KR101737573B1 - Internal reinforced steel pipe girder - Google Patents

Abstract

The present invention relates to an internal reinforcing steel pipe girder which is for increasing bending stiffness of a girder with respect to an exterior load caused by a first reinforcing material, a second reinforcing material, a third reinforcing material, and a fourth reinforcing material inside a steel pipe girder. In particular, the present invention includes a hollow shape steel pipe girder and a first reinforcing portion located inside the steel pipe girder and coupled to the inner surface of the steel pipe girder at both sides. In addition, the internal reinforcing steel pipe girder comprises: an arch shape cutout surface formed at the center of one side of the first reinforcing portion; a non-cutout surface formed on both ends of one side of the first reinforcing portion; a second reinforcing portion formed on a contact surface at one side of the steel pipe girder and the first reinforcing portion; a third reinforcing portion formed on a contact surface at the other side of the steel pipe girder and the first reinforcing portion; and a fourth reinforcing portion coupled to the cutout surface.

Description

[0001] The present invention relates to an internal reinforced steel pipe girder,

The present invention relates to a steel pipe girder and relates to a technique for increasing the bending rigidity of a steel pipe girder by a reinforcing portion inside the steel pipe girder.

Patent Document 001 relates to a girder in which a truss is squeezed, and is a steel girder with increased rigidity. The present invention provides a steel pipe girder manufactured by providing a girder which is a steel pipe combined with a truss, fabricating two semi-divided steel pipes in the longitudinal direction of the steel pipe, inserting the truss in the steel pipe and joining the two steel pipes, In order to improve the effective stress of the bent girder by matching the axis connecting the upper and lower triangular points of the truss to the bent direction of the bent girder in the bent girder installed at the bent span.

Patent Literature 002 relates to a steel pipe girder for bridges, in which a compressive stress and a tensile stress act almost equally so that a steel pipe girder combined with a steel upper plate is formed at the upper end of a structural steel pipe, It is possible to use it for cutting and long length, and to improve stability and durability of the structure. That is, it is preferable that the steel pipe comprises a steel pipe installed in the longitudinal direction of the bridge, a vertical connecting member formed on both sides of the upper end of the steel pipe so as to be combined with the steel upper plate and a reinforcement plate attached with a curvature similar to the lower inner circumferential surface of the steel pipe, And the vertical stiffeners are attached to the upper and lower central points of the steel pipe in the vertical direction at a predetermined interval in the longitudinal direction of the steel pipe.

Patent Document 003 relates to a horizontal member subjected to a flexural load such as a girder of a bridge. More particularly, the present invention relates to a prestressed steel pipe structural member capable of securing sufficient space while increasing rigidity by introducing a prestress into a hollow steel pipe, The prestressing steel material having the camber is subjected to a face-to-face contact, the load is applied to the prestressing steel material, the prestressing steel material is installed in a flattened state so as to face the prestressing steel material, and then the load is removed to introduce the prestress into the hollow steel pipe.

Patent Document 004 is a concrete filled steel pipe girder in which a partition plate is installed. A steel pipe having a cylindrical pipe shape and provided with end plates at both ends in the longitudinal direction; A pair of longitudinally divided plate members vertically installed to be spaced apart from each other with a longitudinal central axis of the steel pipe interposed therebetween and to be coupled to the interior of the steel pipe; A plurality of stud bolts fastened to opposite surfaces of the outer side surfaces of the pair of longitudinally divided plate members; Two or more steel wires arranged in the longitudinal direction of the steel pipe and coupled to end plates having opposite ends in the longitudinal direction different from each other and arranged so as to be spaced apart in the vertical direction between the pair of longitudinally divided plate materials; And concrete poured between the pair of longitudinally divided plate materials. In the patent document 004, a concrete filled steel pipe girder in which a dividing plate is installed has a composite structure of a steel wire having a large tensile strength and a concrete having a high compressive strength, so that the strength against deflection stress is high and only a part of the inner space of the steel pipe is filled with concrete And it is an invention to improve productivity by facilitating wire arrangement and fastening.

KR 10-1011866 B1 (Registration date January 24, 2011) KR 10-1229472 B1 (Registration date January 29, 2013) KR 10-1141685 B1 (Registered on April 24, 2012) KR 10-1391950 B1 (Registered on April 28, 2014)

The present invention relates to an inner reinforced steel pipe girder and aims at enhancing the bending rigidity of the girder by combining a first reinforcing material, a second reinforcing material, and a third reinforcing material fourth reinforcing material in the steel pipe girder.

In order to solve the problems of the prior art, the inner reinforced steel pipe girder of the present invention comprises a hollow steel pipe girder 100, a first reinforcing portion 210 located inside the steel pipe girder, .

The inner reinforced steel pipe girder of the present invention is the steel pipe girder and the first reinforcing part of the present invention, which is formed on the lower surface of the first reinforcing part and has an arcuate cut surface (211) (Not shown).

The inner reinforced steel pipe girder of the present invention includes the steel pipe girder and the first reinforcing portion of the invention as described above, and a second reinforcing portion 220 formed between the steel pipe girder and the non-rolling surface.

The inner reinforced steel pipe girder of the present invention includes the steel pipe girder and the first reinforcing portion of the invention as described above, and a third reinforcing portion (230) formed between the steel pipe girder and the upper surface of the first reinforcing portion.

The inner reinforced steel pipe girder according to the present invention is the steel pipe girder and the first reinforcing part of the present invention as described above, wherein the steel pipe girder and the second reinforcing part (220) formed between the steel pipe girder and the non- And a third reinforcing portion 230 formed between the sub-surfaces.

The inner reinforced steel pipe girder according to the present invention includes the fourth reinforcing part 240 coupled to the incision surface.

In the present invention, since the first to fourth reinforcing portions are accommodated in the steel pipe girder, no external interference is generated, and a small high rigidity girder can be obtained.

The first reinforcing member of the present invention has an arch shape, which has an effect that the load on the upper surface of the girder is stably alternately supported.

Since the steel pipe girder of the present invention has the second reinforcing portion and the third reinforcing portion formed on both sides and the inner upper surface of the inner side of the steel pipe girder, local deformation is not generated at the supporting point and the load point.

The steel pipe girder according to the present invention selectively injects concrete into the second reinforcement portion and / or the third reinforcement portion, which can effectively support tensile and compressive loads due to deformation of the girder.

Since the steel pipe girder of the present invention accommodates the corrugated first reinforcing portion, it is possible to accommodate the deformability of the tensile and compressive load due to the bending deformation of the girder.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a sectional view of an arch-shaped first reinforcing portion inside a steel pipe girder. Fig.
2 is a perspective view of a second reinforcing portion and a third reinforcing portion inside a steel pipe girder.
3 is a perspective view of a fourth reinforcing part inside the steel pipe girder according to the embodiment of the present invention.
4 is a perspective view of a first reinforcing portion formed of a bent plate material.
5 is a sectional view of the arcuate first reinforcement portion of the present invention formed continuously.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

(Example 1-1) The inner reinforced steel pipe girder of the present invention includes a hollow steel pipe girder 100, a first reinforcing portion 210 located inside the steel pipe girder and formed in the upper and lower steel pipe girders, do.

The first reinforcing portion is inserted into the steel pipe girder, and the steel pipe girder and the first reinforcing portion are welded together. Beam-shaped steel pipe The upper part of the girder is subjected to concentrated load and uniformly distributed load, and both lower sections of the steel pipe girder are supported alternately. Therefore, the center portion of the steel pipe girder generates deflection. The bending stiffness of the steel pipe girder should be increased to reduce the deflection deformation. The first reinforcing portion raises the secondary moment of inertia of the steel pipe girder, thereby reducing the amount of deflection of the steel pipe girder. The reinforced portion of the steel pipe girder is accommodated inside the steel pipe girder for preventing external interference and aesthetic effect.

(Example 1-2) The internal reinforced steel pipe girder of the present invention is formed in a circular or polygonal cross section of the steel pipe girder in the above-described embodiment 1-1.

The circular steel pipe girder 110 is manufactured by using a general circular pipe standard product, by rolling a plate material, or by spiral processing of a plate material. The rectangular steel pipe girder 120 is manufactured by welding a plate material, and is formed in a square shape according to the sectional shape.

 (Example 1-3) In the inner reinforcing steel pipe girder of the present invention, in the above-mentioned Example 1-2, the steel pipe girder and the first reinforcing portion have a uniform cross-section.

In order to improve productivity, the steel pipe girder and the first reinforcing portion may be made of the same steel plate. The thickness of the first reinforcing portion is thicker or thinner than the thickness of the steel pipe girder.

(Embodiment 1-4) In the internal reinforcing steel pipe girder of the present invention, in the above-described embodiment 1-2, the steel pipe girder and the first reinforcing portion are formed to have a non-uniform cross-section.

The maximum deflection of a simple supported steel pipe girder occurs at the center of the steel pipe girder. To reduce this maximum deflection, both ends of the steel tube girder are formed thicker than the central portion.

(Embodiment 1-5) In the embodiment 1-2 described above, the steel pipe girder and the first reinforcing portion of the present invention are formed of the same material.

In order to improve welding efficiency, the steel pipe girder and the first reinforcing portion are formed of the same material. Preferably, a rolled steel plate or structural steel is used.

(Example 2-1) The internal reinforced steel pipe girder of the present invention is the same as the above-mentioned Example 1-1, except that the internal reinforcing steel pipe girder is formed on the lower surface of the first reinforcing portion and has an arcuate cut surface 211, And a non-cutting face 212 on both sides.

A normal steel pipe girder takes a simple support form. Therefore, the maximum deflection and the maximum moment are generated at the center of the steel pipe girder. The center of the steel pipe girder in which the maximum deflection occurs generates a high bending stress, so that the diameter of the steel pipe girder must be increased to reduce the stress at the center of the steel pipe girder. In order to solve this problem, the steel pipe girder should reduce the amount of moment due to its own weight. Therefore, the shape of the first reinforcing portion can be overcome by taking an arch shape. This may reduce the outer diameter of the steel pipe girder, reduce the amount of material and cause aesthetic effect.

(Example 2-2) The internal reinforced steel pipe girder of the present invention is such that the length of the non-rolling surface is formed to be 0.5 to 2.0 times larger than the diameter of the steel pipe girder in the above-mentioned Example 2-1.

The alternating contact area with the steel pipe girder is subjected to a localized concentrated load. In order to disperse the concentrated stress due to the local load, the contact part is required to be reinforced separately. In order to increase the reinforcement effect, the contact part should avoid the arch shape and the non-threaded surface should be located. If the length of the non-interrupted face is long, the size of the arch becomes small. If the length of the non-interrupted face becomes short, the contact portion due to the local concentrated load is deformed. Therefore, the non-rolling surface length is formed to have a size of 0.5 to 2.0 with respect to the steel pipe girder diameter. This maintains the arch shape of a certain size and has critical meaning and effect to prevent deformation due to concentrated load on both end faces of steel pipe girder.

(Example 3-1) The internal reinforced steel pipe girder of the present invention includes the second reinforcing part 220 formed between the steel pipe girder and the non-rolling surface in the example 2-1 described above.

A second reinforcing portion is additionally formed for reinforcing the alternate contact portion with the steel pipe girder. One side of the second reinforcing portion is located on the non-breaking surface of the first reinforcing portion, and the other side is located on the inner surface of the steel pipe girder.

(Example 3-2) In the example 3-1 described above, the inner reinforced steel pipe girder of the present invention has a uniform cross-section and forms the second hollow portion 224 in the second reinforced portion.

The second reinforcing portion forms second reinforcing portions 222 and 223 in a U-shape or a C-shape so that two supporting surfaces are formed to increase rigidity.

(Example 3-3) In the interior reinforced steel pipe girder of the present invention, in the above-described Example 3-2, the second hollow portion is filled with the concrete 221.

The U-shaped or U-shaped second reinforcing parts 222 and 223 are formed with a hollow part therein. The interior of the hollow part is filled with concrete, which increases the bending stiffness and has the purpose of improving vibration.

(Example 4-1) The internal reinforced steel pipe girder of the present invention includes the third reinforcing portion 230 formed between the steel pipe girder and the upper surface of the first reinforcing portion in the above-described Example 2-1.

(Example 4-2) In the example 4-1 described above, the inner reinforced steel pipe girder of the present invention has the third reinforced portion having a uniform cross-section and forms the third hollow portion 234.

(Example 4-3) In the interior reinforced steel pipe girder of the present invention, concrete 231 is filled in the third hollow portion in the embodiment 4-2 described above.

The beam-shaped steel pipe girder induces deflection due to its own weight. Deflection of the steel pipe girder generates compressive stress in the upper layer of the steel pipe girder and tensile stress in the lower layer of the steel pipe girder. In particular, the largest compressive stress is generated at the upper center of the steel pipe girder. U-shaped or C-shaped third reinforcing parts 232 and 233 are mounted between the upper side of the steel pipe girder and the third reinforcing part to prevent sagging. The third reinforced portion has a uniform cross-section, and the interior is hollow. U-shaped or U-shaped open sides are welded with steel girders, and the internal hollow space fills the concrete. Since the concrete has high compressive rigidity, it can effectively prevent the vibration effect and the sagging of the steel pipe girder.

(Example 5-1) An internal reinforced steel pipe girder according to Example 2-1 of the present invention comprises: a second reinforcing portion 220 formed between the steel pipe girder and the non-rolling surface; And a third reinforcing part 230 formed between the upper surface of the first reinforcing part.

(Example 5-2) In the example 5-1 described above, the inner reinforced steel pipe girder of the present invention has a uniform cross-section, and the second hollow portion and the third hollow portion are formed do.

(Example 5-3) In the interior reinforced steel pipe girder of the present invention, in the example 5-2 described above, the second hollow and the third hollow fill the concrete.

Examples 5-1 to 5-3 are inventions in which the second reinforcing portion of Example 3 and the third reinforcing portion of Example 4 are combined. In other words, the steel pipe girder is prevented from sagging by the third reinforcing portion, and the effect of dispersing the local load of the contact portion by the second reinforcing portion is complex.

(Example 6-1) The inner reinforced steel pipe girder of the present invention is the inner reinforced steel pipe girder according to Examples 2-1 to 5-1 described above, which includes a fourth reinforcing portion 240 coupled to the incision surface Reinforced steel pipe girder.

(Embodiment 6-2) In the embodiment 6-1 described above, the inner reinforced steel pipe girder according to the present invention is characterized in that the fourth reinforcing portion is formed of one of the plate material 241, the circular 242, and the polygon 243 .

(Example 6-3) In the example 6-2 described above, the inner reinforced steel pipe girder of the present invention has the circular and polygonal forms the fourth hollow portion.

(Example 6-4) In the inner reinforced steel pipe girder of the present invention, in the above-described Example 6-3, the circular hollow and the polygonal fourth hollow are filled with concrete.

Steel pipe girders are exposed to repeated fatigue loads. The fatigue load exerts a periodic stress on the arcuate incised portion of the first reinforced portion. The periodic tensile stress of the arcuate uncovered part is exposed to the risk of fatigue, and even minute cracks cause instant fatigue failure. To prevent this, a fourth reinforcing portion is formed on the arch-shaped incision portion. The fourth reinforcing portion is formed in any one of a plate material, a circular tube, and a polygonal tube. The fourth reinforced portion of the plate-like shape is welded along the arch shape with a steel plate having a uniform width. Or a non-uniform steel sheet is welded along the arch shape. The fourth reinforced portion of the cylindrical shape and the multi-pipe shape is filled with concrete to reduce the tensile force according to the fatigue load.

(Example 7-1) In the internal reinforced steel pipe girder of the present invention, in the above-described Example 6-1, the cut surface 211 is extended in plural.

The steel pipe girder of the officer supports the steel pipe girder at the alternation of both sides and a plurality of piers at the middle side. Therefore, the moment is small at the portion where the steel pipe girder is in contact with the bridge pier and the alternation, and a maximum moment is generated at the midway point between the bridge pier and the alternation. That is, one steel pipe girder is subjected to repeated deflections continuously. The first reinforcing portion and the second reinforcing portion to the fourth reinforcing portion of the arcuate shape shown in Embodiments 1 to 7 should be continuously included in one steel pipe girder.

(Example 8-1) In the interior reinforced steel pipe girder of the present invention, in the above-mentioned Example 7-1, the first reinforced portion is a folded plate material.

(Example 8-2) In the embodiment 8-1 described above, the bent steel plate is formed in a zigzag shape in a semicircle.

(Embodiment 8-3) In the embodiment 8-1 described above, the inner reinforced steel pipe girder of the present invention has a "C" groove formed in a zigzag shape in the bent plate member.

When the elongated first reinforcing portion is bent and deformed, the lower end of the first reinforcing portion is pulled, and the upper end of the first reinforcing portion is compressed. If the tensile and compression loads exceed the allowable range, they will be damaged. Therefore, in order to improve the elasticity against tensile and compressive load, the first reinforcing portion forms a corrugated plate by continuously connecting semicircular or U-shaped grooves. The wrinkle shape maintains elasticity in accordance with a change in load, thereby prolonging the life of the first reinforced portion and safely supporting the load of the weight.

100: Steel pipe girder 110: Circular steel pipe girder
120: square steel pipe girder 210: first reinforcing portion
211: incision surface 212:
220: second reinforcing portion 221: concrete
222: U-shaped second reinforcing portion 223: C-shaped second reinforcing portion
230: third reinforcing portion 231: concrete
232: U-shaped second reinforcing portion 233: C-shaped second reinforcing portion
234: third hollow portion 240: fourth reinforcing portion
241: plate-like fourth reinforcing portion 242: circular fourth reinforcing portion
243: polygonal fourth reinforcing portion 244: fourth hollow portion

Claims (12)

delete delete A hollow steel pipe girder 100;
A first reinforcing part 210 located inside the steel pipe girder and having an upper and lower surfaces formed inside the steel pipe girder;
An arcuate incision surface 211 formed on the lower surface of the first reinforcement portion;
A non-cutting face (212) formed on both sides of the first reinforcing portion,
A second reinforcing portion 220 formed between the steel pipe girder and the non-rolling surface;
And a fourth reinforcing part (240) coupled to the cut surface.
A hollow steel pipe girder 100;
A first reinforcing part 210 located inside the steel pipe girder and having an upper and lower surfaces formed inside the steel pipe girder;
An arcuate incision surface 211 formed on the lower surface of the first reinforcement portion;
A non-cutting face (212) formed on both sides of the first reinforcing portion,
And a third reinforcing part (230) formed between the steel pipe girder and the upper surface of the first reinforcing part.
A hollow steel pipe girder 100;
A first reinforcing part 210 located inside the steel pipe girder and having an upper and lower surfaces formed inside the steel pipe girder;
An arcuate incision surface 211 formed on the lower surface of the first reinforcement portion;
A non-cutting face (212) formed on both sides of the first reinforcing portion,
A second reinforcing portion 220 formed between the steel pipe girder and the non-rolling surface;
And a third reinforcing portion (230) formed between the steel pipe girder and the upper surface of the first reinforcing portion.
The method according to claim 4 or 5,
And a fourth reinforcing part (240) coupled to the cut surface.
The method of claim 6,
Wherein the fourth reinforcement portion is formed in any one of a plate shape, a circular shape, and a polygonal shape.

The method of claim 7,
Wherein the circular or polygonal interior is filled with concrete.
The method according to claim 3 or 5,
And the second reinforcing portion includes a second hollow portion 224 formed in a U-shape or a C-shape.
The method of claim 9,
And the second hollow portion (224) is filled with concrete.
The method according to claim 4 or 5,
And the third reinforcing part (230) includes a third hollow part (234) formed in a U shape or a C shape.
The method of claim 11,
And the third hollow portion (234) is filled with concrete.

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