KR102249973B1 - Circular Steel Girder - Google Patents

Abstract

The present invention relates to a circular steel pipe girder capable of uniformly distributing the stress of a slab, comprising: a circular girder coupled to the lower end of the slab and formed in a circular shape; a reinforcing girder coupled to the circular girder and reinforcing the circular girder; an upper girder; and a lower girder.

Description

Circular Steel Girder}

The present invention relates to a circular steel pipe girder capable of uniformly distributing the stress of the slab.

Patent Document 001 discloses that a steel pipe girder has an upper inclined wall extending sideways while facing obliquely upward at the upper end of the vertical partition wall, and a lower inclined wall extending sideways while facing obliquely downward is formed at the lower end of the vertical partition wall, A side outer wall is formed to connect the end of the upper inclined wall and the end of the lower inclined wall, thereby including a first side tube and a second side tube having a tubular shape, wherein the first side tube and the second side tube are each other. The vertical bulkheads are bolted so as to be interviewed with their back on their backs and installed side by side, and an upper outer wall is formed to connect the upper end of the upper inclined wall of the first side pipe and the end of the upper inclined wall of the second side pipe, A lower outer wall is formed to connect the end of the lower inclined wall of the second side tube and the end of the lower inclined wall of the second side tube, so that the upper inclined wall of the first side tube, the upper inclined wall of the second side tube, and An upper conduit having the upper outer wall as a circumferential wall, a lower inclined wall of the first side tube, a lower inclined wall of the second side tube, and a lower conduit having the lower outer wall as a circumferential wall, and the upper conduit and It presents a technology that is made by pouring concrete into the lower pipe.

Patent document 002 is a circular steel pipe girder, a girder body in the form of a circular cross-section and the upper side facing each other, the opening portion facing the slab of the bridge is formed by spaced apart from each other; A support frame inserted and fixed inside the girder body to support the girder body; It is coupled to the opening of the girder body and includes a slab support plate for supporting the slab of the bridge, and the support frame is formed by radially coupling three or more supports, and the free end is fixed to the inner circumferential surface of the girder body, and the three Among the above supports, two supports are provided with a technique in which the free ends are fixed so as to support the ends on both sides of the opening of the girder body from the inside.

Patent Document 003 is a) preparing a circular steel pipe; b) forming an installation hole by cutting a lower reinforcing surface located at a point portion of an alternating or pier among circular steel pipes; c) manufacturing a branch reinforcement by pouring mortar on the cut-separated lower reinforcing surface; d) inserting the branch reinforcement body into the installation hole of the circular steel pipe so that the poured mortar is located inside the steel pipe, and then welding the lower reinforcement surface of the branch reinforcement body to integrate with the circular steel pipe; characterized by comprising: A method of manufacturing an assembled steel pipe girder for a bridge is provided. At this time, step c) is a technology consisting of a process of installing side plates on both side ends of the lower reinforcing surface, forming a mortar filling space inside the mortar filling space by installing membrane plates at the front and rear ends, and then pouring mortar into the mortar filling space. Are presented.

Patent Document 004 is a hollow cylindrical steel pipe that is mounted on the top of a pier, cured through centrifugal molding, and includes a high-strength concrete layer into which prestress is introduced, an abdomen vertically coupled to the central upper surface of the steel pipe, and the abdomen. It relates to a steel pipe girder, characterized in that it comprises an upper flange connected at a right angle to the upper end, and further, welding a transmission connector to a semi-cylindrical steel pipe, arranging a plurality of PS steels in the longitudinal direction, the semi-cylindrical steel pipe A preparation step of mounting the steel bar in the center of the circular steel plate formed on both sides of the; A pretension step of tensioning the PS steel material through a circular steel plate by pulling the steel bar from the outside; While the PS steel is tensioned, concrete is poured using the semi-cylindrical steel pipe as a formwork, and the remaining semi-cylindrical steel pipes are welded to the semi-cylindrical steel pipe to form a cylindrical steel pipe, and the cylindrical steel pipe is fixed to a fixing device. Forming a concrete layer having a hollow portion inside the cylindrical steel pipe by curing by centrifugal molding by a driving motor; It proposes a technology composed of a prestress step in which compressive forces are introduced into cylindrical steel pipes and concrete layers by releasing external forces.

KR 10-1725686 B1 (04/05, 2017) KR 10-1454888 B1 (October 20, 2014) KR 10-1889791 B1 (August 13, 2018) KR 10-2010-0076124 A (July 6, 2010)

The present invention relates to a circular steel pipe girder capable of uniformly distributing the stress of the slab.

It is to solve the problems of the prior invention, the present invention is coupled to the lower end of the slab 300, circular girder 100 formed in a circular shape; It is coupled to the circular girder 100, a reinforcing girder 200 for reinforcing the circular girder 100; consists of a configuration including.

The present invention is an invention for a circular steel pipe girder, and the circular girder 100 presented above;, in the invention consisting of a reinforcing girder 200; the circular girder 100 is formed at the lower end of the slab 300, and a semicircle The upper girder 110 formed of; A lower girder 120 coupled to the upper girder 110 and fixed to a support extending from the ground is added.

The present invention is an invention for a circular steel pipe girder, and is formed on the side of the circular girder 100 in the invention consisting of a circular girder 100 presented above;, a reinforcing girder 200; and a plurality of the circular girders 100 ) To connect the connection girder 400; is added.

The present invention is an invention for a circular steel pipe girder, and the circular girder 100 presented above;, the reinforcing girder 200 in the invention consisting of; the reinforcing girder 200 is coupled to the inside and outside of the circular girder 100 To become; add.

In the present invention, the reinforcing girder is coupled to the inside of the circular girder, so that the position of the neutral axis is located at the center of the circular girder, so that the stress can be uniformly distributed.

In the present invention, the upper girder and the lower girder are fastened by welding, and the reinforcing girder is coupled to the lower girder, thereby increasing the integrity of the circular girder and the reinforcing girder.

As the lower girder and the reinforcing girder of the present invention are bent and formed, manufacturing efficiency can be improved.

The reinforcing girder of the present invention is installed on the lower girder in various ways, and the stress dispersion effect can be made uniform depending on the purpose of use.

Welding holes are formed in the reinforcing girder and the lower girder of the present invention to prevent separation of the reinforcing girder.

1 is a perspective view of a bridge in which the circular steel pipe girder of the present invention is installed.
Figure 2 is an exploded perspective view showing the bridge shown in Figure 1;
3 is a front view of a bridge in which the circular steel pipe girder of the present invention is installed.
Figure 4 is a perspective view of a deck installed with a circular steel pipe girder of the present invention.
Figure 5 is an exploded perspective view showing the deck shown in Figure 4;
Figure 6 is a cross-sectional view showing the circular steel pipe girder of the present invention.
7 is a perspective view showing the connection girder of the present invention.
Figure 8 is a perspective view showing a circular steel pipe girder and reinforcement girder of the present invention.

Hereinafter, in order to describe in detail enough that a person of ordinary skill in the art can easily implement the present invention, the most preferred embodiment of the present invention will be described in detail.

The numbers cited in the following examples are not limited only to the object of reference, and may be applied to all examples. Objects that exhibit the same purpose and effect as the configuration presented in the examples correspond to equivalent substitutional objects. The upper concept presented in the examples includes the object of the lower concept that is not described.

(Example 1-1) The present invention is a circular steel pipe girder, coupled to the lower end of the slab 300, the circular girder 100 formed in a circular shape; It is coupled to the circular girder 100, a reinforcing girder 200 for reinforcing the circular girder 100; includes.

(Example 1-2) The circular steel pipe girder of the present invention in Example 1-1, wherein the slab 300 is formed of concrete and asphalt; includes.

(Example 1-3) The circular steel pipe girder of the present invention in Example 1-1, wherein the reinforcing girder 200 is coupled to all and part of the inner circumferential surface of the circular girder 100; includes.

(Example 1-4) In the circular steel pipe girder of the present invention in Example 1-1, the reinforcing girder 200 has a thickness adjusted according to the size of the circular girder 100; includes.

The present invention relates to a circular steel pipe girder, and specifically to form a girder for supporting the load of the slab 300 formed as a driveway and a sidewalk in a circular shape. The circular steel pipe girder of the present invention is to support the deck 310 which is spaced apart from the ground and bridge connecting the pier and the abutment and used as a sidewalk. These circular steel pipe girders support the slab 300 formed of concrete and asphalt so as to be formed into roadways and sidewalks, and a reinforcing girder formed in the circular girder 100 and the circular girder 100 to reinforce strength It is formed by 200. At this time, the reinforcing girder 200 formed inside the circular girder 100 is coupled to the whole and part of the circular girder 100 to induce it to be formed around a neutral axis. This is to ensure that the upper stress is evenly distributed. For example, when the slab 300 is coupled to the upper portion of the circular girder 100, the stress does not uniformly progress toward the upper portion of the neutral axis. At this time, when the reinforcing girder 200 is coupled to the inside of the circular girder 100 only to the whole or part of the circular girder 100 and the neutral axis is positioned at the center of the circular girder 100, the stress is uniformly distributed. The thickness of the reinforcing girder 200 is adjusted according to the size of the circular girder 100. At this time, the reinforcing girder 200 may be formed integrally with the circular girder 100. And the reinforcing girder 200 is not formed in the center of the lower end of the circular girder 100, but may be coupled to be deflected to one side in the inside of the circular girder 100 according to the stress acting on the plurality of circular girders 100 .

Accordingly, the circular steel pipe girder has a characteristic of being formed of a circular girder 100 to which the reinforcing girder 200 is coupled therein in order to uniformly distribute the load and stress of the slab 300 formed as a roadway and a sidewalk.

(Example 1-5) In the circular steel pipe girder of the present invention in Example 1-1, the slab 300 is a deck 310 mounted on a horizontal beam connecting the upper portions of the plurality of circular girders 100 It includes;

(Example 1-6) In Example 1-5, the circular steel pipe girder of the present invention is formed on the upper portion of the circular girder 100, and includes a coupling plate 320 coupled to the slab 300; do.

The present invention relates to the slab 300, specifically, the slab 300 is formed of a deck 310 made of a wooden material to be coupled to the upper portion of the circular girder 100. The slab 300 of the present invention may be formed as a deck 310 to which a person moves, and is installed to be spaced apart from the ground in a place where it is not smooth for a person to move. The slab 300 is formed so that the deck 310 plates formed of a plurality of wood, concrete, and steel overlap each other, and is formed to be perpendicular to the circular girder 100 coupled to the lower portion. At this time. The circular girder 100 supporting the slab 300 has a coupling plate 320 coupled to the upper portion thereof, and the integrity of the slab 300 and the circular girder 100 is improved by the coupling plate 320. The coupling plate 320 is formed of various materials such as wood and iron, and may be fastened by welding and bolts to be fixed to the circular girder 100. In addition, the coupling plate 320 has the center of the circular girder 100 in contact with the circular girder 100 so as not to be biased in one direction from the top of the circular girder 100. In this way, the coupling plate 320 is connected in the longitudinal direction of the circular girder 100, and the slab 300 is fastened to the upper portion.

Accordingly, the slab 300 is installed on the upper portion of the plurality of circular girders 100, and is formed of a sidewalk or the like.

(Example 1-7) In Example 1-1, the circular steel pipe girder of the present invention is formed between the slab 300 and the plurality of circular girders 100, and is excellent in treating rain transmitted from the top. It includes; processing plate 330.

(Example 1-8) In the circular steel pipe girder of the present invention in Example 1-1, the excellent treatment plate 330 is a top plate 331 in contact with the lower portion of the slab 300;, a plurality of the top plates ( It is formed between 331), the lower plate 332 for treating rain; It includes; a guide plate 333 that connects the upper plate 331 and the lower plate 332 to each other, and guides the excellence.

The present invention relates to an excellent treatment plate (330). The rainwater treatment plate 330 is for collecting and discharging rainwater that is coupled to the lower portion of the slab 300 and passes through the slab 300 and transmitted to the lower portion. This excellent treatment plate 330 is formed between the slab 300 and a plurality of circular girders 100, and the upper plate 331 in contact with the lower portion of the slab 300 and the lower plate 332 spaced apart from the upper plate 331 are Is formed. At this time, the upper plate 331 is located on both sides of the coupling plate 320 of the circular girder 100, and the upper plate 331 is also fixed when the coupling plate 320 and the slab 300 are fixed. And the upper plate 331 and the lower plate 332 are connected by the guide plate 333, and as the guide plate 333 is formed in an oblique line, the rain delivered from the slab 300 is concentrated to the lower plate 332 to the outside. Can be discharged. The lower plate 332 is provided with a separate drain hole to store rainwater and discharge it to the outside, and the stored rainwater can be recycled and used.

Accordingly, the rainwater treatment plate 330 is formed between the slab 300 and the circular girder 100, and rainwater is transmitted to the ground and lower portions, thereby reducing damage caused by rainwater.

(Example 2-1) The present invention relates to a circular steel pipe girder, and in Example 1-1, the circular girder 100 is formed at the lower end of the slab 300, and an upper girder formed in a semicircle ( 110); Includes; a lower girder 120 coupled to the upper girder 110 and fixed to a support extending from the ground.

(Example 2-2) The circular steel pipe girder of the present invention in Example 2-1, wherein the reinforcing girder 200 is formed by bending at the end of the lower girder 120; includes.

(Example 2-3) The circular steel pipe girder of the present invention in Example 2-2, wherein the lower girder 120 and the reinforcing girder 200 are formed by welding; includes.

The present invention relates to a circular girder 100, specifically, the circular girder 100 is divided into an upper girder 110 and a lower girder 120, and is formed to be detachable from each other. The circular girder 100 of the present invention is formed at the lower end of the slab 300, and the upper girder 110 to which the coupling plate 320 is fastened and the lower girder 120 coupled to the lower end of the upper girder 110 are formed. do. At this time, the upper girder 110 and the lower girder 120 are formed in a circular shape by bending the steel plate, but if the diameter of the circular girder 100 is large, it is difficult to bend it in a circular shape, so a plurality of steel plates are bent to form a circular shape. do. In this way, the upper girder 110 and the lower girder 120 bend the steel plate, and the upper girder 110 and the lower girder 120 are formed in a semicircular shape. And the upper girder 110 and the lower girder 120 are butt welded or overlapped with each other. In addition, the lower girder 120 has a reinforcing girder 200 coupled therein to be thicker than the upper girder 110, but except for the reinforcing girder 200, the thickness of the lower girder 120 is reduced to the upper girder 110. It can be manufactured using a thicker iron plate. In this way, the lower girder 120 is formed thicker than the upper girder 110, and the lower girder 120 is bent to increase the integrity with the reinforcing girder 200 to generate the reinforcing girder 200. Specifically, the steel plate is bent in a semicircle to create the lower girder 120, and then bent at 90 degrees at the end and then bent again at 90 degrees at a position spaced from the lower girder 120 to reinforce the inside of the lower girder 120. 200) is bent again. And by welding and fixing the ends of the lower girder 120 and the reinforcing girder 200 connected to each other, the integrity of the lower girder 120 and the reinforcing girder 200 is improved, and the thickness is made thicker than the upper girder 110. By doing this, the strength can be increased.

Therefore, the circular girder 100 is formed by separating the upper girder 110 and the lower girder 120 from each other, and fixing each end by welding.

(Example 2-4) The circular steel pipe girder of the present invention in Example 2-1, wherein the upper girder 110 and the lower girder 120 are coupled by a fastening bolt 130; includes. .

(Example 2-5) The circular steel pipe girder of the present invention in Example 2-4, wherein the lower girder 120 includes a seating groove 121 in which the upper girder 110 is seated.

The upper girder 110 and the lower girder 120 of the present invention are formed to overlap each other and are fixed with a fastening bolt 130. Specifically, the upper girder 110 and the lower girder 120 formed in a semicircular shape are positioned so that their ends overlap each other, and are fastened with fastening bolts 130. At this time, the fastening bolts 130 are formed of high-tension bolts, and a plurality of fastening bolts are fastened in the longitudinal direction of the circular girder 100 so that the upper girder 110 and the lower girder 120 are not damaged. In addition, since the lower girder 120 may be separated or damaged when a large load is generated on the upper girder 110, a seating groove 121 is formed so that the end of the upper girder 110 is seated on the lower girder 120. The seating groove 121 is created when the steel plate is bent to create the lower girder 120. For example, when bent to face each other at both ends of the lower girder 120 formed in a curved surface and then re-bent upward, a seating groove 121 in which the upper girder 110 is seated is formed, and at the same time, the upper girder 110 and The overlapping lower girder 120 is formed. At this time, by fastening the upper girder 110 and the lower girder 120 with the fastening bolts 130, it is possible to increase the efficiency of dispersing the stress of the upper girder 110 to the lower girder 120.

Accordingly, the lower girder 120 has a seating groove 121 in which the upper girder 110 is seated, and the upper girder 110 and the lower girder 120 overlapping each other in the seating groove 121 are fastening bolts 130 It is concluded by

(Example 2-6) In the circular steel pipe girder of the present invention in Example 2-1, the lower girder 120 is formed in a plurality, each having a different thickness formed and combined lower module 140; includes do.

The present invention relates to the lower girder 120, and specifically, a plurality of lower modules 140 are formed by being combined with each other. The lower girder 120 of the present invention is formed by combining the lower modules 140, and the lower modules 140 have different thicknesses, so that the arrangement of the lower modules 140 is different depending on the position to which the stress is transmitted. For example, the thickness of the center where the stress is concentrated is formed thicker than the side surface, thereby reducing the weight of the lower girder 120 and reducing material waste. In this case, when the lower girder 120 has the same thickness, the reinforcing girder 200 may have a different thickness and may be modularly coupled to the lower girder 120.

(Example 3-1) The present invention relates to a circular steel pipe girder, and in Example 2-1, a connection girder formed on the side of the circular girder 100 and connecting a plurality of the circular girders 100 (400); includes.

(Example 3-2) In the circular steel pipe girder of the present invention in Example 3-1, the connection girder 400 is through which a plurality of the circular girders 100 pass, and the slab 300 is coupled to the upper part. Include;

The present invention relates to a connection girder 400, specifically, a plurality of circular girders 100 are connected to each other to mount the slab 300. The connection girder 400 of the present invention surrounds a plurality of circular girders 100, and a slab 300 is coupled thereto. In this connection girder 400, through holes are formed equal to the number of circular girders 100 so that the plurality of circular girders 100 pass through, and both ends are formed in diagonal lines to induce stress to be concentrated on the ground. And the connection girder 400 is formed at equal intervals at the bottom of the slab 300, and induces the load of the slab 300 to be transmitted to the circular girder 100.

(Example 3-3) In the circular steel pipe girder of the present invention in Example 3-1, the connection girder 400 is an assembly 410 coupled to the side surface of the circular girder 100;, a plurality of the assembly It is formed between (410), the support beam 420 for supporting the slab 300; includes.

(Example 3-4) The circular steel pipe girder of the present invention in Example 3-3, wherein the coupling body 410 is formed by being coupled to the circular girder 100 and the coupling plate 320; includes .

(Example 3-5) The circular steel pipe girder of the present invention in Example 3-4, wherein the connection girder 400 is installed at equal intervals; includes.

The present invention relates to a connection girder 400, specifically, the connection girder 400 is formed with a coupling body 410 coupled to the side of the circular girder 100, and the coupling body 410 is coupled by welding and bolts. Support beam 420 is formed. The assembly 410 is a combination plate 320 formed on the upper portion of the circular girder 100 and is coupled to the side of the circular girder 100, and when three or more circular girders 100 are formed, a circular girder formed in the center Combined bodies 410 are formed by being coupled to both sides of (100), respectively. And the combination body 410 is preferably coupled to the side of the circular girder 100 and the bonding plate 320 by welding, and the load of the slab 300 is concentrated so that it is firmly fixed so as not to be separated from the circular girder 100 . In addition, the assembly 410 extends laterally from the circular girder 100 to be coupled to the support beam 420 by welding and bolting, and is formed to have a width wider than the diameter of the bolt so as to overlap the support beam 420. The support beam 420 may be formed in various ways such as a steel plate, an I-beam, an H-beam, etc., and is coupled to the assembly 410 in order to connect between the plurality of circular girders 100.

Therefore, the connection girder 400 connects a plurality of circular girders 100 to each other to prevent sagging of the slab 300, and at the same time, the upper stress is dispersed and coupled to the assembly 410 so that it is guided to the circular girder 100. do.

(Example 4-1) The present invention relates to a circular steel pipe girder, and in Example 3-1, the reinforcing girder 200 is coupled to the inside and outside of the circular girder 100; includes. .

(Example 4-2) In Example 4-1, the circular steel pipe girder of the present invention includes a welding hole 500 that penetrates the surface of the reinforcement girder 200 and through which a welding rod passes.

The present invention relates to a reinforcing girder 200, and specifically, the reinforcing girder 200 is coupled to the inside and outside of the circular girder 100 to reinforce the strength. The reinforcing girder 200 of the present invention is formed in a curved surface in the same manner as the circular girder 100, and is formed by bending the circular girder 100 or is formed by welding and fastening inside and outside with bolts. When the reinforcing girder 200 is welded to the circular girder 100, both sides are generally fixed to the circular girder 100, but this is due to the lack of integrity between the reinforcing girder 200 and the circular girder 100. (200) may be deviated. Thus, in order to firmly couple the reinforcing girder 200 to the circular girder 100, a plurality of welding holes 500 formed at equal intervals on the surface of the reinforcing girder 200 are formed. The welding hole 500 is formed with a diameter through which the welding rod penetrates, and may be coupled to the circular girder 100 by welding through the welding hole 500 through the reinforcing girder 200. At this time, the welding hole 500 is filled by welding.

And the circular girder 100 to which the reinforcing girder 200 is coupled is also formed with a welding hole 500, and when the circular girder 100 is coupled to the inside, a welding hole 500 to fix the reinforcing girder 200 from the outside. ) To proceed with welding. In this way, the reinforcing girder 200 may be welded to the welding hole 500 to be coupled to the inside and outside of the circular girder 100, and when fastened with bolts, it may be fixed through a separate fastening hole.

Accordingly, the reinforcing girder 200 is coupled to the inside and outside of the circular girder 100 to reinforce the strength of the circular girder 100.
As another embodiment, the present invention is coupled to the lower end of the slab 300, the circular girder 100 formed in a circular shape; A reinforcing girder 200 coupled to the circular girder 100 and reinforcing the circular girder 100; The circular girder 100 is formed at the lower end of the slab 300, and the upper girder 110 is formed in a semicircle; A lower girder 120 coupled to the upper girder 110 and fixed to a support extending from the ground; A coupling plate 320 positioned between the slab 300 and the upper girder 110, divided into two and symmetrically formed, and formed in a plate shape; The reinforcing girder is formed integrally with the lower girder; The reinforcing girder is located in the middle of the lower girder, the reinforcing girder is formed in an arc shape, the arc-shaped radius is formed equal to the radius of the lower girder, and the thickness of the reinforcing girder is the lower girder. It includes; formed thicker than the thickness of. In another embodiment, a circular girder 100 coupled to the lower end of the slab 300 and formed in a circular shape; A reinforcing girder 200 coupled to the circular girder 100 and reinforcing the circular girder 100; The circular girder 100 is formed at the lower end of the slab 300, the upper girder 110 formed in a semicircle; A lower girder 120 coupled to the upper girder 110 and fixed to a support extending from the ground; A coupling plate 320 positioned between the slab 300 and the upper girder 110, divided into two and symmetrically formed, and formed in a plate shape; The reinforcing girder is formed integrally with the lower girder; The reinforcing girder is located in the middle of the lower girder, the reinforcing girder is formed in an arc shape, the arc-shaped radius is formed equal to the radius of the lower girder, and the thickness of the reinforcing girder is the lower girder. It is formed thicker than the thickness of; consisting of a configuration that includes.

100: circular girder 110: upper girder
120: lower girder 121: seating groove
130: fastening bolt 140: lower module
200: reinforcement girder 300: slab
310: deck 320: bonding plate
330: excellent treatment plate 331: upper plate
332: lower plate 333: guide plate
400: connecting girder 410: combination
420: support beam 500: welding hole

Claims (5)

A circular girder 100 coupled to the lower end of the slab 300 and formed in a circular shape;
A reinforcing girder 200 coupled to the circular girder 100 and reinforcing the circular girder 100;
The circular girder 100 is formed at the lower end of the slab 300, and the upper girder 110 is formed in a semicircle;
A lower girder 120 coupled to the upper girder 110 and fixed to a support extending from the ground;
A coupling plate 320 positioned between the slab 300 and the upper girder 110, divided into two and symmetrically formed, and formed in a plate shape;
The reinforcing girder is formed integrally with the lower girder;
The reinforcing girder is integrally formed by welding at the center of the inner surface of the lower girder, and the reinforcing girder has a plate shape extending in a uniform longitudinal section into the circular girder, and the contact portion of the reinforcing girder of the lower girder is the reinforcement. Formed in the form of a plate in close contact with the girder;
Round steel pipe girder comprising a.
delete delete delete A circular girder 100 coupled to the lower end of the slab 300 and formed in a circular shape;
A reinforcing girder 200 coupled to the circular girder 100 and reinforcing the circular girder 100;
The circular girder 100 is formed at the lower end of the slab 300, and the upper girder 110 is formed in a semicircle;
A lower girder 120 coupled to the upper girder 110 and fixed to a support extending from the ground;
A coupling plate 320 positioned between the slab 300 and the upper girder 110, divided into two and symmetrically formed, and formed in a plate shape;
The reinforcing girder is formed integrally with the lower girder;
The reinforcing girder is located in the middle of the lower girder, the reinforcing girder is formed in an arc shape, the arc-shaped radius is formed equal to the radius of the lower girder, and the thickness of the reinforcing girder is the lower girder. To be formed thicker than the thickness of;
Round steel pipe girder comprising a.

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