KR102265916B1 - T-shaped Steel Seismic Frame Structure - Google Patents

Abstract

Disclosed is a T-steel seismic frame structure. The T-steel seismic frame structure is installed on a concrete structure formed in a rectangular shape by connecting a plurality of horizontal and vertical frameworks to support a column, a beam, and a floor in a building and comprises: a corner frame corresponding to each corner portion of the concrete structure; a connection frame horizontally or vertically connecting the corner frames; and a reinforcing frame formed to be overlapped with the connection frame to be coupled to disperse a load. Accordingly, the T-steel seismic frame structure is mounted on a column, a beam, and a floor in a building to provide supporting power, and beam aggregate is coupled through a cement wall by a drill to accurately bury a bolt in cement aggregate in a straight line shape to improve durability and prevent defects to greatly improve seismic performance.

Description

T-shaped Steel Seismic Frame Structure

The present disclosure relates to a T-beam earthquake-resistant frame structure, and more particularly, to a T-beam earthquake-resistant frame structure mounted on columns and beams of a building (including a piloti-type structure) to improve seismic performance.

Unless otherwise indicated herein, the material described in this section is not prior art to the claims of this application, and inclusion in this section is not an admission that it is prior art.

A column-beam joint structure refers to a structure including columns, beams, and joint members connecting columns and beams in a building.

Recently, the demand for high-rise buildings and piloti-type buildings is increasing, and interest in seismic design to prevent the collapse of buildings and minimize damage caused by high-intensity earthquakes is increasing. Accordingly, interest in and need for a column-beam joint structure having stable seismic performance to prepare for an earthquake is also increasing.

Looking at some forms in relation to such a column-beam joint structure, only the upper flange and lower flange of the beam aggregate were joined by bolting with respect to the rectangular steel pipe column.

Here, 'H-beam' is mainly used as the beam aggregate, and it is composed of a web connecting the upper and lower flanges and the upper and lower flanges.

As shown in Figure 12, the prior art is a concrete frame (F1, F2) using a hammer drill (T) a long bolt (B) passing through the lower flange 740 from the upper flange 720 of the 'H-beam' ), but in this process, as the length of the long bolt (B) becomes longer, there is a risk that it may be bent in the drilling process or the depth of insertion into the concrete frame (F1, F2) becomes shallow, especially Since the view is obscured by the upper flange 720, there is a problem in that it is difficult to penetrate the long bolt (B) to the concrete frame (F1, F2) in an accurately vertical state.

Therefore, in the prior art, there was a problem in that the bolt was deformed or weakened in the process of penetrating the upper flange and the lower flange of the H-beam, so that it could not be accurately buried in the concrete wall or beam aggregate in the end, resulting in poor durability.

Republic of Korea Patent Registration No. 10-2012883

The disclosed content can be mounted on columns, beams, and floors in a building to provide bearing capacity, and by penetrating the cement wall and the beam aggregate by means of a drill, the bolt can be embedded in the cement aggregate in a straight line precisely, improving durability The purpose of this is to provide a T-beam steel seismic frame structure that significantly improves seismic performance by preventing the occurrence of overheating and defects.

The T-beam earthquake-resistant frame structure according to the embodiment is to be installed in a concrete structure in the shape of a 'ㅁ' by connecting a number of horizontal and vertical frames to support the columns, beams, and floors inside the building (including the piloti-type structure), a corner frame made to be connected to a plurality of box-shaped frame members and corresponding to each corner portion of the concrete structure; a connecting frame connecting the corner frames in a horizontal or vertical direction; and a reinforcing frame formed to overlap and combine with the connection frame to distribute the load;
The connection frame is formed by abutting two angle members having a '┻' shape in cross section consisting of an external support plate and a reinforcing plate formed perpendicular to the center of the external support plate, and at the end of the connection frame, the corner frame. A flange is attached in close contact with the outer surface, the connecting frame is composed of a pair of two, each of the two connecting frames is spaced apart from each other, and the reinforcing plate of one of the two connecting frames has a hole in the reinforcing plate. is formed, and the reinforcing plate of the other one of the two connecting frames is formed in an oval shape and a slot hole having a length is formed, and the other connecting frame of the two connecting frames is formed by the distance between the two connecting frames. A buffer zone that can be moved with fluidity in the horizontal or vertical direction is formed with respect to one of the connection frames of the connection frame, and the length is variably adjusted in the horizontal or vertical direction between the two connection frames due to the slot hole, A fastening member is coupled to a hole or a slot hole formed in the connection frame, the reinforcing frame is coupled to a single number across the two connection frames, and the inner support plate and the inner support plate are vertically formed in the center of the inner support plate. It is composed of a plate and has a '⊥' shape in cross section, and the adhesion plate is in close contact with the reinforcing plate of the connection frame and a hole is formed to be coupled by the fastening member, and a spacer is formed between the adhesion plate and the reinforcing plate. and a friction pad are respectively interposed therebetween, a hole corresponding to the hole of the reinforcing plate and the hole of the contact plate is formed in the spacer, and a slot hole of the reinforcing plate and a hole corresponding to the hole of the contact plate are formed in the friction pad. It is characterized by the formation of long pores.

delete

delete

delete

According to the disclosed embodiment, it is possible to secure work stability and shorten the time when installing the anchor, the vertical and horizontal length can be adjusted with the slot hole, the rigidity is increased compared to the H-shaped steel by installing the double T-beam, and the installation is performed only by fastening bolts without on-site welding. This makes construction easier.

In addition, it can be mounted on columns, beams, and floors in the building to provide support, and by penetrating the cement wall and the beam aggregate with a drill, the bolt can be embedded in a straight line precisely in the cement aggregate, improving durability and causing defects. It has the effect of significantly improving the seismic performance by preventing

1 is a perspective view showing a T-beam earthquake-resistant frame structure according to an embodiment;
Figure 2 is a combined front view showing the T-beam earthquake-resistant frame structure according to the embodiment;
3 is an exploded perspective view showing the T-beam earthquake-resistant frame structure according to the embodiment;
4 is an enlarged exploded perspective view of a portion of the T-beam earthquake-resistant frame structure according to the embodiment;
5 is a cross-sectional view of a T-beam earthquake-resistant frame structure according to the embodiment;
6 is an enlarged cross-sectional view of a part in FIG. 4;
7 is an exploded perspective view showing a T-beam earthquake-resistant frame structure according to another embodiment;
8 is a perspective view showing a state in which a 'friction pad' is coupled in the T-beam earthquake-resistant frame structure according to the embodiment;
9 is an exploded perspective view showing a state in which the 'friction pad' is separated from the T-beam earthquake-resistant frame structure according to the embodiment;
10 is a cross-sectional view showing a state in which a 'friction pad' is coupled in the T-beam earthquake-resistant frame structure according to the embodiment;
11 is a view showing an example of mounting the T-beam earthquake-resistant frame structure to the concrete frame according to the embodiment;
12 is a view showing an example of mounting the earthquake-resistant frame structure according to the prior art to the concrete frame.

Hereinafter, preferred embodiments will be described in detail with reference to the accompanying drawings.

The embodiments to be described below are intended to describe in detail enough to be easily practiced by those of ordinary skill in the art to which the present invention pertains, thereby limiting the technical spirit and scope of the present invention. doesn't mean

In addition, the size or shape of the components shown in the drawings may be exaggerated for clarity and convenience of explanation, and the terms specifically defined in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user or operator. It should be noted that definitions of these terms should be made based on the content throughout this specification.

Of the accompanying drawings, FIG. 1 is a perspective view showing a T-beam earthquake-resistant frame structure according to an embodiment, FIG. 2 is a combined front view showing a T-beam earthquake-resistant frame structure according to an embodiment, and FIG. 3 is a T-beam earthquake-resistant frame structure according to an embodiment An exploded perspective view showing the frame structure, FIG. 4 is an enlarged exploded perspective view of a part of the T-beam earthquake-resistant frame structure according to the embodiment, FIG. 5 is a cross-sectional view of the T-beam steel earthquake-resistant frame structure according to the embodiment, and FIG. An enlarged cross-sectional view of a part, FIG. 7 is a view showing an example of mounting a T-beam earthquake-resistant frame structure according to another embodiment to a concrete frame, FIG. 8 is a T-beam earthquake-resistant frame structure according to an embodiment in which a 'friction pad' is combined A perspective view showing the state, FIG. 9 is a perspective view showing a state in which the 'friction pad' is separated from the T-beam earthquake-resistant frame structure according to the embodiment, and FIG. It is a cross-sectional view showing the state.

As shown in Figures 1 to 7, the T-beam earthquake-resistant frame structure according to the embodiment connects a plurality of vertical or horizontal concrete frames (F1, F2) to support the columns, beams and floors inside the building. It is installed in close contact with the inner circumferential surface of a concrete structure with a ㅁ' shape.

A plurality of frames are assembled so as to be in close contact with the upper, lower, left, and right concrete frames, and each frame is formed to enable load distribution by interconnecting.

1 and 2, the T-beam earthquake-resistant frame structure according to the embodiment connects a number of horizontal and vertical frames to support the columns, beams and floors inside the building (including the piloti-type structure) ' to be installed on a concrete structure in the shape of a box, and a plurality of box-shaped frame members are connected to each other, and a corner frame corresponding to each corner of the concrete structure; a connecting frame connecting the corner frames in a horizontal or vertical direction; and a reinforcing frame formed to overlap and combine with the connection frame to distribute the load;
The connection frame is formed by abutting two angle members having a '┻' shape in cross section consisting of an external support plate and a reinforcing plate formed perpendicular to the center of the external support plate, and at the end of the connection frame, the corner frame. A flange is attached in close contact with the outer surface, the connecting frame is composed of a pair of two, each of the two connecting frames is spaced apart from each other, and the reinforcing plate of one of the two connecting frames has a hole in the reinforcing plate. is formed, and the reinforcing plate of the other one of the two connecting frames is formed in an oval shape and a slot hole having a length is formed, and the other connecting frame of the two connecting frames is formed by the distance between the two connecting frames. A buffer zone that can be moved with fluidity in the horizontal or vertical direction is formed with respect to one of the connection frames of the connection frame, and the length is variably adjusted in the horizontal or vertical direction between the two connection frames due to the slot hole, A fastening member is coupled to a hole or a slot hole formed in the connection frame, the reinforcing frame is coupled to a single number across the two connection frames, and the inner support plate and the inner support plate are vertically formed in the center of the inner support plate. It is composed of a plate and has a '⊥' shape in cross section, and the adhesion plate is in close contact with the reinforcing plate of the connection frame and a hole is formed to be coupled by the fastening member, and a spacer is formed between the adhesion plate and the reinforcing plate. and a friction pad are respectively interposed therebetween, a hole corresponding to the hole of the reinforcing plate and the hole of the contact plate is formed in the spacer, and a slot hole of the reinforcing plate and a hole corresponding to the hole of the contact plate are formed in the friction pad. It is characterized by the formation of long pores.

The corner frame 100 is formed in an approximately 'L' shape by connecting a plurality of box-shaped frame members, and is mounted inside each corner of the 'ㅁ' shape concrete structure.

Corner frame 100 is mounted on the concrete frame (F1, F2) using a method such as bolt fastening.

After each corner frame 100 is mounted on the four corners of the concrete frame (F1, F2), each corner frame 100 is connected with the connecting frame 200 to form a 'ㅁ' shape, and finally the reinforcement frame 300 is coupled to the connection frame 200 to complete the earthquake-resistant frame structure according to the present embodiment.

The connection frame 200 has a '┣' or '┻' shape in cross section, and includes an external support plate 220 and a reinforcing plate 240 formed perpendicular to the center of the external support plate 220 .

The connection frame 200 is to be attached to the vertical or horizontal concrete frame (F1) (F2), so that the external support plate 220 is horizontally or vertically arranged to be attached to the vertical or horizontal concrete frame (F1) (F2) and , so that the external support plate 220 faces the outside, it is in close contact with the concrete frame (F1, F2).

The connection frame 200 attached to the left and right sides of the concrete frame is arranged symmetrically with a '┣' shape in cross section.

The connecting frame 200 attached to the upper and lower sides of the concrete frame is arranged symmetrically with a '┻' shape in cross section.

The connection frame 200 is such that the two form a pair. Therefore, each of the connecting frames installed on each side of the upper, lower, left, and right is composed of two in a set. Each of the two connection frames is disposed with a predetermined distance from each other.

By forming such a separation distance, any one of each connection frame 200 is formed with a buffer zone (Z) that can be moved left and right or up and down.

By this buffer zone (Z), it is possible to ensure the fluidity between the connection frames 200 on both sides.

The connection frame 200 attaches the external support plate 220 to the concrete frame (F1, F2), and then drives the bolt (B) so that the bolt (B) passing through the external support plate 220 is the concrete frame (F1, F2). It is inserted into and made to be in a combined state.

This bolting operation, as shown in FIG. 7, may be performed on both sides of the side of the reinforcing plate 240, and an element that interferes with the hammer drill T from the process of initially drilling the bolt B, that is, Since there is no upper frame 720 (shown in FIG. 8) that blocks the view or distances the distance as in the prior art, drilling can be performed with the hammer drill T closer to the external support plate 220. The bolt (B) can be accurately inserted in the vertical state into the concrete frame (F1, F2), and the bolt (B) can be inserted deeper, so that a solid bonding state can be realized.

As shown in FIG. 3 , the connection frame 200 has a plurality of holes 280 formed in the external support plate 220 or the reinforcing plate 240 to enable the bolt 500 to be fastened.

Two connecting frames 200 mounted on one side form a set.

And a slot hole 280 ′ is formed in the reinforcing plate 240 in any one of the two connecting frames 200 .

The slot hole 280' is a long hole formed in an oval shape and having a length. Due to the slot hole 280', the length can be variably adjusted vertically and horizontally between the modular frame units.

A fastening member 500 such as a bolt is coupled to the hole 280 or the slot hole 280 ′.

On the other hand, the reinforcing frame 300 is coupled to the connection frame 200 butt.

Therefore, when the movement occurs in the longitudinal or transverse direction of the connection frame 200 due to seismic vibration, the reinforcement frame 300 supports it, thereby minimizing the vibration amplitude and reinforcing durability.

After loosening the bolt 500 due to the length of the slot hole 280 ′, it can be adjusted to an appropriate position by moving the connection frame 200 .

The reinforcing frame 300 is composed of an inner support plate 330 and a contact plate 350 vertically formed in the center of the inner support plate 330 to have a '⊥' shape in cross section, and the contact plate ( 350 is closely coupled to the reinforcing plate 240 .

The reinforcing frame 300 is provided singly, and the upper end and the lower end are formed to be close to both corner frames 100 , respectively.

Meanwhile, as shown in FIG. 4 , the end of the connection frame 200 is attached and fixed to the corner frame 100 , and a flange 203 is attached to the end of the connection frame, and the flange 203 and the corner frame 100 are attached to each other. After making the outer surface close, they are joined by welding or bolting.

The T-beam earthquake-resistant frame structure according to the embodiment is vertical and horizontal length adjustable by the slot hole 280'.

In general, since the reinforcing frame is manufactured in advance at a factory and installed in the opening of the concrete structure, there are many cases where the width and length of the reinforcing frame do not exactly match the width and length of the opening of the concrete structure.

In this case, there is a problem in that the construction period is prolonged and the construction cost is increased accordingly because it is necessary to proceed with frame construction in advance or post-work such as filling the groove in order to accurately align the reinforcing frame.

On the other hand, the T-beam seismic frame according to the present invention consists of mutually separated units, that is, the connecting frame 200, the reinforcing frame 300, and the corner frame 100, and these units are respectively coupled to each other through bolting. By being implemented, it is possible to install by variably adjusting the length between the modular frame units due to the slot hole processing in the frame when fastening the bolts.

Therefore, the reinforcing frame 300 can be custom installed by adjusting the verticality and horizontality to the width and length of the structure opening by using the slot hole 280', which is a length adjustment means, and thus, it is possible to secure effective support for lateral force and At the same time, constructability may be improved.

According to the present invention, the system rigidity can be increased. That is, the thickness is increased by installing the connecting frame 200 and the reinforcing frame 300, which are T-shaped steel frames, so as to increase the moment of inertia. Therefore, it is effective in controlling lateral displacement by increasing the flexural rigidity of the structure.

That is, since the T-beam is assembled to overlap the double, the thickness of the web is increased compared to that of the H-beam, which is often used in the existing vacuum-resistant method, so that the moment of inertia can be increased.

As the moment of inertia rises in this way, the flexural rigidity of the structure can be increased.

Meanwhile, as shown in FIG. 7 , according to another embodiment, the connection frame 200 ′ may be formed by butting two angle members 200a and 200b having a '┗' shape in cross section.

That is, the vertical surfaces of each of the angle members 200a and 200b are treated with each other, and the contact plate 350 of the reinforcing frame 300 is inserted therebetween and then connected by bolting.

Meanwhile, as shown in FIGS. 8 to 10 , a friction pad 600 and a spacer 600 ′ interposed between the adhesion plate 350 and the reinforcing plate 240 to have frictional force may be included.

The friction pad 600 is positioned on the pillar, and is provided on the left and right sides to correspond to each reinforcing plate 240 of the connection frame 200 , and the contact plate 350 and the reinforcing plate in which the hole 280 is located. A spacer 600' for maintaining the same distance between the 240 is provided.

A long hole 610 ′ is formed in the friction pad 600 so that the fastening member 500 can be coupled thereto, and a hole 610 is formed in the spacer 600 ′.

Therefore, after arranging the friction pad 600 so that the long holes 280 ′ of the reinforcing plate 240 or the contact plate 350 coincide with each other, the long holes ( Each fastening member 500 is through-coupled to 280'.

In addition, after disposing the spacer 600 ′ so that the long holes 280 of the reinforcing plate 240 or the close contact plate 350 coincide with each other, the fastening member 500 is coupled.

Although described with reference to the preferred embodiment, it will be readily recognized by those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the invention, and all such changes and modifications fall within the scope of the appended claims. is self-evident

100: corner frame F1, F2: concrete frame
200: connection frame 220: external support plate
240: reinforcing plate 280: hole
280': slot hole 300: reinforcement frame
330: inner support plate 350: adhesion plate
500: fastening member

Claims (6)

It is installed in a 'ㅁ'-shaped concrete structure by connecting a number of horizontal and vertical frames to support the columns, beams and floors inside the building (including piloti-type structures).
a corner frame made to be connected to a plurality of box-shaped frame members and corresponding to each corner portion of the concrete structure;
a connecting frame connecting the corner frames in a horizontal or vertical direction; and
A reinforcing frame formed to overlap and combine with the connection frame to distribute the load;
The connecting frame is
An external support plate and a reinforcing plate formed perpendicular to the center of the external support plate are formed by facing two angle members having a '┻' shape in cross section,
A flange is attached to the end of the connection frame in close contact with the outer surface of the corner frame,
The connection frame consists of a pair of two, and each of the two connection frames is disposed with a separation distance,
A hole is formed in the reinforcing plate of one connection frame among the two connection frames, and a slot hole having a length formed in an oval shape is formed in the reinforcement plate of the other connection frame among the two connection frames,
A buffer zone that can be moved horizontally or vertically with respect to one connection frame of the two connection frames is formed by the separation distance of the other connection frame of the two connection frames,
The length is variably adjusted in the horizontal or vertical direction between the two connection frames due to the slot hole,
A fastening member is coupled to a hole or a slot hole formed in the connection frame,
The reinforcing frame is coupled to a single number buttted across the two connecting frames,
It is composed of an inner support plate and a close contact plate formed perpendicular to the center of the inner support plate so that the cross-section is made in a '⊥' shape,
A hole is formed in the adhesion plate to be in close contact with the reinforcing plate of the connection frame and coupled by the fastening member,
A spacer and a friction pad are respectively interposed between the adhesion plate and the reinforcing plate, and a hole in the spacer that coincides with a hole in the reinforcing plate and a hole in the adhesion plate is formed in the spacer, and a hole in the reinforcing plate is formed in the friction pad. T-shaped steel earthquake-resistant frame structure, characterized in that a slot hole and a long hole corresponding to the hole of the adhesion plate are formed. delete delete delete delete delete

Images