KR100945050B1 - Steel concrete tube girder - Google Patents

Abstract

PURPOSE: A steel pipe composite girder is provided to reduce manufacturing costs by easily manufacturing in a construction site, and to easily construct a bridge. CONSTITUTION: A steel pipe composite girder is composed as follows. Two arc shaped members(110a,110b) are arranged left and right. Connection corners(120a,120b) of a vertical plate shape are formed by upward bending each bottom end of the arc shaped member. The connection corners are each other coupled by a connection unit(130) which comprises a bolt and a nut. Shield plates(132) are integrally fixed between the inner surface of the arc shaped members and the top end of the connection corners. A space formed by the shield plates and the arc shaped members are filled with concrete(150). Tendons(160) are inserted inside the concrete, and tensed. A cover(180) is integrally installed on the opened top of the arc shaped members.

Description

Steel Pipe Composite Girder {STEEL CONCRETE TUBE GIRDER}

The present invention relates to a steel pipe composite girder manufactured by synthesizing a steel pipe and concrete, and more specifically, bending the steel sheet to form an arc-shaped member, combining them integrally to form a circular cross section as a whole, and then forming concrete inside. It can be produced in the production site by introducing the tension force using the tension material to achieve a reduction in the production cost, and relates to a steel pipe composite girder that can be easily applied in the bridge site can be used to build a bridge.

In general, a box girder is generally used as a conventional technique for the girder of a bridge. Such a box-shaped girder is composed of a rectangular cylindrical shape by standing two vertical plates on both sides, and fixing flanges at the upper and lower ends thereof, respectively. Such box girders support the top plate of the bridge by increasing its width to support the top plate of the bridge alone, or by making several pieces of the width smaller.

On the other hand, inside the box girders to install a diaphragm consisting of a square plate to prevent deformation of the girders, neighboring box girders are connected to the beam to share the load evenly.

Another conventional technique is to have a cross-sectional structure of "I" shape with the abdomen and the upper and lower flanges, and then use the "I" shaped structures, which are thus braced each other vertically and horizontally, as bridge girders. There is a way.

However, such a conventional technique is to reattach vertical and horizontal stiffeners separately or to require separate bracing after welding the upper and lower flanges by welding, and thus, workability is very low and air There is a significant problem. In addition, because a large number of reinforcing members are required, there is a problem in that the consumption of the material is not economical.

In order to solve such a problem, a conventional steel pipe concrete composite girder 1 is shown as shown in FIG. 1.

Such a conventional girder 1 constitutes the frame 10 using a large diameter steel pipe, and internally forms the inner concrete 20 integrally with the upper side so as to occupy a part of the cross section of the frame 10, and the rest of the frame 10. Was to serve as a structural member by forming the reinforcement plate 32 of the "T" -shaped cross section into a space 30 mounted in a number of longitudinal directions.

The conventional steel pipe composite girder 1 as described above is a structure used to form the inner concrete 20 only in the upper portion, when a load acts on the structural steel pipe composite girder such a bending member, the tensile stress is applied to the lower portion Compression stress acts on the upper part, and in this case, the frame 10 resistant to the tensile stress is responsible for the tensile stress formed on the lower surface thereof. However, for the compressive stress acting on the upper side, since the steel pipe is relatively disadvantageous to the compressive stress, the inner concrete 20 of the upper part of the frame 10 is in charge of the compressive stress.

On the other hand, such a conventional steel pipe composite girder (1) is the self-weight is increased by the internal concrete 20 formed on the upper side is such a self-weight increase is limited, rather it is advantageous for vibration and noise.

In addition, when a live bridge is loaded with live traffic, the actual bridge is very fluctuated up and down. To prevent this, a certain weight must be secured. Conventional concrete bridges do not have this problem, but when the steel pipe is used because its own weight is not large, it should be designed in consideration of vibration.

However, such a conventional steel pipe composite girder (1) is advantageous in many aspects because it is easy to construct and can secure sufficient required strength of the structure, such a conventional steel pipe composite girder (1) is a simple large diameter integrated circular pipe There is a problem in that it is not practical in terms of cost to manufacture the frame 10 using.

The present invention has been made in order to solve the conventional problems as described above, the object is to form a circular member by bending the steel sheet, and to form a circular cross-section by combining them integrally, to form concrete therein, By introducing tension force using tension material, it can be easily manufactured at the production site or the site, which can reduce the production cost, and provide an improved steel pipe composite girder for easy application at the bridge site. have.

In order to achieve the above object, the present invention, the plate is bent to form a plurality of arc-shaped member, the lower end of the arc-shaped member is coupled to each other by a connecting means including a bolt and nut coupling or welding, the upper portion is A frame having an open arc cross section is formed, and a lower diaphragm is integrally fixed to the lower inner side of the frame, and a reinforcement including a stud is fixed to a space between the lower diaphragm and the frame, thereby integrally formed with internal concrete, The inner concrete is tensioned by inserting a tension member, and the open upper portion of the frame is connected by integrally mounting the cover. Through this, it can be easily manufactured at the production site, which can reduce the production cost, and can be easily assembled at the bridge site and used for building the bridge.

And the present invention preferably the cover is fixed to the upper side by side to the inner side of the frame to form a reinforcement comprising a stud on the upper side to the lower side side by side, the space between the cover and the upper plate is filled with concrete By forming the upper internal concrete integrally. Therefore, the present invention further reinforces structurally, and further reduces vibration and noise when live loads are transmitted from the outside.

In addition, the present invention preferably the tension member extends through the sheath tube located across the center of the space between the lower diaphragm and the frame, both ends are provided with a fixing device is introduced into the tension force. Through this, the lower side of the steel girder composite girder can be strengthened more structurally.

In order to achieve the above object, the present invention, the first member is formed by bending the plate to form a semi-circular cross-section, forming a connecting edge in the form of a horizontal plate on the upper side, the camber bent downward from both ends in the longitudinal direction Forming a first internal concrete therebetween by fixing a reinforcing material including a stud on the lower inner surface of the first member, and then fixing the lower diaphragm at a predetermined height upward from the reinforcing material; The plate is bent and formed, the upper surface of which is connected to a flat straight line to form an arc with the same diameter with respect to the first member, and forms a connecting plate in the form of a horizontal plate on the lower side, both ends from the center in the longitudinal direction thereof. A second member having a camber bent downward is formed, and a reinforcing material including a stud is fixed to an inner side of the second member, and then an upper plate is fixed below a predetermined interval to form a second internal concrete therebetween. and; Arranging the connecting edges of the first member upward and facing each other with the connecting edges of the second member downward; And it provides a steel pipe composite girder characterized in that the coupling edges of the first member and the second member is coupled through a connecting means including a bolt and nut coupling or welding. Therefore, it can be easily manufactured in the shop, it is possible to reduce the production cost, it can be easily assembled into a bridge.

According to the steel pipe composite girder of the present invention, the steel sheet is bent to form an arc-shaped member, which is integrally formed to form a circular cross section, and then internal concrete is formed at the bottom of the inner diameter of the steel pipe, and a tension force is introduced using a tension member. .

Therefore, through such a structure can be easily manufactured in the production site or on-site to achieve a reduction in the production cost, light weight and structurally robust to obtain an excellent effect that can be easily applied in the bridge site and easily perform the bridge construction.

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

Steel pipe composite girder 100 according to the present invention, as shown in Figure 2, has a plurality of arc-shaped member (110a) (110b) formed by bending the plate, such arc-shaped member (110a) (110b) are Bending portions 115a and 115b are formed at the bottom to form connection edges 120a and 120b.
That is, the sheet is bent to arrange two semicircular arc-shaped members 110a and 110b to the left and right, and the lower end of each of the arc-shaped members 110a and 110b is bent upward from the bent portions 115a and 115b. Connecting edges 120a and 120b in the form of vertical plates are formed.

The connecting edges 120a and 120b are integrally aligned and fixed to each other by the connecting means 130 including bolt and nut coupling or welding, thereby forming a frame 130 having an upper arc shape. And the lower plate 132 is fixed to the frame 130 of the arc-shaped cross-section in the lower portion of the inner, the stud or "T" in the space formed between the lower plate 132 and the frame 130 The reinforcing material 136 including the reinforcing plate of the mold cross section is fixed integrally by welding.
That is, the connection edges 120a and 120b in the form of vertical plates face each other, and the connection edges 120a and 120b are integrally coupled to each other by the connection means 130 including bolt and nut coupling or welding. Spaced between the upper edges 124a and 124b of each of the arc-shaped members 110a and 110b to form a frame 130 having an arc-shaped cross section with an open top,
The lower plate 132 of the horizontal plate shape is integrally fixed between the upper ends of the connecting edges 120a and 120b and the inner surfaces of the arc-shaped members 110a and 110b inside the frame 130. In the space formed by the lower portion of the 132 and the frame 130 is fixed to the reinforcement 136 including a reinforcement plate of the stud or "T" -shaped cross-section.

In addition, in the space in which the reinforcing material 136 is located, concrete is poured to form the internal concrete 150 integrally, and the tension material 160 is inserted into the interior of the internal concrete 150 to give a tension force.
That is, in the space formed by the lower portion of the lower plate 132 and the frame 130, the internal concrete 150 is poured so that the reinforcement 136 including the reinforcement plate of the stud or "T" -shaped cross section is embedded, The tension material is inserted therein.

This tension member 160 extends through the sheath tube 162 located across the center of the space between the lower diaphragm 132 and the frame 130, as shown in cross section in FIG. There is a fixing unit 170 is provided with a tension force. The fixing unit 170 is located in the fixing unit groove 172 formed in the front and rear edges of the arc-shaped members (110a) (110b) connected to each other is fixed without being exposed to the outside of the steel pipe composite girder (100).

In addition, the plurality of arc-shaped members 110a and 110b are integrally connected by integrally welding fixing the cover 180 made of an iron plate between the open upper portion of the frame 130, that is, the upper side of the connection edge.

The present invention is a steel pipe composite girder 100 of the present invention having such a structure is integrally manufactured at the production site through a process as shown in Figure 4a, is assembled in the field.

First, the plate is bent to provide a plurality of arc-shaped members 110a and 110b at the fabrication site, and the lower ends of the arc-shaped members 110a and 110b are connected to each other by connecting means 130 including bolt and nut coupling or welding. By integrally coupling with each other to produce a frame 130 of the arc-shaped cross section the upper corners (124a, 124b) is open.

Subsequently, the lower diaphragm 132 is integrally fixed to an inner lower portion of the frame 130 of the arc-shaped cross section, and a reinforcement plate having a stud or “T” -shaped cross section is provided in a space between the lower diaphragm 132 and the frame 130. Fixing the reinforcement 136 including a, and the sheath pipe 162 for the installation of the tension member 160 to a fixed height (using a spacer not shown).

At this time, the sheath tube 162 is preferably positioned to extend in the longitudinal direction of the frame 130 across the center of the space between the lower diaphragm 132 and the frame 130.

And the open top of the frame 130 is integrally mounted with a cover 180 to complete the steel structure.

In this case, the diaphragm 110 may be further provided on the lower diaphragms 132 on the inner surfaces of the arc members 110a and 110b to increase the rigidity according to the length extension.

In addition, the next filling the concrete into the space between the lower plate 132 and the frame 130 is formed integrally with the internal concrete 150, in this case, the filled concrete is non-concrete or small particle size It is made of concrete, and at the same time, made of concrete having a small particle size, the filling of concrete into the space can be easily performed, and the blockage of concrete caused by the reinforcing material 136 or the sheath pipe 162 is eliminated, thereby preventing material peeling in advance. do. In addition, after curing, shrinkage does not occur. At this time, the inner concrete 150 may be filled by forming a concrete inlet (hole) not shown in the lower partition 132.

In addition, after curing the concrete to form the inner concrete 150 in this way, the tension member 160 is inserted and tensioned through the sheath pipe 162 inserted into the inner concrete 150, the anchorage in both ends By fixing the 170 to the lower side of the steel pipe composite girder 100 according to the present invention is to be given a tension and more structurally reinforced.

Meanwhile, in the manufacturing process, the present invention is manufactured to have a different cross-sectional structure and is reinforced more structurally. The cover 180 includes a reinforcement plate 186 including a stud or a "T" -shaped cross-section on an upper surface thereof at a lower side thereof. The upper plate 190 is formed side by side to the inner side of the frame 130, and the space between the cover 180 and the upper plate 190 is filled with concrete to fill the upper inner concrete (150a) It is a structure formed integrally. In addition, the upper inner concrete 150a may be filled by forming a concrete injection hole (hole) not shown in the cover 180.

That is, by forming another upper inner concrete 150a on the upper side of the arc-shaped members 110a and 110b separately from the inner concrete 150 formed in the space between the lower diaphragm 132 and the frame 130, To be reinforced.

Therefore, the steel pipe composite girder 100 of the present invention can be further structurally reinforced through such a reinforcing structure, and when the live load is transmitted from the outside, vibration and noise can be further reduced.

Such a manufacturing process is illustrated in FIG. 4B.

First, the plate is bent to provide a plurality of arc-shaped members 110a and 110b at the fabrication site, and the lower ends of the arc-shaped members 110a and 110b are connected to each other by connecting means 130 including bolt and nut coupling or welding. Integral to each other to produce a frame 130 of the arc-shaped cross section is open.

Then, the lower diaphragm 132 is integrally fixed to the inner lower portion of the frame 130 of the arc-shaped cross section, and a reinforcement plate of a stud or “T” -shaped cross section is provided in the space between the lower diaphragm 132 and the frame 130. The reinforcing material 136 is fixed, and the sheath pipe 162 for the installation of the tension material 160 is fixed to a predetermined height.

In addition, the open upper portion of the frame 130 is integrally mounted with the cover 180, the upper plate formed with a reinforcement 186 including a stud or a "T" shaped cross-section reinforcement plate on the upper side to the lower side ( 190 is fixed to the inner side of the frame 130 side by side to complete the iron structure.

Next, the concrete is filled into the space between the lower diaphragm 132 and the frame 130 and the space between the cover 180 and the upper diaphragm 190 so that the internal concrete 150 and 150a are integrated. To be formed.

In addition, after such curing of the internal concrete 150 is made, the tension member 160 is tense through the sheath pipe 162 inserted into the lower inner concrete 150 to tension the anchorage 170 at both ends thereof. Complete by fixing.

In this case, the sheath pipe 162 and the tension member 160 may be installed in the inner concrete 150a of the space between the cover 180 and the upper diaphragm 190 to introduce a tension force. This is because it is very useful when the steel composite girder is set at the position where the bending parent moment occurs.

5 shows a steel pipe composite girder 200 according to a modification of the present invention.

In the modified structure of the present invention, instead of installing the tension member 160, a camber is provided to the steel structure to more effectively resist the load applied from the top.

The steel pipe composite girder 200 according to the modified example of the present invention includes first and second members 210a and 210b having a semicircular cross section by bending a sheet material, and the first and second members 210a. The connecting edges 220a and 220b of the 210b are made up and down the middle.

That is, the first member 210a forms a connecting edge 220a toward the upper side, and forms a camber that is bent downward from both ends from the center in the longitudinal direction, and below the inner surface of the first member 210a. After fixing the reinforcement 236 including the stud or the reinforcement plate of the "T" -shaped cross-section, and then fixed the lower diaphragm 232 to a certain height to form a first internal concrete (250a) therebetween.
That is, the arc-shaped first formed by forming a connecting plate (220a) in the form of a horizontal plate bent horizontally bent to the upper side by bending the plate and horizontally bent to both upper sides, and formed a camber bent downward from the center in the longitudinal direction Forms a member 210a,
A reinforcing member 236 including a reinforcing plate having a stud or a “T” shaped cross section is fixed to a lower inner surface of the first member 210a, and then a lower plate 232 having a horizontal plate shape upward from the reinforcing member 236. Is fixed between the inner surfaces of the first member 210a to form the first internal concrete 250a in the lower space of the lower diaphragm 232.

And the second member (210b) forms a connecting edge 220b to the lower side, the upper edge of the opposite side of the connecting edge 220b forms a flat straight portion 226, both sides of the straight portion 226 Is successively extended to the connecting edge 220b on the lower side while forming an arc with the same diameter with respect to the first member 210a. Such second member 210b forms a camber bent downward from the center in the longitudinal direction thereof, and a reinforcing plate having a stud or "T" cross section on the inner side of the straight portion 226 of the second member 210b. Fixing the reinforcing material 246 comprising a, and fixed the upper plate 248 below a predetermined interval to form a second internal concrete (250b) therebetween.
That is, the plate is formed by bending, the upper surface is connected to the flat straight portion 226 to form an arc with the same diameter with respect to the first member (210a), the horizontal plate-like connection horizontally bent to both lower sides A second member 210b is formed to form an edge 220b, a camber bent downward from the center in the longitudinal direction thereof, and a stud or a “” is formed on a bottom surface of the straight portion 226 of the second member 210b. Fixing the reinforcement 246 including a reinforcement plate having a T ″ cross section, and then fixing the upper diaphragm 248 downward from the reinforcement 236 between the inner surfaces of the second member 210b to fix the upper portion of the upper diaphragm. The second internal concrete 250b is formed in the space.

In addition, the first member 210a and the second member 210b are disposed such that the connecting edge 220a of the first member 210a is upward, and the connecting edge 220b of the second member 210b is lowered. They are integrally coupled through a connecting means 260 including bolt and nut coupling or welding in a state in which they face each other toward.
That is, the connecting edges 220a of the first member 210a are disposed upward, and the connecting edges 220b of the second member 210b are disposed downward to face each other so as to face each other up and down; The coupling edges 220a and 220b of the first member 210a and the second member 210b are coupled to each other through a connecting means 260 including bolt and nut coupling or welding.

Such a series of manufacturing process is shown in Figure 5, the steel pipe composite girder 200 according to the modified example of the present invention through such a manufacturing process can be easily manufactured in the production site can achieve a reduction in the production cost, It can be easily assembled into a bridge.

The steel pipe composite girder 200 according to the present invention is structurally solid without mounting the tension member 160 therein, and effectively resists the live load applied from the outside to produce a stable bridge construction.

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

1 is a cross-sectional view showing a steel pipe composite girder according to the prior art.

Figure 2 is a perspective view showing a steel pipe composite girder according to the present invention.

3 is a cross-sectional view showing a steel pipe composite girder according to the present invention.

4A and 4B are explanatory views sequentially illustrating a manufacturing process of the steel pipe composite girder according to the present invention.

5 is an explanatory diagram sequentially illustrating a manufacturing process of a steel pipe composite girder according to a modification of the present invention.

Description of the Related Art

1 ..... steel pipe concrete composite girder 10 ..... frame

20 .... inside concrete 30 ... space

32 .... Reinforcement plate of "T" section 100,200 ..... Steel pipe composite girder of the present invention

110a, 110b .... arcing member 115a, 115b .... bend

120a, 120b .... Connection edge 130,260 .... Connection means

124a, 124b .... Upper edge 130 .... Frame of arc cross section

132,232 .... bottom plate 136,236 .... stiffeners

150,150a .... inner concrete 160 .... tension

162 .... Sheath Pavilion 170 ..... Settlement

172 .... Fixture Home 180 ..... Cover

186 .... stiffener 190 .... upper plate

210a, 210b .... First and second member 220a, 220b .... Connecting edge

250a .... the first internal concrete 250b .... the second internal concrete

226 ..... straight part 246 .... stiffener

248 ..... upper plate 260 ..... connecting means

Claims (4)

Bending the plate material to arrange the two semi-circular arc-shaped member (110a) (110b) left and right, Connecting edges 120a and 120b in the form of vertical plates formed by bending the lower ends of the arc-shaped members 110a and 110b upward from the bent portions 115a and 115b to each other, and the connecting edges ( 120a and 120b are integrally coupled to each other by connecting means 130 including bolt and nut coupling or welding so that the upper edges 124a and 124b of each of the arc-shaped members 110a and 110b are spaced apart from each other. The upper portion of the frame 130 of the arc-shaped cross section is opened, The lower plate 132 of the horizontal plate shape is integrally fixed between the upper ends of the connecting edges 120a and 120b and the inner surfaces of the arc-shaped members 110a and 110b inside the frame 130. In the space formed by the lower portion of the 132 and the frame 130 is fixed to the reinforcement member 136 including a reinforcement plate of the stud or "T" -shaped cross-section and integrally formed with the internal concrete 150, Insert the tension member 160 in the interior of the inner concrete 150 to tension, and the open upper portion of the frame 130 is a steel pipe composite, characterized in that the cover 180 is integrally mounted and finished. Girder. The upper plate 190 of claim 1, wherein the cover 180 has a reinforcing member 186 having a reinforcing member 186 including a reinforcing plate having a stud or a “T” -shaped cross section at an upper side thereof. Fixed side by side on the inner side, the space between the cover 180 and the upper plate 190 is filled with concrete to form a steel pipe composite girder, characterized in that the upper internal concrete (150a) integrally formed. The tension member 160 is also tensioned by inserting the tension member 160 in the upper inner concrete 150a. The tension member 160 includes a lower diaphragm 132 and a frame 130, and an upper diaphragm 190 and a cover. Steel pipe composite girder, characterized in that extending through the sheath pipe 162 positioned across the center of the space between the 180, both ends thereof is provided with a fixing device 170. An arc-shaped first member formed by bending a plate to form a concave semi-circular cross section and forming a horizontal plate-shaped connecting edge 220a horizontally bent to both upper sides, and forming cambers bent downward from the center in the longitudinal direction thereof. 210a), A reinforcing member 236 including a reinforcing plate having a stud or a “T” shaped cross section is fixed to a lower inner surface of the first member 210a, and then a lower plate 232 having a horizontal plate shape upward from the reinforcing member 236. Fixed between the inner surfaces of the first member (210a) to form a first internal concrete (250a) in the lower space of the lower diaphragm (232); The plate is bent and formed, the upper surface of which is connected to the flat straight portion 226 to form an arc with the same diameter with respect to the first member (210a), the horizontal edges of the horizontal plate shape bent horizontally to both lower sides ( 220b), and a second member 210b having a camber bent downward from the center in the longitudinal direction thereof is formed. The reinforcing member 246 including a stud or a “T” shaped reinforcement plate is fixed to the bottom surface of the straight portion 226 of the second member 210b, and then the upper plate 248 is downwardly moved from the reinforcing member 236. Fixing between inner surfaces of the second member 210b to form second internal concrete 250b in an upper space of the upper diaphragm; Arranging the connecting edges 220a of the first member 210a upwards, and arranging the connecting edges 220b of the second members 210b downward to face each other so as to face each other up and down; And the steel pipe composite girder, characterized in that by coupling the connecting edges (220a, 220b) of the first member (210a) and the second member (210b) through a connecting means 260 including a bolt and nut coupling or welding .

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