to be introduced into the upper cast steel of the point portion mold, it is possible to effectively resist the bending moment generated in the point portion.

An embodiment of the present invention described above and illustrated in the drawings should not be construed as limiting the technical spirit of the present invention. Those skilled in the art of the present invention can change and change the technical spirit of the present invention in various forms. Therefore, such improvements and modifications fall within the protection scope of the present invention as long as it will be apparent to those skilled in the art.

Claims (4)

In the temporary bridge including a plurality of molds and perforated plate is installed on the temporary support structure including a temporary vent, A point mould having an I-type cross section in which the upper malleable steel set to be installed at the site where the perforated plate is to be formed is longitudinally synthesized in the upper flange, and the lower stranded steel is further longitudinally synthesized in the lower flange; A cross beam installed in a transverse direction between the point side mold and the top surface side of the point portion mold; Point covering plate is installed on the horizontal beam upper surface is extended in the longitudinal direction in contact with the side of the upper strand steel; And a span part rest plate installed on the span part mold so as to be in contact with both end faces of the branch part rest plate. Said staging steel material is a synthetic hypothesis bridge, characterized in that the point portion upper tension material including a PC steel wire or steel rod is installed between the fixing plates installed at both ends is fixed after the tension. 2. The synthetic hypothesis bridge according to claim 1, wherein a bracing material is further provided between the connecting portion of the cross beam and the point portion mold. The synthetic temporary bridge according to claim 1 or 2, wherein the upper or lower steel is T-shaped steel. According to claim 3, Synthesis characterized in that the span portion tensioning device including a PC steel wire or steel rod is further installed between the anchorage spaced apart from each other on the lower portion of the span portion between the branch portion and the branch portion is fixed after tension Temporary bridge.

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