KR200395629Y1 - Bridge deck with stay-in-place precast concrete panel - Google Patents

Abstract

The present invention is to install the height-adjustable half-section precast bottom plate using bolts to facilitate the height adjustment of the bottom plate by the superelevation slope, camber, construction error, etc., which is the most serious problem of the half-section precast bottom plate. In addition to improving workability and safety, precise construction can be easily performed. Also, there is a high possibility of cracking due to the age difference and cross-sectional change of concrete between the half-section precast deck and the cast-in-place joint. The cross-sectional shape and the cross-sectional shape of the half-section precast floor plate are designed so that the bedding layer can be easily combined with the beam to form a solid floor plate for easier construction and no cracking. It is possible to construct a floor plate with excellent durability as well as initial investment cost It works.

Description

Bridge deck with stay-in-place precast concrete panel

The present invention relates to a bridge structure having a half-section precast deck and a construction method thereof, and more particularly, to a bridge structure having a half-section precast deck and improved construction convenience, safety, economics and ease of maintenance. It is about.

In general, the decking method of multi-column bridge is divided into cast-in-place concrete slab and half-section precast decking method. In addition, the half-section precast decking method can be applied to the shear depth half-section precast deck, half-depth precast deck, and permanent formwork, depending on the type of deck. Divided by.

1 is a cross-sectional view showing a multi-column bridge.

As shown therein, a multi-column bridge is generally provided side by side with a plurality of girders or beams 20 (hereinafter referred to as 'beams') in the longitudinal direction of the bridge over the bridge 10 or alternating (not shown), After the slab 30 is formed on the beam 20, the slab 30 is paved with asphalt or the like.

Here, the method of constructing the slab 30 is a cast-in-place method using the form 41 and the club 42 as shown in Figure 2a, shear surface precast to construct the shear surface as shown in Figure 2b precast floor plate 43 Method, a half-section precast method using only the half-section precast 44 as shown in FIG. 2C to precast only about 50% of the thickness of the slab 30 and cast the remainder in situ.

2a has a disadvantage in that the construction speed is slow and the construction safety is low, such as frequent falling and falling accidents, because the construction site should be installed by installing the copper bar 42 and the formwork 41 at a high place above the pier during construction. There is this.

2b has improved the disadvantages of the cast-in-place flooring method as described above, but it is difficult to apply to the section where the superelevation slope changes, the cross section is large and heavy, difficult to carry, lift, hypothesis, etc. Cracks tend to occur at the lateral joints.

Therefore, the half-section precast decking method as shown in FIG. 2c compensates for the shortcomings of the method shown in FIGS. 2a and 2b, and is effective in preventing falling accidents by mounting the precast decking plate 44 during the construction of the floorboard. In addition, there is an advantage that the workability is improved because the cross section is small and light and the adjustment of the superelevation slope or camber is easy.

In this half-section precast decking method, a prefabricated half-section precast decking 44 is installed between the beam 20 and the beam 20 having the 'I' beam structure, and the concrete 33 is placed thereon. On-site casting to form a synthesized slab (30).

And it is common to wrap with a packaging material 35, such as ascones on top of the slab 30 synthesized as described above.

However, as described above, in the bridge structure using the conventional half-section precast deck, cracks occur in the slab 30 around the connection portion of the half-section precast deck 44 as shown in FIGS. 3 and 4. There is a problem.

That is, Figure 3 is a view showing the longitudinal crack state of the bridge, the cause of such a crack (X) is caused by dry shrinkage of the concrete 33, breakage and settlement of the poor bedding layer, on the fish beam 20 Due to the change in the stiffness of the bottom plate 44, in particular, there is a problem that the crack is generated by the vibration when passing the heavy vehicle. In addition, Figure 4 is a diagram showing the lateral crack state of the bridge, the crack (Y) due to the dry shrinkage of the concrete 33, regardless of the structural function of the bottom plate 44, but problems in usability and maintenance occurs Done.

In addition, as described above, in the bridge structure having the conventional half-section precast deck, the height difference of the beam 20 for each construction position of the deck 44 due to the change of the transverse slope, the construction error, the camber, etc. occurs, and thus the precision construction is performed. It is difficult and there is a problem that causes factors such as cracks, load increase due to non-uniform cross-sectional formation accordingly.

The present invention has been devised to solve the above problems, by manufacturing and transporting a half-section precast deck with attached height adjusting bolts in a factory or on-site manufacturing site, as well as preventing falling and falling objects accidents. By making it easy to adjust the height, it is possible to make more precise construction, and to configure the detailed cross-sectional shape to minimize the occurrence of lateral or longitudinal cracking of the bridge, and the half-section precast deck and the cast-in-place concrete can perform the full composite behavior. The purpose of the present invention is to provide a bridge structure having a half-section precast slab and a construction method thereof, which can be easily and securely constructed and can be improved economically while improving the structural safety of the entire bridge by devising appropriate joints. There is this.

A bridge structure having a half-section precast deck according to the present invention for realizing the above object is a half-section precast deck that connects between the upper portion of a fish beam or a steel composite bridge (hereinafter referred to as 'beam'). In the bridge deck structure using the above, between the beam and the half-section precast bottom plate, the elastic material to prevent the impact of the bottom plate during the initial installation of the half-section precast bottom plate, and the half-section precast bottom plate After adjusting the height of the plate is characterized in that the bedding material for supporting the half-section precast bottom plate is provided.

The half-section precast bottom plate has at least a side edge of a portion raised on the upper portion of the beam as a curved surface or an inclined surface, and a portion supported by the bedding material has a step thickness thinner than other portions.

The half-section precast deck is installed with reinforcing bars in the longitudinal and transverse directions, and the rebar is exposed to the outside of the half-section precast deck to allow complete synthesis with the cast-in-place concrete, and the lifting rebar is exposed at the top. do.

The half-section precast bottom plate is provided with a height adjusting hole into which a height adjusting bolt is inserted to adjust the height from the top of the fish beam.

In addition, a bridge construction method having a half-section precast deck according to the present invention for realizing the above object, the step of installing an elastic material on the top of the beam; Hypothesizing a half-section precast deck over the elastic material so as to span the tops of both beams; Appropriately adjusting a height of the half-section precast deck provided above the beam; Installing a bedding material for space support in the space between the half-section precast deck and the beam; The half-section precast deck is characterized in that it comprises the step of constructing the slab by placing concrete on top of the beam.

Hereinafter, a preferred embodiment of the present invention with reference to the accompanying drawings as follows.

Figure 5 is a perspective view showing the installation structure of the bridge using a half-section precast bottom plate according to the present invention, Figure 6 is a cross-sectional view of the main part showing the bridge using a half-section precast bottom plate according to the present invention.

For a bridge structure using a half-section precast deck according to the present invention, referring to FIG. 5, a plurality of fish beams 55 or steel beams (hereinafter, referred to as 'beams') on a vertically pier 50 or alternation (not shown) Are described side by side).

A half-section precast bottom plate 60 is installed between the beam 55 and the beam 55, and the half-section precast bottom plate 60 and the upper portion of the beam 55 are illustrated in FIG. 6. After the slab is completed in the cast concrete, etc., the pavement layer 85 is formed on the asphalt or the like.

Figure 7 is a perspective view showing a half-section precast bottom plate 60 used in the bridge as described above, the half-section precast bottom plate 60 is configured to be prefabricated in the factory or manufacturing workshop to carry In this case, when the bridge deck plate installation work, without the need for formwork and clubs, etc. is installed on the beam 55, and then the concrete is placed on the site to achieve the slab composite.

The half-section precast bottom plate 60 is pre-installed when the reinforcement bars 62 are produced in the longitudinal direction, pre-installed when the reinforcing bars 61 are manufactured in the transverse direction, and the lifting reinforcement 63 is disposed on the upper part. Installed to be exposed. And the upper surface of the chair bar 63 for installing the upper rebar is exposed to combine with the site-cast concrete layer 80 to achieve a more perfect composite structure.

And the upper surface of the half-section precast bottom plate 60 is roughly formed so that the synthesis of the old and new concrete alone, but when the concrete is placed so that the shear resistance with the chair bar 65 when the concrete is placed so as to be fully synthesized It is desirable to be.

On the other hand, the half-section precast bottom plate 60 is provided with a height adjusting hole 67 is inserted into the height adjustment bolt to be described later to adjust the height from the top of the beam 55.

FIG. 8 is a lateral cross-sectional view showing a structure in which the half-section precast bottom plate 60 is installed on the beam 55, and is designed to prevent longitudinal cracking as shown in FIG. It shows a cross-sectional structure designed to form a solid bedding layer.

Between the beam 55 and the half-section precast bottom plate 60, the half-section precast bottom plate 60 supports the half-section precast bottom plate 60 while preventing an impact from occurring during the initial installation of the half-section precast bottom plate 60. An elastic material 70 and a bedding material 72 are placed after the height adjustment of the half-section precast bottom plate 60 to firmly support the half-section precast bottom plate.

Here, the elastic material 70 is formed of a rubber pad or the like, and the bedding material 72 is preferably formed by pouring concrete, a specific installation process will be described again below.

In addition, the half-section precast bottom plate 60 has an edge of a portion raised on the upper portion of the beam 55 is formed with a curved surface 66, and a transverse connecting main reinforcement 61 is formed on the outside of the beam 55. It is configured to be exposed to the top of).

The reason why the edge of the half-section precast bottom plate 60 is formed as the curved surface 66 is to prevent the sudden change of the cross section with the gentle curved surface 66 to prevent the occurrence of cracks as shown in FIG. 3. Of course, it is also possible to configure the inclined surface instead of the curved surface 66.

In addition, a portion on which the bedding material 72 is supported on the bottom surface of the half-section precast bottom plate 60 forms a step portion 60a that is relatively thinner than other portions, and the step portion 60a is formed. The reason for forming is to help form a stronger bedding layer without changing the bottom plate height.

In addition, the reason that the main reinforcing bar 61 is formed to be exposed to the side of the half-section precast bottom plate 60 is also the half-section precast bottom plate 60 when the cast-in-place concrete 80 is formed after the installation of the bottom plate 60. In order to minimize the occurrence of cracks as shown in Figure 3 by strengthening the adhesive strength between the) and the cast-in-place floor plate (80).

9 is a longitudinal cross-sectional view showing the longitudinal connection of the half-section precast deck 60, showing a structure that can prevent the transverse cracks as shown in FIG.

That is, the longitudinal connection portion of the half-section precast bottom plate 60 and the half-section precast bottom plate 60 is formed with a protrusion 68 in a triangular cross-sectional structure in a relative direction. At this time, the protrusion 68 is preferably formed in a triangular structure of the upper interval is large and the lower interval is small.

In particular, on the upper portion of the triangular protrusion 68 of the two half-section precast bottom plate 60, the lifting bars 62 connected in the longitudinal direction of the half-section precast bottom plate 60 are mutually engaged 62A. At the bottom of the contact portion of the triangular protrusion 68, Bird's Mouth Joint is formed, and the sealing material 69 is installed at the time of construction.

Accordingly, as described above, the longitudinal connecting portions of both half-section precast bottom plates 60 are mutually contacted in a triangular structure, and both of the half-section precast bottoms are connected at the upper portion of the contact portions by interconnecting the two reinforcement bars 62. By strengthening the connection strength between the plate 60, the sealing member 69 is provided at the bottom to reduce the occurrence of the step between the two half-section precast bottom plate 60 and to prevent leakage.

10 and 11 are a plan view and a cross-sectional view for explaining the installation process of the half-section precast deck 60, and the half-section precast deck 60 is referred to as The following describes the process installed on the top.

Half-section precast bottom plate 60 is manufactured in advance in a factory or the like as shown in FIG. 7, and a beam 55 is installed on the piers as shown in FIG. 5. Using a half-section precast bottom plate 60 is installed on the beam 55.

Here, looking at the installation process of the half-section precast bottom plate 60, the elastic material 70 is installed long to support the half-section precast bottom plate 60 on top of both fish beams 55.

Next, a half-section precast bottom plate 60 is placed on the elastic material 70 so as to span the upper portions of both beams 55, and then the half-section precast bottom plate 60 from the top of the beam 55. It will adjust the height of.

Here, the height adjustment of the half-section precast bottom plate 60 is fastened to the height adjustment bolt 75 to the height adjustment hole 67 of the half-section precast bottom plate 60 by the end portion of the upper part of the beam 55. When the height adjustment bolt 75 is rotated in a state of being in contact with the support, the height of the half-section precast bottom plate 60 is adjusted.

The reason for adjusting the height of the half-section precast deck 60 is that, when the half-section precast deck 60 is installed on the beam 55, the half-section is made flat due to superelevation variation, construction error or camber. If the heights of the ends of the precast bottom plate 60 do not coincide with each other, the thickness of the bottom plate is not constant and cannot be precisely constructed. Therefore, the height of the end of the half-section precast bottom plate 60 is changed to the bolt 75. Using to adjust the height of the construction.

When the height of the half-section precast bottom plate 60 is properly adjusted as described above, the bedding material 72 for supporting the bottom plate in the space between the half-section precast bottom plate 60 and the beam 55. Will install

Here, the bedding material 72 is preferably made of a method of pouring concrete so as to withstand the load of the half-section precast bottom plate 60 to minimize the occurrence of cracks.

When the bedding material 72 is hardened to some extent, the height adjustment bolt 75 is removed so that the load is not concentrated on the bolt. When the bedding material is completely cured, the half-section precast bottom plate 60 and the beam 55 are removed. Concrete is placed on top of the site to form a pour layer 80 to build the slab.

The bridge deck structure and construction method using the half-section precast deck as described above is manufactured and installed in advance in a half-section precast deck at the factory, and firmly combined with cast-in-place concrete, so that formwork, copper ball It is possible to improve safety by preventing fall accidents of workers, etc., and it is easy to construct, which improves the constructability as well as the cost of construction, and the construction speed is high, which shortens the air and increases safety.

In particular, the present invention is formed in the upper side connection of the beam, the side edge of the half-section precast bottom plate to the curved surface, and configured to expose the cast reinforcing bar, by inserting a bedding material with sufficient rigidity in the lower, There is an advantage that can prevent the occurrence of cracks to improve the structural strength of the bridge.

In addition, the present invention installs the height adjustment bolt on the half-section precast deck to easily cope with the change of single-gradient and camber to enable the construction of the deck precisely, thus improving the workability as well as the solid construction. There is an advantage that can be constructed.

1 is a cross-sectional view showing a conventional bridge,

Figures 2a, 2b, 2c is a view showing the bottom plate mounting structures of a conventional bridge,

3 is a cross-sectional view of the main portion for explaining the longitudinal cracking problem of a bridge having a conventional half-section precast deck;

4 is a longitudinal sectional view of an essential part for explaining the problem of transverse cracking of a bridge having a conventional half-section precast deck;

5 is a perspective view showing the installation structure of a bridge having a half-section precast deck according to the present invention,

6 is a cross-sectional view showing a bridge having a half-section precast deck according to the present invention,

Figure 7 is a perspective view of a half-section precast bottom plate according to the present invention,

8 is a cross-sectional view of the main part showing the construction state of the half-section precast deck in the present invention,

Figure 9 is a longitudinal cross-sectional view of the main part showing the construction state of the half-section precast deck in the present invention,

10 is a plan view for explaining the installation process of the half-section precast deck according to the present invention,

Figure 11 is a cross-sectional view for explaining the installation process of the half-section precast deck according to the present invention.

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

50: pier 55: fish beam

60: half-section precast bottom plate 61: cast steel

62: lifted reinforcement 63: lifted reinforcement

65: chair bar 66: curved surface

67: height adjustment bolt hole 68: protrusion

69: sealing material 70: elastic material

72: bedding material 75: height adjustment bolt

80: pouring layer 85: pavement layer

Claims (4)

In a bridge deck structure using a half-section precast deck that connects between the top of a fish beam or a steel composite bridge (hereinafter referred to as the 'beam'), Between the beam and the half-section precast deck, an elastic material that prevents the impact of the bottom plate upon initial installation of the half-section precast deck, and a half section after adjusting the height of the half-section precast deck. A bridge structure having a half-section precast bottom plate, characterized in that a bedding material for supporting the precast bottom plate is provided. The method according to claim 1, The half-section precast bottom plate has at least a side edge of the raised portion of the beam is formed in a curved surface or an inclined surface, the portion supported by the bedding material is characterized in that the stepped portion is thinner than the other portion is formed Bridge structure with half-section precast deck. The method according to claim 1, The half-section precast deck is installed with reinforcing bars in the longitudinal and transverse directions, and the rebar is exposed to the outside of the half-section precast deck to allow complete synthesis with the cast-in-place concrete, and the lifting rebar is exposed at the top. A bridge structure having a half-section precast deck. The method according to claim 1, The half-section precast bottom plate is a bridge structure having a half-section precast bottom plate, characterized in that the height adjustment hole is inserted into the height adjustment bolt is inserted to adjust the height from the top of the fish beam.