KR102032941B1 - Double composite plate girder bridge - Google Patents

Abstract

The present invention relates to a bridge structure of reinforcing a plate girder, which is a plate girder bridge using an I-shaped assembling girder manufactured by assembling an upper flange, a lower flange and a web cut by a steel plate. The present invention is provided with a front end connecting material for composition with slab concrete at the upper flange of the I-shaped assembling girder, is further provided with a pair of T-shaped embedded steels positioned at both sides of the upper flange in parallel and embedded in the slab concrete at a point part in which negative moment is generated, allows the lower flange of the I-shaped assembling girder to have greater width than the upper flange, is formed with a closing space at an upper surface of the lower flange by being provided with a pair of closed reinforcing materials around the web, and allowing a reinforcing bar and concrete to be reinforced and placed in the closing space at the point part in which the negative moment is generated.

Description

Double composite plate girder bridge {DOUBLE COMPOSITE PLATE GIRDER BRIDGE}

The present invention relates to a structure of a bridge reinforced with a plate girder, and more specifically, to improve the efficiency of the cross section of the upper structure of the bridge by synthesizing and strengthening concrete on the upper and lower portions of the I-type girder assembled from steel It relates to a double composite plate girder bridge.

 Plate girder bridge is a structure of the composite structure of I-type girder made of steel plate and cast its upper slab.The girder has a small weight of girder for easy construction work, good aesthetics and construction without being affected by ground conditions. have.

However, this plate girder bridge is not only disadvantageous to secure the space of the mold due to the high height, but also has a problem of the possibility of falling during the work process because of the high center of gravity of the girder. Therefore, efforts have been made to reduce the profile of steel girders through various reinforcement methods according to stress distribution.

 1 is an invention named 'assembled double composite plate girder bridge and its construction method' of Patent No. 10-1705002, which is installed on the substructure 1 of the bridge and spaced apart from each other at regular intervals in the transverse direction of the bridge. Two plate girders 20, a precast bottom plate 30 installed on the plurality of plate girders 20, and a plurality of plate girders 20 connected to a lower portion of the plurality of plate girders 20. Reinforcement concrete 40 to reinforce the rigidity, the upper surface of the plate girder 20, the shear connector 25 is formed protruding, the precast bottom plate 30, the shear connector 25 is The front end pocket 31 to be inserted is formed therethrough, and the front end connection member 25 is connected to and supports the upper portions of the plurality of plate girders 20 laterally by using the precast bottom plate 30. Fixing device 26 for fixing the precast bottom plate 30 is installed, the fixing device 26, the fixing member 27 is coupled to the upper end of the shear connector 25, and the fixing member ( 27 is fixed to the fixing plate 28 is fixed to the upper side of the precast bottom plate 30 and the fixing nut 29 is screwed to the fixing member 27 to secure the fixing plate 28 The lower portion of the plurality of plate girders 20 is connected and supported by the reinforcement concrete 40 before the synthesis of the precast bottom plate 30 and the plate girder 20 and the upper portion of the plurality of plate girders 20 is It is characterized by connecting and supporting the precast bottom plate 30 to prevent twisting and buckling of the plate girder 20.

However, the above-described plate girders of the prior art simply synthesize the point portion of the reinforced concrete, so that the external integrity of the bridge section where the lower flange of the I-girder is exposed as it is not maintained, thereby inhibiting the appearance of the bridge. In addition, the exposed reinforcement concrete is not easy to cast on-site, resulting in an increase in unit cost due to the production of a small number of factories, as well as structurally deteriorated structural stability is easily destroyed by vibration during earthquake.

KR 10-1705002 B1

The present invention is to solve the above-mentioned problems of the prior art, to ensure the uniformity in the appearance of the bridge while the reinforcement corresponding to the stress change is made to ensure the effective cross-sectional performance of the plate girders, improve the workability to shorten the air The purpose is to provide a double composite plate girder bridge that can be made.

According to the most preferred embodiment of the present invention for solving the above problems, a plate girder bridge using an I-type assembly girder manufactured by assembling the upper flange, the lower flange and the web cut with a steel plate, the upper portion of the I-type assembly girder The flange is provided with a shear connecting material for synthesis with the slab concrete, and a pair of T-type buried steel buried in the slab concrete, which is located in parallel on both sides of the upper flange at the point where the parent moment occurs is further provided, The lower flange of the type I assembly girder has a width larger than that of the upper flange, and a pair of closed reinforcement materials are provided on both sides of the web to form a closed space on the upper surface of the lower flange, and at the point where the parent moment occurs. Provided is a double composite plate girder bridge characterized in that reinforcement and concrete are placed and poured in a closed space.

At this time, the T-type buried steel is composed of an abdominal plate by continuously arranging a plurality of abdominal pieces on the upper plate and the lower surface of the upper plate. And, the upper part of the abdominal piece can be configured to form a square opening.

On the other hand, by integrating the pair of T-type buried steel in advance with a connecting reinforcing bar, the slab reinforcement in the field can complete the reinforcement work of the slab reinforcing bar by simply connecting to the connecting bar.

According to still another embodiment of the present invention, a cross beam is provided between two adjacent I-type girders, and a double composite plate girder bridge is provided between a bottom vertical reinforcement of the cross beam and a half vertical reinforcement. In this case, the vertical reinforcement may be further installed between the upper flange and the upper surface of the closed reinforcement in the type I girder where the cross beam is not installed.

In addition, according to another embodiment of the present invention, a double composite plate girder bridge is provided on the lower surface of the horizontal beam installed in the point portion of the cross beam is inclined reinforcement is connected to the stiffening reinforcement inclined to both sides.

The present invention optimizes the cross section of the plate girder as the stress is shared by the reinforcing structure of the cross beam while efficiently reinforcing the tensile stress portion and the leaflet point of the plate girder, so that a small mold height and a large mold space can be achieved. It is possible to build an economical plate girder bridge, such as reducing the amount of use.

In addition, the present invention is to enable the reinforcement structure of the tensile stress portion to function as an anchor body to maintain the plate girder and the high composite force with the slab concrete, and to prevent deformation of the plate girder through the box-shaped reinforcement means at the leaflet point and concrete By forming a double compound with and allows the high structural stability of the plate girder bridge.

1 is a perspective view and a cross-sectional view of a plate girder bridge according to the prior art.
2 is a cross-sectional view of a plate girder bridge according to an embodiment of the present invention.
3 is a cross-sectional view at points A, B, and C of FIG. 2.
4 is a cross-sectional view at points D, E, and F of FIG. 2.
5 is a perspective view of an embodiment of a T-type buried steel structure which is a reinforcing means of an I-type girder applied to the plate girder bridge of the present invention.
Figure 6 is a cross-sectional view of an embodiment provided with an inclined reinforcement to the horizontal beam installed in the I-type assembly girder.

Hereinafter, with reference to the accompanying drawings, the most preferred embodiment of the present invention will be described in detail. However, in describing the present invention, when the technical concept of the present invention is obscured or obscured by describing the known configuration in detail, the description of the known configuration will be omitted.

FIG. 2 is an overall cross section of a plate girder bridge PB according to an embodiment of the present invention, and FIG. 3 is a cross sectional view of points A, B, and C of the span portion L2 in which a constant moment is generated. 4 shows each cross section at points D, E, and F of the point portion L1 where the parent moment occurs.

Plate girder bridge (PB) of the present invention is the I-type assembly girder (100) of the plate girder welded and assembled each steel sheet pieces of the upper flange 110 and the lower flange 130 and the web 120 made by cutting a thin steel sheet While using to add a reinforcing means according to the magnitude of the stress to reduce the mold height of the I-type assembly girder (100).

For example, when the plate girder bridge (PB) consists of two spans as shown in Figure 2, the largest parent is generated in the point portion (L1) where the piers (P) is installed, the stress of the point portion (L1) A separate reinforcing means to bear the burden of reducing the mold height of the I-type assembly girder (100) to reduce the steel material usage and to secure a larger mold space.

The reinforcing means for this is to make the I-type assembly girder 100 has a double composite structure with concrete, while stiffening the tensile stress through the cross-sectional reinforcement at the point (L1) slab concrete 170 It has high compounding power with.

That is, the upper flange 110 of the I-type assembly girder 100 is provided with a shear connecting material 111 for the synthesis with the slab concrete 170, and can be combined with a separate reinforced concrete on the upper surface of the lower flange 130. Closed space 132 is formed so that the plate girder bridge (PB) of the present invention can have a double composite structure.

The shear connector 111 may be installed on the upper surface of the lower flange 130 for synthesis with the reinforced concrete in the closing space 132.

In addition, the point portion (L1) that generates the parent moment is further provided with a T-type buried steel 140 in the upper flange 110 to improve the resistance to tensile stress, and to be embedded in the slab concrete 170 By doing so, the synthesis of the I-type assembly girder 100 to the slab concrete 170 is more firmly suppressed to increase the rigidity of the parent cement and cracking of the slab concrete 170.

The T-type buried steel 140 is composed of an upper plate 141 parallel to the upper flange 110 and an abdomen plate 142 connecting between the upper plate 141 and the upper flange 110 of the I-type assembly girder 100. .

The abdominal plate 142 is configured by arranging a plurality of abdominal pieces 142a having a trapezoidal shape of a lower light image as a whole on the lower surface of the upper plate 141.

Therefore, the V-shaped slit 144 is formed between the abdominal pieces 142a adjacent to each other so that the reinforcement of the slab reinforcement 171 can be made.

In addition, a bar opening 143 is also formed on the upper part of the abdominal piece 142a, the bar opening 143 is also a space in which the slab reinforcing bar 171 is placed, or the connection reinforcing bar 145 to be described later fixedly installed Functions as

At this time, the lower end of the rectangular opening 143 may function as a cradle of the slab reinforcing bar 171, thereby eliminating the installation of the reinforcement spacer.

As such, the rectangular openings 143 and the V-shaped slits 144 provided in the T-type buried steel 140 facilitate the reinforcement of the slab reinforcing bars 171 as described above, on the other hand, the slab concrete 170 By placing the hardened concrete when pouring the T-type buried steel 140 acts as an anchor body of the I-type assembly girder 100 to the slab concrete 170, the greater synthetic force between them To be possible.

The T-type buried steel 140 is installed in parallel on both sides of the upper flange 110 of the I-type assembly girder 100.

At this time, as shown in Figure 5 through the square opening 143 provided in each of the abdominal piece (142a) of the T-shaped buried steel 140 facing each other and fixedly installed connecting bar 145 protruding to both sides By doing so, the installation work of the T-type buried steel 140 for the I-type assembly girder 100 and the workability for reinforcement of the site is improved.

For example, the upper part of the abdominal piece 142a is independently installed on the upper plate 141 by welding, and an inadvertent impact is applied during the working process, so that the installed state of the abdominal piece 142a may be poor.

In this case, the connecting reinforcing bars 145 integrally integrate each of the abdominal pieces 142a, and further structurally integrate the entire pair of T-shaped buried steel 140, so that each of the abdominal pieces 142a is affected by an external impact. The attachment state is not easily deformed.

In addition, when reinforcing the slab reinforcement 171 in the field bar without being required to insert the slab reinforcement 171 in the rectangular opening 143 of the narrow space bar can be completed by the simple reinforcement with the connecting reinforcement bar 145 In addition, reinforcement work of rebar becomes easier.

The lower flange 130 of the I-type assembly girder 100 has a larger width than the upper flange 110 to sufficiently correspond to the tension portion of the positive moment generated in the span portion (L2).

However, this wide lower flange 130 has a possibility of local buckling when the bending deformation occurs. Therefore, in the present invention, a pair of closed reinforcement 131 is provided on both sides of the web 120 of the I-type assembly girder 100.

The closed reinforcement 131 is to be installed for the entire length of the I-type assembly girder 100, by configuring in the shape of the a-section so that the closing space 132 can be formed on the upper surface of the lower flange (130).

Due to the closed reinforcement 131, the buckling strength of the lower flange 130 is increased, and with this, the installation of reinforced concrete for double synthesis of the I-type assembly girder 100 is possible.

Placement of the reinforcement of the reinforcing bar 132a and the concrete 132b to the closing space 132 is made only to the point portion L1 where the parent moment occurs so that the weight of the plate girder is not unnecessarily increased. To improve the strength of the shear stress in the part (L1).

Between the closed reinforcement 131 and the lower flange 130, the triangular reinforcement piece 133 is continuously installed at regular intervals.

Horizontal beams 150 are installed between two adjacent I-type assembly girder 100. The cross beam 150 not only distributes the load acting on each I-shaped assembly beam, but also integrates each I-type assembly girder 100 so that they can be operated integrally.

The horizontal beam 150 is attached to the upper end of the web 120 to be in close contact with the upper flange 110 of the I-type assembly girder 100 to support the slab. Therefore, the cross beam 150 is spaced apart from the upper surface of the closed reinforcement 131.

Meanwhile, the web 120 of the type I assembly girder 100 is made of a thin steel plate. Therefore, when the cross beam 150 is located on only one side as described above, there is a possibility that deformation such as local buckling occurs in the web 120 by the load acting through the cross beam 150.

Therefore, in the present invention, by installing the half vertical stiffener 121 between the lower surface of the cross beam 150 and the upper surface of the closed stiffener 131 to prevent the deformation occurs in the web 120 located below the cross beam 150. can do.

A portion of the web 120 of the I-type assembly girder 100 in which the horizontal beam 150 is not installed may be provided with a vertical reinforcement 122 with respect to the entire surface between the lower flange 130 and the upper surface of the closed reinforcement 131.

In addition, in another embodiment of the present invention, as shown in Figure 6, the inclined reinforcing bar 160 for inclinedly connecting the lower surface of the horizontal beam 150 and the closed reinforcement 131 is further installed.

The inclined reinforcing bar 160 is installed in a site where stress is largely applied, for example, a point L1 or a section in which the width of the cross beam 150 is increased, and serves as an elastic support point for the cross beam 150. Reduce the magnitude of the cross-sectional force acting on 150.

In addition, a portion of the load acting on the cross beam 150 is directly transmitted to the closed reinforcement 131 without passing through the web 120, thereby reducing the shear load to be burdened by the web 120 made of a thin steel sheet.

Due to the configuration of the inclined reinforcement 160, it is possible to reduce the size of the cross beam 150 and the half vertical stiffener 121, and further reduce the thickness of the web 120, as shown in Figure 6 If the joint is to reduce the number of the joint plate 151 and the fastening bolt 152 to enable the construction of an economic plate girder bridge (PB).

The present invention has been described in detail above with reference to specific embodiments, but the above embodiments are merely examples for easy understanding of the present invention, so that those skilled in the art have the scope of the technical idea of the present invention. It will be apparent that various modifications can be made within the scope of the invention. Therefore, such modifications will be described within the scope of the present invention as described in the claims.

100; I type assembly girder 110; Upper flange
111; Shear connector 120; Web
121; Half Vertical Reinforcements 122; Vertical Reinforcements
130; Lower flange 131; Waste Reinforcement
132; Closed space 132a; rebar
132b; Concrete 133; Triangle reinforcement
140; T-filled steel 141; Tops
142; Abdominal plate 142a; Abdomen
143; Square opening 144; V-shaped Slit
145; Rebar 150; Sidewalk
151; Joint plate 152; Tightening Bolt
160; Inclined reinforcement 170; Slab concrete
171; Slab reinforced PB; Plate girder bridge
P; Pier L1; Branch office
L2; Span section

Claims (6)

In the plate girder bridge using the I-type assembly girder 100 manufactured by assembling the upper flange 110, the lower flange 130 and the web 120 cut with a steel sheet,
The upper flange 110 of the I-type assembly girder 100 is provided with a shear connector 111 for synthesis with the slab concrete 170, the point portion (L1) that the parent is generated of the upper flange 110 It is further provided with a pair of T-type buried steel 140 which is located in parallel on both sides and embedded in the slab concrete 170,
The lower flange 130 of the I-type assembly girder 100 has a width larger than that of the upper flange 110, and a pair of closed reinforcement materials 131 are provided on both sides of the web 120 to provide a lower flange 130. Closing space 132 is formed on the upper surface of the), the reinforcing bar 132a and concrete 132b are placed in the closed space 132 in the point portion (L1) where the parent moment occurs,
The T-type buried steel 140 is composed of an upper plate 141 and an abdominal plate 142 in which a plurality of abdominal pieces 142a are continuously disposed on a lower surface of the upper plate 141.
The abdominal piece 142a has a trapezoidal shape of a lower light beam as a whole, and a V-shaped slit 144 is formed between adjacent abdominal pieces 142a, and a rectangular opening 143 is formed on the upper part of the abdominal piece 142a. The double composite plate girder bridge. delete The method of claim 1,
The pair of T-type buried steel 140 is integrated by a connecting reinforcing bar 145, the connecting reinforcing bar 145 is a double composite plate girder bridge, characterized in that the joint with the slab reinforcing bar (171) The method of claim 1,
A horizontal beam 150 is installed between two adjacent I-type assembly girder 100, and a half vertical stiffener 121 is installed between the lower surface of the horizontal beam 150 and the upper surface of the closed reinforcement 131,
I-shaped assembly girder 100 is not installed horizontal beam 150 is a double composite plate girder bridge, characterized in that the vertical reinforcement 122 is installed between the upper flange 110 and the top surface closed stiffener 131. The method of claim 4, wherein
The double composite plate girder bridge, characterized in that the inclined reinforcement rod 160 is further installed on the lower surface of the horizontal beam 150 installed in the point portion (L1) of the horizontal beam 150 inclined to both sides. The method of claim 1,
Double composite plate girder bridge, characterized in that between the closed reinforcement 131 and the lower flange 130, the triangular reinforcement piece 133 is continuously installed at a predetermined interval.

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