KR20160148416A - Steel-Concrete Composite Rahmen Bridge - Google Patents

Abstract

The present invention relates to a steel-concrete composite Rahmen bridge having a stationary wall-steel composite girder connection structure which provides convenience of installation by applying a simple mounting method to a connection of a wall-steel composite girder in a steel-concrete composite Rahmen bridge, and is capable of improving structural safety of a connection portion by performing a gap filling connection and a moment connection immediately after the installation.

Description

Steel-Concrete Composite Rahmen Bridge with Reinforced Walls-Steel Composite Girder Bridges>

The present invention relates to a steel composite rayman bridge having a connecting wall-steel composite girder connection structure, and more particularly, to a steel-concrete composite rayman bridge having a simple installation method for connection between a wall and a steel composite girder Steel composite girder connection structure capable of improving the structural stability of a joint by providing a hypothetical convenience and performing a fluid connection and a moment connection immediately after a hypothesis.

Conventional Steel Composite Raman Bridge Bridges - Steel Composite Girder Bridging Method is a moment connection method that connects the upper and lower flanges of the steel type to be connected to each other by using a joint plate which is a connecting method of a conventional steel bridge and a high tension bolt.

This type of connection is commonly used because of its structural safety. However, since it requires a foundation foundation to secure the stability of the temporary vent and the temporary vent to support the steel composite girder until the connection is completed, There is a problem that the construction period is increased.

For small bridges, there is a case where a crane hangs on a girder in a state where a composite girder is suspended without a temporary vent, but this is a negligence on the safety of the operator.

In addition, in connecting the steel composite girder to the wall made of reinforced concrete, the connecting steel is used as the intermediate member and the steel composite girder is to be constructed in a way that it is sandwiched between the connecting steel types installed on the wall, In case of errors in the production length error or installation position of the wall, it is necessary to compensate for the increase or decrease of the length of the steel composite girder or connection steel.

Therefore, there is a problem that the precision work is required, the workability is poor, and the construction cost and the construction period are increased due to the correction work due to the construction error. Such a construction error is a large-scale operation, not a lathe, and it is necessarily inevitable because it is susceptible to drying shrinkage and temperature changes due to the material properties of concrete and steel.

In recent years, new composite steel framing bridges have been developed that complement the problems of conventional steel composite bridges and increase the convenience of the hypothesis and do not require correction work errors.

Such a composite steel girder bridges can be constructed easily by installing a steel girder with a low height on the wall and by laying a steel composite girder on the girder.

In addition, even if a construction error occurs depending on the length and the position, there is no difficulty in setting up, and the connecting part is integrated with the right-angled concrete, so that appearance problems are not caused.

However, the two-way connection between the wall and the support stiffness is a negative joint of the construction, and a cold joint is formed immediately adjacent to the reinforcement joint using the coupler. The support of the unrestrained steel composite girder is made of steel There is a structural problem in that cracks are generated outside the wall of the common wall.

Fig. 1 is a view showing a concrete composite girder bridge in a conventional steel composite rammen bridge and a moment connection method as a connection method of a wall-steel composite girder.

1, before the steel composite girder 84 is integrated with the connecting rigid 83, a hypothetical vent 89 for supporting the steel composite girder 84 is provided, and the stability of the hypothetical vent 89 is ensured A hypothetical foundation 88 is installed. Since the steel composite girder 84 must be sandwiched by the crane C between the connecting steel 83 provided on both the walls 82 so as to prevent the steel composite girder 84 or the connecting steel 83 It is necessary to correct the length of the steel composite girder 84 or the connecting rigid 83 by increasing or decreasing the length of the steel composite girder 84 or the installation position error of the wall 82. Therefore, the utilization of the mold space due to the hypothetical equipment is inferior, the construction cost and the construction period due to the installation and demolition of the temporary equipment are increased, and the construction error in the large civil engineering works is an inevitable overcoming problem. There is a problem that it takes time.

FIG. 2A is a vertical cross-sectional view of a conventional simple framed steel composite framing, and FIG.

2A and 2B, a support rod 86 having a low height is disposed on the wall 82, and a pad 87 for permitting rotational displacement of the steel composite girder 84, It is assumed that it is mounted in a simple mounting manner by placing it on the installed supporting steel 86. This hypothesis and the connection method are convenient for the hypothesis. However, since the connection part between the supporting stiffness 86 and the wall 82 and the connection part such as the wall reinforcement 821, the coupler reinforcing part and the steel part are overlapped, There is a structural problem in that cracks are generated in the substrate.

As a background technique of the present invention, there is a patent registration No. 1007708 entitled "Semi-hinge Ramen bridge" (patent document 1). In the background art, "a foundation 1 to be laid on a ground, a wall 2 to be installed with the concrete section being separated on the foundation 1, (3) between the wall (2) and the foundation (1) so that the wall (2) resists conduction of the wall (2) (2), a top beam (7) connected to the connecting rigid body (4), a covering concrete (5) placed to cover the connecting beam (7) 8). ≪ / RTI > We propose a semi-hinged ramen bridge.

However, since the above-mentioned background technique also requires construction of a temporary vent and a foundation foundation, it must be installed in a manner that the steel composite girder is sandwiched between the connection steel structures installed on both walls precisely. Therefore, There is a problem that a correction operation such as increasing or decreasing the length of the steel composite girder or the connecting rigid is required.

Patent Registration No. 1007708 "Semi-Hinge Ramen Bridge"

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to solve the above-mentioned problems, and to provide a method and apparatus for improving the structural stability of a connecting portion by performing a simple mounting method, And to provide a steel composite ramen bridge having a girder connection structure.

The present invention relates to a floor structure comprising a foundation provided on a ground, a wall provided on the foundation, a vertical part connected to the upper end of the wall and vertically formed, and a horizontal part having an H- In the case of a bridging bridges consisting of a steel composite girder connected to a connection rigid and a connecting rigid and having a H-shaped cross section and a concrete formed at the lower part of the steel girder, the girder rigid is connected to the connecting rigid, A horizontal member formed horizontally, and a vertical member formed at a central portion of the horizontal member, the horizontal member having a substantially U-shaped cross- A first vertical member and a second vertical member formed at a lower portion and a vertical lower portion at one end of the horizontal member, Wherein the joining reinforcement member composed of the joining portion vertical member is coupled such that each of the horizontal member and the upper vertical member has the b-shaped engaging portion and the engaging portion vertical member at the corners of the a- Shaped composite bridge girder bridge structure, wherein the bridge bridge bridge is fixedly coupled to the upper portion of the c-shaped bridge bridge.

In addition, the vertical part of the connection rigid structure is spaced apart from the wall reinforcing bars protruding upward from the upper end of the wall, so as to provide a steel composite ramp bridge having a connecting wall-steel composite girder connection structure.

Also, in the joint reinforcing member, an additional vertical reinforcement member is formed in the vertical direction at the opposite end of the vertical member of the joining portion of the horizontal member, to provide a steel composite razor bridge having a connecting wall-steel composite girder connection structure.

In addition, the steel composite girder is formed to have a certain length shorter than the interval between the connecting steel and the connecting steel so as to have a constant spacing at the upper part of the connecting steel, and a combination of the connecting reinforcing member of the connecting steel- And the filler plates are inserted into the grooves of the adjacent joint reinforcement members and are coupled to each other.

The filling plate is composed of a plate-shaped baffle plate formed vertically with a predetermined size, a joint portion composed of a vertical lower portion at the center of the lower end portion of the baffle plate, and a flange plate formed at the lower end portion of the joint portion with the same width as the baffle plate Steel composite girder bridges with steel girder bridges.

The steel composite rammen bridge having the connecting wall-steel composite girder connection structure of the present invention is constructed by applying a simple installation method in which the " a " end of the steel composite girder is placed on the " It is possible to improve the convenience of construction since precision is not required when the steel composite girder is installed between the connecting steel plates provided on both sides by forming a stream in the connecting part with a smaller production length, It is possible to prevent lateral movement of connecting steel or steel composite girder by fastening with vertical bolt which is high tension bolt together with vertical reinforcing plate of steel type vertical reinforcing plate and steel composite girder and to share shear force transmitted from steel composite girder to connecting steel type It is possible to reduce the safety of the baffle plate and the vertical stiffener and the horizontal stiffener, The structural safety is improved by using the vertical bolt and the joint plate, and it is very useful to improve the safety against cracks because the structural weakness is dispersed because the steel connection part and the hetero connection part and the reinforcing steel part are separated from each other. .

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate exemplary embodiments of the invention and, together with the description, serve to explain the principles of the invention, Shall not be construed as limiting.
Fig. 1 is a view showing a concrete composite girder bridge in a conventional steel composite rammen bridge and a moment connection method as a connection method of a wall-steel composite girder.
FIG. 2A is a vertical cross-sectional view of a conventional simple framed steel composite framing, and FIG.
Fig. 3 is a hypothetical view showing the installation of a steel composite girder in a steel composite ramen bridge having a connecting wall-steel composite girder connecting structure according to the present invention.
4 is a side view and an exploded perspective view of a connecting portion of a joining reinforcing member of a steel composite rammen bridge having a connecting wall-steel composite girder connecting structure of the present invention.
Fig. 5 is a view showing a filling plate of a steel composite ramen bridge having a connecting wall-steel composite girder connecting structure according to the present invention.
FIG. 6A is a side view showing load-resistance in the case of a composite synthetic ramen bridge having a connecting wall-steel composite girder connecting structure according to the present invention without a filler plate. FIG.
6B is a cross-sectional view taken along line AA of FIG. 6A.
7 is a side view showing the tilting of the wall in a ramen bridge in which a rotary displacement receiving device is formed at the lower end of the wall without a filler plate.
8A is a view showing a load-resistance diagram in a steel composite raymond bridge having a connecting wall-steel composite girder connecting structure of the present invention.
8B is a cross-sectional view taken along line BB of FIG. 8A.
Fig. 9 is a view showing details of connection of a right-angled portion of a steel composite ramen bridge having a connecting wall-steel composite girder connecting structure according to the present invention.
10 is a view showing another embodiment of a filler plate applied to a steel composite raymond bridge having a connecting wall-steel composite girder connecting structure of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto.

Hereinafter, the technical structure of the present invention will be described in detail with reference to the preferred embodiments.

The present invention applies a simple mounting method to the connection of walls and steel composite girders in steel-concrete composite rafter bridges to provide the convenience of hypothesis, Steel composite girder connection structure capable of improving structural safety.

Fig. 3 is a hypothetical view showing the installation of a steel composite girder in a steel composite ramen bridge having a connecting wall-steel composite girder connecting structure according to the present invention.

As shown in FIG. 3, the composite synthetic raman bridge having the grounded-steel composite girder connection structure according to the present invention has the foundation 1 installed on the ground, the wall 2 installed on the foundation, And a steel composite girder 4 having an end connected to the connecting steel 3, as shown in Fig.

Particularly, the connecting rigid body 3 is composed of a vertical part 31 connected to the upper end part of the wall body 2 and a horizontal part 32 horizontally connected to the upper part of the vertical part 31 and having an H- And the steel composite girder 4 is connected to the connecting rigid 3 and the concrete 42 is formed by combining the lower portion of the girder 41 having the H-shaped section.

The horizontal portion 32 and the girder 41 of the steel composite girder 4 are configured so as to have an H-shaped cross section composed of upper and lower flanges and a web vertically connecting the widthwise central portions of the upper and lower flanges And have cross-sections of the same size and shape, thereby facilitating mutual connection.

In the present invention, the upper part of the outer end of the horizontal part 32 of the connecting rigid 3 is cut into a b shape to form a b-shaped engaging part 321 and the outer end of the girder 41 of the steel composite girder 4 So that the a-shaped coupling portion 411 of the steel composite girder 4 is mounted on the upper portion of the b-shaped coupling portion 321 of the connecting rigid 3 so as to form the a-shaped coupling portion 411 Lt; / RTI > In addition, the coupling reinforcement member 5 is formed on the a-shaped coupling portion 321 and the a-shaped coupling portion 411, respectively.

The steel composite rammen bridge having the connecting wall-steel composite girder connecting structure of the present invention is connected to the connecting steel bar 3 to apply the simple mounting method in which the steel composite girder 4 is placed on the connecting steel 3 connected to the upper end of the wall 2 Forming an end portion at the upper end of the rigid die 3 so as to have a bend-like engaging portion 321 and forming a a-shaped engaging portion 411 at both ends of the steel composite girder 4.

4 is a side view and an exploded perspective view of a connecting portion of a joining reinforcing member of a steel composite rammen bridge having a connecting wall-steel composite girder connecting structure of the present invention.

4A, the coupling reinforcement member 5 includes a horizontal member 51 formed horizontally and a horizontal member 51 formed horizontally, A first vertical member 52 and a second vertical member 53 formed vertically upper and lower at a central portion of the member 51 and an engaging portion vertical member 53 formed at a vertical lower portion at one end of the horizontal member 51 54).

4A and 4B, the coupling reinforcing member 5 has a coupling portion vertical member 54 at a b-shaped coupling portion 321 formed by the horizontal member 51 and the first vertical member 52, Respectively, and are configured on both sides of the web of the horizontal portion 32, respectively.

The c-shaped coupling portion 321 is formed by a vertical plane and a horizontal plane, because it means a portion cut in the form of a letter. Therefore, it is preferable that the horizontal member 51 of the joint reinforcing member 5 be coupled with the horizontal plane of the b-shaped coupling portion 321, and the length thereof is about twice the horizontal plane of the b-shaped coupling portion 321 .

It is preferable that the first vertical member 52 is configured so as to coincide with the vertical surface of the cemented portion 321 and the length thereof is located to a position spaced a certain distance from the lower surface of the upper flange of the horizontal portion 32 And the lower end of the second vertical member 53 is also located to a position spaced apart from the upper surface of the lower flange by a predetermined distance so that the connection part between the horizontal part 32 of the connecting rigid 3 and the girder- 7 can be ensured, and the installation interval at this time is preferably 100 mm or more.

It is preferable that the joining portion vertical member 54 is formed in the vertical lower portion at the outer end of the horizontal member 51 and is formed to have the same length as the second vertical member 53.

The connection of the coupling member 4 to the a-shaped coupling portion 411 of the coupling member 5 is symmetrical with the coupling direction of the coupling member 321. The horizontal member 51 and the first vertical member 52 Are formed on the a-shaped engaging portion 411 and the engaging portion vertical members 54 are respectively directed outward.

Fig. 5 is a view showing a filling plate of a steel composite ramen bridge having a connecting wall-steel composite girder connecting structure according to the present invention.

5, the steel composite girder 4 is formed so as to have a constant length and a length shorter than the interval between the connecting rigid 3 and the connecting rigid 3 so as to have an interval d at constant intervals at the upper portion of the connecting rigid 3, And such an inflow space d is formed between the joint reinforcing member 5 of the cemented joint portion 321 of the connecting rigid 3 and the joint reinforcing member 5 of the a-shaped joint portion 411 of the steel composite girder 4 And the filler plate 6 may be inserted into the flow field d so as to be coupled to each other.

That is to say, a flow length d is formed at the connecting portion between the horizontal portion 32 of the connecting steel 3 and the girder 41 of the steel composite girder 4 with a manufacturing length shorter than the installation length of the steel composite girder 4 Precision is not required when the steel composite girder 4 is installed between the connecting rigid molds 3 provided on both sides so that the convenience of the construction can be improved and the filling plate 6 is installed in the connecting portion flow d The vertical member 54 and the first vertical member 52 of the first vertical member 52 and the vertical member 54 of the connecting rigid 3 and the joining portion vertical member 54 of the steel composite girder 4 are fixed to the fill plate 6 (3) or the steel composite girder (4) is prevented from being horizontally moved, and the shear force transmitted from the steel composite girder (4) to the connecting steel mold (3) is shared by the horizontal bolt And the upper and lower flanges of the connecting rigid body 3 and the steel composite girder 4 are fastened by using a vertical bolt as a high tension bolt and a joint plate 7, So that integrity is improved.

The slope provided for the convenience of the construction of the composite girder has a detrimental effect on the safety and stability of the connection after the hypothesis is completed. Therefore, it is possible to prevent the horizontal movement of the connecting steel or composite girder by fixing the slag with the filling plate and horizontal bolt, and to share the shear force transmitted from the steel composite girder to the connecting steel, thereby reducing the vertical load and vertical stiffener There is an effect that can be.

The joint plate 7 connecting the flange of the horizontal section 32 of the connecting rigid 3 and the flange of the girder section 41 of the steel composite girder 4 and the vertical bolt of high tension bolt, .

The filling plate 6 has the same width and length as the first vertical member 52 and the coupling vertical member 54 of the joint reinforcing member 5 and has a thickness The filling plate 6 is inserted into the flow path d and then fastened together with the coupling reinforcing member 5 formed on the right and left sides of the filling plate 6 using horizontal bolts. As a result, the rigidity of the connecting portion is increased and the stability is increased.

FIG. 6A is a side view showing a load-resistance diagram in the case of a steel composite raymond bridge having a connecting wall-steel composite girder connecting structure according to the present invention without a filler, FIG. 6B is a sectional view taken along the line AA in FIG. Is a side view showing the tilting of a wall in a ramen bridge in which a rotating displacement receiving device is formed at the bottom of the wall without a filler plate.

When the filler plate 6 is not installed in the flow field d in the steel composite rammen bridge having the putting wall-steel composite girder connecting structure of the present invention, the horizontal portion 32 of the connecting rigid 3 and the steel Since the shear resistance area of the bending plate 41 of the composite girder 4 corresponds to half of the height of the bending plate, there is a problem that a greater amount of reinforcement is required because the bending plate is subjected to high stress concentration at the cut end edge.

7, in the case of a ramen bridge having a rotary displacement receiving device installed at the lower end of the wall 2, the connecting rigid 3 or the steel composite girder 4 can be moved horizontally by the disturbance of the connecting portion, Therefore, when the steel composite girder 4 is formed so as to form the distillate d, the provision of the filler plate 6 in the distillate d is effective in reducing the stiffener and securing the stability of the wall.

 8A is a view showing a load-resistance diagram in a steel composite raymond bridge having a connecting wall-steel composite girder connecting structure according to the present invention, and FIG. 8B is a sectional view taken along line B-B of FIG. 8A.

8, in the wall-to-steel composite girder connecting apparatus according to the present invention, the horizontal reinforcing member 3 is joined to the horizontal part 32 of the connecting rigid 3 and the girder 41 of the steel composite girder 4, The shear resistance area of the baffle plate with respect to the girder load corresponds to the total height of the baffle plate, so that the concentration of stress acting on the edges is relaxed and the number and size of the stiffeners can be reduced There is an effect.

Fig. 9 is a view showing details of connection of a right-angled portion of a steel composite ramen bridge having a connecting wall-steel composite girder connecting structure according to the present invention.

The steel composite ramp bridge having the connecting wall-steel composite girder connecting structure of the present invention comprises a horizontal portion 32 for horizontal steel connection at the upper end of the vertical portion 31 of the connecting steel 3, 3) The lower end portion of the vertical portion 31 is configured to be spaced apart from the wall reinforcing bar 21 protruding upward from the upper end of the wall body 2 so that the reinforcing ribs of the right-angled portion are spaced apart from each other, By separating structural vulnerabilities from each other, it is possible to improve safety against cracks.

10 is a view showing another embodiment of a filler plate applied to a steel composite raymond bridge having a connecting wall-steel composite girder connecting structure of the present invention.

As shown in FIG. 10, the filler plate 6 can be formed as a workpiece capable of filling all the distances of the connecting portion, thereby further improving the bonding force.

That is, the filling plate 6 has a vertically formed plate-shaped bobbin plate 61 having a predetermined size, a joint portion 62 formed of a vertical lower portion at the central portion of the lower end of the bumper plate 61, And a flange plate 63 formed at the lower end at the same width as the bend plate 61 so that the flange plate 63 is connected to the horizontal portion 32 of the connecting rigid 3 and the girder- 41, and the bumper plate 61 is arranged between the joining reinforcing members 5. [0050] At this time, the joint portion 62 penetrates the joint plate 7 to both sides and can be easily engaged.

The steel synthetic rammen bridge having the above-mentioned connecting type wall-steel composite girder connecting structure of the present invention adopts a simple installation method in which the " a " end of the steel composite girder is placed on the " It is possible to improve the convenience of construction since precision is not required when the steel composite girder is installed between the connecting steel plates provided on both sides.

It is also possible to prevent the horizontal movement of the connecting steel or composite girder by fastening it with horizontal bolts of high tension bolts together with the vertical reinforcing plates of the connecting steel and the vertical strengthening plates of the steel composite girder after installing the filler plate By sharing the shear force transmitted from the composite girder to the connecting steel, the safety of the stiffener and the vertical stiffener and the horizontal stiffener can be saved.

In addition, the structural safety is improved by fastening the upper and lower flanges of the connecting steel girder and the steel composite girder using the vertical bolt and the seam plate, which are high tension bolts, and the structural weakness is dispersed because the steel connecting portion and the hetero connecting portion and the steel reinforcing layer are separated from each other. There is a very useful effect that can improve the safety against cracking.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the above teachings. will be. The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

1: Foundation
2: Wall
21: Wall Reinforcement
3: Connection rigid
31:
32:
4: Steel composite girder
41: Girder steel type
42: Concrete
5:
51: Horizontal member
52: first vertical member
53: second vertical member
54: engaging portion vertical member
6: Filled plate
7: joint plate

Claims (4)

A vertical portion 31 vertically formed to be coupled to an upper end portion of the wall body 2 and a vertical portion 31 connected to an upper end portion of the wall portion 2 and having an H- And a horizontal portion 32 horizontally connected to the horizontal portion 32. The concrete 42 is attached to the lower portion of the girder 41 having an H-shaped cross section connected to the connecting rigid 3, In a ramming bridge composed of a steel composite girder (4) in which a steel girder (41) is connected to a connecting steel girder (3)
The horizontal part 32 of the connecting rigid 3 is formed by bending the upper part of the outer end into a b-shaped engaging part 321 and the lower part of the outer end of the girder 41 of the steel composite girder 4 A-shaped engaging portion 411 is formed,
A first vertical member 52 and a second vertical member 53 formed vertically upper and lower at a central portion of the horizontal member 51 and a second vertical member 53 formed at one side of the horizontal member 51 And an engaging portion vertical member (54) formed at an end portion of the engaging member (5)
Shaped coupling portion 321 in which the horizontal member 51 and the first vertical member 52 are formed and a coupling vertical member 54 in the a-shaped coupling portion 411 are formed so as to face outward, The a-shaped engaging portion 411 of the connecting rod 4 is engaged with the upper portion of the c-shaped engaging portion 321 of the connecting rigid 3,
The steel composite girder 4 is formed so as to have a constant length shorter than the interval between the connecting rigid 3 and the connecting rigid 3 so as to have a gap d at a constant interval at the upper portion of the connecting rigid 3, The filler plate 6 is inserted into the gap d of the joint reinforcing member 5 of the cemented portion 321 of the steel composite girder 4 and the joint reinforcing member 5 of the a- Wherein the steel composite girder connection structure is characterized in that the reinforced concrete bridge girder connection structure is formed of a steel composite girder bridge structure. The method according to claim 1,
The vertical part 31 of the connecting rigid 3 is spaced apart from the wall reinforcing bar 21 protruding upward from the upper end of the wall 2. The reinforcing wall- Synthetic ramen bridge. The method according to claim 1,
The joining reinforcing member 5 of the cemented coupling portion 321 of the connecting rigid 3 and the joining reinforcing member 5 of the a-shaped coupling portion 411 of the steel composite girder 4 and the filler plate 6 are horizontally bolted Reinforced composite girder connection structure, characterized in that the reinforcing members are mutually combined. The method according to claim 1,
The filling plate 6 has a vertically formed plate-shaped bobbin plate 61 having a predetermined size, a joint 62 having a vertical lower portion at the center of the lower end of the bumper plate 61, And a flange plate (63) formed to have the same width as the bend plate (61).

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