KR102487499B1 - Bridge deck construction structure and method using a precast deck set - Google Patents

Abstract

The present invention relates to a bridge deck construction structure a precast deck set and a construction method thereof, capable of easily performing connection and sealing works of a precast deck. The construction method comprises the steps of: installing two or more girders (1); mounting a precast deck set; and pouring cast-in-place concrete.

Description

Bridge deck construction structure and method using a precast deck set {Bridge deck construction structure and method using a precast deck set}

The present invention relates to a bridge deck construction structure and construction method using a precast deck set used for bridge deck construction.

In detail, the precast deck having two supports in the main body and the simple deck without supports allow the deck installed between the girders to be supported by four sides and to be easily constructed even in the curved part. It relates to a bridge deck construction structure and construction method using a precast deck set.

A bridge is a civil structure that connects spaces and provides passages for people, vehicles, trains, water resources, and cargo to move. Bridges are completed by installing girders on substructures such as abutments and piers, and installing bottom plates and slabs on top of the girders.

Recently, in order to improve the productivity and quality of bridge construction, a bridge construction method that manufactures members in a factory and assembles them at the construction site or minimizes on-site work is widely used.

Bridge decks have traditionally been constructed by installing formwork at the construction site and pouring concrete.

However, in this traditional bridge deck construction method, since all deck concrete is cast-in-place concrete, it is difficult to control the quality of concrete and is greatly affected by external factors such as weather and surrounding environment, and most of the construction process is performed on site. Because it is done in the air, not only has it been exposed to various safety accidents, but it has been exposed to various safety accidents, and there has been a problem that a lot of time, cost, and effort are required for installation and dismantling of formwork, concrete casting and curing.

In order to solve this problem, a method of manufacturing a precast floor plate in advance in a factory, assembling it on site, and then pouring concrete is used.

However, since the method of constructing a bridge deck using a precast deck is a method of assembling a precast deck composed of segments on site and pouring concrete thereon, it is difficult to construct a joint between decks and decks. However, there were many cases where concrete leaked from the joint, and there was a problem that a separate process was required to prevent concrete leaking.

In particular, the vertical alignment of a bridge has not only a straight part but also a curved part. In the curved part, the distance between the decks changes in the width direction of the deck (direction perpendicular to the bridge axis), so construction is performed by connecting the deck and deck. It is very difficult to do, the support structure of the floor plate is weakened, and the joint gap in the curved part is inevitably increased, so there is a problem that the concrete leakage problem is getting bigger.

In addition, since the conventional floor plate is a two-sided support system in which only both ends in the width direction of the floor plate are supported by the girder, the support structure of the floor plate often lacks stability, and the floor plates connected back and forth are only in the same plane. Since they are connected, the strength and durability of the connected bottom plate are often not excellent.

Therefore, it was necessary to develop a precast deck and bridge deck construction method that can be easily constructed in curved parts, has a stable support structure and bending stiffness, and can easily prevent concrete leakage without special processes at the joint.

Registered Patent Publication No. 10-1833373

In order to improve the problems of the prior art as described above, the object of the present invention is to provide a bridge deck construction structure and construction method using a precast deck set that is easy to connect the precast deck not only to the straight part but also to the curved part. .

An object of the present invention is to provide a bridge deck construction structure and construction method using a precast deck set having a stable support structure and high bending stiffness.

An object of the present invention is to provide a bridge deck construction structure and construction method using a precast deck set that can easily perform connecting and sealing operations of the precast deck when constructing the bridge deck.

In the present invention, in the bridge deck construction structure using a precast deck set, the precast deck set includes: a precast deck; It includes a simple deck 200 provided between the precast decks, wherein the precast deck includes a main body portion 110 placed on top of one girder 1 and an adjacent girder 1; It includes a support part 120 provided integrally with the main body part 110 and provided under the front and rear surfaces 113 of the main body part 110, but the length L1 of the main body part 110 is the support part It is longer than the length (L2) of 120, the width (W1) of the main body part 110 is greater than the width (W2) of the support part 120, and the upper surface 121 of the support part 120 is the main body part. It protrudes outward from the front and rear surfaces 113 of the 110, the width W1 of the body portion 110 is greater than the inner distance d between the upper ends of the girder 1, and the width of the support portion 120 (W2) is equal to the inner distance (d) between the top ends of the girders (1) or smaller than the inner distance (d) between the top ends of the girders (1), and the support part 120 is the main body part 110 It is provided under both of the two front and rear surfaces 113, the simple deck 200 has no support, and when the precast deck and the simple deck 200 are mounted on the top of the girder, any one simple deck 200 ) provides a bridge deck construction structure using a precast deck set, characterized in that it is mounted on the upper surface 121 of the support part 120 of two adjacent precast decks in front and rear, so as to be in surface contact.

In addition, in the present invention, in the construction method of the bridge deck construction structure, a) installing two or more girders (1); b) mounting a precast deck set on top of a girder (1) adjacent to any one girder (1); c) Provides a bridge deck construction method using a precast deck set comprising the step of placing cast-in-place concrete on top of the mounted precast deck set.

The bridge deck construction structure and construction method using the precast deck set of the present invention have the following effects.

First, when constructing in a curved part, the interval of the joint between decks may vary along the width direction of the deck. Since the deck of the present invention can always be positioned so that the main body part overlaps the top of the support part even in the curved part, the curved part It is easy to construct in

Second, since both sides of the body part (both ends of the body part in the direction perpendicular to the bridge axis) are supported by girders, and support parts are provided below and in front of the body part along the bridge axis direction, a four-sided support structure can be completed, which is more stable and more stable than before. , it can become a solid supporting structure and improve the resistance to sagging and cracking.

In particular, the portion drawn in both directions in FIG. 4 (the part where the main body and the support meet to form a rectangular cross section) becomes a rectangular beam, and exhibits much greater bending stiffness than the main body (bending stiffness increases in proportion to the third power of the vertical height). As a result, the deck of the four-sided support structure can be completed.

Third, since the support of one deck forms a structure to support the other adjacent deck, and the adjacent decks form a structure to support each other throughout the entire area where the deck is installed, the decks arranged in the front and rear form a structure that interlocks with each other, so that the connected decks Like a sole plate, it can organically resist the upper load.

Fourth, there are inevitably errors in manufacturing the precast deck and construction errors in the construction of the upper structure of the bridge. Since the support integrally provided on the lower surface of the main body can absorb various errors that inevitably occur, the precast Mounting of the deck can be done quickly and easily.

Fifth, when the precast deck is mounted so as to span the upper part of the two girders, the support part is located at the lower part between the main body parts located in front and back, so that the connection work and sealing work of the precast deck can be easily and quickly performed. there is.

Sixth, since the effect of correcting various errors can be obtained by the support part located under the main body part, the quality of construction of the deck plate of the bridge can be improved, and synergistic effects such as reduction of construction cost, shortening of the construction period, and increase of durability and safety of the bridge can be achieved. can be obtained.

Seventh, when the precast deck of the present invention is mounted on two girders, the main body part spans the upper part of the adjacent girder, and the support part is mounted in a form sandwiched between the girders below the main body part, so that the deck mounting and alignment work It can be easily made and can be mounted in a stable state that is not separated from the girder without separate fixing work.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 and 2 are a plan view and a side view of the precast deck 100 of the present invention.
3 is a perspective view of the precast deck 100 of the present invention.
Figure 4 is for explaining that one end of the body portion and the support portion become a rectangular beam.
5 is a plan view, a side view, and a perspective view showing that the precast deck 100 of the present invention is continuous.
6 is a cross-sectional side view and a perspective view of the precast deck 100 of the present invention provided with first and second connecting parts (ring type hoops).
7 is a cross-sectional side view and a perspective view of the precast deck 100 of the present invention provided with first and second connecting parts (helical hoops).
8 and 9 are perspective views of the sealing material provided in the precast deck 100 of the present invention.
10 is a plan view and a side cross-sectional view of the support portion of the present invention formed in a planar trapezoidal shape.
11 is a perspective view of the support portion of the present invention formed in a trapezoidal shape.
12 is a plan view, a side view, and a perspective view, in which support parts are provided on both sides of the body part and the support part is formed in a planar trapezoidal shape.
13 is a plan view and a cross-sectional view illustrating a process of passing through the precast deck 100 of the present invention while the support absorbs and compensates for errors that may occur in the part where the decks are connected without any additional measures.
14 is a perspective view illustrating a process of passing the precast deck 100 of the present invention while the support absorbs and compensates for an error that may occur in a portion where the decks are connected without any additional measures.
15 is a plan view illustrating that the precast deck 100 is mounted on a curved portion when the planar shape of the support portion is rectangular.
16 is a plan view illustrating that the precast deck 100 is mounted on a curved portion when the planar shape of the support portion is trapezoidal.
17 is a plan view illustrating that a precast deck having a rectangular support portion is mounted on a straight portion and a precast deck having a trapezoidal support portion is mounted on a curved portion.
18 is a perspective view illustrating the construction of a bridge deck on a straight part.
19 is a plan view and a cross-sectional view illustrating the construction of a bridge deck on a straight part.
20 is a perspective view illustrating the construction of a bridge deck on a curved part.
21 is a plan view and a side view illustrating an embodiment of a simple deck without a deck and a support provided with support (flat rectangle) on both sides of the main body.
22 is a perspective view illustrating an embodiment of a simple deck without a deck and a support provided with support (planar trapezoidal) on both sides of the main body.

Hereinafter, embodiments of the present invention will be described in detail so that those skilled in the art can easily practice with reference to the accompanying drawings. 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 certain component is said to "include", it means that it may further include other components without excluding other components unless otherwise stated. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention relates to a bridge deck construction structure and construction method using a precast deck set.

First, the precast deck that completes the four-side support structure will be described, and then the bridge deck construction method will be described.

Based on the bridge axis direction (longitudinal direction of bridge and girder), the dimensions of the deck are explained. That is, the size of the body part and the support part formed in the longitudinal direction of the girder is expressed as 'length', and the size of the body part and support part formed in the direction orthogonal to the longitudinal direction of the girder is expressed as 'width'.

The precast deck 100 of the present invention includes a body portion 110 and a support portion 120.

The body portion 110 is formed in a flat plate shape, and includes one upper surface 111, one lower surface 112, two front and rear surfaces 113, and two side surfaces 114.

The upper surface 111 and the lower surface 112 are upper and lower surfaces, respectively, the front and rear surfaces 113 are surfaces facing the bridge axis direction, and the side surface 114 is a surface facing the bridge axis direction at right angles.

The body portion 110 is formed in a flat plate shape, but may have protrusions and/or concave portions and/or convex portions on the upper and lower surfaces in some cases.

The support part 120 is formed in a flat plate shape and includes one upper surface 121, one lower surface 122, two front and rear surfaces 123, and two side surfaces 124.

The upper surface 121 and the lower surface 122 are upper and lower surfaces, respectively, the front and rear surfaces 123 are surfaces facing the bridge axis direction, and the side surface 124 is a surface facing the bridge axis direction.

The side surface 124 of the support part 120 may be provided as a vertical surface in a vertical direction, or may be provided as an inclined surface forming a certain angle with a vertical line (FIG. 3, 6, 10), and the vertical surface and the inclined surface are provided together. (Figs. 8 and 9).

The support part 120 is integrally provided with the main body part 110, and is provided below one of the two front and rear surfaces 113 of the main body part 110.

It is preferable that the upper surface 121 of the support part 120 and the lower surface 112 of the body part 110 are provided at the same height.

In order to conveniently mount the deck and improve the strength of the attachment between the cast-in-place concrete and the deck, chamfered surfaces 115 may be provided above the end of the main body 110 in the lengthwise direction where no support is provided.

Since the support part 120 supports the upper body part 110 under the upper end of the girder, the length L2 of the support part 120 is smaller than the length L1 of the body part 110 it is desirable

Since the main body part 110 spans over two girders and the support part 120 supports the main body part 110 at the upper part below the upper end of the girder, the width W1 of the main body part 110 is the support part It should be provided larger than the width (W2) of (120).

Since the body portion 110 is mounted so as to span over two adjacent girders 1, the width W1 of the body portion 110 must be greater than the inner distance d between the upper ends of the girders 1.

Since the support part 120 must be inserted inside between the upper ends of two adjacent girders 1, the width W2 of the support part 120 should be the same as the inner distance d between the upper ends of the girders 1. can However, in consideration of various errors such as manufacturing errors that may occur during deck manufacturing and construction errors that may occur during girder construction, the width (W2) of the support part 120 is the inner distance (d) between the upper ends of the girder (1) It is preferable to make it slightly smaller than .

In addition, since the four-side support precast deck of the present invention has a special advantage in the construction of curved parts, the width W2 of the support part 120 is between the girders 1 and girders 1 even for smooth construction in the curved parts. It is preferable to make it slightly smaller than the inner distance (d) of .

Since the support part 120 should support the main body of the adjacent precast deck 100, the upper surface 121 of the support part 120 should protrude outward from the front and rear surfaces 113 of the main body part 110.

The main body part 110 is mounted so as to span the upper part of the girder 1 adjacent to any one girder 1, and the upper surface 121 of the support part 120 and the lower surface 112 of the main body part 110 By being provided at the same height, the lower surface 112 of the body portion 110 of the adjacent deck 100 is supported on the upper surface 121 of the support portion 120 of any one deck 100.

When the deck 100 of the present invention is mounted, as shown in FIG. 13, the main body part 110 is over the top of the two girders 1, and the support part 120 below the top of the two girders 1 Is positioned in a fitted form, the lower surface 112 of the body portion 110 of the adjacent deck 100 is in surface contact with the upper surface 121 of the support portion 120 of any one deck 100.

As a result, since both sides of the body portion 110 of one deck 100 are supported by girders, and support portions are provided below and in front of the body portion along the axis direction, a four-sided support structure can be completed.

In addition, since the two main body parts 110 overlap on the upper part of one support part 120, the deck connection work and sealing work can be performed easily and quickly, and by adjusting the degree of overlap, inevitably occurs Various errors can be absorbed and corrected.

In addition, by using a special technical feature that can adjust the degree of overlap, it is possible to exert a special effect of making the construction of the floor plate in the curved part very easy.

That is, as shown in FIG. 15, if the amount of overlap decreases from the curved part to the outside of the curve, it is very convenient to mount the deck and construct the bottom plate in the curved part, and it is easy to place concrete at the joint. In addition, the support structure by the support part can be maintained as it is even in the curved part.

In order to further improve workability, strength, and durability in the curved portion, the planar shape of the support portion 120 may be trapezoidal rather than rectangular.

When the planar shape of the support portion 120 is rectangular, the length in the axial direction of the support portion 120 is constant over the entire width, whereas when the planar shape of the support portion 120 is trapezoidal, one side of the support portion 120 has a different length. As one side goes, the length gradually becomes longer or shorter (see FIGS. 10, 11, 16, and 22).

Even if the flat shape of the support part 120 is rectangular, it is possible to construct a curved part, but it may be difficult to apply to a curved bridge (eg, a ramp section bridge) with a large curvature (small radius of curvature).

When the planar shape of the support portion 120 is trapezoidal, a special effect that can be easily applied to the precast deck of the present invention is exhibited even in a curved portion having a large curvature.

The precast deck 100 of the present invention may further include a connecting portion and a sealing material.

The connection part protrudes upward from the body part 110 .

The connection part is a configuration for connecting and integrating the decks with each other as well as the connection between the deck and the cast-in-place concrete.

The connection part includes a first connection part 130 and a second connection part 140, and is provided in a direction parallel to the direction perpendicular to the bridge axis.

The first connection part 130 and the second connection part 140 are provided on the upper part of one end and the other end of the body part 110, respectively, and the first connection part 130 is located on the side (one end) where the support part 120 is located. ), and the second connection part 140 is provided on the opposite side (other end) of the side where the support part 120 is located.

Any one of the first connection part 130 and the second connection part 140 may be provided, and it is preferable to have both the first connection part 130 and the second connection part 140 .

For the first connection part 130 and the second connection part 140, a plurality of separated and closed ring-shaped hoops (FIG. 6) may be used, or one spirally connected spiral hoop (FIG. 7) may be used.

The first connection part 130 and the second connection part 140 can not only increase the shear strength and adhesion to the cast-in-place concrete, but also the first connection part 130 and the second connection part 140 connect adjacent decks. can be unified. That is, if the second connection part 140 provided in any one deck and the first connection part 130 of an adjacent deck are bent, cross each other, and then connected, integration and continuity of adjacent decks is possible.

When the second connection portion 140 and the first connection portion 130 are intersected and fastened, a separate wire, reinforcing bar, or binding member may be used.

In addition, since the first connection part 130 and the second connection part 140 are flexible, it is easy to change the shape to increase the fixing effect, such as bending and fixing between reinforcing bars placed inside the deck when manufacturing a deck, and constructing a floor plate It is possible to avoid interference with reinforcing bars when placing reinforcing bars, so it has excellent workability.

In order to achieve the above effect, the first connection part 130 and the second connection part 140 may use a flexible string form, which is made of metal that can be bent by manpower and can be bent and then maintained in a bent state. It is preferable to use a wire.

The sealing material is for preventing the outflow of concrete and buffering the impact between the decks when cast-in-place concrete is placed on the upper part of the mounted deck, and is mounted on the girder 1 of the lower surface 112 of the body part 110. Of the first sealing material 151 provided in the part, the second sealing material 152 provided at a position overlapping the lower surface of the adjacent deck body part 110 among the upper surfaces 121 of the support part 120, and the support part 120 At least one of the third sealing materials 153 provided on the side surface 124 may be provided.

It is preferable to have all of the first sealing material 151, the second sealing material 152, and the third sealing material 153 above.

In the above, an embodiment in which the support part 120 is provided only under one of the front and rear surfaces 113 of the main body part 110 has been described, but the support part 120 has two parts of the main body part 110. Embodiments provided under both the front and rear surfaces 113 are also possible (Figs. 12, 21, 22).

The body part 110 and the support part 120 of the second embodiment are the same as the embodiment in which the support part 120 is provided only under one front and rear surface 113 of the body part 110 described above, except that the deck There is a difference in that two support parts 120 are provided in one body part 110 of the.

That is, the support portion of the second embodiment may also have a rectangular or trapezoidal planar shape, and one support portion may be rectangular and the other support portion may be trapezoidal.

In the second embodiment, a simple deck 200 is provided between the decks 100. In this case, the deck 100 and the simple deck 200 are used as a deck set.

The simple deck 200 has only the body portion described above and has no support portion. Upper portions of both ends in the longitudinal direction of the simple deck may be provided with chamfered surfaces 215 .

In the second embodiment, when the simple deck 200 is repeatedly mounted between the two decks 100, the same effect as the first embodiment described above can be exerted.

In the second embodiment, since the support is provided on both sides of the main body in the longitudinal direction, the connecting portion may be provided to protrude from both upper portions of the main body where the support is located.

In addition, in order to secure integrity with the simple deck 200, it is preferable to provide connection parts on both sides of the simple deck in the longitudinal direction.

Similarly in the second embodiment, a plurality of separate and closed ring-shaped hoops or one spirally connected spiral hoop may be used as the connecting portion.

Hereinafter, a bridge deck construction structure and construction method using the precast deck set described above will be described.

When the construction of the bridge substructure is completed, the girder 1 is installed.

In order to use the precast deck of the present invention, two or more rows of girders 1 are installed.

When the required girder installation is completed, the deck 100 of the present invention is sequentially mounted on the upper part of the girder 1 adjacent to any one girder 1.

The deck 100 is mounted so that its main body spans both adjacent girders, and the support portion is mounted so as to be interposed between the inner sides of the girders.

And after installing the required formwork, the cast-in-place concrete (2) is poured and cured on the upper part of the mounted deck, and the construction of the bridge deck is completed.

When the hardening of the cast-in-place concrete is completed by the above process, a structure in which the support of one deck supports the other deck adjacent to it, and the interlocking and integrated structure of the decks arranged in front and rear is completed throughout the entire bridge, In addition, the connected decks exert a special effect of resisting the upper load organically like a single floor plate.

In addition, in the process of overlapping the body part with the support part in the above deck mounting process, various errors are corrected and alignment is made easy, so the quality of bridge deck construction can be improved, construction cost can be reduced, the construction period can be shortened, and the durability and safety of the bridge can be improved. You get synergistic effects such as increase.

In the bridge deck construction method using the deck set of the second embodiment, the deck 100 having two supports 120 is used, and a process of passing the simple deck 200 between them is added, and the remaining processes are different. there is no

Although the present invention has been described with reference to the embodiments shown in the drawings, this is only exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. That is, an embodiment in which concrete is filled and an embodiment in which it is not filled, a first supporting means and a second supporting means, and an embodiment having and not including the pile tip support member 300, a height adjusting bolt and position adjustment It is possible to carry out deformation in various forms by applying bolts, etc. to each other.

Therefore, the true technical scope of protection of the present invention should be determined by the technical spirit of the appended claims.

100. Deck
110. Main body
111. Top 112. Bottom
113. Front and back 114. Side
115. Chamfer face
120. Support
121. Top 122. Bottom
123. Front and back 124. Side
130. First connection
140. Second connection
151. First sealing material
152. Second sealing material 153. Third sealing material
200. Simple Deck
215. Chamfer face
d. Inner distance between the top of the girder (1) and the top of the girder (1)
W1. body width
W2. width of support
L1. length of body
L2. length of support
1. Girder
2. Cast-in-place concrete

Claims (2)

In the bridge deck construction structure using a precast deck set,
The precast deck set may include a precast deck; Including a simple deck 200 provided between the precast decks,
The precast deck includes a body portion 110 placed on top of a girder 1 adjacent to any one girder 1; It is provided integrally with the body portion 110, and includes a support portion 120 provided under the front and rear surfaces 113 of the body portion 110,
The length L1 of the body portion 110 is longer than the length L2 of the support portion 120, and the width W1 of the body portion 110 is greater than the width W2 of the support portion 120, The upper surface 121 of the support part 120 protrudes outward from the front and rear surfaces 113 of the body part 110,
The width W1 of the body portion 110 is greater than the inner distance d between the upper ends of the girders 1, and the width W2 of the support 120 is the inner distance between the upper ends of the girders 1 ( Same as d) or smaller than the inner distance (d) between the tops of the girders (1),
The support part 120 is provided under both of the two front and rear surfaces 113 of the body part 110,
The simple deck 200 has no support,
When the precast deck and the simple deck 200 are mounted on the upper part of the girder, any one simple deck 200 is mounted in surface contact with the upper surface 121 of the support part 120 of the two adjacent precast decks in the front and rear characterized by
Bridge deck construction structure using a precast deck set. In the construction method of the bridge deck construction structure of claim 1,
a) installing two or more girders (1);
b) mounting the precast deck set on top of a girder (1) adjacent to any one girder (1);
c) pouring cast-in-place concrete on top of the mounted precast deck set
Bridge deck construction method using a precast deck set.

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