KR102151806B1 - A cushioning member for installing a roof structure and a method of manufacturing the same - Google Patents

Abstract

The present invention relates to a buffer member for installing a roof structure, which has a seismic isolation function for buffering vibration. The buffer member for installing a roof structure includes: a support part connected to a beam of the roof structure; a buffer part of which both ends are connected to the support part and which is provided with a curved flat spring; and a rod body connecting part which is fixed in a selective position in the buffer part and to which a rod of the roof structure is fixed.

Description

A cushioning member for installing a roof structure and a method of manufacturing the same}

The present invention relates to a buffer member for installing a roof structure and a method of manufacturing the same.

In general, an arch roof using a truss structure can be made of a web material that forms a truss structure with the top and bottom chords, connecting the top and bottom chords, and the top and bottom chords. Can be installed as

When the skeleton of the arch roof is formed using the truss structure, the compressive stress applied to the upper chord itself by its own weight can be dispersed into the web material, thereby increasing the overall safety factor.

Accordingly, the truss structure has traditionally been widely applied to arch roofs requiring seismic design.

However, the arch roof with a truss structure is designed to withstand the external force generated by earthquakes only with its own rigidity in the end, and there is no separate buffer member or buffer system, so there are obvious physical limitations in significantly increasing the safety factor. It can be seen as a structure.

Therefore, when strong vibrations are transmitted to the building due to an earthquake or strong wind, the upper chord is greatly shaken and the compressive stress is concentrated on the upper chord and the nodes around it, which can lead to a serious safety accident that leads to collapse of the roof.

Therefore, in addition to the existing traditional truss structure, there is a need for a buffer member and a buffer system capable of preventing the problem that the roof structure is damaged by strong vibration.

The present invention has been invented to solve the above-described conventional problems, and an object of the present invention is to provide an arch roof with seismic isolation performance.

In addition, an object of the present invention is to provide a buffer member optimized to be applied to an arch roof with seismic isolation performance.

In addition, an object of the present invention is to provide a method for efficiently manufacturing the buffer member.

According to an embodiment of the present invention, an arch-shaped top current covering the upper part of a building; A first vertical member connected to a lower portion of the upper chord so that its longitudinal direction is orthogonal to the longitudinal direction of the upper chord; A second vertical member connected to a lower portion of the upper chord so that the longitudinal direction thereof is orthogonal to the longitudinal direction of the upper chord, and positioned at a lower height than the first vertical material; An inclined member having one end connected to the upper end of the first vertical member and the other end connected to the lower end of the second vertical member; And a vertical buffer member that connects the upper chord with the first vertical material and buffers the stress transmitted from the upper chord to the first vertical material. .

In an exemplary embodiment, the vertical buffer member may include a vertical buffer member body provided with a plate spring having a central portion curved toward the upper side.

In an exemplary embodiment, the first vertical material includes a top plate facing the top chord; A vertical plate perpendicular to the upper plate and to which the inclined member is connected; And a sliding slit formed on the upper plate, wherein the vertical buffer member protrudes from both ends of the vertical buffer member body and is inserted into the sliding slit, and a sliding rib that flows in the sliding slit by an external force. can do.

In an exemplary embodiment, the vertical buffer member may further include an auxiliary leg whose end is supported by the first vertical member, and supports the upper chord together with the vertical buffer member body.

In an exemplary embodiment, a clip having one side connected to the upper chord and the other side connected to the central portion of the vertical buffer member body may further include.

In an exemplary embodiment, provided in at least one of between the first vertical member and the inclined member, and between the inclined member and the second vertical member, from the top chord to the second vertical member through the first vertical member. It may further include a; slope buffer member for buffering the transmitted stress.

In an exemplary embodiment, the inclined buffer member may include a buffer part provided as a plate spring curved toward the inclined member.

In an exemplary embodiment, an end member provided at one end of the upper chord and supporting a surface opposite to a surface to which the inclined member is connected in the second vertical member may be further included.

According to an embodiment of the present invention, an arch-shaped top current covering the upper part of a building; A first vertical member connected to a lower portion of the upper chord so that its longitudinal direction is orthogonal to the longitudinal direction of the upper chord; A second vertical member connected to a lower portion of the upper chord so that the longitudinal direction thereof is orthogonal to the longitudinal direction of the upper chord, and positioned at a lower height than the first vertical material; An inclined member having one end connected to the upper end of the first vertical member and the other end connected to the lower end of the second vertical member; And between the first vertical material and the inclined material, and between the inclined material and the second vertical material, and buffering the stress transmitted from the upper chord to the second vertical material through the first vertical material. It is possible to provide a base isolation arch roof using a truss structure, characterized in that it includes;

According to an embodiment of the present invention, an arch-shaped top current covering the upper part of a building; A plurality of vertical members connected to a lower portion of the upper chord so that its longitudinal direction is orthogonal to the longitudinal direction of the upper chord and provided at predetermined intervals; A sloping member provided between the plurality of vertical members, one end connected to the upper end of the vertical member and the other end connected to the lower end of the vertical member; And a vertical buffer member that connects the upper chord with the plurality of vertical members and buffers the stress transmitted from the upper chord to the plurality of vertical members; it is possible to provide a seismic isolation arch roof using a truss structure, comprising: have.

According to an embodiment of the present invention, there is provided a buffer member for installing a roof structure having a seismic isolation function for damping vibration, comprising: a support part connected to a beam of the roof structure; A buffer part having both ends connected to the support part and provided with a curved leaf spring; And a load body connection part fixed at a selective position in the buffer part and to which the rod of the roof structure is fixed. A buffer member for installing a roof structure may be provided.

In an exemplary embodiment, an open surface is formed in the buffer part along the longitudinal direction of the buffer part, and the load body connection part is inserted into the open surface of the buffer part, and slides along the surface of the buffer part forming the open surface. A connection body provided to enable; A rod body fixing part connected to the connection part body and fixing a rod of the roof structure; And a connection part body fixing part extending from both sides of the connection part body and to which a fastening member fixed to the buffer part is fastened.

In an exemplary embodiment, the load body connection part may include a rotating part connected to the load body fixing part and rotating according to a relative motion of the load body and the beam of the roof structure.

In an exemplary embodiment, the support part includes a first support part connected to the buffer part to one end; And a second support part having one end vertically connected to the other end of the first support part and connected to the other end of the buffer part.

In an exemplary embodiment, a fastening rib protruding from the support part and having a through hole through which a fastening member fixed to the beam of the roof structure passes; may be further included.

According to an embodiment of the present invention, there is provided a method of manufacturing a buffer member for installing the roof structure, the method comprising: cutting a metal plate to manufacture the support; Forming an open surface of the buffer part on a predetermined portion; And forming the buffer part by bending a predetermined portion of the support part. It is possible to provide a method of manufacturing a buffer member for installing a roof structure, comprising: a.

According to an embodiment of the present invention, in the buffer member for installing a roof structure having a seismic isolation function to buffer vibration, a vertical buffer member body in which a central portion is provided as a plate spring curved upward, and the roof structure is fixed to the central portion. ; And it is possible to provide a buffer member for installing a roof structure comprising a; body end bent upward at both ends of the vertical buffer member body.

In an exemplary embodiment, a sliding rib protruding from both ends of the vertical buffer member body and inserted into a sliding slit formed in a roof structure, and flowing in the sliding slit by an external force; And a rib end formed by being bent at an end of the sliding rib to prevent the sliding rib from being separated from the sliding slit.

In an exemplary embodiment, an end end is supported by the first vertical material, and an auxiliary leg supporting the upper chord together with the vertical buffer member body; may further include.

In an exemplary embodiment, an arch-shaped top chord covering an upper portion of a building; A first vertical member connected to a lower portion of the upper chord so that its longitudinal direction is orthogonal to the longitudinal direction of the upper chord; A second vertical member connected to a lower portion of the upper chord so that the longitudinal direction thereof is orthogonal to the longitudinal direction of the upper chord, and positioned at a lower height than the first vertical material; And a sloping member having one end connected to the upper end of the first vertical member and the other end connected to the lower end of the second vertical member; Can provide.

The present invention has been invented to solve the above-described conventional problem, and has an effect of providing an arch roof with seismic isolation performance.

In addition, the present invention has the effect of providing a buffer member optimized to be applied to the arch roof with seismic isolation performance assured.

In addition, the present invention has the effect of providing a method for efficiently manufacturing the buffer member.

1 is a perspective view of a base isolation arch roof using a truss structure according to an embodiment of the present invention.
2 is a partially enlarged view of a base isolation arch roof using the truss structure.
3 shows that a vertical buffer member, which is a configuration of a base isolation arch roof using the truss structure, is installed.
4 is a perspective view of the vertical buffer member.
5 is an exploded perspective view of the vertical buffer member.
6 shows that an inclined buffer member, which is one configuration of a base isolation arch roof using the truss structure, is installed.
7 is a perspective view of the inclined buffer member.
8 is an exploded perspective view of the inclined buffer member.

Hereinafter, various embodiments of the present invention will be described with reference to the drawings.

First, an overall configuration of a base isolation arch roof using a truss structure according to an embodiment of the present invention will be described with reference to FIG. 1.

The seismic isolation arch roof using a truss structure according to an embodiment of the present invention includes an arch-shaped top chord (1) covering the top of a building, and the top chord (1) so that its longitudinal direction is perpendicular to the longitudinal direction of the top chord. It may include a plurality of vertical members (2) connected to the lower portion of the.

The plurality of vertical members 2 include a first vertical member 2 connected to a lower portion of the upper chord 1, and a second vertical member 2 connected to a lower portion of the upper chord and positioned at a lower height than the first vertical member. It may include.

As shown in the drawing, the number of the vertical members 2 can be adjusted as needed, but it is essential that two or more vertical members are provided in order to implement a truss structure.

In addition, the seismic isolation arch roof using the truss structure has one end connected to the upper end of the first vertical member 2 and the other end connected to the lower end of the second vertical member 2, the sloping member 5, the upper chord 1 ) And the first vertical material (2) and buffering the stress transmitted from the upper chord (1) to the first vertical material (2), and at least one of both ends of the inclined material (5) It may further include an inclination buffering member 6 provided in any one and buffering the stress transmitted from the upper chord 1 to the second vertical material 2 through the first vertical material 2.

Accordingly, the upper chord 1, the vertical member 2, and the sloping member 5 constitute a truss structure, and the self-weight and the compressive stress due to vibration (earthquake, wind) of the upper chord 1 Distributed into the vertical member 2 and the inclined member 5, vibration can be buffered by the vertical buffer member 3 and the slope buffer member 6 in the process.

As a result, it is possible to obtain an effect of maximizing seismic isolation performance by reducing an instantaneous compressive stress applied to the upper chord 1, the vertical member 2, and the inclined member 5.

In addition, the seismic isolation arch roof using the truss structure has one side fixed to the top chord (1) and the other side is a connection clip 4 connected to the vertical buffer member, and fixed to one end of the top chord (1) The lower portion is supported by the outer wall and may further include an end member 8 supporting a surface opposite to the surface to which the inclined member 5 is connected in the second vertical member 2.

Hereinafter, a structure and a stress distribution of a base isolation arch roof using a truss structure according to an embodiment of the present invention will be described in more detail with reference to FIG. 2.

The vertical member 2 may be provided as an H-beam or an I-beam, and may include a top plate 22 facing the top plate 1 and a vertical plate 21 provided perpendicular to the top plate 22. have.

In addition, the inclined member 5 may include a load body 51 that transmits stress, and a turnbuckle 52 that controls a tensile force of the load body 51.

By the above-described configuration, the stress generated by the vertical member 1 shaking up and down by an external force (vibration, wind) is distributed to the vertical member 2 and the inclined member, and the vertical buffer member ( 3) is buffered in, the inclined cushioning member 6 through the first vertical material 2 is buffered secondly, and the inclined buffering member 6 through the load body 51 of the inclined material is buffered three times. I can.

That is, according to an embodiment of the present invention, stress dispersion and attenuation are simultaneously performed, so that a seismic isolation effect can be maximized.

3 is an enlarged view of the vertical buffer member 3, and a detailed configuration thereof will be described below.

The vertical buffer member (3) is provided with a plate spring whose central portion is curved toward the upper side, the vertical buffer member body 31 supporting the upper chord (1), and the upper side at both ends of the vertical buffer member body (31) It is bent into and may include a body end 32 in contact with the upper plate of the vertical member.

The bent portion of the clip 4 may be connected to the central portion of the vertical buffer member body 31, and the bent portion of the clip 4 and the central portion of the vertical buffer member body 31 are fastening members composed of bolts and nuts ( K, K') can be fixed to each other.

A sliding slit 22a may be formed on the upper plate 22 of the vertical member, and the vertical buffer member 3 may be connected to the upper plate 22 through the sliding slit 22a.

Specifically, the vertical buffer member 3 protrudes from both ends of the vertical buffer member body 31 and is inserted into the sliding slit 22a, and a sliding rib 33 flowing in the sliding slit by an external force, and the It may include a rib end 34 that is bent at the end of the sliding rib 33 and abuts the lower surface of the upper plate 22.

Accordingly, even if a compressive stress is generated in the upper chord 1 in the center direction, the sliding rib 33 may not be separated from the sliding slit 22a by the rib end 34.

Meanwhile, the vertical buffer member 3 has an end supported by the vertical member 2 and is formed by being bent after the vertical buffer member body 31 is cut, and an auxiliary leg 35 supporting the upper chord 1 ), and an auxiliary leg leg end 36 that is bent at an end of the auxiliary leg 35 and abuts the upper plate 22.

Hereinafter, the structure of the inclined buffer member 6 will be described in detail with reference to FIG. 4.

The slope buffer member 6 has a support part 61, a through hole 63a protruding from the support part 61 and through which fastening members K, K'fixed to the vertical plate 21 of the vertical member pass through. The provided vertical plate fastening rib 63, both ends of which are connected to the support part 61 and including a buffer part opening surface 62a formed along the length direction thereof, and a buffer part 62 provided with a curved plate spring, and , It may include a load body connection portion 64 fixed at a selective position in the buffer portion 62 and the load body 51 is fixed.

Accordingly, the stress transmitted through the support part 61 or the load body 51 may be offset by a predetermined portion in the buffer part 62.

In more detail, the load body connection part 64 is inserted into the open surface 62a of the buffer part, and a connection part provided to be slidable along the upper and lower surfaces of the buffer part 62 forming the buffer part open surface 62a A body 641, a connection part body fixing part 642 extending from both sides of the connection part body 641 and to which fastening members K, K'fixed to the buffer part 62 are fastened, and the connection part body 641 It is connected to the load body fixing part 643 to which one end of the load body 51 is fixed, and connected to the load body fixing part 643 according to the relative motion of the load body 51 and the vertical member 2 It may include a rotating part 644 to rotate.

As the connection part body 641 slides in the buffer part, a position where the load body 51 is fixed may be selectively designated, and the rotation part 644 diversifies the flowable direction of the load body 51 The shear stress applied to the load body 51 may be reduced.

5 is an exploded perspective view of the inclined buffer member 6, and the remaining configuration of the inclined buffer member 6 will be described with reference to this.

The rotating part 644 is a rotating ball 641 fixed to the rod body fixing part 643, a rotating ball receiving part 647 provided on the connecting part body to accommodate the rotating ball 641, and the rotating ball receiving part It may include a rotating part cap 6442 for preventing the separation of the rotating ball 641 accommodated in 647, and a cap fastening part 646 for fixing the rotating part cap 6442 to the rotating ball receiving part 647. have.

In addition, a rib-shaped body separation prevention part 648 may be provided in the connection part body 641, and the buffer part 62 may be provided between the body separation prevention part 648 and the connection part body fixing part 642. Part of the can be inserted.

In addition, the support portion 61 and the buffer portion 62 of the inclined buffer member 6 may be manufactured through a process of cutting and bending one metal plate to be integrally formed.

6 is a view showing that the inclination buffer member 7 according to another embodiment is installed on the base isolation arch roof using the truss structure, and FIG. 7 is a perspective view of the inclination buffer member 7 according to the other embodiment.

Hereinafter, the structure of the inclination buffer member 7 according to the other embodiment will be described with reference to FIGS. 6 and 7.

The inclined buffer member 7 according to the other embodiment includes a support portion 71, a buffer portion opening surface 72a formed along the length direction thereof, and a buffer portion 72 provided with a curved plate spring, and one end thereof A first support part 711 connected to the buffer part 72, a second support part 712 having one end vertically connected to the other end of the first support part 711 and the other end connected to the buffer part 72 It may include.

That is, the biggest difference from the above-described embodiment is that two support portions are provided vertically, and the load body connection portion 74 is provided to flow in the vertical direction.

To this end, the inclination buffer member 7 according to the other embodiment protrudes from the first support portion 711 and the through hole through which the fastening members K, K'fixed to the vertical plate 21 of the vertical member pass through. A vertical plate fastening rib 731 having, a top plate fastening rib protruding from the second support part 712 and having a through hole through which fastening members (K, K') fixed to the top plate 22 of the vertical member pass through 732, a load body connection part 74 that is fixed to a selective position in the buffer part 72 and to which the load body 51 is fixed.

The remaining configuration of the inclination buffer member 7 according to the other embodiment will be described with reference to FIG. 8.

The load body connection part 74 is inserted into the open surface 72a of the shock absorber and is provided to slide up and down along the upper and lower surfaces of the shock absorbing part 62 forming the shock absorbing part open surface 72a. ), the connection part body fixing part 742 which extends from both sides of the connection part body 741 and to which the fastening members K, K'fixed to the buffer part 72 are fastened, and is connected to the connection part body 741 A load body fixing part 743 to which one end of the load body 51 is fixed, a rotating part connected to the load body fixing part 743 to rotate according to the relative motion of the load body 51 and the vertical member 2 (744) may be included.

The rotating part 744 includes a rotating ball 741 fixed to the rod body fixing part 743, a rotating ball receiving part 747 provided on the connecting part body to receive the rotating ball 741, and the rotating ball receiving part It may include a rotating part cap 7442 for preventing separation of the rotating ball 741 accommodated in the 747, and a cap fastening part 746 for fixing the rotating part cap 7442 to the rotating ball receiving part 747. have.

In addition, a rib-shaped body separation prevention part 748 may be provided on the connection part body 741, and the buffer part 72 may be provided between the body separation prevention part 748 and the connection part body fixing part 742. Part of the can be inserted.

Finally, as one of the methods of manufacturing the inclined buffer member (6, 7), the step of manufacturing the support (61, 71) by cutting a metal plate (S1), the opening surface (61a) of the buffer part at a preset portion , Forming 71a) (S2), forming the buffer portions 62 and 72 by bending a predetermined portion in the support portions 61 and 71 (S3), and the buffer portions 62 and 72 It may include a step (S4) of connecting the end of the end of the support (61, 71).

Accordingly, by integrally manufacturing the buffer part and the support part at a time, manufacturing cost can be reduced and rigidity can be maximized.

Even if an effect not described in the present specification, the present invention may additionally have different effects of each of the above-described configurations, and a new effect not found in the prior art is derived according to the organic coupling relationship between the above-described configurations. can do.

In addition, the embodiments shown in the drawings may be modified and implemented in other forms, and if implemented including the configuration claimed in the claims of the present invention or implemented within the scope of equality, it should be considered as belonging to the scope of the present invention. something to do.

Sanghyeon 1 Vertical material 2 Vertical plate 21
Top plate 22 Vertical buffer member 3 Vertical buffer member body 31
Body end 32 Sliding rib 33 Rib end 34
Auxiliary leg 35 Leg end 36 Connecting clip 4
Inclined material 5 Road body 51 Turnbuckle 52
Inclined buffering member 6 Supporting part 61 Buffering part 62
Buffer part open surface 62a Vertical plate fastening rib 63 Through hole 63a
Rod body connection 64 Connection body 641 Connection body fixing 642
Rod body fixing part 643 Rotating part 644 Rotating ball 6441
Rotating part cap 6442 Cap fastening part 646 Rotating ball receiving part 647
Body separation prevention part 648 Incline buffer member 7 Base part 71
First support part 711 Second support part 712 Buffer part 72
Buffer part open surface 72a Vertical plate fastening rib 731 Upper plate fastening rib 732
Rod body connection 74 Connection body 741 Connection body fixing 742
Rod body fixing part 743 Rotating part 744 Rotating ball 7441
Rotating part cap 7442 Cap fastening part 746 Rotating ball receiving part 747
Body separation prevention part 748 End member 8 Fastening member K, K'

Claims (10)

In the buffer member for installing a roof structure having a seismic isolation function to buffer vibration,
A support part connected to the beam of the roof structure;
A buffer part having both ends connected to the support part and provided with a curved leaf spring; And
Including; a rod body connection portion fixed at a selective position in the buffer portion, the rod of the roof structure is fixed,
An open surface is formed in the buffer part along its length direction,
The load body connection part
A connection part body inserted into the open surface of the buffer part and provided to be slidable along the surface of the buffer part forming the open surface;
A rod body fixing part connected to the connection part body and fixing a rod of the roof structure; And
And a connection part body fixing part extending from both sides of the connection part body and to which a fastening member fixed to the buffer part is fastened. delete The method of claim 1,
The load body connection part
And a rotating part connected to the load body fixing part and rotating according to the relative motion of the load body and the beam of the roof structure. The method of claim 1,
The support part
A first support part connected to one end of the buffer part; And
A buffer member for installing a roof structure, comprising: a second support having one end vertically connected to the other end of the first support and the buffer connected to the other end. The method of claim 1,
A buffer member for installing a roof structure, further comprising: a fastening rib protruding from the support and having a through hole through which a fastening member fixed to the beam of the roof structure passes. In the method for manufacturing the buffer member for installing the roof structure of claim 1,
Cutting the metal plate to manufacture the support;
Forming an open surface of the buffer part on a predetermined portion; And
The method of manufacturing a buffer member for installing a roof structure, comprising: forming the buffer part by bending a predetermined portion of the support part. delete delete delete In the base isolation arch roof comprising the buffer member for installing the roof structure of claim 1,
Arch-shaped top chord covering the upper part of the building;
A first vertical member connected to a lower portion of the upper chord so that its longitudinal direction is orthogonal to the longitudinal direction of the upper chord;
A second vertical member connected to a lower portion of the upper chord so that the longitudinal direction thereof is orthogonal to the longitudinal direction of the upper chord, and positioned at a lower height than the first vertical material; And
Including; one end is connected to the upper end of the first vertical material, the other end is connected to the lower end of the second vertical material;
The buffer member for installing the roof structure
A buffer member for installing a roof structure, characterized in that it is installed in a space between the first vertical member and the sloping member or a space between the sloping member and the second vertical member.

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