KR102201377B1 - Steel frame of seismic performance structure in which square steel pipe columns and double H-beams are joined and construction method thereof - Google Patents

Abstract

The present invention relates to a steel frame, which includes: a column (100) vertically installed on a floor surface; and a plurality of beams (200) bonded to be perpendicular to the column (100) at each predetermined height of the column (100), wherein at least one of the plurality of beams uses double H-steel (210) in a portion bonded to the column (100). The steel frame applies H-steel and double H-steel to the beams connected to the column by replacing existing T-steel or steel plates, thereby having improved constructability, having excellent performance of a seismic structure, being advantageous for economic feasibility, and having a beautiful appearance.

Description

Steel frame of seismic performance structure in which square steel pipe columns and double H-beams are joined and construction method thereof

The present invention relates to a steel frame of a seismic performance structure in which a square steel pipe column and a double H-beam are joined, and a construction method thereof, and in more detail, by using a square steel pipe column, contamination of spider webs and dust is prevented, and collision with the steel pipe column It is possible to attach prevention signs, and because H-beams are used instead of the existing T-beams or steel plates as beams connected to columns, the workability is improved, the seismic structure performance is improved, and the steel structure is advantageous in economic efficiency.

Steel structure is a structure in which sections, steel plates, plates, etc. are manufactured and assembled into columns and beams by bolts and welding joints, so the stability of the joints is important, and the shape of the joints affects the overall design and construction.

The bonding methods used for steel structures are typically bolted and welded. There are cases when additional beams are installed for reinforcement purposes in the existing steel structure, but bolt jointing is preferred in terms of constructability. However, the joint of the column and the beam is advantageous in terms of force or stress transmission.

Joints requiring moment joints were treated with welding or bolt joints, but welded joints are disadvantageous in workability and economics, and the base material may be deformed by welding heat, and on-site quality control is difficult. Bolted joints are advantageous in workability, but vibration, When subjected to impact or repetitive load, a large deformation occurs in the joint and a problem occurs in which the bolt is loosened.

In addition, T-beams or steel plates are often used as beams to be joined to columns.If T-beams or steel plates are used as beams, plastic hinges may be generated at the joints and the seismic structure performance may be weak.In the case of T-beams, it is troublesome to cut and use. Due to this, there is a problem that it takes a lot of construction time and increases cost.

Registered Patent Publication No. 1642420 (registered on July 19, 2016)

The present invention was conceived to solve the above problems, and an object of the present invention is to use H-beams instead of T-beams or steel plates connected to columns to improve workability, to improve seismic structure performance, and to be economical. It is to provide a steel structure with improved aesthetics.

A steel frame according to an embodiment of the present invention for solving the above problems and a construction method thereof includes a column installed perpendicular to the floor surface and a plurality of beams joined to be perpendicular to the column at a predetermined height of the column, and the At least one of the plurality of beams uses a double H-beam at the junction with the column.

The column is H-beam, and a flat plate for fixing the fixing bolt to the bottom surface of the H-beam is joined to the lower surface of the H-beam, and the fixing bolt is a position between the flange and the flange forming both sides of the web of the H-beam. Is fastened to the flat plate and fixed to the bottom surface, and the double H-beam includes a web, an upper flange and a lower flange formed on both sides of the web, and an intermediate flange formed between the upper flange and the lower flange. And the width between the upper flange and the intermediate flange is the same as that of the general H-beam, and the width between the lower flange and the intermediate flange is relatively narrow compared to the width of the general H-beam, The double H-beam is another double H-beam or general H-beam and the web are connected by a fixing means, and the upper and lower flanges are connected by reinforcing means, and the fixing means is the web of the double H-beam and the other double H-beam. In a state where the web is abutted, a first fixing plate disposed to include one web of the double H-beam and one web of the other double H-beam, the other web of the double H-beam, and the other web of the other double H-beam And passing through the second fixed plate member and the first fixed plate member, the double H-beam and the second fixing plate disposed to face the first fixing plate, and the first fixing plate, the other double H-beam, and the second A plurality of high-tension bolts penetrating the fixed plate, the first fixed plate, the double H-beam, and the end of the high-tensile bolt penetrating through the second fixed plate, and the first fixed plate, the other double H-beam, the second fixing It includes a fixing nut that is fastened to the end of the high-tension bolt penetrating the plate, and the column is a column reinforcement that connects the flange and the flange in a Z-shape or connects in a straight shape, and the flange and the flange A column reinforcement connected in a Z-shape is installed on the lower side of the beam bonded to the column, and a column stiffener connecting the flange and the flange in a straight shape is the upper side of the beam bonded to the column It is installed as.

In the portion where the double H-beam is joined in the pillar, one edge is joined to the flange of the pillar, and the lower edge perpendicular to the one edge is perpendicular to the corner reinforcement and the corner reinforcement joined to the upper flange of the double H-beam. A beam flange reinforcement is installed to connect the flange of the double H-beam and the flange, and the auxiliary reinforcement is further installed to connect the flange and the flange to the beam.

Alternatively, the pillar is a square steel pipe, a plate for fixing the pillar to the bottom surface is joined to the lower surface of the square steel pipe, the fixing bolt is fastened to the four corners of the plate and fixed to the bottom surface, the The H-beam is a structure including a web, an upper flange and a lower flange formed on both sides of the web, and an intermediate flange formed between the upper flange and the lower flange, and between the upper flange and the intermediate flange. The width of is the same as that of the general H-beam, the width between the lower flange and the middle flange is relatively narrow compared to the width of the general H-beam, and the double H-beam is another double H-beam or general H-beam. And the web are connected by a fixing means, and an upper flange and a lower flange are connected by a reinforcing means.

In the part of the pillar to which the double H-beam is joined, the upper reinforcement bonded to the pillar and the upper flange from the upper side of the double H-beam bonded to the pillar, and the middle side of the double H-beam bonded to the pillar. An intermediate reinforcing material bonded to the pillar and the intermediate flange, and a lower reinforcing material bonded to the pillar and the lower flange at the lower side of the double H-beam bonded to the pillar, and an auxiliary installed to connect the flange and the flange to the beam More reinforcement is installed.

The pillar is a circular steel pipe, a plate for fixing the pillar to the bottom surface is joined to the lower surface of the circular steel pipe, the fixing bolt is fastened to the four corners of the plate and fixed to the bottom surface, the double H The section steel has a structure including a web, an upper flange and a lower flange formed on both sides of the web, and an intermediate flange formed between the upper flange and the lower flange, and a width between the upper flange and the intermediate flange Is the same as the width of the general H-beam, the width between the lower flange and the middle flange is relatively narrow compared to the width of the general H-beam, and the double H-beam is another double H-beam or the general H-beam and web Is connected by a fixing means, and an upper flange and a lower flange are connected by a reinforcing means, and a portion of the column to which the double H-beam is joined is joined to the column and the upper flange from the upper side of the double H-beam to be joined to the column. The upper reinforcing member and the intermediate reinforcing member bonded to the column and the intermediate flange at the middle side of the double H-beam bonded to the column and the column and the lower flange at the lower side of the double H-beam bonded to the column Including a lower reinforcement, the beam is further provided with an auxiliary reinforcement installed to connect the flange and the flange.

Alternatively, the column is a square steel pipe, the double H-beam is a structure including a web, an upper flange and a lower flange formed on both sides of the web, and an intermediate flange formed between the upper flange and the lower flange. , The width between the upper flange and the intermediate flange is the same as the width of the general H-beam, the width between the lower flange and the intermediate flange is relatively narrow compared to the width of the general H-beam, the double H As for the section steel, other double H-beams or general H-beams and webs are connected by fixing means, and the upper and lower flanges are connected by reinforcing means, and the double H-beams are joined to the pillars at a portion where the double H-beams are joined at the pillar. An upper reinforcement bonded to the pillar and the upper flange at the upper side of the section steel, and an intermediate reinforcement bonded to the pillar and the intermediate flange at an intermediate side of the double H-beam bonded to the pillar, and the double H-beam bonded to the pillar It includes a lower reinforcing material bonded to the column and the lower flange from the lower side of.

In the double H-beam, a reinforcing sleeve for reinforcing strength is further disposed in a web between the intermediate flange and the lower flange, and the reinforcing sleeve includes a hole formed in the web between the intermediate flange and the lower flange; It is a circular or plate shape that is fitted into the hole.

And a support structure that is joined to at least one of the reinforcement structure, the intermediate flange, and the lower flange to intimately fix the reinforcement structure between the intermediate flange and the lower flange, and the support structure includes a cylindrical shape, a flat plate shape, and A steel structure including at least one or more of a plurality of flat plates arranged at predetermined intervals.

The steel structure according to the first embodiment of the present invention is a structure in which H-beams and H-beams are joined, and some of the H-beams use double H-beams, so that the structural performance of the beams is improved and the seismic structure performance is excellent, It is easy to construct and has an economic effect due to its low cost.

The steel structure according to the second embodiment of the present invention is a structure in which H-beams and H-beams are joined, and some of the H-beams use double H-beams to improve the structural performance of the beams, and Since it further includes a column stiffener, a corner stiffener, a beam flange stiffener, etc. at the junction, there is an effect of increasing the structural rigidity of the column and further improving the structural performance of the junction between the column and the beam.

The steel structure of the third to fourth embodiments of the present invention, unlike the second embodiment using the H-beam column, is prevented from contamination such as spider webs and dust, and it is possible to attach anti-collision signs to the steel pipe column, There is an effect of preventing the electric wiring from being exposed to the outside by arranging electric wiring or the like in an empty space of the steel pipe.

In addition, the steel structure according to the fifth embodiment of the present invention further includes a steel plate sleeve and a support structure to further improve the seismic structure performance of the beam.

In addition, since the first to fifth embodiments of the present invention use H-beams instead of conventional T-beams or steel plates as beams connected to columns, workability is improved, seismic structure performance is improved, and economical efficiency is advantageous.

1 is a perspective view showing a steel structure according to a first embodiment of the present invention.
2 is a perspective view showing a steel structure according to a second embodiment of the present invention.
3 is a partially enlarged perspective view showing a portion of a steel structure according to a second embodiment of the present invention in which a column and a double H-beam are joined.
4 is an enlarged perspective view of a reinforcing member installed on a column and a double H-beam in a steel structure according to a second embodiment of the present invention.
5 is a perspective view showing a steel structure according to a third embodiment of the present invention.
6 is a perspective view showing a steel structure according to a fourth embodiment of the present invention.
7 is a perspective view showing a steel structure according to a fifth 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 according to a first embodiment of the present invention.

As shown in Figure 1, the steel structure 10 according to the first embodiment includes a column 100 and a beam 200. The pillar 100 is installed vertically on the floor surface. The beam 200 is composed of a plurality of joints to be perpendicular to the pillar 100 at every predetermined height of the pillar 100. In the embodiment, three beams 200 are bonded to a certain height of the column 100, and the three beams 200 are disposed and bonded to form a right angle to each other.

The pillar 100 uses H-beam. At least one of the plurality of beams 200 uses a double H-beam 210 at the junction with the column 100. In addition, some of the plurality of beams 200 may use a double H-beam 210 and the rest may use a general H-beam 220.

Specifically, the steel structure 10 according to the first embodiment is a structure in which the H-beam column 100 and the H-beam 200 are joined, and some of the H-beam 200 are double H-beam 210 By using, the structural performance of the beam 200 is improved and the seismic structure performance is excellent. The steel structure 10 applying the H-beam column 100 and the H-beam 200 is economical because it is easier to construct and relatively inexpensive in cost compared to a concrete structure.

Double H-beam 210 is formed between the web 211, the upper flange 212 and the lower flange 214 formed on both sides of the web 211, and the upper flange 212 and the lower flange 214 It has a structure including the intermediate flange 213 to be.

In the double H-beam 210, the width between the upper flange 212 and the intermediate flange 213 is the same as that of the general H-beam 220, and the width between the lower flange 214 and the intermediate flange 213 Is relatively narrow compared to the width of the general H-beam 220. The lower flange 214 and the intermediate flange 213 are formed by further forming an H-beam having a relatively narrow width on the lower surface of the general H-beam 220 to reinforce the strength of the general H-beam.

Two H-beams may be joined up and down to form a double H-beam 210, but in this case, the weight is increased and the load applied to the pillar may increase. Therefore, the double H-beam of an integrated shape in which the width between the lower flange 214 and the intermediate flange 213 is further narrowed compared to the width between the upper flange 212 and the intermediate flange 213 ( 210) is applied to reduce the load applied to the column 100 while reinforcing the structural strength of the beam 200.

Double H-beam 210 is another double H-beam 210a or general H-beam 220 and the web 211 is connected and fixed by a fixing means (230). In addition, the double H-beam 210 has an upper flange 212 and a lower flange 214 connected and fixed with a reinforcing means 240.

The detailed structure of the fixing means 230 and the reinforcing means 240 will be described in detail in the second embodiment of FIG. 3.

The steel structure 10 includes a corner reinforcement 252 and an auxiliary reinforcement 254.

The corner reinforcement 252 is joined to a portion of the column 100 to which the double H-beam 210 is joined. The corner reinforcement 252 has one edge joined to the one side flange 113 of the column 100, and the lower edge perpendicular to the one side edge is joined to the upper flange 212 of the double H-beam 210. Since the joint portion between the column 100 and the beam 200 is a plastic hinge generation section where a large load is applied, a corner reinforcement 252 is applied to prevent the occurrence of the plastic hinge.

The auxiliary reinforcing material 254 is installed to connect the flange 212 and the flange 213 in the beam 200 composed of the general H-beam 220. Moreover, the auxiliary reinforcing member 254 is installed to connect the flange 212 and the flange 213 at the portion of the general H-beam 220 connected to the end position of the double H-beam 210. The corner stiffener 252 and the auxiliary stiffener 254 increase the structural rigidity of the column 100, further improve the structural performance of the joint area between the column 100 and the beam 200, and the structural performance of the beam 200 itself. Also improves.

If a T-beam or a steel plate is used for the beam 200, a plastic hinge occurs at the junction of the column and the beam, and there is a problem that the T-beam must be cut and used, and a lot of construction time is required. However, if you use H-beam without using T-beam or steel plate for beam 200, there is no need to cut H-beam in half, and it is possible to use short and thin H-beam if necessary, so construction time is shortened and cost is reduced. Savings. In addition, there is an advantage that the interlayer height is reduced when a short and thin H-beam is used instead of a T-beam or a steel plate for the beam 200. Specifically, the portion replacing the existing T-beam or steel plate may be a portion of the lower flange 214 in the double H-beam 210.

The pillar 100 is fixed to the bottom surface using the flat plate 50 bonded to the bottom surface.

Specifically, a flat plate 50 for fixing the fixing bolt 55 to the bottom surface of the column 100 is bonded to the lower surface of the H-beam column 100, and the fixing bolt 55 is a web of the H-beam column 100 It is fastened to the flat plate 50 at a position between the flange 112 and the flange 113 forming both sides of 111 to fix the column 100 to the bottom surface. If the H-beam column 100 is used, the column 100 can be firmly fixed to the floor while reducing the size of the flat plate 50, thus minimizing the area of the flat plate 50 on which the column 100 is fixed to the floor. can do.

2 is a perspective view showing a steel structure according to a second embodiment of the present invention.

As shown in Figure 2, the steel structure 10' according to the second embodiment includes a column 100 and a beam 200. The pillar 100 is installed vertically on the floor surface. The beam 200 is composed of a plurality of joints to be perpendicular to the pillar 100 at every predetermined height of the pillar 100. In the embodiment, three beams 200 are bonded to a certain height of the column 100, and the three beams 200 are disposed and bonded to form a right angle to each other.

The pillar 100 uses H-beam. At least one of the plurality of beams 200 uses a double H-beam 210 at the junction with the column 100. In addition, some of the plurality of beams 200 may use a double H-beam 210 and the rest may use a general H-beam 220.

Specifically, the steel structure 10 ′ according to the second embodiment is a structure in which the H-beam column 100 and the H-beam 200 are joined, and some of the H-beam 200 is a double H-beam 210 ) To improve the structural performance of the beam 200 and to make the seismic structure excellent. The steel structure 10 ′ applying the H-beam column 100 and the H-beam 200 is economical because it is easier to construct and relatively inexpensive in cost compared to a concrete structure.

The pillar 100 is fixed to the bottom surface using the flat plate 50 bonded to the bottom surface.

Specifically, a flat plate 50 for fixing the fixing bolt 55 to the bottom surface of the column 100 is bonded to the lower surface of the H-beam column 100, and the fixing bolt 55 is a web of the H-beam column 100 It is fastened to the flat plate 50 at a position between the flange 112 and the flange 113 forming both sides of 111 to fix the column 100 to the bottom surface. If the H-beam column 100 is used, the column 100 can be firmly fixed to the floor while reducing the size of the flat plate 50, thus minimizing the area of the flat plate 50 on which the column 100 is fixed to the floor. can do.

3 is a partially enlarged perspective view showing a portion of a steel structure according to a second embodiment of the present invention in which a column and a double H-beam are joined.

3, the double H-beam 210 includes a web 211, an upper flange 212 and a lower flange 214 formed on both sides of the web 211, an upper flange 212 and a lower It has a structure including an intermediate flange 213 formed between the flanges 214.

In the double H-beam 210, the width between the upper flange 212 and the intermediate flange 213 is the same as that of the general H-beam 220, and the width between the lower flange 214 and the intermediate flange 213 Is relatively narrow compared to the width of the general H-beam 220. The lower flange 214 and the intermediate flange 213 are formed by further forming an H-beam having a relatively narrow width on the lower surface of the general H-beam 220 to reinforce the strength of the general H-beam.

Two H-beams may be joined up and down to form a double H-beam 210, but in this case, the weight is increased and the load applied to the pillar may increase. Therefore, the double H-beam of an integrated shape in which the width between the lower flange 214 and the intermediate flange 213 is further narrowed compared to the width between the upper flange 212 and the intermediate flange 213 ( 210) is applied to reduce the load applied to the column 100 while reinforcing the structural strength of the beam 200.

Double H-beam 210 is another double H-beam 210a or general H-beam 220 and the web 211 is connected and fixed by a fixing means (230). In addition, the double H-beam 210 has an upper flange 212 and a lower flange 214 connected and fixed with a reinforcing means 240.

The fixing means 230 includes a first fixing plate 231, a second fixing plate 232, a high tension bolt 233, and a fixing nut 234.

The first fixed plate 231 is in a state where the web 211 of the double H-beam 210 and the web 211a of the other double H-beam 210 are abutted, one side web 211 of the double H-beam 210 and It is arranged to include the web 211a on one side of the other double H-beam 210. The second fixed plate 232 includes the other web 211 of the double H-beam 210 and the other web 211 of the double H-beam 210 and is disposed to face the first fixed plate 231. The high tension bolt 233 penetrates the first fixing plate 231, the double H-beam 210 and the second fixing plate 232, and the first fixing plate 231, the other double H-beam 210, the second fixing It consists of a plurality of pieces passing through the plate material 232. The fixing nut 234 includes the first fixing plate 231, the double H-beam 210 and the end of the high tension bolt 233 penetrating through the second fixing plate 232 and the first fixing plate 231, the other double H It is fastened to the end of the high-tension bolt 233 passing through the section steel 210 and the second fixing plate 232. The high-tension bolt 233 is fastened in the same number to the web 211 side of the double H-beam 210 and the web 211a side of the other double H-beam 210 so that the double H-beam 210 and the web 211 of the double H-beam 210 The web 211a of the other double H-beam 210 is firmly fixed with the same force.

The high-tension bolt 233 is a high-strength bolt, a round head bolt, and a thread formed in the body. The fixing nut 234 may be a nut having an anti-loosening function including a washer. In addition, although not shown, the fixing nut 234 is composed of two nuts, and the two nuts apply a certain torque to the screw thread due to the double contact effect to function to prevent loosening.

The reinforcing means 240 includes a first reinforcing plate 241, a second reinforcing plate 242, a high tension bolt 243, and a fixing nut 244.

The first reinforcing plate 241 is in a state where the upper flange 212 of the double H-beam 210 and the upper flange 212a of the other double H-beam 210 are abutted on one side of the double H-beam 210 ( It is disposed to include an upper flange 212a on one side of the double H-beam 210 different from 212). The second reinforcing plate 242 includes the other upper flange 212 of the double H-beam 210 and the other upper flange 212a of the other double H-beam 210 and is arranged to face the first reinforcing plate 241 do.

The high tension bolt 243 penetrates the first reinforcing plate 241, the double H-beam 210 and the second reinforcing plate 242, and passes through the first reinforcing plate 241, the other double H-beam 210, and the second reinforcement It is composed of a plurality of pieces passing through the plate material 242. The fixing nut 244 includes the first reinforcing plate 241, the double H-beam 210 and the end of the high tension bolt 243 penetrating through the second reinforcing plate 242 and the first reinforcing plate 241, the other double H It is fastened to the end of the high-tension bolt 233 passing through the section steel 210 and the second reinforcing plate 242. The high-tension bolts 243 are fastened in the same number to the upper flange 212 side of the double H-beam 210 and the upper flange 212a side of the other double H-beam 210, and the upper flange of the double H-beam 210 ( 212) and the upper flange 212a of the other double H-beam 210 are firmly fixed with the same force.

In addition, the first reinforcing plate 241 is in a state in which the intermediate flange 213 of the double H-beam 210 and the intermediate flange 213a of the other double H-beam 210 are abutted on one side of the double H-beam 210 The flange 213 and the other double H-beam 210 are arranged to include an intermediate flange 213a on one side. The second reinforcing plate 242 includes the other intermediate flange 213 of the double H-beam 210 and the other intermediate flange 213a of the other double H-beam 210, and is arranged to face the first reinforcing plate 241 do.

The high tension bolt 243 penetrates the first reinforcing plate 241, the double H-beam 210 and the second reinforcing plate 242, and passes through the first reinforcing plate 241, the other double H-beam 210, and the second reinforcement It is composed of a plurality of pieces passing through the plate material 242. The fixing nut 244 includes the first reinforcing plate 241, the double H-beam 210 and the end of the high tension bolt 243 penetrating through the second reinforcing plate 242 and the first reinforcing plate 241, the other double H It is fastened to the end of the high-tension bolt 233 passing through the section steel 210 and the second reinforcing plate 242. The high tension bolts 243 are fastened in the same number to the intermediate flange 213 side of the double H-beam 210 and the intermediate flange 213a side of the other double H-beam 210, so that the intermediate flange of the double H-beam 210 ( 213) and the intermediate flange (213a) of the other double H-beam 210 is firmly fixed with the same force.

In addition, the first reinforcing plate 241 is in a state in which the middle flange 213 of the double H-beam 210 and the lower flange 214a of the other double H-beam 210 are abutted on one side of the double H-beam 210 It is disposed to include a lower flange 214a on one side of the double H-beam 210 different from the flange 214. The second reinforcing plate 242 includes the other lower flange 214 of the double H-beam 210 and the other lower flange 214a of the other double H-beam 210 and is arranged to face the first reinforcing plate 241 do.

The high tension bolt 243 penetrates the first reinforcing plate 241, the double H-beam 210 and the second reinforcing plate 242, and passes through the first reinforcing plate 241, the other double H-beam 210, and the second reinforcement It is composed of a plurality of pieces passing through the plate material 242. The fixing nut 244 includes the first reinforcing plate 241, the double H-beam 210 and the end of the high tension bolt 243 penetrating through the second reinforcing plate 242 and the first reinforcing plate 241, the other double H It is fastened to the end of the high-tension bolt 233 passing through the section steel 210 and the second reinforcing plate 242. The high tension bolts 243 are fastened in the same number to the lower flange 214 side of the double H-beam 210 and the lower flange 214a side of the other double H-beam 210 to the lower flange of the double H-beam 210 ( 212) and the lower flange (214a) of the other double H-beam 210 is firmly fixed with the same force.

4 is an enlarged perspective view of a reinforcing member installed on a column and a double H-beam in a steel structure according to a second embodiment of the present invention.

As shown in FIG. 4, the steel structure 10 ′ further includes a stiffener 250 for reinforcing the structural strength of the column 100 or the beam 200.

The reinforcement member 250 includes a column reinforcement member 251, a corner reinforcement member 252, a beam flange reinforcement member 253, and an auxiliary reinforcement member 254.

The pillar reinforcement 251 is installed on the pillar 100. The column reinforcement 251 is formed in a shape that connects the flange 112 and the flange 113 of the column 100 in a Z-shape (or zigzag shape) or in a straight shape, and is welded to the column 100 do. The column reinforcement 251 connecting the flange 112 and the flange 113 in a Z-shape is installed under the beam 200 that is joined to the column 100, and the flange 112 and the flange 113 are straight The pillar reinforcement 251 connected in a shape is installed on the upper side of the beam 200 joined to the pillar 100.

The corner reinforcement member 252 and the beam flange reinforcement member 253 are joined to a portion of the column 100 to which the double H-beam 210 is joined.

The corner reinforcement 252 has one edge joined to the one side flange 113 of the column 100, and the lower edge perpendicular to the one side edge is joined to the upper flange 212 of the double H-beam 210.

The beam flange reinforcement 253 is joined to connect the flange 112 and the flange 113 of the double H-beam 210 so as to be perpendicular to the corner reinforcement 252.

The auxiliary stiffener 254 is installed to connect the flange and the flange in the beam 200 composed of the general H-beam 220.

The column stiffener 251, the corner stiffener 252, the beam flange stiffener 253, and the auxiliary stiffener 254 increase the structural rigidity of the column 100 and the structural performance of the joint portion between the column 100 and the beam 200 It further improves, and also improves the structural performance of the beam 200 itself.

In addition, the second embodiment of the present invention does not use T-beams or steel plates for the beam 200, but if H-beams are used, it is not necessary to cut H-beams in half, and it is recommended to use short and thin H-beams as necessary. As it is possible, construction time is shortened and costs are reduced. In addition, there is an advantage that the interlayer height is reduced when a short and thin H-beam is used instead of a T-beam or a steel plate for the beam 200. Specifically, the portion replacing the existing T-beam or steel plate may be a portion of the lower flange 214 in the double H-beam 210.

5 is a perspective view showing a steel structure according to a third embodiment of the present invention.

As shown in Figure 5, the steel structure (10a) according to the third embodiment includes a column (100a) and a beam (200). The pillars 100a are installed perpendicular to the floor surface. The beam 200 is composed of a plurality of beams that are joined to be perpendicular to the pillars 100a at every predetermined height of the pillars 100a. In the embodiment, three beams 200 are bonded to a certain height of the column 100, and the three beams 200 are disposed and bonded to form a right angle to each other.

In the third embodiment, the pillar 100a uses a square steel pipe. At least one of the plurality of beams 200 uses a double H-beam 210 at the junction with the column 100. In addition, some of the plurality of beams 200 may use a double H-beam 210 and the rest may use a general H-beam 220.

Specifically, the steel structure 10a according to the third embodiment is a structure in which a square steel pipe column 100a and an H-beam 200 are joined, and some of the H-beam 200 are double H-beam 210 By using, the structural performance of the beam 200 is improved and the seismic structure performance is excellent. The steel structure (10a) to which the square steel pipe column (100a) and the H-beam (200) are applied is economical because it is easier to construct and the cost is relatively inexpensive compared to the concrete structure.

In addition, the steel structure 10a of the third embodiment using the square steel pipe column 100a has the advantage of preventing contamination such as spider webs and dust unlike the second embodiment using the H-beam column 100. In addition, the steel structure (10a) of the third embodiment using the square steel pipe column (100a) can be attached to the column (100a), such as anti-collision signs. In addition, the steel structure 10a of the third embodiment using the square steel pipe pillar 100a can prevent the electric wiring from being exposed to the outside by arranging electric wiring or the like in the empty space of the square steel pipe pillar 100a. When electric wiring or the like is placed in the empty space of the square steel pipe column 100a, there is an advantage in that the interlayer height is thinned because a separate hanger for hanging the electric wire is not required.

The pillar 100a is fixed to the bottom surface using a flat plate 50 bonded to the bottom surface.

Specifically, a plate (50a) for fixing a fixing bolt to the square steel pipe column (100a) to the bottom surface of the square steel pipe column (100a) is joined, and the fixing bolt (55) is fastened to the four corners of the plate (50a) The square steel pipe column (100a) is fixed to the bottom surface. If the square steel pipe column (100a) is used, the size of the flat plate (50) is slightly larger compared to the case of using the H-beam column (100), but the column (100a) is more stably fixed to the bottom surface.

A description of the configuration of the third embodiment overlapping with the second embodiment will be omitted. In the third embodiment, the structure of the double H-beam structure, the fixing means, and the reinforcing means are the same as those of the second embodiment.

The steel structure 10a according to the third embodiment is different from the second embodiment in a configuration further including an upper reinforcement 271, an intermediate reinforcement 272, and a lower reinforcement 273.

The upper reinforcing material 271, the intermediate reinforcing material 272, and the lower reinforcing material 273 are provided at a portion where double H-beams are joined in the column. The upper reinforcing material 271 is joined to the pillar and the upper flange on the upper side of the double H-beam joined to the pillar. The intermediate reinforcement 272 is joined to the pillar and the intermediate flange at the middle side of the double H-beam joined to the pillar. The lower stiffener 273 is joined to the pillar and the lower flange on the lower side of the double H-beam joined to the pillar.

The steel structure according to the third embodiment improves the structural performance of the joint portion of the column and the beam by connecting double H-beams to the square steel pipe column, and the flange and flange of the general H-beam at the position corresponding to the end of the double H-beam. An auxiliary reinforcement is placed between the beams to improve the structural performance of the beam, and the appearance is excellent by using a square steel pipe column (especially square steel pipe column) as a column, and it is possible to prevent contamination of spider webs and dust, and an anti-collision sign. It is easy to attach, and the construction cost is economical.

In addition, the third embodiment of the present invention does not use T-beams or steel plates for the beam 200, but if H-beams are used, there is no need to cut H-beams in half, and it is recommended to use short and thin H-beams as necessary. As it is possible, construction time is shortened and costs are reduced. In addition, there is an advantage that the interlayer height is reduced when a short and thin H-beam is used instead of a T-beam or a steel plate for the beam 200. Specifically, the portion replacing the existing T-beam or steel plate may be a portion of the lower flange 214 in the double H-beam 210.

6 is a perspective view showing a steel structure according to a fourth embodiment of the present invention.

As shown in Figure 6, the steel structure (10b) according to the fourth embodiment includes a column (100a) and a beam (200). The pillar 100b is installed perpendicular to the floor surface. The beam 200 is composed of a plurality of beams that are joined to be perpendicular to the pillars 100a at every predetermined height of the pillars 100b. In the embodiment, three beams 200 are bonded to a certain height of the column 100b, and the three beams 200 are disposed and bonded to form a right angle to each other.

In the fourth embodiment, the pillar 100b uses a circular steel pipe. At least one of the plurality of beams 200 uses a double H-beam 210 at the junction with the column 100. In addition, some of the plurality of beams 200 may use a double H-beam 210 and the rest may use a general H-beam 220.

Specifically, the steel structure 10a according to the fourth embodiment is a structure in which a circular steel pipe column 100b and an H-beam 200 are joined, and some of the H-beam 200 are double H-beam 210 By using, the structural performance of the beam 200 is improved and the seismic structure performance is excellent. The steel structure (10b) to which the circular steel pipe column (100b) and the H-beam (200) are applied is economical because it is easy to construct and the cost is relatively inexpensive compared to the concrete structure.

In addition, the steel structure 10b of the fourth embodiment using the circular steel pipe column 100b has the advantage of preventing contamination of spider webs and dust, unlike the second embodiment using the H-beam column 100. In addition, the steel structure 10a of the fourth embodiment using the circular steel pipe column 100a can be attached to the column 100b with anti-collision signs. In addition, the steel structure 10a of the fourth embodiment using the circular steel pipe pillar 100b can prevent the electric wiring from being exposed to the outside by arranging electric wiring or the like in the empty space of the circular steel pipe pillar 100a.

The pillar 100b is fixed to the bottom surface using a flat plate 50a bonded to the bottom surface.

Specifically, a flat plate (50a) for fixing a fixing bolt on the bottom surface of the circular steel pipe column (100b) is joined to the lower surface of the circular steel pipe column (100b), and the fixing bolt (55) is fastened to the four corners of the flat plate (50a) The circular steel pipe column (100b) is fixed to the bottom surface. If the circular steel pipe column (100b) is used, the size of the flat plate (50) is slightly larger compared to the case of using the H-beam column (100), but the column (100b) is more stably fixed to the bottom surface.

The description of the configuration of the fourth embodiment overlapping with the second to third embodiments will be omitted.

The steel structure 10b according to the fourth embodiment is different from the second embodiment in a configuration further including an upper reinforcement 271, an intermediate reinforcement 272, and a lower reinforcement 273.

The upper reinforcing material 271, the intermediate reinforcing material 272, and the lower reinforcing material 273 are provided at a portion where double H-beams are joined in the column. The upper reinforcing material 271 is joined to the pillar and the upper flange on the upper side of the double H-beam joined to the pillar. The intermediate reinforcement 272 is joined to the pillar and the intermediate flange at the middle side of the double H-beam joined to the pillar. The lower stiffener 273 is joined to the pillar and the lower flange on the lower side of the double H-beam joined to the pillar.

The steel structure according to the fourth embodiment improves the structural performance of the joint portion of the column and the beam by connecting double H-beams to the circular steel pipe column, and the flange and flange of the general H-beam at the position corresponding to the end of the double H-beam. Auxiliary reinforcement is arranged between the beams to improve the structural performance of the beam, and the appearance is excellent by using a circular steel pipe column as a column, and it can prevent contamination of spider webs and dust, and it is easy to attach anti-collision signs, etc. , Construction cost is also economical.

In addition, the fourth embodiment of the present invention does not use T-beams or steel plates for the beam 200, but if H-beams are used, there is no need to cut H-beams in half, and it is recommended to use short and thin H-beams as needed. As it is possible, construction time is shortened and costs are reduced. In addition, there is an advantage that the interlayer height is reduced when a short and thin H-beam is used instead of a T-beam or a steel plate for the beam 200. Specifically, the portion replacing the existing T-beam or steel plate may be a portion of the lower flange 214 in the double H-beam 210.

7 is a perspective view showing a steel structure according to a fifth embodiment of the present invention.

As shown in Figure 7, the steel structure (10c) according to the fifth embodiment includes a column (100a) and a beam (200). The pillar 100a is installed perpendicular to the floor surface. The beam 200 is composed of a plurality of beams that are joined to be perpendicular to the pillars 100a at every predetermined height of the pillars 100a. In the embodiment, three beams 200 are bonded to a certain height of the column 100, and the three beams 200 are disposed and bonded to form a right angle to each other.

In the fifth embodiment, the pillar 100a uses a square steel pipe. At least one of the plurality of beams 200 uses a double H-beam 210 at the junction with the column 100. In addition, some of the plurality of beams 200 may use a double H-beam 210 and the rest may use a general H-beam 220.

Specifically, the steel structure 10a according to the fifth embodiment is a structure in which a square steel pipe column 100a and an H-beam 200 are joined, and some of the H-beam 200 are double H-beam 210 By using, the structural performance of the beam 200 is improved and the seismic structure performance is excellent. The steel structure (10a) to which the square steel pipe column (100a) and the H-beam (200) are applied is economical because it is easier to construct and relatively inexpensive in cost compared to a concrete structure.

In addition, the steel structure 10a of the fifth embodiment using the square steel pipe column 100a has the advantage of preventing contamination of spider webs and dust, unlike the second embodiment using the H-beam column 100. In addition, the steel structure (10a) of the third embodiment using the square steel pipe column (100a) can be attached to the column (100a), such as anti-collision signs. In addition, the steel structure 10a of the fifth embodiment using the square steel pipe pillar 100a can prevent the electric wiring from being exposed to the outside by arranging electric wiring or the like in the empty space of the square steel pipe pillar 100a.

The pillar 100a is fixed to the bottom surface using a flat plate 50 bonded to the bottom surface.

Specifically, a plate (50a) for fixing a fixing bolt to the square steel pipe column (100a) to the bottom surface of the square steel pipe column (100a) is joined, and the fixing bolt (55) is fastened to the four corners of the plate (50a) The square steel pipe column (100a) is fixed to the bottom surface. If the square steel pipe column (100a) is used, the size of the flat plate (50) is slightly larger compared to the case of using the H-beam column (100), but the column (100a) is more stably fixed to the bottom surface.

The steel structure 10c according to the fifth embodiment is different from the second embodiment in a configuration further including an upper reinforcement 271, an intermediate reinforcement 272, and a lower reinforcement 273.

The upper reinforcing material 271, the intermediate reinforcing material 272, and the lower reinforcing material 273 are provided at a portion where double H-beams are joined in the column. The upper reinforcing material 271 is joined to the pillar and the upper flange on the upper side of the double H-beam joined to the pillar. The intermediate reinforcement 272 is joined to the pillar and the intermediate flange at the middle side of the double H-beam joined to the pillar. The lower stiffener 273 is joined to the pillar and the lower flange on the lower side of the double H-beam joined to the pillar.

In addition, the fifth embodiment is different from the second to fifth embodiments in the structure further including a reinforcing sleeve.

In the fifth embodiment, the double H-beam is further disposed with a reinforcing sleeve 274 for strength reinforcement in the web 211 between the intermediate flange 213 and the lower flange 214. The reinforcing sleeve 274 includes a hole formed in the web 211 between the intermediate flange 213 and the lower flange 214 and a circular or plate-shaped reinforcing structure 275 fitted into the hole. In addition, the fifth embodiment is bonded to at least one of the reinforcing structure 275, the intermediate flange 213, and the lower flange 214 so that the reinforcing structure 275 is in close contact between the intermediate flange 213 and the lower flange 214. It further includes a supporting structure 276 to be fixed. The circular or plate-shaped reinforcement structure 275 is formed of a concrete structure, and the concrete structure makes the structural performance of the beam more excellent.

The support structure 276 includes at least one of a cylindrical shape, a flat plate shape, and a shape in which a plurality of flat plates are arranged at predetermined intervals.

The steel structure according to the fifth embodiment improves the structural performance of the joint portion of the column and the beam by connecting double H-beams to the rectangular steel pipe column, and the flange and flange of the general H-beam at the position corresponding to the end of the double H-beam. An auxiliary reinforcement is arranged between the beams to improve the structural performance of the beam, and a reinforcing sleeve is further disposed between the middle flange and the lower flange of the H-beam to further strengthen the structural performance of the beam 200.

In addition, since it is possible to organize by passing electrical wiring through the empty hole of the square steel pipe column, there is no need to attach a hanger for hanging separate wires under the H-beam, and by applying a thin and short H-beam, the interlayer height can be reduced. The reinforcing sleeves penetrating the beams make the beams more rigid and at the same time enable the function of passing the wires through, thereby helping to organize the wiring neatly.

A square steel pipe column (especially a square steel pipe column) is used as a pillar for excellent aesthetics, it can prevent contamination of spider webs and dust, it is easy to attach anti-collision signs, etc., and the construction cost is economical.

In addition, the fifth embodiment of the present invention does not use T-beams or steel plates for the beam 200, but if H-beams are used, there is no need to cut H-beams in half, and it is recommended to use short and thin H-beams as needed. As it is possible, construction time is shortened and costs are reduced. In addition, there is an advantage that the interlayer height is reduced when using short and thin H-beams instead of T-beams or steel plates for the beam 200. Specifically, the portion replacing the existing T-beam or steel plate may be a portion of the lower flange 214 in the double H-beam 210.

The steel structure of the first to fifth embodiments described above is applied to a parking lot, so it is economical, has a beautiful appearance, and has excellent seismic performance.

In addition, the steel structure of the first to fifth embodiments described above may be applied by mixing some components. In addition, in the steel structures of the first to fifth embodiments described above, a concrete foundation may be applied instead of a flat plate for fixing the pillar to the floor surface.

It is obvious that the detailed configuration of the steel structure according to any one of the first to fifth embodiments can be included in the steel structure according to another embodiment.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and various modifications and equivalent other embodiments are possible from those of ordinary skill in the art. The scope of technical protection should be determined by the technical idea of the appended claims.

10,10',10a,10b,10c: steel structure 50: flat plate
55: fixing bolt 100: column
111: web 112, 113: flange
200: beam 210: double H-beam (double H-beam)
211: web 212: upper flange
213: middle flange 214: lower flange
220: general H-beam 230: fixing means
231: first fixed plate 232: second fixed plate
233: high tension bolt 234: fixing nut
240: reinforcing means 241: first reinforcing plate
242: second reinforcing plate 243: high tension bolt
244: fixing nut 250: reinforcement
251: column reinforcement 252: corner reinforcement
253: beam flange reinforcement 254: auxiliary reinforcement
271: upper reinforcement 272: intermediate reinforcement
273: lower reinforcing material 274: reinforcing sleeve
275: reinforcement structure 276: support structure

Claims (2)

Pillars installed perpendicular to the floor surface;
Including,
Further comprising a; a plurality of beams joined so as to be perpendicular to the column at each predetermined height of the column,
At least one of the plurality of beams uses a double H-beam at the junction with the column,
The pillar is a square steel pipe,
A flat plate for fixing fixing bolts to the bottom surface of the pillar is joined to the lower surface of the square steel pipe, and the fixing bolts are fastened to the four corners of the flat plate and fixed to the bottom surface,
The double H-beam is
A structure including a web, an upper flange and a lower flange formed on both sides of the web, and an intermediate flange formed between the upper flange and the lower flange,
The width between the upper flange and the intermediate flange is the same as the width of the general H-beam, the width between the lower flange and the intermediate flange is relatively narrow compared to the width of the general H-beam,
In the double H-beam, other double H-beam or general H-beam and the web are connected by fixing means, and the upper flange and lower flange are connected by reinforcing means,
In the column where the double H-beam is joined
An upper reinforcing material joined to the pillar and the upper flange from the upper side of the double H-beam joined to the pillar;
An intermediate reinforcing material joined to the pillar and the intermediate flange at the middle side of the double H-beam joined to the pillar,
Including a lower reinforcement joined to the pillar and the lower flange from the lower side of the double H-beam joined to the pillar,
A steel structure in which an auxiliary stiffener is further installed to connect the flange and the flange to the beam.
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