KR20190081319A - Earthquake-proof fittings system, and block supporter for earthquake-proof fittings, and earthquake-proof bracket unit for earthquake-proof fittings - Google Patents

Abstract

The present invention relates to an earthquake-resistant window system, a blocking support member for an earthquake-resistant window, and an earthquake-resistant bracket unit for an earthquake-resistant window, wherein an earthquake-resistant design is applied to an earthquake-resistant window system to prevent an external force from being directly delivered to a blocking member blocking an opening portion of a building even when the same is directly delivered to the earthquake-resistant window system, to prevent the blocking member from colliding with a blocking frame unit surrounding and supporting the blocking member, and to prevent the blocking member and the blocking frame unit from being damaged. To this end, the earthquake-resistant window system of the present invention is an earthquake-resistant window system which opens or closes an opening portion of a building, comprising: a blocking member to block the opening portion of the building; a blocking frame unit coupled to the opening portion of the building and including a plurality of blocking frames surrounding and supporting the blocking member; and a blocking support member provided at the blocking frame unit such that the blocking member may be supported, and elastically supporting the blocking member with respect to the blocking frame unit.

Description

TECHNICAL FIELD [0001] The present invention relates to an earthquake-resistant window system, an earthquake-resistant window block earthquake-resistant bracket unit, and an earthquake-resistant window earthquake-resistant window bracket unit,

The present invention relates to an earthquake-resistant window system, an earthquake-resistant window shielding support member, and an earthquake-resistant window earthquake-resistant bracket unit. More specifically, the present invention relates to an earthquake- It is possible to prevent the blocking member from being directly transmitted to the blocking member for blocking the opening of the building and to prevent the blocking member from hitting the blocking frame unit surrounding the blocking member and to prevent breakage of the blocking frame unit, System, an earthquake-resistant window shielding support member, and an earthquake-resistant window earthquake-proof bracket unit.

Generally, a window (window) means a window, a door, a glass, or the like, which is installed in an opening of a window or an entrance to block an interior space of the building from the outside. In a building, a window is indispensable for circulation of light or indoor air, and is installed in an opening provided at a predetermined position of a wall when a building is constructed.

The type, size, installation position and number of windows are appropriately designed considering the load applied to the building including air conditioning, room insulation, mining and so on. On the other hand, the window is composed of a glass for mining and a chassis for supporting the rim of the glass.

Normally, the window is installed at the opening of the building, so the window itself does not have a vertical load that the window can not afford. The vertical load of the building is mainly responsible for pillars and bearing walls, and the window plays a role of connecting indoor and outdoor.

However, since a conventional window is not provided with a separate earthquake-proof system, when an external force such as external impact, vibration (vibration), or earthquake is transmitted to a conventional window, for example, Or the chassis is damaged. In addition, in a chassis including an aluminum material or a steel material, there is a problem that airtightness with the glass is poor so that it is difficult to prevent heat insulation and leakage.

In addition, the chassis supporting the rim of the glass has a limitation in absorbing the horizontal load and the interlaminar load of the building due to the external force.

In addition, earthquake-resistant design is applied to new buildings to reinforce the structure throughout the building. However, this method is complicated in construction and costs a lot, and seismic performance of window itself is limited. Therefore, There is a limit to prevent.

In recent years, due to frequent earthquakes, the necessity of earthquake-resistant design of windows itself has become urgent.

Korean Registered Patent No. 10-1793601 (Title of invention: Structure of seismic resistant window and its construction method, Announcement of Nov. 2017)

SUMMARY OF THE INVENTION An object of the present invention is to solve the conventional problems by applying seismic design to an earthquake-resistant window system itself, thereby preventing direct transmission of an external force to a shielding member blocking an opening of a building even if the external force is directly transmitted to the earthquake- An earthquake-resistant window system for preventing a blocking member from bumping against a floor frame unit that surrounds the blocking member and for preventing breakage of the blocking frame unit as well as the blocking member, an intercepting member for an earthquake-resistant window, Unit. ≪ / RTI >

According to a preferred embodiment of the present invention, an anti-quake window system according to the present invention is an anti-quake window system for opening or closing an opening of a building, and a blocking member for blocking the opening; A shielding frame unit coupled to the opening and including a plurality of shielding frames surrounding the shielding member; And a blocking member provided on the blocking frame unit to support the blocking member to elastically support the blocking member with respect to the blocking frame unit.

Here, the shielding frame may include a shielding body portion through which the shielding hole is formed, and the shielding member is seated on one side thereof; A first blocking blade extending from one side of the one side of the blocking body; A first blocking jaw provided at the other side of one side of the blocking body and a second blocking jaw part spaced from the first blocking jaw toward the blocking member from the other side of one side of the blocking body, part; And a second blocking wing portion engaged with the blocking wing portion so as to be removably attached to the blocking body portion.

The shielding frame may include a third shielding blade extending from one side of the other side of the shielding body corresponding to the first shielding blade, And a fourth blocking blade portion extending from the other side of the other side of the blocking body portion corresponding to the second blocking blade portion; As shown in FIG.

According to another aspect of the present invention, there is provided an anti-earthquake-resistant window system comprising: a blocking bracket unit that couples two mutually adjacent blocking frames among the blocking frame units, wherein the blocking bracket unit, when a predetermined external force is transmitted, It is possible to slide in the blocking frame.

The earthquake-resistant window system according to the present invention further includes: a member grasping unit coupled to the shielding frame unit and grasping an edge of the shielding member.

The earthquake-resistant window system according to the present invention is characterized in that the member holding unit includes: a holding body coupled to the shielding frame via a holding fixture, the holding body having a turning bracket toward the shielding member; A pivotal link portion linked to the pivot bracket via a first shaft portion; And a gripping fork portion linked to the rotation link portion via a second shaft portion and having a fork member for gripping the blocking member, wherein one of the rotation link portion and the gripping fork portion is provided with the second And a shaft guide portion to which the shaft portion is slidably moved.

The earthquake-resistant window system according to the present invention further includes a fixed frame unit having a plurality of fixed frame frames to which the shielding frame unit is rotatably coupled or the slide frame unit is slidably engaged, while being coupled to the openings .

The earthquake-resistant window system according to the present invention further includes a fixed bracket unit for mutually coupling two fixed frame frames of the fixed frame unit, wherein the fixed bracket unit, when a predetermined external force or more is transmitted, It is possible to slide in the blocking frame.

An earthquake-resistant window screening support member according to the present invention is an earthquake-resistant window screening support member for resiliently supporting the shielding member with respect to a shielding frame unit for enclosing a shielding member for shielding an opening of a building in an earthquake- Wherein the elastic member is formed through the elastic member, the elastic member being elastically supported on one side of the elastic member; An elastic wing portion extending from one side of the one side of the receiving body so as to be elastically supported by the side surface of the blocking member with respect to the blocking frame unit or extending from both sides of one side of the receiving body; And a cushioning uneven portion extending from the other side of the receiving body portion and elastically supporting the receiving frame body while separating the receiving body portion from the blocking frame.

Here, the supporting body part is provided with a dispersion inclined part inclined from the other side toward the other side.

Here, the blocking frame includes a first supporting portion, and the blocking supporting member is provided with a second supporting portion that is engaged with the first supporting portion.

An earthquake-proof bracket unit for an earthquake-resistant window according to the present invention is an earthquake-resistant bracket unit for an earthquake-resistant window which encloses a shielding member for shielding an opening of a building in an earthquake-resistant window system or connects mutually adjacent two frames among frame units coupled to the opening The earthquake-resistant bracket unit comprises: a connecting member coupled to one of the two frames via a connecting member fixing means; A sliding member coupled to the connecting member; And a rupture housing fixed to the other one of the two frames through the housing fixing means and fixed to the connecting member via the member coupling means in a state where the sliding member is fitted.

At this time, the break housing is provided with a breaker for releasing the coupling between the break housing and the connection member so that the sliding member can be slidably moved in the break housing when a predetermined external force or more is transmitted.

An earthquake-proof bracket unit for an earthquake-resistant window according to the present invention is an earthquake-resistant bracket unit for an earthquake-resistant window which encloses a shielding member for shielding an opening of a building in an earthquake-resistant window system or connects mutually adjacent two frames among frame units coupled to the opening , Said earthquake-resistant bracket unit comprising: a connecting member; A sliding member including a first sliding member coupled to the connecting member and a second sliding member coupled to the connecting member in a state spaced apart from the first sliding member; A first rupturing housing fixed to one of two frames through a housing fixing means and fixed to the connecting member via a member coupling means in a state in which the first sliding member is fitted to the housing, And a second rupturing housing fixed to the other one of the two frames through the intermediate member and fixed to the connecting member via the member coupling means in a state where the second sliding member is fitted to the frame.

At this time, the break housing is provided with a breaker for releasing the coupling between the break housing and the connection member so that the slide housing can slide in the break housing when a predetermined external force or more is transmitted.

In the seismic resistant bracket unit for an earthquake-resistant window according to the present invention, the earthquake-resistant bracket unit is embedded in the rupture housing in an elastically compressed state, and the rupture part is broken, whereby the elastic compression state is released, And an elastic member elastically supporting at least one of the sliding members.

Here, the sliding member is linked to the connecting member via a hinge portion.

The earthquake-proof bracket unit for an earthquake-resistant window according to the present invention may further include a frame-tightening unit provided on the connecting member and having a frame insertion slot into which an end of the frame is fitted.

Here, the frame may include a first guide portion, and the breakage housing may include a second guide portion fitted into the first guide portion.

According to the seismic resistant window system of the present invention, the seismic isolation barrier for earthquake resistant windows, and the seismic resistant bracket unit for seismic resistant windows, the earthquake resistant design is applied to the seismic resistant window system itself. Even if the external force is directly transmitted to the seismic resistant window system, It is possible to prevent the blocking member from being directly transmitted to the blocking member to be blocked and to prevent the blocking member from bumping against the blocking frame unit that surrounds the blocking member and to prevent breakage of the blocking member as well as the blocking member.

Further, the present invention can improve the heat insulating performance and the leakage preventing performance between the shielding frame unit and the shielding member through the construction of the barrier support member.

In addition, the present invention can stably support the edge of the blocking member through the detailed configuration of the blocking frame, and can smoothly replace the blocking member.

In addition, the present invention can smoothly slide the blocking frame unit in the case of a sliding window system through the detailed constituent part of the blocking frame, and can make a close contact between the blocking frame unit and the fixed frame unit In the case of a fixed type window or a curtain wall type window, the blocking frame unit can be stably fixed to the opening of the building.

In addition, according to the present invention, the blocking bracket unit can secure the connection between the blocking member and the blocking frame unit and the connection between the blocking frames through the additional structure of the blocking bracket unit, The blocking bracket unit performs a buffering action to prevent deformation or breakage of the blocking frame as well as the blocking member.

Further, the present invention can prevent the blocking member from being separated from the separated blocking frame unit through the additional structure of the member holding unit, and to prevent breakage of the blocking member.

Further, according to the present invention, the degree of freedom of the blocking member is secured through the detailed configuration of the member holding unit, the shock applied to the blocking member is absorbed by absorbing and discharging the vertical load as well as the horizontal load of the predetermined external force, So that the member is stably supported.

Further, according to the present invention, an earthquake-resistant window system can be applied to a sliding window system or a hinged window system through the additional structure of the fixed frame unit, and the earthquake-proof function of the window itself can be given in various window systems.

In addition, according to the present invention, the fixing bracket unit is firmly engaged with the fixed frame frames, and when the external force acts, the fixed bracket unit is slid in the fixed frame unit, It is possible to prevent deformation or breakage of the blocking frame unit and the fixed frame unit as well as the members.

Further, the present invention can prevent external force from being directly transmitted to the blocking member through the blocking support member, and to prevent breakage of the blocking member.

Further, according to the present invention, the elastic deformation of the receiving body portion can be smoothly performed through the elastic hole portion or the dispersion inclined portion, and the elastic support of the blocking member can be stabilized.

Further, according to the present invention, the supporting body portion can be spaced apart from the shielding frame through the cushioning irregular portion, and external force can be prevented from being directly transmitted to the supporting body portion.

Also, the present invention can prevent the flow of the blocking support member from the blocking frame through the fitting between the first supporting portion and the second supporting portion, and stabilize the elastic support of the blocking member.

In addition, the present invention improves the seismic performance of the blocking bracket unit and the fixed bracket unit through the anti-earthquake-resistant window seismic bracket unit, and exhibits the seismic performance in the window frame to prevent breakage of the blocking member. It is possible to prevent breakage.

In addition, according to the present invention, the connecting member or the rupturing housing can stably fix each frame, and the sliding movement of the sliding member can be smoothly performed in the rupture housing, thereby stably absorbing the external force.

Further, according to the present invention, movement of each frame is made to correspond to horizontal load and vertical load of an external force through link coupling between the connecting member and the sliding member, and deformation or breakage of each frame can be prevented.

Further, according to the present invention, it is possible to prevent the movement of the outside air or foreign matter at the connection portion of each frame through the structure of the frame adhered portion, and to prevent leakage.

Further, according to the present invention, it is possible to simplify the engagement of the rupture housing in each frame through the fitting of the first guide portion and the second guide portion, and to prevent the rupture housing from flowing in each frame.

Further, since the frame and the blocking member are prevented from being deformed or broken, the earthquake-resistant window system can be reassembled and replaced only by replacing the breakage housing or replacing the earthquake-resistant bracket unit, and the maintenance cost can be minimized have.

1 is a view showing an anti-earthquake window system according to an embodiment of the present invention.
2 is a view showing a blocking member in an anti-quake window system according to an embodiment of the present invention.
3 is a cross-sectional view illustrating a blocking frame unit and a fixed frame unit in an anti-seismic window system according to an embodiment of the present invention.
4 is a sectional view showing an installation state of an intercepting member based on the portion "A" in Fig. 1 in an anti-quake window system according to an embodiment of the present invention.
5 is a cross-sectional view showing an example of a blocking bracket unit with reference to a portion "B" in Fig. 1 in a system for an anti-seismic window system according to an embodiment of the present invention.
6 is a cross-sectional view illustrating a state in which a blocking bracket unit and a shielding frame unit are engaged in an earthquake-resistant window system according to an embodiment of the present invention.
FIG. 7 is an enlarged view of the rupture portion shown in FIG. 5 in an anti-earthquake window system according to an embodiment of the present invention.
FIG. 8 is a sectional view showing an operation state of the blocking bracket unit shown in FIG. 5 in an anti-seismic window system according to an embodiment of the present invention.
FIG. 9 is a sectional view showing a modification of the blocking bracket unit shown in FIG. 5 in a system for an anti-seismic window system according to an embodiment of the present invention.
10 is a cross-sectional view showing another example of a blocking bracket unit in a system for an anti-seismic window according to an embodiment of the present invention.
11 is a view showing an installation state of the member gripping unit in the system for an anti-se earth window according to an embodiment of the present invention.

Hereinafter, an earthquake-resistant window system according to the present invention, an earthquake-resistant window screening support member, and an earthquake-resistant window earthquake-proof bracket unit will be described with reference to the accompanying drawings. Here, the present invention is not limited or limited by the examples. Further, in describing the present invention, a detailed description of well-known functions or constructions may be omitted for clarity of the present invention.

Hereinafter, an earthquake-resistant window system according to an embodiment of the present invention will be described with reference to FIGS. 1 to 11. FIG. Here, the breakable support member for an anti-seismic window according to an embodiment of the present invention will be described as the breakable support member 40 of the anti-quake window system according to an embodiment of the present invention. In addition, the earthquake-proof bracket unit for an earthquake-resistant window according to an embodiment of the present invention is described as including at least one of a shielding bracket unit 30 and a fixed bracket unit of an earthquake-resistant window system according to an embodiment of the present invention .

An earthquake-resistant window system according to an embodiment of the present invention opens or closes an opening of a building. According to an embodiment of the present invention, the anti-seismic window system is applied to a sliding window system, and the opening of the building can be opened and closed in a sliding manner. When the earthquake-resistant window system according to an embodiment of the present invention is applied to a sliding window system, the fixed frame unit 50 is coupled to the opening of the building, and the interrupting frame unit 20 is slidably mounted on the fixed frame unit 50 The opening of the building can be opened and closed.

The earthquake-resistant window system according to an embodiment of the present invention is not limited to the sliding window system, but can be applied to various windows such as a hinged window system, a fixed system window system, a curtain wall system window system, and the like.

For example, the earthquake-resistant window system according to an embodiment of the present invention is applied to a window-type window, and the opening of the building can be opened and closed by a hinged door system. When the earthquake-resistant window system according to an embodiment of the present invention is applied to a window of a hinged type, a fixed frame unit 50 is coupled to an opening of a building, and the blocking frame unit 20 is connected to a door The opening of the building can be opened and closed by being rotatably coupled to the fixed frame unit 50. [

As another example, the earthquake-resistant window system according to an embodiment of the present invention is applied to a fixed-type window, and the opening of the building can be closed in a fixed manner. When the earthquake-resistant window system according to an embodiment of the present invention is applied to a fixed type of window, the blocking frame unit 20 is fixed directly to the opening of the building, so that the opening of the building can be closed.

As another example, the earthquake-resistant window system according to an embodiment of the present invention is applied to a curtain wall type window, and the opening of the building can be closed by a curtain wall method. When the earthquake-resistant window system according to an embodiment of the present invention is applied to a curtain wall type window, the blocking frame unit 20 is fixed directly to the opening of the building or fixed to the building through a separate space member (not shown) The opening of the building can be closed.

The earthquake-resistant window system according to the embodiment of the present invention includes a blocking member 10, a shielding frame unit 20 and a barrier support member 40 and further includes a fixed frame unit 50, Unit, and may further include an absence gripping unit (70).

The blocking member 10 is for blocking the opening of the building.

The blocking member 10 is transparent or translucent or opaque. The blocking member 10 may be made of various known materials such as a glass material or a plastic material.

The blocking member 10 generally exhibits a rectangular shape, but is not limited thereto, and may exhibit various polygonal shapes.

The edge of the blocking member 10 is rounded so that no scratches appear. The edge of the shielding member 10 is provided with a crack growth preventing portion 11 for rounding the edge of the shielding member 10 by rounding or forming an angle between the corners of the shielding member at an obtuse angle through chamfering, It is possible to prevent cracks from growing on the blocking member 10 starting from scratches and to prevent breakage of the blocking member 10 when an impact is applied to the blocking member 10. [

The blocking frame unit 20 is directly or indirectly coupled to the opening of the building. In one embodiment of the present invention, the shielding frame unit 20 is slidably coupled to the fixed frame unit 50. The shielding frame unit 20 may include a plurality of shielding frames for covering the shielding member 10. [ The plurality of blocking frames include a first blocking frame 20-1 surrounding the lower end of the blocking member 10 and a second blocking frame 20-2 surrounding the upper end of the blocking member 10 on the basis that the opening of the building is rectangular, 2 and a third shielding frame 20-3 which surrounds both ends of the shielding member 10, respectively.

This blocking frame includes the blocking body portion 21, the first blocking blade portion 22, the blocking blade locking portion 23 and the second blocking blade portion 24, and the third blocking blade portion 25 And a fourth blocking blade 26. The fourth blocking blade 26 may be formed of a metal or a metal.

A blocking hole 211 is formed in the cut-off body portion 21. The blocking bracket unit (30) is fitted to the blocking hole portion (211). A cut-off support member (40) is seated on one side of the cut-off body portion (21). The blocking guide portion 212 may be protruded or depressed in the blocking hole 211. For example, the blocking guide portion 212 may protrude from the blocking hole 211 along the longitudinal direction of the blocking hole 211. As another example, the blocking guide portion 212 may be recessed in the blocking hole 211 along the longitudinal direction of the blocking hole 211. The blocking guide portion 212 can guide the fitting of the blocking bracket unit 30.

The first support portion 203 may be formed on the cut-off body portion 21 to protrude or sink. The first support portion 203 can be engaged with the seizing support member 40 to prevent the blocking support member 40 from flowing in the shielding frame.

The blocking body 21 may be provided with a blocking reinforcing rib 214. The blocking reinforcement ribs 214 protrude from the blocking body portion 21 to prevent deformation of the blocking body portion 21 and to maintain the shape of the blocking hole portion 211.

The first blocking blade portion 22 extends from one side of the shut-off body portion 21. At the end of the first blocking blade 22, a blocking support 221 may protrude toward the blocking member 10. The first support portion 203 may be provided on the blocking support portion 221 to be engaged with the second support portion 403 provided on the elastic wing portion 42 described later.

The blocking wing engagement portion 23 allows the second blocking wing portion 24 to be engaged. The blocking wing engagement portion 23 has a first blocking engagement portion 231 provided on the other side of one side of the blocking body portion 21 and a second blocking blocking portion 231 formed on the other side of the blocking body portion 21 toward the blocking member 10 And a second blocking stopping part 232 spaced from the first blocking stopping part 231 may be included.

The second blocking blade portion 24 is engaged with the blocking blade coupling portion 23 so that the second blocking blade portion 24 can be detached and attached to the blocking body portion 21. The second blocking wing 24 includes a first extending portion 241 disposed to face the first blocking wing 22 and a second extending portion 243 extending from the first extending portion 241 can do. The first extending portion 241 is provided at one end thereof with a first engaging portion 242 engaging with the first interlocking tab 231. The other end of the first extending portion 241 is provided with a blocking support portion 221, The wing support portion 245 can be protruded toward the blocking member 10. [ The second extending portion 243 may have a second latching portion 244 which is engaged with the second blocking latching portion 232. Although not shown, the wing support portion 245 may be fitted with the second support portion 403 provided on the elastic wing portion 42, which will be described later, with the first support portion 203 described above.

The third blocking wing portion 25 extends from one side of the other side of the blocking body portion 21 corresponding to the first blocking wing portion 22. The fourth blocking wing portion 26 extends from the other side of the blocking body portion 21 in correspondence with the second blocking wing portion 24. A first blocking protrusion 251 protrudes from the end of the third blocking wing 25 and a first blocking protrusion 251 corresponding to the first blocking protrusion 251 is formed at the end of the fourth blocking wing 26. [ The second blocking protrusions 262 may be protruded to be spaced apart from each other. A third blocking protrusion 253 protrudes from the first blocking protrusion 251 toward the blocking body 21 and a second blocking protrusion 252 protrudes from the second blocking protrusion 262 against the third blocking protrusion 253, The fourth blocking protrusion 264 may be protruded toward the second blocking protrusion 21. The first blocking protrusions 251 to the fourth blocking protrusions 264 may be provided with a solenoid coupling portion 254 for coupling a support brush (not shown).

At least one of the third blocking blade 25 and the fourth blocking blade 26 may be provided with a blocking reinforcing rib 214. The blocking reinforcing ribs 214 protrude from at least one of the third blocking wing portion 25 and the fourth blocking wing portion 26 so that at least one of the third blocking wing portion 25 and the fourth blocking wing portion 26 It is possible to prevent any deformation and to maintain the shape of at least one of the third blocking wing portion 25 and the fourth blocking wing portion 26.

The blocking support member 40 is provided in the blocking frame unit 20 so that the blocking member 10 is supported. The blocking support member (40) elastically supports the blocking member (10) against the blocking frame unit (20). In the embodiment of the present invention, the blocking support member 40 is described as being provided in the first blocking frame 20-1 in which the vertical load of the blocking member 10 of the blocking frame unit 20 acts, The present invention is not limited to this, and it can be prevented that the blocking frame 10 and the blocking frame 10 are directly bumped by being provided in at least one of the second blocking frame 20-2 and the third blocking frame 20-3.

The blocking support member 40 may exhibit a "B" shape or a "C" shape (not shown). The barrier receiving member 40 may include a receiving body portion 41, an elastic wing portion 42, and a buffering concave portion 43.

A blocking member (10) is elastically supported on one side of the supporting body part (41). An elastic hollow portion 411 is formed through the supporting body portion 41. By forming the air hole in the elastic hole portion 411, elastic deformation of the receiving body portion 41 can be increased, and the elastic supporting force of the blocking member 10 can be improved.

The supporting body part 41 may be provided with a dispersion slope part 412 inclined from the other side toward the other side.

The elastic wing portion (42) allows the side surface of the blocking member (10) to be elastically supported with respect to the blocking frame unit (20). The elastic wings 42 may extend from one side of the one side of the receiving body 41 or may extend from one side of the other side of the receiving body 41, respectively. The second supporting portion 403 may be formed in the elastic wing portion 42 to be recessed or protruded. The second support portion 403 may be fitted to the first support portion 203 provided in the first blocking wing portion 22 or the second blocking wing portion 24.

The cushioning concave / convex portion 43 extends from the other side of the receiving body portion 41. At least one of the buffering concave and convex portions 43 may extend from the other side of the receiving body portion 41. The buffering concave-convex portion 43 separates the receiving body portion 41 from the blocking body portion 21 of the blocking frame. The buffering concave-convex portion 43 elastically supports the receiving body portion 41 with respect to the blocking body portion 21 of the blocking frame. The second support portion 403 may be formed in the buffering concave / convex portion 43 such that the second support portion 403 is recessed or protruded. The second support portion 403 may be fitted to the first support portion 203 of the cut-off body portion 21. The cushioning concave and convex portion 43 prevents the external force from being directly transmitted to the support body portion 41 by supporting the support body portion 41 away from the shielding frame and suppresses breakage of the shielding member 10 by dispersing external force Or can be prevented.

As a result, the first supporting portion 203 may be provided in the blocking frame, and the second supporting portion 403 may be provided in the blocking supporting member 40 to be engaged with the first supporting portion 203.

The fixed frame unit 50 is coupled to the opening of the building. To the fixed frame unit 50, the blocking frame unit 20 is rotatably engaged or the blocking frame unit 20 is slidably engaged.

The fixed frame unit 50 may include a plurality of fixed frame frames coupled to the openings of the building. The plurality of fixed frame frames include a first fixed frame frame 50-1 coupled to a lower end of an opening of a building based on a rectangular opening of the building, a second fixed frame frame 50-2 coupled to an upper end of the opening portion of the building, And a third fixed frame 50-3 coupled to both ends of the opening of the building.

The fixed frame may include a fixed body portion 51 and a first fixed wing portion 52 on the basis of rotation of the blocking frame unit 20. [ The fixed frame 51 includes a fixed body portion 51, a first fixed wing portion 52, a second fixed wing portion 53 and a rail portion 56 on the basis of slide movement of the blocking frame unit 20, . ≪ / RTI > The fixed frame further includes at least one of the third fixed wing portion 54 and the fourth fixed wing portion 55 and may further include an auxiliary wing portion 57.

The fixed body portion 51 has a fixing hole portion 511 formed therethrough. The stationary hole portion 511 is fitted with a stationary bracket unit. The fixed hole portion 511 may be formed with a fixed guide portion 512 protruding or depressed. For example, the fixed guide portion 512 may be formed to protrude from the fixed hole portion 511 along the longitudinal direction of the fixed hole portion 511. As another example, the fixed guide portion 512 may be recessed in the fixed hole portion 511 along the longitudinal direction of the fixed hole portion 511. The stationary guide portion 512 can guide the fitting of the stationary bracket unit.

The fixed body portion 51 may be provided with a fixed reinforcing rib 514. The fixed reinforcing rib 514 protrudes from the fixed body part 51 to prevent deformation of the fixed body part 51 and to maintain the shape of the fixed hole part 511. [

The first fixed wing portion (52) extends from one side of the fixed body portion (51).

The second fixed wing portion (53) extends from the other side of the one side of the fixed body portion (51).

The rail part 56 protrudes between the first fixed wing part 52 and the second fixed wing part 53 to form a slide movement path of the shielding frame unit 20. For example, the rails 56 provided on the first fixed frame 50-1 and the second fixed frame 50-2 of the fixed frame unit 50 are connected to the third blocking wing 25 of the blocking frame And can be inserted into the space between the fourth blocking wings 26. As another example, the rail portion 56 provided in the third fixed frame frame 50-3 of the fixed frame unit 50 is moved in the direction of sliding the third frame wing portion 25 of the blocking frame unit 20, The opening of the building can be opened or closed.

The third fixed wing portion (54) extends from one side of the other side of the fixed body portion (51) corresponding to the first fixed wing portion (52). The fourth fixed wing portion 55 extends from the other side of the fixed body portion 51 in correspondence with the second fixed wing portion 53. A first fixing protrusion 541 protrudes from an end of the third fixing wing 54 and a first fixing protrusion 541 corresponds to the first fixing protrusion 541 at an end of the fourth fixing wing 55. [ The second fixing protrusions 552 can be protruded to be spaced apart from each other. A third fixing protrusion 543 protrudes toward the fixed body 541 and a second fixed protrusion 542 faces the third fixing protrusion 543 to face the fixed body 51 The fourth fixing protrusion 554 can be protruded.

The auxiliary wing portion (57) protrudes from the fixed body portion (51). The auxiliary wing portion 57 can divide the slide space of the shielding frame unit 20 or suppress or prevent deformation of the fixed body portion 51. [

The earthquake-resistant bracket unit couples the mutually adjacent two frames among the frame units which surround the blocking member 10 or are coupled to the opening of the building. At this time, when an abnormal external force is transmitted, the earthquake-proof bracket unit is able to slide on the frame as a part of it is broken. Here, the frame unit can be divided into a blocking frame unit 20 and a fixed frame unit 50, and the frame can be divided into a blocking frame and a fixed frame.

The earthquake-resistant bracket unit comprises a shielding bracket unit 30 for mutually coupling two mutually adjacent shielding frame units of the shielding frame unit 20, and a fixed bracket unit for coupling two mutually adjoining fixed frame units of the fixed frame unit 50 And may include at least any one of them.

The blocking bracket unit (30) couples two mutually adjacent blocking frames among the blocking frame units (20). At this time, when a predetermined external force or more is transmitted, the blocking bracket unit 30 can slide in the blocking frame as a part of the blocking bracket unit 30 is broken.

Further, two adjacent fixed-frame frames of the fixed-frame unit 50 are coupled to each other. At this time, when a predetermined external force or more is transmitted, the fixed bracket unit is slidable in the fixed frame as a part thereof is broken.

In the embodiment of the present invention, the earthquake-resistant bracket unit will be described as the shielding bracket unit 30. [ Here, the fixing bracket unit has the same configuration as that of the blocking bracket unit 30, and a description thereof will be omitted.

For example, the blocking bracket unit 30 may have a breaking housing 33 only in one of two mutually adjacent blocking frames as shown in FIG.

The blocking bracket unit 30 according to an example may further include a connecting member 31, a sliding member 32 and a breaking housing 33 and may include an elastic member 34.

The connecting member 31 is coupled to one of the two blocking frames via the connecting member fixing means 310. The connecting member 31 may be coupled to the third shielding frame 20-3. A part or the whole of the connecting member 31 is inserted into the blocking hole portion 211 of the third blocking frame 20-3. The connecting member 31 may be provided with a first hook 311 for engaging the breaking housing 33.

Here, the connecting member fixing means 310 may include various types of bolts, including but not limited to, bolts, so as to fix the connecting member 31 to the third shielding frame.

The sliding member 32 is engaged with the connecting member 31. [ The sliding member 32 can be linked to the connecting member 31 via the hinge portion 312. [ Then, the sliding member 32 is rotatable about the hinge portion 312. Although not shown, the sliding member 32 may extend from the connecting member 31. [

The break housing (33) is fixed to the other one of the shield frames via the housing fixing means (35). The breaking housing 33 can be fixed to the first blocking frame 20-1 via the housing fixing means 35. [ The breaking housing 33 may be fixed to the first blocking frame 20-1 by the housing fixing means 35 in a state where the breaking housing 33 is inserted into the blocking hole 211 of the first blocking frame 20-1. Further, the breaking housing 33 is fixed to the connecting member 31 via the member coupling means in a state in which the sliding member 32 is fitted.

The breaker housing 33 may be provided with a second hook 331 for coupling with the connecting member 31. And the second hook portion 331 is hooked to the first hook portion 311. [ Then, the member coupling means may include a first hook portion 311 and a second hook portion 331.

The breaking housing 33 may be provided with a breaker 332 for releasing the connection with the connecting member 31. The breakage portion 332 allows the slide member 32 to slide in the break housing 33 by releasing the engagement between the breakage housing 33 and the connection member 31 when an abnormality or a predetermined external force is transmitted . 5 and 7, but the present invention is not limited to this, and the breaking housing 33 and the connecting member 31 may be formed through various known methods. Can be released.

As the sliding hole 333 is formed in the penetrating or recessed housing 33, the sliding member 32 can be slidably engaged.

The sliding hole 333 of the rupture housing 33 may be provided with an elastic supporter 334 for supporting the elastic member 34.

The breaking housing 33 may be provided with a support guide portion 335 corresponding to the blocking guide portion 212. The support guide portion 335 is fitted to the shielding guide portion 212 when the breakage housing 33 is inserted into the shielding hole portion 211. Although not shown, the support guide portion 335 can be fitted to the fixed guide portion 512 when the breakage housing 33 is inserted into the fixed hole portion 511. [

The blocking guide portion 212 or the fixed guide portion 512 means the first guide portion and the support guide portion 335 means the second guide portion.

Here, the housing fastening means 35 may include various types of fasteners, including but not limited to bolts, to secure the break housing 33 to the first shielding frame 20-1.

Here, the member coupling means includes various shapes, including but not limited to, the first hook portion 311 and the second hook portion 331, so that the breaking housing 33 can be connected to the connecting member 31 ). ≪ / RTI >

The elastic member 34 is embedded in the elastic member 33 in a compressed state. The resilient member 34 resiliently supports at least one of the connecting member 31 and the sliding member 32 with respect to the broken housing 33 by releasing the elastic compression state as the breaking portion 332 is broken. The elastic member 34 can elastically support the connecting member 31 or the sliding member 32 while being supported by the elastic supporting step 334. [

The elastic member 34 includes a first elastic member 34-1 for elastically supporting the connecting member 31 with respect to the break housing 33 and a second elastic member 34-1 for elastically supporting the sliding member 32 with respect to the broken housing 33. [ 2 elastic member 34-2.

The connecting member 31 is fixed to the third shielding frame 20-3 via the connecting member fixing means 310 and the connecting member 31 is fixed to the second shielding frame 20-3 via the connecting member 31. [ The breaking housing 33 is fixed according to the combination of the first hooking part 311 and the second hooking part 331 and the breaking housing 33 is fixed to the first blocking frame 20-1 through the housing fixing means 35 do. At this time, since the blocking bracket unit 30 has a bar shape, the breaking housing 33 is stably inserted into the blocking hole 211.

The connection between the connecting member 31 and the breakage housing 33 is released and the breakage of the breakage housing 33 is prevented by the breakage of the breakage housing 33. [ Is separated from the connecting member 31 by the elastic force of the elastic member 34 and the sliding member 32 can slide in the breaking housing 33. [ Then, as shown in FIG. 8, the first blocking frame 20-1 and the third blocking frame 20-3 may be spaced apart from each other. At least the first blocking frame 20-1 and the second blocking frame 20-2 of the blocking frame unit 20 are supported on the fixed frame unit 50 by the elastic force of the elastic member 34 The horizontal load of the predetermined external force can be absorbed. When the predetermined external force is transmitted to the break housing 33, the sliding force of the elastic member 34 is absorbed by the sliding housing 32 as the sliding member 32 slides along with the elastic force of the elastic member 34 . Further, as the sliding member 32 is rotated in the connecting member 31, it is possible to absorb the vertical load of the preset external force. At this time, since the blocking member 10 flows in a state of being connected to the blocking frame unit 20 by the blocking support member 40 and the member holding unit 70, it is possible to prevent a predetermined external force from being transmitted to the blocking member 10 can do.

The earthquake-resistant window system can reassemble the separated shield frame unit 20 by replacing the break housing 33 or replacing the earthquake-resistant bracket unit.

The earthquake-resistant bracket unit according to an example absorbs a horizontal load or a vertical load of a predetermined external force, thereby preventing a predetermined external force from being transmitted to the shutoff member 10, and preventing the shutoff member 10 from being damaged by a sufficient buffering action can do.

As shown in FIG. 5, the blocking bracket unit 30 according to an exemplary embodiment includes the first blocking frame 20-1 and the third blocking frame 20-3 coupled to each other. However, The second shielding frame 20-2 and the third shielding frame 20-3 can be coupled to each other.

5, the connecting member 31 of the blocking bracket unit 30 according to an example is fixed to the third blocking frame 20-3 via the connecting member fixing means 310, The housing 33 is fixed to the first cut-off frame 20-1 via the housing fixing means 35. However, the present invention is not limited thereto and the connecting member 31 may be fixed to the connecting member fixing means 310 And the broken housing 33 can be fixed to the third shielding frame 20-3 via the housing fixing means 35. The third shielding frame 20-3 is fixed to the first shielding frame 20-1.

Alternatively, the blocking bracket unit 30 may wrap the end of the blocking frame as shown in FIG. The blocking bracket unit 30 according to the modified example may further include a frame contact portion 313. [ The frame contact portion 313 is provided on the connecting member 31. The frame fitting portion 313 is provided with a frame insertion slot portion 314 into which the end portion of the blocking frame is fitted. According to the structure of the frame adhering portion 313, the two adjacent blocking frames are in close contact with each other, so that outside air or foreign matter can be prevented from moving between two adjacent blocking frames, and leakage can be prevented.

As another example, the blocking bracket unit 30 may be provided with a breaking housing 33 in two mutually adjacent blocking frames as shown in Fig.

The blocking bracket unit 30 according to another example may further include a connecting member 31, a sliding member 32 and a breaking housing 33 and may include an elastic member 34. [

The connecting member 31 is inserted into the blocking hole portion 211 of the first blocking frame 20-1 and the blocking hole portion 211 of the third blocking frame 20-3. The connecting member 31 may be provided with a first hook 311 for engaging the breaking housing 33.

The sliding member 32 is engaged with the connecting member 31. [ The sliding member 32 can be linked to the connecting member 31 via the hinge portion 312. [ Then, the sliding member 32 is rotatable with respect to the connecting member 31. Although not shown, the sliding member 32 may extend from the connecting member 31. [

The sliding member 32 includes a first sliding member 32-1 coupled to the connecting member 31 corresponding to one of the two blocking frames adjacent to each other, And a second sliding member 32-2 coupled to the connecting member 31 in correspondence with the first sliding member 32-2. 10, the first sliding member 32-1 is coupled to the connecting member 31 corresponding to the first blocking frame 20-1, and the second sliding member 32-2 is coupled to the connecting member 31 And may be coupled to the connecting member 31 corresponding to the third shielding frame 20-3.

The break housing (33) is fixed to the two shielding frames via the housing fixing means (35). The breaking housing 33 includes a first breaking housing 33-1 fixed to one of the two blocking frames adjacent to each other via the housing fixing means 35, And a second break housing (33-2) fixed to the other one of the two adjacent blocking frames. The first breaking housing 33-1 is fixed to the first blocking frame 20-1 by the housing fixing means 35 while being inserted into the blocking hole 211 of the first blocking frame 20-1, The second breaking housing 33-2 can be fixed to the third blocking frame 20-3 by the housing fixing means 35 while being inserted into the blocking hole 211 of the third blocking frame 20-3 have.

Further, the breaking housing 33 is fixed to the connecting member 31 via the member coupling means in a state in which the sliding member 32 is fitted. Here, the first rupture housing 33-1 is fixed to the connecting member 31 via the member coupling means in a state where the first sliding member 32-1 is fitted. Further, the second rupture housing 33-2 is fixed to the connecting member 31 via the member coupling means in a state in which the second sliding member 32-2 is fitted.

The first rupturing housing 33-1 and the second rupturing housing 33-2 may be provided with a second hook 331 for coupling with the connecting member 31, respectively. And the second hook portion 331 is hooked to the first hook portion 311. [ Then, the member coupling means may include a first hook portion 311 and a second hook portion 331.

The first rupturing housing 33-1 and the second rupturing housing 33-2 may be provided with a breaking portion 332 for releasing the connection with the connecting member 31, respectively. The breakage portion 332 can slide the sliding member 32 in the breakage housing 33 by releasing the engagement between the breakage housing 33 and the connection member 31 when a predetermined external force or more is transmitted . Although the breaking portion 332 shows a "V" -shaped groove shape, the present invention is not limited thereto. The breaking housing 33 and the connecting member 31 can be disengaged through various known shapes.

The sliding member 32 may be slidably inserted into the first and second rupturing housings 33-1 and 33-2 as the sliding hole 333 is formed in the first and second rupturing housings 33-1 and 33-2.

The sliding hole 333 of the rupture housing 33 may be provided with an elastic supporter 334 for supporting the elastic member 34.

The first rupture housing 33-1 and the second rupture housing 33-2 may have support guide portions 335 corresponding to the blocking guide portions 212, respectively. The support guide portion 335 is fitted to the shielding guide portion 212 when the breakage housing 33 is inserted into the shielding hole portion 211. Although not shown, the support guide portion 335 can be fitted to the fixed guide portion 512 when the breakage housing 33 is inserted into the fixed hole portion 511. [ Here, the blocking guide portion 212 or the fixed guide portion 512 means the first guide portion, and the support guide portion 335 means the second guide portion.

Here, the housing fastening means 35 may include various types of fasteners, including but not limited to bolts, to secure the break housing 33 to the first shielding frame 20-1.

Here, the member coupling means includes various shapes, including but not limited to, the first hook portion 311 and the second hook portion 331, so that the breaking housing 33 can be connected to the connecting member 31 ). ≪ / RTI >

The elastic member 34 is embedded in the elastic member 33 in a compressed state. The resilient member 34 resiliently supports at least one of the connecting member 31 and the sliding member 32 with respect to the broken housing 33 by releasing the elastic compression state as the breaking portion 332 is broken. The elastic member 34 can elastically support the connecting member 31 or the sliding member 32 while being supported by the elastic supporting step 334. [

The elastic member 34 includes a first elastic member 34-1 for elastically supporting the connecting member 31 with respect to the break housing 33 and a second elastic member 34-1 for elastically supporting the sliding member 32 with respect to the broken housing 33. [ 2 elastic member 34-2.

The earthquake-resistant bracket unit according to another example may further include the above-described frame-tightening portion 313.

The earthquake-resistant bracket unit according to another example absorbs not only the horizontal load of the predetermined external force but also the vertical load, thereby preventing the predetermined external force from being transmitted to the blocking member 10 and preventing the blocking member 10 from being damaged Can be prevented.

The member holding unit 70 is coupled to the shielding frame unit 20. The member holding unit (70) holds the edge of the blocking member (10). The member holding unit 70 can grip at least one of both end edge portions of the blocking member 10 and the upper end edge of the blocking member 10. The member holding unit 70 can grip the lower end edge of the blocking member 10.

The member holding unit 70 may include a grip body 71, a pivotal link portion 73, and a gripping fork portion 74.

The gripping body part (71) is engaged with the shielding frame via the grip fixing means (72). The pawl body 71 may be provided with a pivotal bracket 711 toward the blocking member 10.

Here, the grip fastening means 72 includes bolts, but is not limited thereto, and the grip body portion 71 can be coupled to the shielding frame unit 20 through various known types.

The rotation link portion 73 is linked to the rotation bracket 711 through the first shaft portion 731.

The gripping fork portion 74 is linked to the rotation link portion 73 via the second shaft portion 732. The fork fork 74 is provided with a fork member 741 for gripping the blocking member 10.

At this time, either one of the rotation link portion 73 and the gripping fork portion 74 may be provided with a shaft guide portion 733 through which the second shaft portion 732 is slidably moved. Accordingly, the blocking member 10 can move up and down and left and right in accordance with the rotation of the pivotal link portion 73, and can prevent the member holding unit 70 from being damaged.

Although not shown, the member holding unit 70 may further include a holding elastic member (not shown) that elastically supports the pivotal link portion 73 with respect to the holding body portion 71.

The member holding unit 70 can freely move the blocking member 10 in the left and right direction and move the blocking member 10 in the up and down direction corresponding to the horizontal load of the predetermined external force as well as the vertical load, The breakage of the blocking member 10 can of course be prevented.

Reference numeral 80 is a spacer inserted between the second blocking blade portion 24 and the blocking member 10. The spacer 80 has elasticity.

Reference numeral 90 denotes a sealing material for sealing between the first blocking blade 22 and the blocking member 10 or for sealing the space between the second blocking blade 24 and the blocking member 10. The sealing member 90 has elasticity and can be separated from at least one of the first blocking wing portion 22 and the second blocking wing portion 24 and the blocking member 10 when the breaking portion 332 is broken have.

According to the above-mentioned earthquake-resistant window system, earthquake-resistant window screening support member, and earthquake-resistant window earthquake-resistant bracket unit, the earthquake-resistant window system itself is subjected to seismic design to shield the opening of the building even if the external force is directly transmitted to the earthquake- It is possible to prevent the blocking member 10 from being directly transmitted to the blocking member 10 and prevent the blocking member 10 from bumping against the blocking frame unit 20 surrounding the blocking member 10, It is possible to prevent breakage of the battery 20. Further, the heat insulating performance and the leakage preventing performance between the shielding frame unit 20 and the shielding member 10 can be improved through the structure of the barrier support member 40.

Further, the edge of the shielding member 10 can be stably supported through the detailed structure of the shielding frame, and the replacement of the shielding member 10 can be smoothly performed. In the case of a sliding door type window through the detailed constituent part of the blocking frame, the blocking frame unit 20 can be smoothly moved in the sliding direction. In the case of the window type, the blocking frame unit 20 and the fixed frame unit 50 In the case of a fixed type window or curtain wall type window, the blocking frame unit 20 can be stably fixed to the opening of the building.

In addition, the blocking bracket unit 30 can secure the coupling between the blocking member 10 and the blocking frame unit 20 and the coupling between the blocking frames through the additional structure of the blocking bracket unit 30, The shielding frame unit 20 can be prevented from being deformed or damaged as well as the shielding member 10 due to the buffering action of the shielding bracket unit 30 by sliding movement in the shielding frame unit 20. [

It is also possible to prevent the blocking member 10 from being separated from the separated blocking frame unit 20 through the additional structure of the member holding unit 70 and to prevent breakage of the blocking member 10. The degree of freedom of the blocking member 10 is secured through the detailed configuration of the member holding unit 70 and the shock applied to the blocking member 10 is absorbed by absorbing and discharging the vertical load as well as the predetermined external force , So that the blocking member (10) is stably supported in the blocking frame unit (20).

Further, the earthquake-resistant window system can be applied to the sliding window system or the hinged window system through the additional structure of the fixed frame unit 50, and the earthquake-proof function of the window itself can be given in various window systems.

In addition, when the external force is applied, the fixed bracket unit is slid in the fixed frame unit 50 by the additional structure of the fixed bracket unit, so that the fixed bracket unit is buffered It is possible to prevent deformation or breakage of the blocking frame unit 20 and the fixed frame unit 50 as well as the member 10.

In addition, external force can be prevented from being directly transmitted to the blocking member 10 through the blocking support member 40, and breakage of the blocking member 10 can be prevented. Further, the elastic deformation of the receiving body portion 41 can be smoothly performed through the elastic hole portion 411 or the dispersion inclined portion 412, and the elastic support of the blocking member 10 can be stabilized. Further, the receiving body 41 can be separated from the blocking frame through the buffering concave / convex portion 43 to prevent the external force from being directly transmitted to the receiving body 41. It is also possible to prevent the flow of the blocking support member 40 from the blocking frame unit 20 through the fitting between the first supporting portion 203 and the second supporting portion 403 and to stabilize the elastic support of the blocking member 10 .

In addition, the seismic performance of the blocking bracket unit 30 and the fixed bracket unit is improved through the earthquake-resistant window seismic bracket unit, and the seismic performance is exhibited in the window frame to prevent breakage of the blocking member 10, It is possible to prevent deformation or breakage of the battery. In addition, the connecting member 31 or the broken housing 33 can securely fix each frame, and the slide member 32 can smoothly slide in the broken housing 33, thereby stably absorbing the external force. Further, through the linkage between the connecting member 31 and the sliding member 32, the movement of each frame is made to correspond to the horizontal load and the vertical load of external force, and deformation or breakage of each frame can be prevented. In addition, through the structure of the frame tightening portion 313, it is possible to prevent the movement of outside air or foreign matter at the connection portion of each frame, and to prevent leakage. In addition, it is possible to simplify the engagement of the broken housing 33 in each frame through the fitting of the first guide portion and the second guide portion, and prevent the breaking housing 33 from flowing in each frame.

Further, since the frame and the shielding member 10 are prevented from being deformed or damaged, it is possible to repair the earthquake-resistant window system by replacing the broken housing 33 or replacing the earthquake-resistant bracket unit, Can be minimized.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Modify or modify the Software.

10: blocking member 11: crack growth preventing portion 20: blocking frame unit
20-1: first blocking frame 20-2: second blocking frame 20-3: third blocking frame
203: first support part 21: cut-off body part 211:
214: blocking reinforcement rib 212: blocking guide portion 22: first blocking blade portion
221: blocking support 23: blocking wedge 231: first blocking jaw
232: second blocking jaw portion 24: second blocking blade portion 241: first extending portion
242: first latching portion 243: second extending portion 244: second latching portion
245: wing support part 25: third blocking blade part 251: first blocking part
253: third blocking protrusion 254: sole engaging portion 26: fourth blocking wing portion
262: second blocking protrusion 264: fourth blocking protrusion 30: blocking bracket
310: connecting member fixing means 31: connecting member 311: first hook portion
312: hinge portion 313: frame fitting portion 314: frame insertion groove
32: sliding member 32-1: first sliding member 32-2: second sliding member
33: rupture housing 33-1: first rupture housing 33-2: second rupture housing
331: second hook portion 332: rupture portion 333: sliding hole portion
334: elastic supporting step 335: support guide part 35: housing fixing means
40: interception member 403: second support portion 41: support body portion
411: elastic hole portion 412: dispersion inclined portion 42: elastic wing portion
43: cushioning concave / convex portion 50: fixed frame unit 50-1: first fixed frame frame
50-2: second fixed frame frame 50-3: third fixed frame frame 51: fixed body part
511: Fixed hole portion 512: Fixed guide portion 514: Fixed reinforcing rib
52: first fixed wing portion 53: second fixed wing portion 54: third fixed wing portion
541: first fixing protrusion 543: third fixing protrusion 55: fourth fixing wing
552: second fixing protrusion 554: fourth fixing protrusion 56:
57: auxiliary wing part 70: member holding unit 71: gripping body part
711: Rotation bracket 72: Retaining means 73:
731: first shaft portion 732: second shaft portion 733: shaft guide portion
74: gripping fork portion 75: fork member 80: spacer
90: sealing material

Claims (17)

An earthquake-resistant window system for opening or closing an opening of a building,
A blocking member for blocking the opening;
A shielding frame unit coupled to the opening and including a plurality of shielding frames surrounding the shielding member; And
And a shielding support member provided on the shielding frame unit to support the shielding member and elastically supporting the shielding member with respect to the shielding frame unit. The method according to claim 1,
The shielding frame includes:
A blocking body portion through which a blocking hole is formed and on which the blocking support member is mounted;
A first blocking blade extending from one side of the one side of the blocking body;
A first blocking jaw provided at the other side of one side of the blocking body and a second blocking jaw part spaced from the first blocking jaw toward the blocking member from the other side of one side of the blocking body, part; And
And a second blocking blade part engaged with the blocking blade engagement part so as to be removably attached to the blocking body part. 3. The method of claim 2,
The shielding frame includes:
A third blocking blade extending from one side of the other side of the blocking body corresponding to the first blocking blade; And
A fourth blocking blade extending from the other side of the other side of the blocking body corresponding to the second blocking blade; Wherein the at least one of the at least one of the first and second windows is a window. The method according to claim 1,
And a blocking bracket unit for coupling two mutually adjacent blocking frames among the blocking frame units,
Wherein the shut-off bracket unit is slidable in the shut-off frame as a part of the shut-off bracket unit is damaged when an abnormal external force is transmitted. 5. The method of claim 4,
And a member grasping unit coupled to the shut-off frame unit and configured to grasp an edge of the shut-off member. 6. The method of claim 5,
The member holding unit includes:
A gripping body coupled to the shielding frame via gripping means and having a pivoting bracket toward the shielding member;
A pivotal link portion linked to the pivot bracket via a first shaft portion;
And a fork portion linked to the pivotal link portion via a second shaft portion and having a fork member for holding the blocking member,
And a shaft guide part in which the second shaft part is slidably moved is provided to one of the rotation link part and the gripping fork part. 7. The method according to any one of claims 1 to 6,
Further comprising: a fixed frame unit having a plurality of fixed frame frames coupled to the openings so that the blocking frame unit is rotatably coupled or the blocking frame unit is slidably coupled. 8. The method of claim 7,
Further comprising: a fixed bracket unit for coupling two mutually adjoining fixed frame frames of the fixed frame unit,
Wherein the stationary bracket unit is slidable in the shut-off frame as a part of the fixed bracket unit is damaged when an external force or a predetermined external force is transmitted. A seismic isolation system for an earthquake-resistant window system for resiliently supporting a shielding frame unit for enclosing a shielding member for shielding an opening of a building in an earthquake-resistant window system,
Wherein the barrier-
A support body part having an elastic hole formed therethrough and having a side surface elastically supported by the blocking member;
An elastic wing portion extending from one side of the one side of the receiving body so as to be elastically supported by the side surface of the blocking member with respect to the blocking frame unit or extending from both sides of one side of the receiving body; And
And a cushioning protruding portion extending from the other side of the receiving body portion and elastically supporting the receiving frame body while separating the receiving body portion from the blocking frame. 10. The method of claim 9,
Wherein the support body portion is provided with a dispersion inclined portion inclined from the other side toward the other side of the support body. 11. The method according to claim 9 or 10,
The blocking frame is provided with a first supporting portion,
Wherein the barrier support member is provided with a second support portion fitted to the first support portion. An earthquake-resistant bracket unit for an earthquake-resistant window system that encloses a shielding member for shielding an opening of a building in an earthquake-resistant window system or connects two mutually adjacent frames among frame units coupled to the opening,
The earthquake-resistant bracket unit includes:
A connecting member coupled to one of the two frames via the connecting member fixing means;
A sliding member coupled to the connecting member; And
And a breaking housing fixed to the other one of the two frames via the housing fixing means and fixed to the connecting member via the member coupling means in a state in which the sliding member is fitted,
In the breaking housing,
And a breaker for releasing the coupling between the breakage housing and the connection member so that the sliding member can be slidably moved in the breakage housing when a predetermined external force or abnormality is transmitted. An earthquake-resistant bracket unit for an earthquake-resistant window system that encloses a shielding member for shielding an opening of a building in an earthquake-resistant window system or connects two mutually adjacent frames among frame units coupled to the opening,
The earthquake-resistant bracket unit includes:
A connecting member;
A sliding member including a first sliding member coupled to the connecting member and a second sliding member coupled to the connecting member in a state spaced apart from the first sliding member; And
A first rupturing housing fixed to one of two frames through a housing fixing means and fixed to the connecting member via a member coupling means in a state in which the first sliding member is fitted to the frame, And a second rupturing housing fixed to the other one of the two frames and fixed to the connecting member via member coupling means in a state in which the second sliding member is fitted,
In the breaking housing,
And a breaking part for releasing the coupling between the rupture housing and the connecting member so that the sliding member can be slidably moved in the rupture housing when a predetermined external force or abnormality is transmitted. The method according to claim 12 or 13,
The earthquake-resistant bracket unit includes:
And an elastic member embedded in the rupture housing in an elastically compressed state and releasing the elastic compression state as the rupture portion is broken to elastically support at least one of the connecting member and the sliding member with respect to the rupture housing Wherein said earthquake-resistant bracket unit comprises: The method according to claim 12 or 13,
Wherein the sliding member is linked to the connecting member via a hinge portion. The method according to claim 12 or 13,
The earthquake-resistant bracket unit includes:
The frame according to claim 1, further comprising a frame-tightening unit provided on the connecting member and having a frame insertion slot into which an end of the frame is fitted. The method according to claim 12 or 13,
The frame is provided with a first guide portion,
And a second guide part fitted to the first guide part in the rupture housing.

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