KR101932889B1 - Windows system improved in shock-resistance - Google Patents

Abstract

According to the present invention, a shock-resistant window system comprises: a door frame forming an opening and closing type interior side window with a glass member, and an internal horizontal frame pair and an internal vertical frame pair surrounding the glass member; and an external side frame forming an exterior side window. An internal horizontal frame in a lower end comprises at least one U-shaped support unit supporting a load of the glass member. The support unit comprises: an elastic member surrounding a lower end portion of the glass member; and silicon interposed between the elastic member and the glass member. In the silicon, a ceramic particle is dispersed. Moreover, the ceramic particle may be at least one of AlN, SiC and BN.

Description

{Windows system improved in shock-resistance}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an anti-seismic reinforcement window system, and more particularly, to a window system having a structure capable of reinforcing an anti-seismic reinforcement of aramid fiber.

A glass window is provided in the opening of the building for inflow, shutoff, ventilation, etc. of solar radiation. However, glass windows have a negative effect on the heating and cooling energy consumption of buildings. In recent years, various types of glass windows for reducing energy consumption through glass windows have been proposed, such as switchable transparent glass windows, building integrated photovoltaic windows, and blind windows.

The blind window is a proposed technology to improve the insulation performance by installing a shade between glass and glass, and to block and control solar radiation at the same time. In general, since the awning is not exposed to the outside, there is an advantage that the design simplicity can be intended. However, although window systems such as blinds include a plurality of windows, due to material and structural problems, the window system is somewhat fragile in the invisible portion compared to other structures or other members.

In the existing seismic retrofit system, for example, Korean Patent No. 10-1793601, a seismic resistant window is realized by simply adding a cap member or the like to a double-layer glass. However, when the adhesive force between the cap member and the double- There is a problem that microscopic impact and deformation impact due to vibration occur between the cap member and the multilayered glass due to the lack of uniformity. That is, micro-impact between the glass and the member directly contacting with the glass is generated, which may cause a problem that the seismic performance is deteriorated.

The present invention provides a window system capable of minimizing micro-shocks caused by failure to form a sense of unity due to the occurrence of gaps or gaps formed between a glass frame and a window frame directly contacting the glass frame.

An earthquake-resistant window system according to the present invention comprises a glass member, a door frame forming an openable and closable indoor side window including an inner horizontal frame pair and an inner vertical frame pair surrounding the glass member; And an outer frame forming an outdoor side window,

And an inner horizontal frame at a lower end of the inner horizontal frame includes at least one U-shaped support for supporting a load of the glass member,

The supporting portion includes: an elastic member surrounding the lower end of the glass member; And silicone interposed between the elastic member and the glass member, wherein the silicon particles are dispersed in the ceramic particles.

The ceramic particles may be at least one of AlN, SiC, and BN.

Further, the glass member may be a multi-layered plate glass pair; A first seismic strengthening member provided to surround the lower end of the plate glass and having a tensile strength strengthened in an upward oblique direction from a vertex portion of the lower end of the plate glass; A second seismic reinforcing member joined to a first seismic strengthening member provided outside the pair of plate glasses and having a tensile strength strengthened in a longitudinal direction of the lower end of the plate glass; A spacer provided between the pair of plate glasses and provided between the first seismic strengthening members to maintain a gap between the pair of plate glasses; And a sealant disposed between the lower portion of the spacer and the pair of plate glasses.

The width of the first aramid yarn of the weft yarn and the warp yarn forming the plain weave structure is 1.2 to 1.5 times larger than the width of the other one of the second aramid yarns, Wherein the second seismic reinforcing member is an aramid fiber, and the third aramid yarn of any of the weft yarn and the warp yarn is made of a third aramid yarn and the third aramid yarn, wherein the third aramid yarn is reinforced with a tensile strength in the longitudinal direction of the second aramid yarn, And a third 3-2 aramid yarn which is 1.5 to 1.8 times larger than the thickness of the yarn, wherein the 3-1 aramid yarn and the 3-2 aramid yarn are alternately weaved in a plain weave structure, It can be formed in a shape in which irregularities are repeated.

And a third seismic reinforcement member provided to surround the side surface of the plate glass and having a tensile strength strengthened in a direction perpendicular to the longitudinal direction of the plate glass, wherein the third seismic reinforcement member is an aramid fiber, One third third aramid yarn comprises a third-2 aramid yarn formed to a size of 1.5 to 1.8 times larger than the thickness of the third-third aramid yarn and the third-1 aramid yarn, The aramid yarn and the 3-2 aramid yarn may be alternately formed into a shape that is woven in a plain weave structure and is repeated in the horizontal direction.

And the inner side vertical frame includes a first elastic supporting portion and a second elastic supporting portion for pressing and supporting both sides of the inserted side of the plate glass, And the second elastic supporter may protrude in a horizontal direction and protrude in mutually opposite directions to form protrusions for pressing both sides of the side surface of the plate glass.

The protruding portion may be provided so as to be in contact with the third seismic strengthening member.

The window system according to the present invention can minimize the occurrence of gaps or gaps formed between the window frame and the window frame directly contacting the glass member, thereby improving seismic performance.

1 is an exploded perspective view showing a part of a window system according to an embodiment.
2 is a plan view showing a part of a window system according to an embodiment.
3 and 4 are a schematic perspective view and a side view for explaining a bottom view of a door frame according to an embodiment.
Fig. 5 is an enlarged view of a part of Fig. 4 enlarged.
6 is a schematic view for explaining a first seismic strengthening member according to an embodiment.
7 is a schematic view for explaining a second seismic strengthening member according to an embodiment.
8 is a schematic enlarged view for explaining a first seismic reinforcement member and a second seismic reinforcement member according to an embodiment.
9 is a schematic plan view for explaining a side view of a door frame according to an embodiment.
10 is a schematic view for explaining a second seismic strengthening member according to an embodiment.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In the absence of special definitions or references, the terms used in this description are based on the conditions indicated in the drawings. The same reference numerals denote the same members throughout the embodiments. For the sake of convenience, the thicknesses and dimensions of the structures shown in the drawings may be exaggerated, and they do not mean that the dimensions and the proportions of the structures should be actually set.

An earthquake-resistant window system according to an embodiment of the present invention will be described with reference to FIGS. 1 to 3. FIG. FIG. 1 is a perspective view showing a part of a window system according to an embodiment of the present invention, FIG. 2 is a plan view showing a part of a window system according to an embodiment, FIG. 3 is a perspective view of a door frame according to an embodiment Fig.

The window system according to an embodiment of the present invention includes various frames. And a door frame 300 for fixing the interior side window 220 as a frame for fixing the windows.

An inner horizontal frame 130 is provided on the upper and lower sides of the door frame 300 and an inner vertical frame 160 is provided on the left and right sides of the door frame 300. The inner horizontal frame 130 and the inner vertical frame 160 form one frame and are paired with the door frame 300 to be hinged and supported such that the door frame 300 is opened or closed .

Outer frames are provided on the upper and lower sides of the outdoor side window. The outer frame includes an outer horizontal frame 110 and an outer vertical frame 170. The outer horizontal frame 110 and the outer vertical frame 170 function as a frame for supporting and protecting the load of the outer window (glass member 210).

The inner vertical frame 160 has a hinge structure or a locking structure to support the inner window so that the inner window can be opened and closed as shown in FIG. The components associated with the hinge and locking structure are capable of various known configurations and need not be limited to any particular configuration.

The inner vertical frame 160 and the outer vertical frame 170 in this embodiment include a connecting member 180 for reinforcing the connecting structure. The connecting member 180 can use an H-shaped frame.

Meanwhile, an intermediate frame 120 may be provided between the inner frame 130 and the outer frame 110 located at the bottom of the single window. The intermediate frame 120 may be fixed to the connecting member 180 or the like. Further, the intermediate frame 120 may form a space separated from the inner frame 130 or the outer frame 110. The gap formed between the intermediate frame 120 and the inner frame 130 and / or the outer frame 110 functions as an air inlet through which air flows, and a blind or the like may be provided.

Referring to FIG. 3, the glass members 220 are provided so as to overlap one or more. The glass members 220 according to the present embodiment are arranged in a pair and are assembled in a state where they are maintained at a constant interval by a pair of glass members 220 by means of the bases 3301 and 3353, 3353 may be sealed by using a separate sealing material.

Also, a support part 330 may be provided at the lower end and / or the upper end of the glass member 220 made of one block as shown in FIG. It is preferable that the glass member 220 and the support portion 330 are manufactured as one block for ease of assembly at the time of construction.

The support portion 330 is a component for fixing the glass member 220 block to the door main frame 310 as described above. The support portion 330 is fixed to the door frame 310 together with the glass member 220 using a fastening member such as a bolt or a rivet.

For example, the support portion 330 may be made of stainless steel, aluminum, or the like. Further, the support part 330 may be provided at a quarter of the lateral length from both sides of the upper and / or lower ends to support the glass member 220 block.

The support portion 330 includes a fastening surface 332 and a support surface 331. The engagement surface 332 and the support surface 331 are provided in a state of being bent in an L shape. The fastening surface 332 is fastened to the side of the bottom 310 of the door main frames 310, 311. The fastening surface 332 may be secured to the door main frame 310 in a variety of ways such as piece, bolt, weld, and the like.

A glass member 220 may be provided on the support surface 331 and an elastic member 333 may be provided between the support surface 331 and the glass member 220. The elastic member 333 prevents damage due to friction between the support surface 331 and the glass member 220 due to an external impact and improves the airtightness between the support surface 331 and the glass member 220 do.

A first sealing member 339 provided along the longitudinal direction of the door main frame 310 and sealing the side surface of the door main frame 310 and the glass member 220 is provided at the upper portion of the engagement surface 332 .

Also, as described above, the inner horizontal frame 130 includes the latching portion 1303. The engagement portion 1303 prevents the door frame 300, which rotates adjacent to the upper portion, from turning to the outer frame side, i.e., to the outdoor side. The hook 1303 is provided with a first elastic member 1305 for increasing airtightness between the supporting surface 331 of the door frame 300 and the lower end of the glass member 220 supported by the supporting surface 331, May be provided.

3 to 5, a bottom view of the door frame according to an embodiment will be described. FIGS. 3 and 4 are a schematic perspective view and a side view for explaining a bottom view of the door frame according to an embodiment, and FIG. 5 is an enlarged view of a part of FIG.

As described above, the earthquake-resistant window system according to the present embodiment includes a glass member 220 and an inner horizontal frame pair 300 surrounding the glass member.

The inner horizontal frame at the lower end of the inner horizontal frame 300 includes at least one U-shaped support portion 330 having a support surface 331 for supporting the load of the glass member 220. An elastic member 333 surrounding the lower end of the glass member 220 is provided between the support part 330 and the glass member 220. Silicon 243 is injected between the elastic member 333 and the glass member 220.

The glass member 220 is formed of a pair of plate glasses having a plurality of layers. A first vibration proof reinforcement member 230 is disposed at the lower end of the plate glass and a second vibration proof reinforcement member 235 is attached to the outer surface of the plate glass pair. The first and second seismic retrofitting members 230 and 235 may be aramid fabrics. In the case of the second seismic strengthening member 230, the aramid fabrics may be impregnated and then attached to the resin.

On the other hand, the silicon according to this embodiment uses a ceramic particle dispersed therein. In this case, the ceramic particles may be at least one of AlN, SiC, and BN, and spherical particles having a size of about 50 to 10 um may be used. By using the silicon in which the ceramic particles are dispersed as described above, it is possible to obtain an effect of improving vibration resistance at the time of generation of vibration and delaying physical separation of glass and silicon.

A spacer 241 and a sealant 242 are provided between the pair of plate glasses surrounded by the first seismic strengthening member 230. The spacers 241 serve to support the glass member structure while maintaining a gap between the pair of glass plates, and the sealant 242 functions to seal between the glass sheets. The spacer 241 and the first seismic strengthening member 230 may be made of polyisobutylene and the sealant 242 may be a polysulfide. Butyl has a low water vapor permeability and low gas permeability to maximize the adiabatic effect of the insulating layer inside the multi-layer insulating glass and to prevent condensation due to penetration of moisture. Thiokol has a high oil resistance and can protect weak butyl from oil, thus minimizing the defective rate which may occur in the insulating double layer glass.

The first seismic reinforcement member and the second seismic reinforcement member will be described with reference to Figs. 6 to 9. Fig. FIG. 6 is a schematic view for explaining a first seismic strengthening member according to an embodiment, FIG. 7 is a schematic view for explaining a second seismic reinforcement member according to an embodiment, and FIG. 8 is a cross- Fig. 8 is a schematic enlarged view for explaining an earthquake-proof reinforcement member and a second earthquake-reinforcement member.

The first seismic strengthening member 230 is preferably made of aramid fiber. The width of the first aramid yarn of the weft yarn and the warp yarn forming the plain weave structure is formed to be 1.2 to 1.5 times larger than the width of the other one of the second aramid yarns, The tensile strength can be strengthened in the longitudinal direction of the yarn. 6, the first aramid yarn 231 and the second aramid yarn 232 may be woven using the first aramid yarn 231 and the second aramid yarn 231. The width of the first aramid yarn 231 may be greater than the width of the second aramid yarn 232, So that the tensile strength is reinforced in the direction D1 of the first aramid yarn 231. In this case, the tensile strength is strengthened in a constant direction (D1) even when the same thickness is used as compared with the case of using the same yarn.

The second earthquake-reinforcement member 235 may be manufactured in the same manner as the first earthquake-reinforcement member 230 as described above. In addition, the second earthquake-reinforcement member 235 may be formed in a shape in which the concave- have. Specifically, the second seismic reinforcing member 235 is preferably made of aramid fiber, and the third aramid yarn of any of the weft yarn and the warp yarn is preferably made of aramid yarn of the 3-1 aramid yarn and the 3-1 aramid yarn Wherein the third 3-1 aramid yarn and the third 3-2 aramid yarn may be alternately weaved in a plain weave structure. That is, the second seismic strengthening member 235 is formed in a plain structure or a structure in which the tensile strength is reinforced in a predetermined direction, and the thickness of the third aramid yarns reinforcing the tensile strength can be formed differently as shown in FIG. have. The concave portion P1 and the convex portion P2 can be alternately formed by alternately arranging and weaving the 3-1 aramid yarn 231a and the relatively thick third 3-2 aramid yarn 231b . In this case, irregularities are formed in a direction perpendicular to the direction of increasing the tensile strength.

8, the first seismic strengthening member 230 is provided so as to surround the lower end of the plate glass 220, and the tensile strength is strengthened D1 from the vertex portion of the lower end of the plate glass 220 in the upward oblique direction . In this case, a direction in which the tensile strength is strengthened symmetrically with respect to the center of the plate glass is formed.

The second tensile strength reinforcing portion 235 is bonded to the first seismic strengthening member 230 on the outer surface of the pair of plate glasses. The second tensile strength reinforcing portion 235 allows the tensile strength to be strengthened D1 in the longitudinal direction of the lower end of the plate glass 220. At this time, as described above, the second seismic strengthening member 235 is formed so that the irregularities are repeated in a direction perpendicular to the direction of reinforcing the tensile strength, and consequently the irregularities are repeated in the vertical direction.

A side view of the door frame will be described with reference to Figs. 9 and 10. Fig. FIG. 9 is a schematic plan view for explaining a side view of a door frame according to an embodiment, and FIG. 10 is a schematic view for explaining a second to a reinforcing member according to an embodiment.

The side portion of the plate glass 220 is inserted into the inner vertical frame 170. The inner vertical frame 170 includes a first elastic support portion 171 and a second elastic support portion 172 for pressing and supporting both sides of the side portion of the inserted plate glass 220. The first elastic supporting portion 171 and the second elastic supporting portion 172 are formed with protrusions 1711 and 1721, respectively. The protrusions 1711 and 1721 protrude in the horizontal direction and protrude in opposite directions to press the plate glass 220, particularly the third seismic strengthening member 236.

The third seismic strengthening member 236 is preferably formed of aramid fiber and has the same structure as the second seismic reinforcement member described above. However, it is formed so as to surround the side surface of the plate glass 220 and has a length in the vertical direction, and is formed so as to reinforce the tensile strength in the vertical direction. As a result, the third seismic strengthening member 236 can be formed in a shape in which the concave and convex portions are repeated in the horizontal direction.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. have.

230: first earthquake-proof reinforcement member
235: second earthquake-proof reinforcement member
241: Spacer
242: Sealant
243: Silicone

Claims (7)

A glass member, a door frame forming an openable and closable indoor side window including an inner horizontal frame pair and an inner vertical frame pair surrounding the glass member;
And an outer frame forming an outdoor side window,
And an inner horizontal frame at a lower end of the inner horizontal frame includes at least one U-shaped support for supporting a load of the glass member,
The support portion
An elastic member surrounding the lower end of the glass member;
And silicone interposed between the elastic member and the glass member,
The silicon has ceramic particles dispersed therein,
Wherein the ceramic particles are at least one of AlN, SiC, and BN,
Wherein the glass member comprises:
A double-layered plate glass pair;
A first seismic strengthening member provided to surround the lower end of the plate glass and having a tensile strength strengthened in an upward oblique direction from a vertex portion of the lower end of the plate glass;
A second seismic reinforcing member joined to a first seismic strengthening member provided outside the pair of plate glasses and having a tensile strength strengthened in a longitudinal direction of the lower end of the plate glass;
A spacer provided between the pair of plate glasses and provided between the first seismic strengthening members to maintain a gap between the pair of plate glasses; And
And a sealant disposed between the lower portion of the spacer and the pair of plate glasses,
Wherein the first seismic reinforcing member is an aramid fiber and the first aramid yarn width of any one of the weft yarns and the warp yarns forming the plain weave structure is formed to be 1.2 to 1.5 times larger than the width of the other second aramid yarn, 2 reinforces the tensile strength in the longitudinal direction of the aramid yarn,
Wherein the third seam reinforcement member is an aramid fiber and the third aramid yarn of any one of the weft yarn and the warp yarn is 1.5 to 1.8 times larger than the thickness of the 3-1 aramid yarn and the 3-1 aramid yarn. 3-2 aramid yarn, wherein the 3-1 aramid yarn and the 3-2 aramid yarn are alternately weaved in a plain weave structure and are formed in a shape in which irregularities are repeated in a vertical direction,
And a third seismic strengthening member provided to surround the side surface of the glass member and having a tensile strength strengthened in a side direction of the glass member in the vertical direction,
Wherein the third seismic reinforcing member is an aramid fiber and the third third aramid yarn of any of the weft yarns and the warp yarns is formed to be 1.5 to 1.8 times larger than the thickness of the 3-1 aramid yarn and the 3-1 aramid yarn Wherein the yarns of the 3-1 aramid yarn and the yarns of the 3-2 aramid yarn are alternately formed into a shape that is woven in a plain weave structure and is repeated in the horizontal direction,
A side portion of the glass member is inserted into the inner vertical frame,
Wherein the inner vertical frame includes a first elastic support portion and a second elastic support portion for pressing and supporting both sides of a side surface portion of the inserted glass member,
The first elastic support portion and the second elastic support portion each have a protrusion protruding in a horizontal direction and protruding in opposite directions to press both sides of the side surface of the glass member,
And the protruding portion is provided to be in contact with the third seismic strengthening member . delete delete delete delete delete delete

Images