KR102348654B1 - Steel structure in which square steel pipe columns and beams are joined, and its construction method - Google Patents

Abstract

The present invention relates to a steel frame structure in which a square steel pipe column and an improved beam are coupled, and a construction method thereof. The steel frame structure comprises: a square steel pipe column (100-1) vertically installed on a floor surface; and a double H-shaped improved steel beam (200) perpendicularly joined with the square steel pipe column (100-1) for each predetermined height. According to the present invention, constructability is improved, seismic structure performance is improved by a fully welded structure, economic feasibility is advantageous, and appearance is improved.

Description

Steel structure in which square steel pipe columns and beams are joined, and its construction method

The present invention relates to a steel structure and a construction method thereof, and more particularly, to a steel structure in which a rectangular steel pipe column and an improved beam of a seismic-resistant performance structure are joined, and a construction method thereof.

Since a steel structure is a structure in which beams and beams are manufactured by bolting and welding sections, steel plates, and flat plates, the stability of the joint is important, and the shape of the joint affects the overall design and construction.

The joining methods used for steel structures are typically bolted and welded. In some cases, additional beams are installed to the existing steel structure for the purpose of reinforcing, but bolted connection is preferred in terms of constructability. However, the moment joint is advantageous in terms of force or stress transmission for the connection between columns and beams.

Joints requiring moment joining were treated by welding or bolting, but welded joints have poor workability and economic feasibility. When an impact or repeated load is applied, large deformation occurs in the joint and the problem of bolt loosening occurs.

In addition, a lot of T-beams or iron plates are used as beams to be joined to columns. If T-beams or steel plates are used as beams, plastic hinges occur at the junctions, which may weaken the seismic performance of the structure. As a result, there is a problem in that the construction time is long and the cost is increased.

In addition, the double H-beam beam, in which the width of the web is widened by joining two existing H-beams up and down, is cumbersome and cost-effective due to the large number of high-tensile strength bolts. There is a problem that the appearance is not beautiful due to the bolt.

1. Registered Patent Publication No. 1642420 (Registered on July 19, 2016) 2. Registered Patent Publication No. 2229712 (Registered on March 12, 2021)

The present invention has been devised to solve the above problems, and an object of the present invention is to improve workability, improve seismic performance, economical efficiency, and a steel structure in which a rectangular steel pipe column and an improved beam are joined to improve the aesthetics. and to provide a construction method thereof.

A steel structure in which a rectangular steel pipe column and an improved beam are joined according to an embodiment of the present invention for solving the above problems is a rectangular steel pipe column installed vertically on the floor surface, and the square steel pipe column is connected to form a vertical at a certain height of the column Including double H-beam improved beam.

The double H-beam improved beam includes a wide H-beam connected to the prismatic steel pipe column, and a narrow H-beam welded to an end of the wide H-beam in a straight line shape.

The wide H-beam has a relatively wide web width compared to the narrow H-beam, and the wide H-beam and the narrow H-beam have the same width of the upper flange and the lower flange, and the wide H-beam and The narrow width H-shaped steel is connected and welded so that the upper flanges are flush with each other, and the lower flanges are not connected and welded because they are staggered from each other.

The double H-beam improvement beam extends from the end of the lower flange of the narrow-width H-beam to both sides of the web of the wide H-beam so as to be in close contact with both sides of the web of the wide H-beam, the lower part of the narrow H-beam One end is welded to the wide H-shaped steel and the other end is welded to the wide H-shaped steel so as to obliquely connect the overlap girder welded to the end of the flange and the lower flange of the wide H-shaped steel and the lower surface of the narrowed H-shaped steel. It includes a reinforcing girder joined to the bottom surface of the lower flange of the width H-shaped steel.

The reinforcing girder further includes a triangular reinforcing plate portion in close contact with the web of the wide H-shaped steel, and a first weld joint for welding the upper flange of the wide H-shaped steel and the upper flange of the narrow H-shaped steel; A second weld joint for welding the lower flange of the narrow H-shaped steel and the overlapping girder performs welding using a ceramic backing material, and a third weld joint for welding one end of the reinforcing girder and the wide H-shaped steel and a fourth weld joint for welding the other end of the reinforcing girder and the lower flange of the narrow H-shaped steel to perform general welding.

In the wide H-beam, a web is connected as a fixing means to a bracket H-beam that is welded to form a perpendicular to the square steel pipe column, and an upper flange and a lower flange are connected by a reinforcing means, and the wide H-beam and the bracket H-beam are connected to each other. is H-beam of the same standard with the same width of web and flange.

The fixing means includes a first fixing plate disposed to include one side web of the bracket H-shaped steel and one side web of the wide H-shaped steel in a state in which the web of the bracket H-beam and the web of the wide H-beam are abutted against each other, and the A second fixing plate and the first fixing plate disposed to include the other web of the bracket H-beam and the other web of the wide H-beam, the first fixing plate passing through the bracket H-beam and the second fixing plate, A plurality of high-tension bolts passing through the wide H-beam steel, the second fixing plate, the first fixing plate, the bracket H-beam and the end of the high-tensile bolt penetrating the second fixing plate, and the first fixing plate, the It includes a wide H-beam, a fixing nut fastened to the end of the high-tensile bolt penetrating the second fixing plate.

The reinforcing means includes a first reinforcing plate and the bracket disposed to include one side flange of the bracket H-shaped steel and one side flange of the wide H-shaped steel in a state where the flange of the bracket H-shaped steel and the wide H-shaped steel flange are facing each other. A second reinforcing plate disposed to include the other flange of the H-shaped steel and the other flange of the wide H-shaped steel, the first reinforcing plate, the bracket H-shaped steel and the second reinforcing plate passing through the first reinforcing plate, the first reinforcing plate, the A wide H-beam, a plurality of high-tensile bolts penetrating the second reinforcing plate, the first reinforcing plate, the bracket H-beam and the end of the high-tensile bolt penetrating the second reinforcing plate, and the first reinforcing plate, the wide Width H-shaped steel, and a fixing nut fastened to the end of the high-tensile bolt penetrating the second reinforcing plate material.

At a portion where the square steel pipe column and the bracket H-beam are joined, an upper reinforcement joined to the upper flange of the square-shaped steel pipe column and the bracket H-beam from an upper side of the bracket H-beam joined to the square steel pipe column, and the square shape and a lower reinforcement joined to the lower flange of the square steel pipe column and the bracket H-shaped steel at the lower side of the bracket H-shaped steel joined to the steel pipe column.

The steel structure in which the rectangular steel pipe column and the improved beam are joined may include an absorber for absorbing vibrations generated from external shocks by being coupled to a wide H-beam, a narrow H-beam, and a bracket H-beam.

The absorbing part may include an upper absorbing part coupled to the upper flange, a lower absorbing part coupled to the lower flange, and a connection part vertically connecting the upper absorbing part and the lower absorbing part in both directions.

The upper absorption part and the lower absorption part include a case, a vertical center support part mounted inside the case to support the vertical center of the case, and a horizontal center support part mounted inside the case to support the horizontal center of the case. And, elastically coupling the vertical center support portion and the horizontal center support portion to the case portion, and may include an elastic transmission unit for transmitting the vibration generated from an external shock to the vertical center support portion and the horizontal center support portion.

The vertical center support part may absorb the vibration transmitted from the elastic transmission part and be inserted through the horizontal center support part.

The horizontal center support unit may absorb the vibration transmitted from the elastic transmission unit.

The elastic transmission part may include a first elastic coupling part for coupling the case and the vertical center support part, and a second elastic coupling part for coupling the case and the horizontal center support part.

The second elastic coupling part may be inserted through the inside of the horizontal center support part.

The connection part may include a dispersion hole for dispersing vibrations not absorbed by the upper absorbing part and the lower absorbing part.

Since the present invention constructs a steel structure by welding and joining a double H-beam improved beam to a rectangular steel pipe column, bolt fastening is minimized and workability is improved.

In addition, in the present invention, the double H-beam improved beam has a structure that prevents stress concentration, and the ceramic backing material is applied when welding the wide H-beam and the narrow-width H-beam constituting the double H-beam improved to prevent leakage of the weldment. Therefore, the welding performance is improved and complete welding is possible, which improves the seismic structure performance, is advantageous in economical efficiency, and has the effect of improving the appearance.

In addition, since the present invention is applied to a rectangular steel pipe column, contamination of cobwebs and dust is prevented, a collision prevention sign can be attached to the rectangular steel tube column, and electric wiring is arranged in an empty space of the rectangular steel tube to prevent electrical wiring. It has the effect of preventing exposure to the outside.

1 is a perspective view showing a steel structure in which a rectangular steel pipe column and an improved beam are joined according to an embodiment of the present invention.
2 is a perspective view showing a double H-beam improved beam according to an embodiment of the present invention.
3 is a partial enlarged view showing a weld joint of a steel structure in which a rectangular steel pipe column and an improved beam are joined according to an embodiment of the present invention.
4 is a partial enlarged view showing a state in which the ceramic butting material is removed from the weld joint of the steel structure in which the rectangular steel pipe column and the improved beam are joined according to an embodiment of the present invention.
5 is a partially enlarged view showing the fixing means and the reinforcing means of the steel structure in which the rectangular steel pipe column and the improved beam are joined according to an embodiment of the present invention.
6 is a perspective view showing a steel structure in which a rectangular steel pipe column and an improved beam are joined according to another embodiment of the present invention.
7 is a perspective view showing a steel structure in which a rectangular steel pipe column and an improved beam are joined according to another embodiment of the present invention.
8 and 9 are perspective views illustrating an absorption part of a steel structure in which a rectangular steel pipe column and an improved beam are joined according to an embodiment of the present invention.

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

1 is a perspective view showing a steel structure in which a rectangular steel pipe column and an improved beam are joined according to an embodiment of the present invention, and FIG. 2 is a perspective view showing a double H-beam improved beam according to an embodiment of the present invention.

1 and 2, a steel structure 10-1 (hereinafter, a steel structure) in which a rectangular steel pipe column and an improved beam are joined according to an embodiment of the present invention is a rectangular steel pipe column 100-1 and double It includes an H-beam improved beam 200 .

The steel structure (10-1) is a structure in which a square steel pipe column (100-1) and a double H-beam improved beam (200) are joined, and the steel structure (10-1) to which the square steel tube column (100-1) is applied is a concrete structure. It is economical because it is easy to construct and the cost is relatively low compared to the structure.

In addition, the rectangular steel pipe column 100-1 has the advantage of preventing contamination of spider webs and dust, unlike the case of using the H-shaped steel column. In addition, it is possible to attach an anti-collision mark to the rectangular steel pipe column 100-1, and it is possible to prevent the electrical wiring from being exposed to the outside by arranging electric wiring in the empty space of the rectangular steel pipe column 100-1. . When electric wiring is arranged in the empty space of the square steel pipe column 100-1, there is no need for a separate hanger to hang the electric wire, so there is an advantage in that the height between floors becomes thin.

The rectangular steel pipe column 100-1 is fixed to the bottom surface by using the flat plate 50 joined to the lower surface.

Specifically, a flat plate 50 for fixing the square steel pipe column 100-1 to the bottom surface with a fixing bolt 55 is coupled to the lower surface of the square steel pipe column 100-1, and the fixing bolt 55 is a flat plate It is fastened to the four corners of (50) to fix the rectangular steel pipe column (100-1) to the bottom surface. When the rectangular steel pipe column 100-1 is used, the size of the flat plate 50 is slightly larger than that of the H-shaped steel column, but is more stably fixed to the floor surface.

The rectangular steel pipe column 100-1 is installed vertically on the floor surface. The rectangular steel pipe column 100-1 has the advantage of easy material supply and convenient construction. The double H-beam improved beam 200 is joined so as to form a vertical at each predetermined height of the square-shaped steel pipe column. In the embodiment, two double H-beam improved beams 200 are connected to a predetermined height of the rectangular steel pipe column 100-1, and the two rectangular steel pipe columns 100-1 have a height difference between the rectangular steel pipe columns 100- 1) is arranged and connected to form a right angle to the outer surface of In addition, the general H-beams 300 are joined to the prismatic steel pipe columns 100-1 so as to be perpendicular to each predetermined height. The double H-beam improved beam 200 and the general H-beam 300 are at right angles to each other.

Double H-beam improved beam 200 is a structure in which a wide H-beam 210 and a narrow H-beam 220 are welded in a straight line shape. This double H-beam improved beam 200 connects the wide H-beam 210 to the portion connected to the square steel pipe column 100-1 to increase the rigidity where the stress is concentrated.

The wide H-beam steel 210 is connected to the square steel pipe column 100-1. Specifically, the wide H-beam steel 210 is connected to the rectangular steel pipe column 100-1 via a bracket H-beam steel 260 to be described later. The narrow H-beam steel 220 is welded to be connected in a straight line to the end of the wide H-beam steel 210 . The wide H-beam steel 210 has a relatively wider width of the web 211 compared to the narrow H-beam steel 220, and the wide H-beam steel 210 and the narrow H-beam steel 220 have the upper portion for easy interconnection. The flanges 212 and 222 and the lower flanges 213 and 223 have the same width.

In the embodiment, the narrow H-beam 220 means a general H-beam, and the wide H-beam 210 means an improved H-beam in which the width of the web 211 is relatively wider than that of the general H-beam. do. In the embodiment, the wide H-beam 210 is an H-beam of the same standard as the bracket H-beam 260 in order to increase the strength of the part connecting the square steel pipe column 100-1 and the double H-beam improved beam 200. It is applied as an example. The bracket H-shaped steel 260 is welded to the square steel pipe column 100-1.

The wide H-beam steel 210 and the narrow H-beam steel 220 are connected and welded so that the upper flanges 212 and 222 are flush with each other, and the lower flanges 213 and 223 are positioned to be stepped (staggered) from each other and are not connected and welded.

*34 The double H-beam improved beam 200 further includes an overlapping girder 230 and a reinforcing girder 240 in order to increase the rigidity where the stress is concentrated.

The overlap girder 230 is formed in the shape of a plate welded to the end of the lower flange 223 of the narrow H-shaped steel 220, and the webs 221 and 211 of the narrow H-shaped steel 220 and the wide H-shaped steel 210. ) to increase the rigidity of the connection part.

The overlap girder 230 has a plate shape extending from the end of the lower flange 223 of the narrow H-shaped steel 220 to both sides of the web of the wide H-shaped steel 210, and the wide H-shaped steel 210. It is welded to the end of the lower flange 223 of the narrow H-shaped steel 220 so as to be in close contact with both sides of the web 211 . This overlapping girder 230 wraps the joint connection part of the wide H-beam steel 210 and the narrow-width H-beam steel 220 having different widths of the webs 211 and 221 in close contact with a predetermined area before and after the narrow width H-beam steel ( 220) and serves to reinforce the strength of the connection portion of the wide H-shaped steel 210.

The reinforcing girder 240 has one end wide H-beam steel 210 so as to obliquely connect the end of the lower flange 213 of the wide H-shaped steel 210 and the lower surface of the lower flange 223 of the narrow H-shaped steel 220 . ) and the other end is joined to the bottom surface of the lower flange 223 of the narrow H-shaped steel 220. The reinforcing girder 240 further includes a triangular reinforcing plate portion 241 in close contact with the web 211 of the wide H-shaped steel 210 . The reinforcing plate part 241 fills the stepped empty space between the lower flange of the narrow H-shaped steel and the web 211 of the wide H-shaped steel 210 to reinforce the strength of the inclined portion.

The reinforcing girder 240 and the reinforcing plate part 241 are for increasing the rigidity of the place where the stress is concentrated. Specifically, the reinforcing girder 240 and the reinforcing plate portion 241 are welded at an angle between the lower flanges 213 and 223 of the wide H-shaped steel 210 and the narrow H-shaped steel 220 to prevent stress concentration and increase the rigidity.

3 is a partially enlarged view showing a weld joint of a steel structure in which a rectangular steel pipe column and an improved beam are joined according to an embodiment of the present invention, and FIG. 4 is a steel structure in which a rectangular steel pipe column and an improved beam are joined according to an embodiment of the present invention. It is a partial enlarged view showing the appearance of removing the ceramic butting material from the weld joint of

As shown in FIG. 3 , the wide H-beam steel 210 and the narrow H-beam steel 220 are connected in a straight line by welding four places, and the four welded places are the first weld joint 251 . , and a second weld joint 252 , a third weld joint 253 , and a fourth weld joint 254 .

The first weld joint 251 is a part where the upper flange 212 of the wide H-shaped steel 210 and the upper flange 222 of the narrow H-shaped steel 220 are welded together, and the second weld joint 252 is The lower flange 213 of the narrow H-shaped steel 220 and the overlapping girder 230 are welded together, and the third welded joint 253 is one end of the reinforcing girder 240 and the wide H-shaped steel 210. It is a welding joint part, and the fourth weld joint part 254 is a part in which the other end of the reinforcing girder 240 and the lower flange 223 of the narrow H-shaped steel 220 are welded together.

The first weld joint 251 and the second weld joint 252 are welded using the ceramic backing material 255 to enable complete welding. When butt welding the ends of the upper flange 212 of the wide H-shaped steel 210 and the upper flange 222 of the narrow H-shaped steel 220, attaching the ceramic backing material 255 to the lower surface and performing welding The plate width of the ceramic backing material 255 is sufficiently welded so that complete welding is possible. Full welding improves the seismic performance by securing the rigidity of the weld joint.

In addition, when the lower flange 223 of the narrow width H-shaped steel 220 and the end of the overlap girder 230 are butt-welded, the ceramic backing material 255 is attached to the lower surface and welding is performed, the leakage (flowing down) of the weldment. ) is prevented and complete welding is possible because it is sufficiently welded for the plate width of the ceramic backing material 255. Therefore, in the part where butt welding is performed in a straight shape, complete welding is possible by attaching the ceramic backing material 255 to include the two lower surfaces and performing welding.

The third weld joint 253 for welding one end of the reinforcing girder 240 and the wide H-shaped steel 210 and the other end of the reinforcing girder 240 and the lower flange 223 of the narrow H-shaped steel 220 are welded. The fourth weld joint 254 to be joined performs general welding. Since the third weld joint 253 and the fourth weld joint 254 are buttted with a predetermined inclination, leakage of the weld is prevented, and thus the welding quality is excellent even without the use of the ceramic backing material 255 .

As shown in FIG. 4 , the ceramic backing material 255 is removed after the first weld joint 251 and the second weld joint 252 are welded together.

5 is a partially enlarged view showing the fixing means and the reinforcing means of the steel structure in which the rectangular steel pipe column and the improved beam are joined according to an embodiment of the present invention.

As shown in FIG. 5 , the wide H-beam steel 210 is connected to the bracket H-beam steel 260 by welding so as to be perpendicular to the square steel pipe column 100-1 and the web 211 is connected by a fixing means 270 . and the upper flange 212 and the lower flange 213 are connected by a reinforcing means 280 .

The wide H-shaped steel 210 and the bracket H-shaped steel 260 are H-shaped steels having the same width of the web 211,261 and the flanges 212,213, 262,263.

The fixing means 270 includes a first fixing plate 271 , a second fixing plate 272 , a high tension bolt 273 and a fixing nut 274 . The fixing means 270 fixes the butt state of the web 261 of the bracket H-shaped steel 260 and the web 211 of the wide H-shaped steel 210 .

In the state where the fixing means 270 abuts the web 261 of the bracket H-shaped steel 260 and the web 211 of the wide H-shaped steel 210, the first fixing plate 271 is the bracket H-shaped steel 260 of the It is arranged to include one side web 261 and one side web 211 of the wide H-shaped steel 210, and the second fixing plate 272 is the other side web 261 of the bracket H-shaped steel 260 and the wide H-shaped steel 210. It is arranged to include the other side of the web 211 of 210 .

And, the high tension bolt 273 penetrates the first fixing plate 271, the bracket H-beam steel 260 and the second fixing plate 272, and the first fixing plate 271, the wide H-beam steel 210, the second 2 It becomes a plurality of pieces passing through the fixing plate member 272 . The fixing nut 274 includes the end of the high tension bolt 273 passing through the first fixing plate 271, the bracket H-shaped steel 260 and the second fixing plate 272 and the first fixing plate 271, the wide H It is fastened to the end of the high tension bolt 273 penetrating the section steel 210 and the second fixing plate 272 .

The reinforcing means 280 includes a first reinforcing plate 281 , a second reinforcing plate 282 , a high tension bolt 283 , and a fixing nut 284 . The reinforcing means 280 fixes the flanges 262 and 263 of the bracket H-shaped steel 260 and the flanges 212 and 213 of the wide H-shaped steel 210 in abutment.

The reinforcing means 280 is a state in which the flanges 262 and 263 of the bracket H-shaped steel 260 and the flanges 212 and 213 of the wide H-shaped steel 210 are abutted, the first reinforcing plate 281 is the bracket of the H-shaped steel 260. It is arranged to include one side flanges 262 and 263 and one side flanges 212 and 213 of the wide H-shaped steel 210, and the second reinforcing plate 282 is the other side flanges 262 and 263 of the bracket H-shaped steel 260 and the wide H-shaped steel. It is arranged to include the flanges 212 and 213 on the other side of the 210 .

And, the high-tensile bolt 283 penetrates the first reinforcing plate 281, the bracket H-beam steel 260 and the second reinforcing plate 282, and the first reinforcing plate 281, the wide H-beam steel 210, the second 2 It becomes a plurality of pieces passing through the reinforcing plate material (282). The fixing nut 284 includes the end of the high tension bolt 283 passing through the first reinforcing plate 281, the bracket H-shaped steel 260 and the second reinforcing plate 282 and the first reinforcing plate 281, the wide H It is fastened to the end of the high tension bolt 283 penetrating the section steel 210 and the second reinforcing plate 282 .

6 is a perspective view showing a steel structure in which a rectangular steel pipe column and an improved beam are joined according to another embodiment of the present invention.

As shown in FIG. 6 , the steel structure 10-1a in which the rectangular steel pipe column and the improved beam are joined according to another embodiment further includes an upper reinforcing material 411 and a lower reinforcing material 413 .

The upper reinforcing material 411 and the lower reinforcing material 413 are provided at the portion where the bracket H-shaped steel 260 is joined in the rectangular steel pipe column 100-1. The upper reinforcement 411 is welded to the upper flange 262 of the square steel tube column 100-1 and the bracket H-shaped steel 260 on the upper side of the bracket H-shaped steel 260 joined to the square-shaped steel tube column 100-1. do. The intermediate reinforcement 412 is welded to the lower flange 263 of the square steel pipe column 100-1 and the bracket H-shaped steel 260 at the lower side of the bracket H-shaped steel 260 joined to the square-shaped steel tube column 100-1. do.

The upper reinforcing material 411 and the lower reinforcing material 413 serve to increase rigidity by relieving stress concentration at the joint portion of the rectangular steel pipe column 100 - 1 and the bracket H-shaped steel 260 . The upper reinforcing material 411 and the lower reinforcing material 413 further improve the structural performance of the joint portion of the square steel pipe column 100-1 and the bracket H-beam steel 260, so that the square steel tube column 100-1 is a double H-beam steel. The structural performance of supporting the improved beam 200 is further improved.

The steel structure 10-1 connected to the rectangular steel pipe column 100-1 by applying the above-described double H-beam improved beam 200 has a structure in which the double H-beam improved beam 200 prevents stress concentration, Weld joint is applied to minimize bolt fastening, but since the weld joint is structured to prevent leakage of the weldment by applying a ceramic backing material, welding performance is improved and complete welding is possible, thereby securing seismic structural performance.

If, instead of the double H-beam improved beam 200, the conventional double H-beam that widens the web width by splicing two H-beams up and down is applied, the number of parts for fastening the high-tensile bolts is relatively large, making construction cumbersome and labor-intensive It is economical due to the large number of high-tensile bolts and the appearance is not beautiful.

In addition, if a T-beam or an iron plate is used instead of the double H-beam improved beam 200, a plastic hinge occurs at the junction of the column and the beam, and there is a problem in that it is cumbersome and takes a lot of construction time to cut and use the T-beam. However, if the double H-beam improved beam 200 is used without using T-beam or steel plate for the beam, there is no need to cut the H-beam in half, and it is possible to construct using a short and thin H-beam if necessary, so the construction time is shortened. and cost is reduced

7 is a perspective view showing a steel structure in which a rectangular steel pipe column and an improved beam are joined according to another embodiment of the present invention.

As shown in FIG. 7 , the steel structure 10-1b in which the rectangular steel pipe column and the improved beam are joined according to another embodiment further includes a reinforcing rib 440 .

The reinforcing rib 440 is installed to connect the upper flange 222 and the lower flange 223 in the narrow H-shaped steel 220 . Furthermore, the reinforcing rib 440 is installed to connect the upper flange 222 and the lower flange 223 at a position connected to the reinforcing girder 240 in the narrow H-shaped steel 220 . The reinforcing rib 440 further improves the structural performance of the junction of the wide H-shaped steel 210 and the narrow H-shaped steel 220 and improves the structural performance of the narrow H-shaped steel 220 itself.

In addition, in another embodiment, the length (b) of the wide H-shaped steel 210 is relatively long compared to the length (a) of the bracket H-shaped steel 260 . It is preferable that the length (b) of the wide H-beam steel 210 is twice the length (a) of the bracket H-beam steel 260.

The construction method of the steel frame structure in which the prismatic steel pipe column and the improved beam are joined is first welding by welding the upper flange 212 of the wide H-beam 210 and the upper flange 222 of the narrow H-beam 220 by welding. Forming the joint 251, welding the lower flange 223 of the narrow H-shaped steel 220 and the overlap girder 230 to form a second weld joint 252, and the reinforcement girder 240 ) forming a third weld joint 253 by welding one end of the wide H-shaped steel 210 to the other end of the reinforcing girder 240 and the lower flange 223 of the narrow H-shaped steel 220. and forming a fourth weld joint 254 by welding.

In the step of forming the first weld joint 251 and the step of forming the second weld joint 252 , welding is performed using the ceramic backing material 255 to prevent leakage of the weldment, and the third weld joint 253 is performed. ) and the step of forming the fourth weld joint 254 is a structure to be welded with a predetermined inclination, and thus, general welding is performed because the weldment leak does not occur.

After the first weld joint 251 and the second weld joint 252 are formed, the ceramic backing material 255 is removed.

The embodiment of the present invention described above has a structure in which a double H-beam improved beam is welded to a wide H-beam and a narrow H-beam to prevent stress concentration, and a wide H-beam and a narrow H-beam constituting the double H-beam improved By applying a ceramic backing material to prevent leakage of the welded material when welding section steel, the welding performance is improved and complete welding is possible, which improves the seismic structure performance, is advantageous in economical efficiency, and improves the appearance.

The above-described steel structure in which the rectangular steel pipe column and the improved beam are joined may be applied to a steel structure forming a parking lot or a steel structure of a building.

The present invention can be applied by mixing the embodiment, another embodiment, and another embodiment.

8 and 9 are perspective views illustrating an absorption part of a steel structure in which a rectangular steel pipe column and an improved beam are joined according to an embodiment of the present invention.

Referring to FIGS. 8 and 9 , the steel structure in which the rectangular steel pipe column and the improved beam are joined may further include an absorption part.

The absorption unit 500 is coupled to the wide H-beam steel 210 , the narrow H-beam steel 220 , and the bracket H-beam steel 260 to absorb vibrations generated from external shocks. To this end, the absorbing part 500 may include an upper absorbing part 510 , a lower absorbing part 520 , and a connecting part 530 .

The upper absorption part 510 may be coupled to the upper flanges 212 and 262 of the wide H-shaped steel 210 , the narrow H-shaped steel 220 , and the bracket H-shaped steel 260 .

The lower absorption part 520 may be combined with the lower flanges 213 and 263 of the wide H-shaped steel 210 , the narrow H-shaped steel 220 , and the bracket H-shaped steel 260 .

The connection part 530 may vertically connect the upper flanges 212 and 262 and the lower flanges 213 and 263 .

The upper absorption part 510 and the lower absorption part 520 are,

Cases 511 and 521, vertical center support parts (512, 522), horizontal center support parts (513, 523), and may further include elastic transmission parts (514, 524).

The cases 511 and 521 may have internal spaces. In addition, the cases 511 and 521 are screwed to the upper flanges 212 and 262 and the lower flanges 213 and 263 of the wide H-shaped steel 210, the narrow H-shaped steel 220, and the bracket H-shaped steel 260, respectively. can be And the case (511, 521) is formed with a lid can be opened and closed.

The vertical center support portions 512 and 522 are mounted inside the cases 511 and 521 to support the vertical centers of the cases 511 and 521 .

In this case, the vertical center support portions 512 and 522 may be rods formed in a circle. Also, the vertical center support portions 512 and 522 may be made of rubber, or may be wrapped with a rubber material along the circumference.

The horizontal center support parts 513 and 523 may be mounted inside the cases 511 and 521 to support the horizontal centers of the cases 511 and 521 . Also, the horizontal center support portions 513 and 523 may be made of rubber or latex.

The elastic transmission units 514 and 524 elastically couple the vertical center support portions 512 and 522 and the horizontal center support portions 513 and 523 to the cases 511 and 521, and apply vibration generated from an external shock to the vertical center support portion 512. , 522) and can be transmitted to the horizontal center support (513, 523).

In addition, the elastic transmission parts 514 and 524 may include first elastic coupling parts 514a and 524a and second elastic coupling parts 514b and 524b.

The first elastic coupling portions 514a and 524a may couple the cases 511 and 521 and the vertical center support portions 512 and 522 to each other. In addition, the second elastic coupling portion (514b, 524b) may couple the cases (511, 521) and the horizontal center support (513, 523).

At this time, the second elastic coupling parts (514b, 524b) are inserted into the horizontal center support parts (513, 523), and at this time, the second elastic coupling parts (514b, 524b) are horizontal center support parts (513, 523) inside the horizontal center support part. An insertion hole may be formed so as not to be constrained from the .

In addition, the vertical center support parts (512, 522) can absorb the vibration transmitted from the elastic transmission, and penetrate through the horizontal center support (513, 523) can be inserted.

In addition, the horizontal center support portion (513, 523) can absorb the vibration transmitted from the elastic transmission.

The connection part 530 may include a dispersion hole 531 capable of dispersing vibrations not absorbed by the upper absorption part 510 and the lower absorption part 520 to the outside.

Although the present invention has been described with reference to the embodiment shown in the drawings, this is only exemplary, and various modifications and equivalent other embodiments are possible therefrom by those of ordinary skill in the art, as well as of the present invention The technical protection scope should be determined by the technical spirit of the appended claims.

10-1: Steel structure in which a rectangular steel pipe column and beam are joined
100-1: square steel pipe column 200: double H-beam improved beam
210: wide H-beam 211: web
212: upper flange 213: lower flange
220: narrow H-beam 221: web
222: upper flange 223: lower flange
230: overlap girder 240: reinforcement girder
241: reinforcing plate part 251: first welding joint
252: second weld joint 253: third weld joint
254: fourth weld joint 255: ceramic backing material
260: bracket H-beam 261: web
262: upper flange 263: lower flange
270: fixing means 271: first fixing plate
272: second fixing plate 273: high tension bolt
274: fixing nut 280: reinforcing means
281: first reinforcing plate 282: second reinforcing plate
283: high tension bolt 284: fixing nut
300: general H-beam 411: upper reinforcement
413: lower reinforcement 440: reinforcement rib
500: absorption part 510: upper absorption part
511: case 512: vertical center support
513: horizontal center support part 514: elastic transmission part
514a: first elastic coupling part 514b: second elastic coupling part
520: lower absorption part 521: case
522: vertical center support 523: horizontal center support
524: elastic transmission part 524a: first elastic coupling part
524b: second elastic coupling part 530: connection part
531: dispersion hole 50: flat plate
55: fixing bolt

Claims (3)

Square steel pipe columns installed vertically on the floor; and
a double H-beam improved beam connected to form a vertical position at each predetermined height of the rectangular steel pipe column;
including,
The double H-beam improvement
a wide H-beam connected to the prismatic steel pipe column; and
Narrow H-beams welded to the ends of the wide H-beams in a straight line shape;
including,
The wide H-beam has a relatively wide web width compared to the narrow H-beam, and the wide H-beam and the narrow H-beam have the same width of the upper flange and the lower flange,
The wide H-beam and the narrow H-beam are connected and welded so that the upper flanges are flush with each other, and the lower flanges are not connected and welded because they are staggered to each other,
The double H-beam improvement
Welded to the end of the lower flange of the narrow H-beam steel so as to extend from the end of the lower flange of the narrow H-shaped steel to both sides of the web of the wide H-shaped steel and closely contact both sides of the web of the wide H-shaped steel. overlapping girder; and
One end is welded to the wide H-shaped steel and the other end is joined to the lower flange of the narrow H-shaped steel so as to connect the end of the lower flange of the wide H-shaped steel and the bottom of the lower flange of the narrow H-shaped steel in an inclined manner. reinforcing girder;
includes,
The reinforcing girder further comprises a triangular reinforcing plate in close contact with the web of the wide H-beam,
A first weld joint for welding the upper flange of the wide H-shaped steel and the upper flange of the narrow H-shaped steel and a second weld joint for welding the lower flange of the narrow H-shaped steel and the overlapping girder are ceramic backing materials Welding using
A third weld joint for welding one end of the reinforcing girder and the wide H-shaped steel and a fourth weld joint for welding the other end of the reinforcing girder to the lower flange of the narrow H-shaped steel perform general welding,
In the wide H-beam, a web is connected as a fixing means to a bracket H-beam that is welded to form a perpendicular to the square steel pipe column, and an upper flange and a lower flange are connected as a reinforcing means,
The wide H-beam and the bracket H-beam are H-beams of the same standard with the same web and flange widths,
The fixing means
In the state where the web of the bracket H-beam and the web of the wide H-beam are abutted,
a first fixing plate disposed to include one side web of the bracket H-shaped steel and one side web of the wide H-shaped steel;
a second fixing plate material disposed to include the other side web of the bracket H-shaped steel and the other side web of the wide H-shaped steel;
a plurality of high-tensile bolts passing through the first fixing plate, the bracket H-beam and the second fixing plate, and passing through the first fixing plate, the wide H-beam, and the second fixing plate; and
The first fixing plate, the bracket H-beam and the end of the high-tension bolt passing through the second fixing plate, and the first fixing plate, the wide H-shaped steel, fastened to the end of the high-tensile bolt penetrating the second fixing plate fixed nut;
includes,
The reinforcement means
In the state where the flange of the bracket H-beam and the flange of the wide H-beam are facing each other,
a first reinforcing plate material disposed to include one side flange of the bracket H-shaped steel and one side flange of the wide H-shaped steel;
a second reinforcing plate material disposed to include the other flange of the bracket H-shaped steel and the other flange of the wide H-shaped steel;
a plurality of high-tensile bolts penetrating the first reinforcing plate, the bracket H-beam and the second reinforcing plate and penetrating the first reinforcing plate, the wide H-beam, and the second reinforcing plate; and
The first reinforcing plate, the bracket H-beam, and the end of the high-tensile bolt passing through the second reinforcing plate, and the end of the high-tensile bolt passing through the first reinforcing plate, the wide H-beam, and the second reinforcing plate. fixed nut;
including,
In the portion where the square steel pipe column and the bracket H-beam are joined,
an upper reinforcing material joined to the upper flange of the square steel pipe column and the bracket H-shaped steel at an upper side of the bracket H-shaped steel joined to the square-shaped steel pipe column;
a lower reinforcement joined to the lower flange of the square steel pipe column and the bracket H-shaped steel at the lower side of the bracket H-shaped steel joined to the square-shaped steel pipe column;
The steel structure in which the rectangular steel pipe column and the improved beam are joined,
It is coupled to the wide H-beam steel, the narrow H-beam steel, and the bracket H-beam steel and includes an absorbing part for absorbing vibrations generated from external shocks,
The absorber is
an upper absorption part coupled to the upper flange;
a lower absorption part coupled to the lower flange;
and a connection part vertically connecting the upper absorption part and the lower absorption part in both directions,
The upper absorption part and the lower absorption part,
case and
a vertical center support part mounted inside the case to support the vertical center of the case;
a horizontal center support part mounted inside the case to support the horizontal center of the case;
And an elastic transmission unit for elastically coupling the vertical center support portion and the horizontal center support portion to the case portion, and transmits vibration generated from an external shock to the vertical center support portion and the horizontal center support portion,
The vertical center support portion,
Absorbs the vibration transmitted from the elastic transmission unit, is inserted through the horizontal center support,
The horizontal center support portion,
Absorbs the vibration transmitted from the elastic transmission unit,
The elastic transmission unit,
And a first elastic coupling portion for coupling the case and the vertical center support;
and a second elastic coupling part for coupling the case and the horizontal center support part,
The second elastic coupling portion,
It is inserted through the inside of the horizontal center support part,
The connection part,
and a dispersion hole for dispersing vibrations not absorbed by the upper absorption part and the lower absorption part,
A steel structure in which a rectangular steel pipe column and an improved beam are joined.

delete delete

Images