KR20210077407A - Impact resitstant curtain wall and curtain wall strucrure - Google Patents

Abstract

The present invention provides an impact resistant curtain wall, which comprises: a protruding bumper unit formed to protrude forward than an exterior plate material and having a protruding buffer layer for buffering external impact; a vertical support unit disposed on a rear side of the protruding bumper unit and having a vertical buffer layer which buffers the external impact; and a bumper connecting unit for connecting the protruding bumper unit and the vertical support unit.

Description

Collision-resistant curtain wall and curtain wall structure {IMPACT RESITSTANT CURTAIN WALL AND CURTAIN WALL STRUCRURE}

The present invention relates to a collision-resistant curtain wall with improved structural performance, and a curtain wall structure.

It should be noted that the content described in this section merely provides background information on the present invention and does not constitute the prior art.

Curtain walls and building exterior materials are composed of glass members or exterior members, base frames, and various parts connecting them.

General curtain walls are verified through comprehensive performance evaluation such as sealing performance such as airtightness/watertightness, structural performance to resist wind pressure and earthquake, insulation and condensation prevention performance, fire resistance, and sound insulation.

Structural performance of curtain wall can be realized by the structural performance of the glass and curtain wall mullion/transom frame (vertical/horizontal frame), the connection performance between the vertical/horizontal frame and the structure, and the structural performance of the underlying frame itself.

The connection between the glass member - the lower frame and the lower frame - the structure is connected by parts called fasteners and anchors. When external physical load conditions such as wind pressure, earthquake, collision, or explosion occur, glass-frame-fastener -Anchor-structure is delivered in order, and structural safety is judged based on the deflection and residual displacement limits for the behavior of each member, and whether or not parts are dropped.

According to the relevant regulations of the Ministry of Land, Infrastructure and Transport, it is mandatory to design a high-rise building or large-scale complex with a total floor area of 20,000 m2 or more or 50 stories or more to respond to loads that may occur due to terrorism such as collisions or explosions.

Introduced as a design guideline for the prevention of building terrorism in 2008, high-rise buildings with 50 stories or more or a building height of 200 m or more according to Article 2 No. 15 of the Building Act Enforcement Decree, cultural and assembly facilities according to Annex 1 of the 「Building Act Enforcement Decree」 ), sales facilities, transportation facilities (excluding airport facilities), general hospitals among medical facilities, business facilities, and tourist lodging facilities among lodging facilities with a total floor area of 20,000 square meters or more This applies to

In particular, energy-saving materials were selected for the finishing materials of the exterior walls of the underground lobby floor, but safety was also ensured from debris in the event of a collision or explosion.

The guidelines above can be used when the heads of central administrative agencies and local governments conduct bidding, ordering, service, design evaluation, performance evaluation of existing buildings, and deliberation by the building committee.

Due to the increase in vehicles, the aging and inexperience of drivers, and defects in automobiles, vehicle crashes to buildings occur every year, and property damage and casualties of internal users are continuously occurring. A vehicle collision is primarily loaded as a partial load on the low-rise envelope of a building, and it is important to absorb the collision at the envelope point in order to prevent the spread of damage to internal life, property, and members around the collision.

Therefore, in the event of a collision, it is necessary to implement the collision-resistance performance by configuring so that the lateral movement or energy absorption behavior of the exterior material through these parts is possible.

In the case of a general curtain wall, if the glass surface and the mullion/transom (vertical/horizontal member) frame are loaded with a load in the horizontal direction, which is the vehicle collision transmission direction, and a stress is generated more than the strength of the material by the load, the glass is broken and the frame will plastically behave.

If the glass and frame are broken, the vehicle will rush into the interior and cause a secondary impact on people or property.

Therefore, in order to realize the collision-resistance performance, it is necessary to install a material or size with very high strength so that the glass and frame behave elastically, or to design to prevent penetration of a rushing vehicle into the interior even with a certain degree of plasticity. Do.

In order to achieve elastic behavior, it may not be economical because high strength tempered glass or a large size frame must be applied. Therefore, it is a concept that prevents the vehicle from rushing into the interior by absorbing collision energy through plastic behavior such as the film structure of glass and frame. It is desirable to design

The advantage of curtain walls using steel is that the structural rigidity and strength of steel are greater than other metals or non-metal materials such as aluminum or plastic, so the structural performance, that is, the resistance to high wind pressure, earthquake, and the weight of heavy exterior members is excellent. to be.

Such a steel curtain wall can have excellent resistance to high-speed loads such as vehicle collisions when high-strength steel is applied.

At the same time, since the melting point is higher than that of aluminum (AL) or PVC materials, it has superior performance in resisting heat in case of fire, and has excellent thermal insulation and dew condensation performance due to low thermal conductivity, so additional performance improvement can be expected.

KR 10-1997-0021577 A

An aspect of the present invention is to provide a collision-resistant curtain wall and a curtain wall structure that can more stably buffer external shocks.

As one aspect for achieving the above object, the present invention is a protruding bumper portion which is formed to protrude forward than the exterior plate material, and a protruding buffer layer for buffering external impact is formed; a vertical support part disposed behind the protruding bumper part and having a vertical buffer layer that cushions external shocks; And, it provides a collision-resistant curtain wall comprising a; bumper connecting portion connecting between the protruding bumper portion and the vertical support portion.

Preferably, the protruding bumper portion is formed to protrude forward than the exterior plate, and a protruding frame having a hollow inside; and a protruding buffer layer formed inside the protruding frame and filled with an energy absorbing material.

Preferably, the protruding bumper part is formed to extend in the longitudinal direction to correspond to at least the height of the entire floor of the building, and a plurality of the protruding bumper parts may be installed at a predetermined interval in the lateral direction.

Preferably, the protruding bumper portion is formed to extend in the longitudinal direction, and may be installed to cover the front surface of the connecting portion of the adjacent exterior plate material connected in the transverse direction.

Preferably, the vertical support portion is connected to the bumper connection portion, the shock-absorbing energy absorber is filled with a buffer flange; and a first support web supporting the buffer flange from the rear and having a straight cross-section.

Preferably, the vertical support portion is connected to the bumper connection portion, the shock-absorbing energy absorber is filled with a buffer flange; and a second support web supporting the buffer flange from the rear and having a 'T-shaped' cross section.

Preferably, the buffer flange is formed with a connection groove to which the bumper connection part is connected, the buffer frame having a hollow inside; and a vertical buffer layer formed inside the buffer frame and filled with an energy absorber.

Preferably, the bumper connecting portion is joined to the protruding bumper portion, the inner cap member for fixing the exterior plate; and a fixing bolt for fixing the inner cap member in a state of being fixed to the connection groove of the vertical support unit.

Preferably, it is installed at the rear of the vertical support, the tensile support for providing a tensile force in a state fixed to the building; may further include.

Preferably, the tension support part, a support pipe member extending in the longitudinal direction along the vertical support part; and a tensile support member disposed through the support pipe member and providing tensile force while being fixed to the building.

Preferably, the tension support member includes: an embedded anchor having one end fixed to be embedded in a slab of a building, and having an internal thread inserted into a portion protruding from the slab; a fixing cap having an external thread fastened to the internal thread formed at the rear of the buried anchor; and a tension member having an end fixed to the fixing cap and extending in the longitudinal direction.

Preferably, it is provided on the connecting portion of the exterior plate material connected in the longitudinal direction, the connection bumper portion is formed to buffer the external impact is formed; may further include.

Preferably, it is installed to cross the vertical support, horizontal support for supporting the rear surface of the exterior plate together with the vertical support; may further include.

As another aspect for achieving the above object, the present invention is a collision-resistant curtain wall according to any one of claims 1 to 8; a fastener bumper for buffering and supporting the rear of the collision-resistant curtain wall; a first fastener member fixed to a building and supporting the fastener bumper from a rear side; and a second fastener member installed through the fastener bumper and the first fastener member and fixed to the collision-resistant curtain wall and the first fastener member.

Preferably, the fastener bumper includes: a fastener frame having a hollow inside and having a bumper hole through which the second fastener member passes; and a fastener buffer layer formed inside the fastener frame and filled with an energy absorbing material.

According to an embodiment of the present invention, there is an effect of more stably buffering an external shock.

1 is a transverse cross-sectional view of a collision-resistant curtain wall according to an embodiment of the present invention.
FIG. 2 is a longitudinal cross-sectional view taken in a direction I-I' of FIG. 1 .
Figure 3 is a transverse cross-sectional view of the collision-resistant curtain wall according to another embodiment of the present invention.
4 is a lateral cross-sectional view illustrating an embodiment in which the collision-resistant curtain wall of FIG. 1 is coupled to a building.
5 is a longitudinal cross-sectional view illustrating another embodiment in which the collision-resistant curtain wall of FIG. 1 is coupled to a building.
6 is a longitudinal cross-sectional view of a curtain wall structure according to an embodiment of the present invention.
FIG. 7 is an exploded perspective view illustrating a coupling method of the fastener bumper, the first fastener member, and the second fastener member of the curtain wall structure of FIG. 6 .

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, the embodiment of the present invention may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below. Further, the embodiments of the present invention are provided in order to more completely explain the present invention to those of ordinary skill in the art. The shapes and sizes of elements in the drawings may be exaggerated for clearer description.

Hereinafter, the collision-resistant curtain wall 10 according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 5 .

The collision-resistant curtain wall 10 according to an embodiment of the present invention includes a protruding bumper part 100 , a vertical support part 200 , and a bumper connection part 300 , and additionally a horizontal support part 400 , a tension support part 500 . , it may include a connection bumper unit 600 .

1 and 2, the collision-resistant curtain wall 10 is formed to protrude forward than the exterior plate H, and the protruding bumper part 100 in which the protruding buffer layer 130 for buffering external impact is formed. and a vertical support part 200 disposed behind the protruding bumper part 100 and having a vertical buffer layer 213 for buffering external shocks formed therein, and the protruding bumper part 100 and the vertical support part 200 It may include a bumper connection part 300 connecting between the.

Referring to FIGS. 1 and 2 , the protruding bumper part 100 is disposed in front of the exterior plate H to first absorb a shock applied from the outside.

In addition, the protruding bumper part 100 is formed to protrude in the front of the exterior plate material (H), it can serve as a shading to block sunlight while first absorbing the shock applied from an external shock source such as a vehicle.

That is, the protruding bumper part 100 may serve to reduce energy by controlling excessive solar radiation from entering the room in summer.

The protruding bumper part 100 is formed to extend in the longitudinal direction, and may be installed in plurality by being spaced apart from each other by a predetermined interval in the lateral direction.

The protruding bumper part 100 may have a cross-section of a trapezoid shape in the transverse direction.

The protruding bumper part 100 may be formed with a protruding buffer layer 130 that is filled with an energy absorbing material in at least a partial region to cushion an external impact.

As an example, the energy absorbing material may be configured to buffer external impact by inserting a corrugated reinforcing material or foamed metal.

1 and 2 , the vertical support part 200 is disposed at the rear of the protruding bumper part 100 to support the protruding bumper part 100 via the bumper connection part 300 , and the protruding bumper part 100 . ) can buffer external shocks transmitted from

The vertical support unit 200 may absorb an impact such as a collision load transmitted through the protruding bumper unit 100 and the exterior plate material (H).

The vertical support part 200 may be fixed to the rear of the protruding bumper part 100 via the bumper connection part 300 .

In addition, the vertical support unit 200 may support the rear surface of the exterior plate (H).

Referring to FIG. 1 , the vertical support unit 200 may support the ends of two adjacent exterior plates H.

Referring to FIG. 2 , the vertical support part 200 may extend in the longitudinal direction, and the connection groove 270 into which the bumper connection part 300 is inserted may be continuously formed in the longitudinal direction.

The bumper connection part 300 may be connected to the connection groove 270 , and an energy absorber may be filled in at least a partial region of the vertical support part 200 .

The vertical support unit 200 may be formed with a vertical buffer layer 213 that is filled with an energy absorbing material in at least a partial region to cushion an external impact.

1 and 2 , the bumper connection part 300 may connect the protruding bumper part 100 and the vertical support part 200 .

The bumper connection part 300 may have one side fixed to the protruding bumper part 100 , the other side being fixed to the vertical support part 200 , and the exterior plate H together with the vertical support part 200 .

That is, the exterior plate material (H) may be installed between the bumper connection part 300 and the vertical support part 200, and the exterior plate material (H) may be composed of a glass member.

A gasket (G) for securing sealing performance, airtight performance, etc. may be installed between the protruding bumper part 100 and the exterior plate material (H) and between the vertical support part 200 and the exterior plate material (H).

The protruding bumper part 100 and the vertical support part 200 may be filled with an energy absorbing material in at least some regions to cushion external impact, and the protruding bumper part 100 and the vertical support part 200 are on the transmission path of the external shock. may be filled with an energy absorber.

For example, referring to FIG. 1 , the protruding buffer layer 130 is a first region filled with an energy absorber in the protruding bumper part 100 and a vertical buffer layer that is a second region filled with an energy absorber in the vertical support part 200 ( 213) may be disposed in the front-rear direction, which is the transmission path of the external impact.

The protruding bumper part 100 and the vertical support part 200 are filled with an energy absorbing material on the transmission path of the external shock, so that the external shock is overlapped by the protruding bumper part 100 and the vertical support part 200, It has the effect of more stably buffering the applied shock.

The collision-resistant curtain wall 10 of the present invention may be configured to include a metal material such as steel.

At least some of the components such as the protruding bumper part 100, the vertical support part 200, and the bumper connection part 300 constituting the collision-resistant curtain wall 10 may be made of a metal material such as steel.

As an example, the collision-resistant curtain wall 10 may be composed of a steel curtain wall made of steel.

Of course, various metal materials in addition to steel can be applied to the collision-resistant curtain wall 10 as long as structural rigidity equal to or higher than that of steel can be secured while securing economic feasibility.

As another example, the collision-resistant curtain wall 10 is made of high-strength steel, and by reducing the cross-sectional size of the collision-resistant curtain wall 10, structural rigidity and economic efficiency can be improved at the same time.

1 and 2, the protruding bumper part 100 is formed to protrude forward than the exterior plate material (H) and has a hollow inside of the protruding frame 110 and the protruding frame 110 inside. The protrusion buffer layer 130 formed and filled with the energy absorbing material may be provided.

The protruding bumper part 100 is formed to extend in the longitudinal direction to correspond to at least the height of the entire layer of the building S, and a plurality of protruding bumper units 100 may be installed at a predetermined interval in the lateral direction.

For example, the protruding bumper part 100 may be formed to extend in the longitudinal direction to correspond to the height of the entire layer of the building (S).

As another example, the protruding bumper part 100 may be formed to extend in the longitudinal direction to correspond to the height of two or more floors of the building (S).

1 and 2 , the protruding bumper part 100 is formed to extend in the longitudinal direction and may be installed to cover the front surface of the connection part of the adjacent exterior plate H connected in the transverse direction.

1 and 2, the vertical support part 200 is connected to the bumper connection part 300, and a buffer flange 210 that is filled with an energy absorber for buffering an impact, and the buffer flange 210. Supported from the rear, it may be provided with a first support web 230 having a straight cross-section.

The buffer flange 210 may be connected to the protruding bumper part 100 via the bumper connection part 300 .

The shock applied to the collision-resistant curtain wall 10 from the outside is primarily buffered by the protruding bumper part 100 , and the shock transmitted from the protruding bumper part 100 is absorbed by the buffer flange 210 of the vertical support part 200 . It has the effect of being able to transmit to the building (S) by buffering the shock applied from the outside more stably by secondary buffering.

The buffer flange 210 is formed with a connection groove 270 to which the bumper connection part 300 is connected, and an energy absorbing material may be filled in the buffer flange 210 .

The vertical support 200 may form a 'T-shaped' cross section while the buffer flange 210 and the first support web 230 are joined by welding or the like.

The first support web 230 supports the buffer flange 210 from the rear, and may be composed of a heavy plate made of a metal material having a straight cross-section.

As an example, the first support web 230 may be composed of a thick plate made of high-strength steel.

While the first support web 230 is composed of a heavy plate of a metal material having a straight cross-section, the stress due to the impact transmitted from the protruding bumper part 100 and the exterior plate material (H) to the buffer flange 210 is stably relieved. can support

The first support web 230 may be formed to extend rearwardly from the central portion in the transverse direction of the buffer flange 210 .

The first support web 230 may be formed to extend in the longitudinal direction together with the buffer flange 210 .

Referring to FIG. 1 , the vertical support 200 may have a 'T-shaped' cross-section while the first support web 230 is coupled to the rear of the buffer flange 210 .

Referring to FIG. 3 , the vertical support part 200 is connected to the bumper connection part 300 and supports the buffer flange 210 and the buffer flange 210 in which an energy absorber for buffering shock is charged from the rear and , may be provided with a second support web 250 having a 'T-shaped' cross section.

The buffer flange 210 is formed with a connection groove 270 to which the bumper connection part 300 is connected, and an energy absorbing material may be filled in the buffer flange 210 .

The second support web 250 supports the buffer flange 210 from the rear, and may be composed of a heavy plate made of a metal material having a 'T-shaped' cross section.

The second support web 250 has a horizontal plate 251 on the upper portion of the 'T-shaped' cross-section in contact with the rear of the buffer flange 210, and a vertical plate 253 at the center of the horizontal plate 251 in the transverse direction. It may be formed to extend backwards.

The second support web 250 may be formed to extend in the longitudinal direction together with the buffer flange 210 .

The horizontal plate 251 of the second support web 250 may be installed to support the entire rear surface of the buffer flange 210 .

1 to 3 , the buffer flange 210 has a connection groove 270 to which the bumper connection part 300 is connected, and a buffer frame 211 with a hollow inside, and the buffer frame 211 . ) and may include a vertical buffer layer 213 filled with an energy absorbing material.

The buffer flange 210 may be supported by the first support web 230 or the second support web 250 .

Referring to FIGS. 1 and 2 , the bumper connection part 300 is bonded to the protruding bumper part 100 , and an inner cap member 310 for fixing the exterior plate H, and the vertical support part 200 of the A fixing bolt 330 for fixing the inner cap member 310 in a state of being fixed to the connection groove 270 may be provided.

The inner cap member 310 may be welded to the protruding frame 110 of the protruding bumper part 100 .

The fixing bolt 330 may fix the inner cap member 310 in a state inserted and fixed in the connection groove 270 formed in the buffer flange 210 of the vertical support 200 .

That is, the fixing bolt 330 fixes the buffer flange 210 and the inner cap member 310 , and the exterior plate H is fixed between the buffer flange 210 and the inner cap member 310 .

1 and 2, the collision-resistant curtain wall 10 is installed at the rear of the vertical support 200, and further includes a tensile support 500 that provides a tensile force in a state fixed to the building S. can do.

The tension support part 500 is a component that serves to increase the cross-sectional secondary moment of the collision-resistant curtain wall 10 together with the vertical support part 200 by installing the vertical support part 200 at the rear.

Accordingly, as the vertical support part 200 and the tension support part 500 are integrally installed, the cross-sectional secondary moment is greatly improved, and the collision resistance performance can be maximized. Due to this, a collision source such as a vehicle may be prevented from penetrating into the interior of the building S.

The tensile support unit 500 may support the collision-resistant curtain wall 10 to resist the tensile force in a state fixed to the building S.

The tensile support part 500 is formed to extend in the longitudinal direction together with the vertical support part 200 , and may be integrally joined to the rear of the vertical support part 200 by welding bonding or the like.

The tensile support unit 500 may be fixed to the slab of the building (S).

As an example, referring to FIG. 4 , the tension support part 500 is disposed on the front surface of the slab, and is fixed together with the vertical support part 200 by a fixing bracket (I) installed in the front of the slab, and the fixing bracket (I) is It can be fixed to the slab through anchor bolts.

The vertical support part 200 in which the tension support part 500 is installed is fixed via a fastening member such as a bolt member in a state to be disposed between a pair of fixing brackets (I) having a 'L' cross section in front of the slab. can be fixed.

As another example, referring to FIG. 5 , the tensile support unit 500 may resist at least tensile force in a state in which both ends in the height direction are fixed to the building (S).

Tensile support unit 500 may be fixed to the height direction both ends to the slab of the building (S).

1 and 2 , the tension support part 500 is disposed through the support pipe member 510 and the support pipe member 510 extending in the longitudinal direction along the vertical support part 200 . and may be provided with a tensile support member 530 that provides a tensile force while being fixed to the building (S).

The support pipe member 510 may be made of a circular steel pipe with a hollow inside, and the tension member 531 of the tension support member 530 may be disposed inside the hollow.

The support pipe member 510 is made of a high-strength steel pipe, and the tension support member 530 may include a high-strength cable in which a plurality of metal wires are twisted.

Referring to FIG. 5 , the tension support member 530 has an embedded anchor 535 having one end fixed embedded in the slab of the building S, and an internal thread inserted into a portion protruding from the slab, and the embedding. A fixing cap 533 having an external thread fastened to the internal thread formed at the rear of the anchor 535, and a tension member 531 having an end fixed to the fixing cap 533 and extending in the longitudinal direction. can do.

The tension support member 530 has a tension member 531 extending in the longitudinal direction, and fixed caps 533 and embedded anchors 535 may be installed at both ends of the tension member 531 in the longitudinal direction, respectively.

While the buried anchors 535 at both ends are fixed to the slab, the tension member 531 may be fixed to the building S such as the slab.

In the buried anchor 535, a fixing cap 533 may be fixed to the other end in a state in which one end is fixed to the slab.

The fixing cap 533 may be fixed to the embedded anchor 535 in a state in which the end of the tension member 531 is fixed.

Both ends of the tension member 531 are fixed by a fixing cap 533 , and both ends of the tension member 531 may be supported by the slab while the fixing cap 533 is fixed to the buried anchor 535 .

The tension member 531 may be formed of a high-strength cable in which a plurality of strands are twisted.

1 and 2, the collision-resistant curtain wall 10 is provided in the connection portion of the exterior plate material (H) connected in the longitudinal direction, the connection buffer layer 630 for buffering the external impact is formed. It may further include a bumper unit 600 .

The connection bumper part 600 may serve to protect the connection part of the exterior plate material (H) connected in the longitudinal direction.

The connecting bumper unit 600 may be formed to extend in the transverse direction along the connecting portion of the exterior plate material (H) connected in the longitudinal direction.

The connection bumper unit 600 may include a connection frame 610 disposed in front of the exterior plate H, and a connection buffer layer 630 formed inside the connection frame 610 and filled with an energy absorbing material. .

Referring to FIG. 1 , the connecting bumper part 600 is installed to cross the protruding bumper part 100 , and may be installed on both sides of the protruding bumper part 100 .

1 and 2, the collision-resistant curtain wall 10 is installed to intersect the vertical support part 200, and a horizontal support part (H) supporting the rear surface of the exterior plate material (H) together with the vertical support part (200). 400) may be further included.

The horizontal support part 400 is formed to extend in the transverse direction, and may be installed in plurality by being spaced apart from each other by a predetermined interval in the longitudinal direction.

The horizontal support part 400 is formed to extend in the lateral direction so as to intersect the vertical support part 200 , and a plurality of horizontal support parts 400 may be installed to be spaced apart from each other in the longitudinal direction.

In this way, the collision-resistant curtain wall 10 of the present invention can be more firmly fixed to the building S while the plurality of vertical support parts 200 and the plurality of horizontal support parts 400 are arranged in a grid shape while crossing each other. .

For example, the vertical support 200 may be installed in a vertical direction, and the horizontal support 400 may be installed in a horizontal direction.

The horizontal support unit 400 is installed in the transverse direction and provided with a horizontal flange 410 installed to intersect the buffer flange 210, and a horizontal web 430 supporting the horizontal flange 410 from the rear and having a straight cross-section. can do.

Referring to FIG. 2 , the horizontal support unit 400 may have a 'T-shaped' cross-section while the horizontal web 430 is coupled to the rear of the horizontal flange 410 .

Next, the curtain wall structure will be described in detail with reference to the drawings.

6 to 7 , the curtain wall structure according to an embodiment of the present invention includes a collision-resistant curtain wall 10, a fastener bumper 20, a first fastener member 30, and a second fastener member 40. may include.

6 to 7, the curtain wall structure is fixed to the collision-resistant curtain wall 10, the fastener bumper 20 for buffering and supporting the rear of the collision-resistant curtain wall 10, and the building (S). and a first fastener member 30 supporting the fastener bumper 20 from the rear, and installed through the fastener bumper 20 and the first fastener member 30, and the collision-resistant curtain wall 10 ) and a second fastener member 40 fixed to the first fastener member 30 .

Of course, various embodiments of the collision-resistant curtain wall 10 having various embodiments described above may be applied to the curtain wall structure of the present invention.

Accordingly, the configuration of the protruding bumper part 100, the vertical support part 200, the bumper connection part 300, etc. of the collision-resistant curtain wall 10 utilized in the curtain wall structure is the structure of the collision-resistant curtain wall 10 as already described. Since the configuration is the same, a detailed description thereof will be omitted to avoid duplication.

The fastener bumper 20 is a component installed at the rear of the collision-resistant curtain wall 10 and serves to buffer the impact transmitted from the collision-resistant curtain wall 10 .

The fastener bumper 20 is disposed between the collision-resistant curtain wall 10 and the first fastener member 30 to buffer the impact transmitted from the collision-resistant curtain wall 10, the first fastener member 30, the second It can be delivered to the building (S) through the fastener member (40) and the like.

In this way, the fastener bumper 20 installed at the rear of the collision-resistant curtain wall 10 cushions the impact transmitted from the collision-resistant curtain wall 10, thereby fixing the first fastener member 30 fixed to the structural material J, etc.; It is possible to prevent damage to the second fastener member 40 and the like.

For example, referring to FIG. 6 , the second fastener member 40 may be fixed to a structural member J such as an H-shaped steel fixed to a slab of the building S.

Referring to FIG. 7 , in the fastener bumper 20 , a bumper hole 22 through which the second fastener member 40 penetrates may be formed through in the longitudinal direction.

Referring to FIG. 7 , the fastener bumper 20 has a hollow interior and a bumper hole 22 through which the second fastener member 40 penetrates. A fastener buffer layer 25 formed therein and filled with an energy absorbing material may be provided.

Referring to FIG. 6 , the first fastener member 30 is installed at the rear of the fastener bumper 20 to transmit the shock transmitted from the fastener bumper 20 to the building S through the structural material J such as H-beam. can

Referring to FIG. 7 , the first fastener member 30 may have an “L” cross-section, and the first fastener hole 32 through which the second fastener member 40 penetrates may be formed through in the longitudinal direction.

The first fastener member 30 is formed in a direction crossing the first through flange 31 having the first fastener hole 32 through which the second fastener member 40 passes, and the first through flange 31 . And it may be provided with a first fixing flange 35 fixed to the structural material (J) such as H-beam.

Referring to FIG. 6 , the second fastener member 40 is installed through the fastener bumper 20 and the first fastener member 30 , and the collision-resistant curtain wall 10 and the first fastener member 30 are installed. can be fixed to each.

One side of the second fastener member 40 may be fixed to the collision-resistant curtain wall 10 , and the other side may be fixed to the first fastener member 30 . At this time, the first fastener member 30 may be fixed to the building (S) through a structural material (J) such as H-beam (H-beam).

Referring to FIG. 7 , in the second fastener member 40 , a pair of second fastener modules 40M having an “L” cross-section may be disposed to be spaced apart from each other.

In a state in which the vertical support part 200 of the collision-resistant curtain wall 10 is inserted between the pair of second fastener modules 40M, it may be fixed through a fastening member such as a bolt member.

The second fastener module 40M passes through the fastener bumper 20 and the first fastener member 30, and a second insertion flange 41 fixed to the collision-resistant curtain wall 10, and the second insertion flange ( 41 ) and may include a second fixing flange 45 fixed to the first fastener member 30 .

The second insertion flange 41 penetrates the bumper hole 22 of the fastener bumper 20 and the first fastener hole 32 of the first fastener member 30, and the vertical support part 200 of the collision-resistant curtain wall 10 is ) and can be fixed.

The second fixing flange 45 may be fixed through the first through flange 31 of the first fastener member 30 and a fastening member such as a bolt member.

In the curtain wall structure, the collision-resistant curtain wall 10 can be fixed to the building S through the fastener bumper 20, the first fastener member 30, the second fastener member 40, etc. have.

The curtain wall structure buffers the impact in the internal structure of the collision-resistant curtain wall 10, and the fastener bumper 20 overlaps the shock transmitted from the collision-resistant curtain wall 10 to see the impact applied from the outside. It has the effect of being stably buffered and delivered to the building (S).

For example, when the vertical support 200 includes the configuration of the buffer flange 210 in which the energy absorber is filled, it is primarily buffered by the protruding bumper part 100 in the internal structure of the collision-resistant curtain wall 10 and , the shock transmitted from the protruding bumper part 100 can be secondaryly buffered by the buffer flange 210 of the vertical support part 200 , and the fastener bumper 20 absorbs the shock transmitted from the collision-resistant curtain wall 10 . It has the effect of being able to buffer the external shock more stably and deliver it to the building (S) by tertiary buffering.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and variations are possible within the scope without departing from the technical spirit of the present invention described in the claims. It will be apparent to those of ordinary skill in the art.

10: anti-collision curtain wall 20: fastener bumper
21: fastener frame 22: bumper hole
25: fastener buffer layer 30: first fastener member
31: first through flange 32: first fastener hole
35: first fixing flange 40: second fastener member
40M: second fastener module 41: second insertion flange
45: second fixing flange 100: protruding bumper part
110: protrusion frame 130: protrusion buffer layer
200: vertical support 210: buffer flange
211: buffer frame 213: vertical buffer layer
230: first support web 250: second support web
251: horizontal plate 253: vertical plate
270: connection groove 300: bumper connection part
310: inner cap member 330: fixing bolt
400: horizontal support 410: horizontal flange
430: horizontal web 500: tensile support
510: support pipe member 530: tension support member
531: tension member 533: fixed cap
535: buried anchor 600: connecting bumper part
610: connection frame 630: connection buffer layer
G: Gascat H: Exterior plate
I: Fixing bracket J: Structural material
S: building

Claims (15)

a protruding bumper portion which is formed to protrude forward from the exterior plate and is formed with a protruding buffer layer that cushions external impact;
a vertical support part disposed behind the protruding bumper part and having a vertical buffer layer that cushions external shocks; and;
Collision-resistant curtain wall comprising a; bumper connecting portion connecting between the protruding bumper portion and the vertical support portion.
According to claim 1, wherein the protruding bumper portion,
A projecting frame that is formed to protrude forward than the exterior plate and has a hollow inside; and;
A collision-resistant curtain wall comprising a; a protruding buffer layer formed inside the protruding frame and filled with an energy absorber.
According to claim 1,
Collision-resistant curtain wall, characterized in that the protruding bumper portion is formed to extend in the longitudinal direction to correspond to at least the height of the entire floor of the building, and is spaced apart from each other at a predetermined interval in the lateral direction.
According to claim 1,
The protruding bumper portion extends in the longitudinal direction and is installed so as to cover the front surface of the connecting portion of the adjacent exterior plate material connected in the transverse direction.
According to claim 1, wherein the vertical support portion,
a buffer flange connected to the bumper connection part and filled with an energy absorbing material for buffering an impact; and;
Collision-resistant curtain wall comprising; a first support web supporting the buffer flange from the rear and having a straight cross-section.
According to claim 1, wherein the vertical support portion,
a buffer flange connected to the bumper connection part and filled with an energy absorbing material for buffering an impact; and;
Collision-resistant curtain wall comprising; a second support web supporting the buffer flange from the rear and having a 'T-shaped' cross section.
According to claim 5, The buffer flange,
a buffer frame in which a connection groove is formed to which the bumper connection part is connected, and the inside is hollow; and;
Collision-resistant curtain wall comprising; a vertical buffer layer formed inside the buffer frame and filled with an energy absorber.
According to claim 1, wherein the bumper connection portion,
an inner cap member joined to the protruding bumper portion and fixing the exterior plate material; and;
Collision-resistant curtain wall comprising a; a fixing bolt for fixing the inner cap member in a state fixed to the connection groove of the vertical support.
9. The method according to any one of claims 1 to 8,
Collision-resistant curtain wall further comprising a; is installed at the rear of the vertical support, and provides a tensile force in a state fixed to the building.
10. The method of claim 9, wherein the tension support portion,
a support pipe member extending in the longitudinal direction along the vertical support part; and;
Collision-resistant curtain wall having; a tension support member disposed through the support pipe member and providing a tensile force while being fixed to the building.
11. The method of claim 10, wherein the tension support member,
A buried anchor having one end fixed to the slab of a building and having an internal thread inserted into a portion protruding from the slab;
a fixing cap having an external thread fastened to the internal thread formed at the rear of the buried anchor; and;
A collision-resistant curtain wall comprising a; a tension member having an end fixed to the fixing cap and extending in the longitudinal direction.
9. The method according to any one of claims 1 to 8,
Collision-resistant curtain wall further comprising a; it is provided on the connection portion of the exterior plate connected in the longitudinal direction, the connection buffer portion is formed with a connection buffer layer for buffering external impact.
9. The method according to any one of claims 1 to 8,
Collision-resistant curtain wall further comprising a; is installed so as to cross the vertical support, horizontal support for supporting the rear surface of the exterior plate together with the vertical support.
The collision-resistant curtain wall according to any one of claims 1 to 8;
a fastener bumper for buffering and supporting the rear of the collision-resistant curtain wall;
a first fastener member fixed to a building and supporting the fastener bumper from a rear side; and;
Curtain wall structure comprising a; a second fastener member installed through the fastener bumper and the first fastener member, and fixed to the collision-resistant curtain wall and the first fastener member.
15. The method of claim 14, wherein the fastener bumper,
a fastener frame having a hollow inside and having a bumper hole through which the second fastener member passes; and;
A curtain wall structure comprising a; a fastener buffer layer formed inside the fastener frame and filled with an energy absorbing material.

Images