KR102260467B1 - Sliding window having earthquake-resistance unit - Google Patents

Abstract

The present invention relates to a sliding window equipped with an earthquake-resistance unit and, more specifically, to technology for protecting a sliding window from an earthquake by relieving or damping an impact from an earthquake through an earthquake-resistance unit provided between a wall and a window frame of a sliding window. In particular, the present invention relates to technology for relieving or damping an impact from an earthquake onto a sliding window through a constitution in which an earthquake-resistance frame provided in the earthquake-resistance unit is separated into two frames, and an earthquake-resistance reinforcement material is inserted into the earthquake-resistance frame, and then, the earthquake-resistance frame is combined with the earthquake-resistance reinforcement material. Moreover, the present invention relates to a sliding window equipped with an earthquake-resistance unit, formed to effectively protect a sliding window from an earthquake by additionally relieving a part of an earthquake impact through an impact relieving structure provided between earthquake-resistance units.

Description

Sliding window having earthquake-resistance unit

The present invention relates to a seismic window provided with a seismic unit, and by providing a seismic unit between the window frame and the wall of the seismic window to cushion or damp the shock caused by the earthquake, it relates to a technology for protecting the miseo window from earthquakes. In particular, the present invention is configured by separating the seismic frame provided in the seismic unit into two frames, inserting the seismic reinforcing material inside the seismic frame, and then buffering the shock of the earthquake through a configuration in which the seismic frame and the seismic reinforcing material are combined. Or it relates to a technique for attenuating. In addition, a portion of the earthquake shock is additionally buffered through the buffer structure provided between the seismic units, and it relates to a Miseogi Chang having a seismic unit configured to effectively protect the Miseogi Chang from an earthquake.

Recently, the occurrence of earthquakes has been increasing in Korea as well, and there are cases where earthquakes with a magnitude of 5 or more have occurred depending on the region. In addition, there is a growing need to prevent earthquake damage to buildings. Moreover, as buildings become taller, the need to prepare for earthquakes is increasing, and as the safety requirements increase, the need to improve the safety level of buildings against earthquakes is increasing.

On the other hand, in case of an earthquake, windows installed on the exterior wall of a building may have a problem in that the glass window is broken or the window frame or window frame is damaged due to external force in the vertical or horizontal direction or a complex external force transmitted through the window frame and window frame.

Miseogi Chang is a window that is installed in a space partitioned by a window frame and is configured to move while sliding left and right. Although the Miseogi window has many convenient features, its structure is rather complicated because the entire window must be separated from the window frame and configured to move freely.

On the other hand, as described above, as the need to apply seismic structures to buildings increases, the need to adopt seismic structures in Miseogi Chang is also increasing.

Most of the glass windows are constructed of glass materials. In the case of glass windows, damage due to external force occurs more easily than metal window frames or window frames. If the intensity of an earthquake increases, even the window frames and window frames are deformed or damaged. This can happen.

In the case of a strong earthquake, the building itself, window frames, and window frames may be damaged. However, in regions where earthquakes do not occur frequently like Korea, if an earthquake-resistant unit is provided in the structure of the window itself, window frames, window frames, and glass windows The possibility of effectively preventing the breakage of the

On the other hand, even before the filing of the present invention, there was a window technology having the following earthquake-resistant function.

For example, Korean Patent Registration No. 10-1754637 (announced on July 6, 2017) is an invention named earthquake-resistant and heat-blocking structural unit, which is a joint surface that is coupled to a window frame and a window frame of an exterior wall or window frame of a building. A lower profile provided along the; And, one end is coupled to the lower surface of the window frame and the other end is coupled to the upper surface of the lower profile to support the load of the window frame and block direct heat transfer between the window finishing material and the main profile of the window through an insulating member that blocks the indoor and outdoor areas to insulate. It is configured to reduce the separation, deformation or damage of windows and doors by external force by providing an elastic member that can act as a buffer for external force between the finishing material and the window. In the present invention, it is configured to provide a plurality of elastic members 150 between the window frame 110 and the lower profile 130 in an earthquake-resistant configuration, and these elastic members 150 and 250 are formed on the upper profile ( 120) and provided in a separated state, and a heat insulating member 140 is provided between the elastic members for blocking heat.

In the case of this invention, it seems that the seismic effect between the window frame and the wall can be achieved to some extent, but the insulating member 140 provided in the seismic unit is easily damaged by an earthquake, and if it is damaged, it is repaired from the outside. It becomes difficult to do, and there are problems such as the difficulty in firmly coupling the window frame 110 and the earthquake-resistant unit.

In addition, Korean Patent Registration No. 10-2060361 (notice on Dec. 30, 2019) applies the seismic design to the seismic window system itself, so that even if external force is directly transmitted to the seismic window system, it is transmitted directly to the blocking member blocking the opening of the building. A seismic window system for preventing damage to the blocking frame unit surrounding and supporting the blocking member, and preventing damage to the blocking member as well as the blocking frame unit, a blocking support member for earthquake-resistant windows, and an earthquake-resistant It relates to an earthquake-resistant bracket unit for windows. The seismic window system of the present invention is an earthquake-resistant window system that opens or closes an opening of a building, and includes a blocking member for blocking the opening of the building, and a plurality of blocking frames coupled to the opening of the building and surrounding and supporting the blocking member It is configured to include a blocking frame unit and a blocking support member provided in the blocking frame unit to support the blocking member and elastically supporting the blocking member with respect to the blocking frame unit.

Another prior art, Korean Patent Registration No. 10-2097234 (announced on March 3, 2020) relates to earthquake-resistant windows, and when installing windows, which is the most vulnerable part of a building structure when an earthquake occurs, fixed anchors and wires are used in the window installation structure. It relates to a window with a seismic structure that was created to exhibit a very effective seismic effect while being simpler to install compared to the existing ones through an earthquake-resistant design that introduced a new hold structure of concrete walls and window frames.

The present invention relates to a technology for protecting the Miseogi window installed in a building through a configuration different from the prior art from the effects of an earthquake, and a window frame and a window to buffer or damp the impact of an earthquake transmitted to the Miseogi window through the wall of the building It relates to a technique for installing an earthquake-resistant unit between frames. In particular, after the main frame constituting the earthquake-resistant unit is separated into two and manufactured, they are combined, and an earthquake-resistant reinforcing material capable of buffering or damping the earthquake-resistant impact is provided inside the main frame. In addition, the seismic unit is an invention configured so that the shock of the earthquake can be additionally buffered or damped through the surrounding elements.

- Domestic Registered Patent No. 10-1754637 (2017.07.06. Announcement) - Domestic Registered Patent No. 10-2060361 (2019.12.30. Announcement) - Domestic Registered Patent No. 10-2097234 (2020.04.03. Announcement)

The present invention is to provide a Miseogi Chang having an earthquake-resistant unit capable of effectively buffering or damping an external force caused by an earthquake in the Miseogi Chang, thereby minimizing the damage of windows and windows.

In the event of an earthquake, the seismic reinforcing material provided inside the seismic frame absorbs external force or shock caused by the earthquake to provide a Miseogi window that can protect the window frame and the glass window from being damaged. This is to provide a seismic window configured so that the seismic frame itself, which is the core component of the seismic unit, cannot be damaged even in the event of an earthquake.

That is, in the case of a weak earthquake, the present invention can absorb the external force caused by the earthquake through the structure of the earthquake-resistant unit, thereby preventing damage to windows and doors and windows, and in the case of a stronger earthquake, the structure of the earthquake-resistant unit Among the elements, the parts that are easy to repair or replace are damaged first, and the earthquake-resistant frame, which is the most important component, is intended to provide a misseogi window configured to withstand even the last stage.

In the present invention, when an earthquake occurs within the elastic range of the earthquake-resistant reinforcement provided in the earthquake-resistant unit, the earthquake-resistant reinforcement buffers or attenuates the shock of the earthquake so that the windows and doors are not damaged or the earthquake-resistant frame itself is not damaged and only other parts are damaged. This is to provide a seismic unit equipped with an earthquake-resistant unit that can be repaired or restored by replacing only the damaged part by the earthquake, and thus can greatly reduce the repair or restoration costs of windows and doors after an earthquake. .

The present invention is applied to windows and doors of a building made of a Miseogi window, and in a Miseogi window comprising a vertical window frame and a horizontal window frame, by providing an earthquake-resistant unit between the vertical and horizontal window frames and the wall of the building. It is designed to protect windows from the impact of earthquakes.

The earthquake-resistant unit of the present invention includes an earthquake-resistant frame 100 provided on the indoor side of a building, an external frame 500 provided on the outdoor side, a heat insulating fastening member 400 connecting the earthquake-resistant frame and the external frame, and an earthquake-resistant frame It relates to an earthquake-resistant unit of Miseogichang comprising an inner cap 300 forming the finishing part of the seismic frame from the indoor side, and an outer cap 600 for finishing the outer frame from the outdoor side of the outer frame.

In particular, the seismic frame of the present invention is configured by combining the frames manufactured by being separated into two with each other. That is, the seismic frame of the present invention is constituted by coupling a first earthquake-resistant frame and a second earthquake-resistant frame to each other, and an earthquake-resistant reinforcement made of an elastic metal inside the earthquake-resistant frame formed by combining the first and second earthquake-resistant frames. 200 is provided.

The earthquake-resistant frame made of two of the present invention, that is, the first earthquake-resistant frame 110 and the second earthquake-resistant frame 130 is configured to be firmly coupled with the earthquake-resistant reinforcement using a plurality of fixing pieces. The seismic reinforcing material 200 of the present invention is formed of a material that has elasticity and can withstand strong external forces, such as a cold-rolled iron plate, and when an earthquake occurs, the external force of the earthquake is configured to act as a force to primarily deform the earthquake-resistant reinforcing material.

An inner cap that closes the gap between the first and second seismic frames is provided on the indoor side of the seismic frame, and when an earthquake occurs, the inner cap is damaged first. On the other hand, on the outdoor side of the outer frame, an outer cap for finishing the outside of the earthquake-resistant unit is provided, and when an earthquake occurs, the outer cap is damaged together with the inner cap, or a part of the outer frame coupled with the insulating fastening member is separated from the outer cap. will be separated

In the present invention, when an earthquake occurs, the deformation of the Miseogi window is primarily made within the elastic movement range of the earthquake-resistant reinforcement, and when the external force of the earthquake disappears, the earthquake-resistant reinforcement is restored to its original shape, and the overall shape of the window is also restored to its original shape. . However, even in this case, depending on the strength of the earthquake, the inner cap or the outer cap may be damaged or both may be damaged. On the other hand, when an earthquake strong enough to deviate from the elastic limit of the seismic reinforcing material occurs, deformation or damage to the seismic frame itself may occur.

Another configuration that is combined with the earthquake-resistant frame of the present invention is a heat insulating fastening member (400). The heat insulating fastening member 400 is made of a material such as polyamide, and at the same time firmly couples the earthquake-resistant frame 100 and the external frame 500 to each other, and at the same time, heat transfer between the inside and outside of the window that can be achieved through the earthquake-resistant unit. It is provided to block.

The present invention effectively cushions or attenuates the external force of an earthquake through the interaction with the earthquake-resistant frame and components coupled to the earthquake-resistant frame in the process in which the external force caused by the earthquake is transmitted to the windows and doors through the walls, thereby preventing the deformation or damage of the windows. It is to provide a seismic window equipped with a seismic unit that can prevent or reduce.

The present invention can effectively prevent the breakage of the window by allowing the shock of the earthquake applied to the windows and doors in the vertical or horizontal direction to be buffered or damped through the seismic unit. In particular, if it is not a strong earthquake, it is possible to effectively protect the Miseogi Chang from the external force of the earthquake.

In particular, the present invention effectively cushions or attenuates the impact transmitted to the windows through the earthquake-resistant unit by using the elastic force of the earthquake-resistant reinforcement inserted inside the earthquake-resistant frame, thereby minimizing the damage to the Miseogi-chang caused by the earthquake.

In addition, when the configuration of the present invention is applied, even if some damage occurs to the Miseogi window due to the occurrence of an earthquake, the earthquake-resistant frame itself is not damaged and the components around the earthquake-resistant frame are damaged or separated first, so that the earthquake-resistant frame is not damaged It is possible to repair or restore the earthquake-resistant unit and windows by replacing the components around the damaged area, making it possible to repair the windows without replacing the earthquake-resistant frame, thereby significantly reducing the cost for repair or restoration. have.

1 is an external view of the present invention is applied Miseogi-chang.
Figure 2 is a block diagram of the seismic unit of the present invention.
3 is an exploded view of the seismic unit of the present invention.
Figure 4 is a partial view of a perspective view of the vertical section of the seismic unit of the present invention is applied Miseogichang.
Figure 5 is a vertical sectional view of the seismic unit of the present invention is applied Miseogi window.
Figure 6 is a partial view of a perspective view of a horizontal cross section of the seismic unit of the present invention is applied Miseogichang.
Figure 7 is a horizontal cross-sectional view of the seismic unit of the present invention is applied Miseogi window.
8 is a view showing a state in which a part of the earthquake-resistant unit of the present invention is damaged.
9 is a view related to another embodiment of the seismic unit of the present invention.
10 is a view of another embodiment of the seismic reinforcement applied to the present invention.
Figure 11 is a view showing a part of the seismic unit of the present invention is applied Miseogi window.
12 is a view showing the overall shape of the seismic unit of the present invention is applied Miseogi window.

The present invention relates to a seismic unit configured to effectively cushion or damp the impact of an earthquake through a seismic unit. The seismic unit applied to the seismic window of the present invention has an earthquake-resistant frame as its core configuration, and the earthquake-resistant frame consists of two frames, that is, the first earthquake-resistant frame and the second earthquake-resistant frame, and these are combined to form the entire earthquake-resistant frame. will form An earthquake-resistant reinforcement is provided inside the earthquake-resistant frame, and the first and second earthquake-resistant frames and the earthquake-resistant reinforcement are screwed into a fixing piece, so that they are firmly fixed to each other.

The seismic frame of the present invention configured as above is again firmly coupled to the window frame using a plurality of other fixing pieces.

The present invention particularly relates to a Miseogi Chang having an earthquake-resistant unit configured so that external force caused by an earthquake transmitted to an earthquake-resistant frame can be effectively buffered and damped through an earthquake-resistant elastic part included in an earthquake-resistant reinforcement.

The seismic window equipped with the seismic unit of the present invention absorbs external force caused by an earthquake by using the elasticity of the seismic reinforcing material coupled with the first and second seismic frames on the inside of the separated seismic frame, that is, the first and second seismic frames. It is configured to buffer, and in addition, through a secondary buffer structure through an inner cap inserted between the first and second seismic frames on the indoor side of the seismic unit, and an outer cap inserted on the outdoor side of the outer frame By additionally buffering the external force of the earthquake, it is configured to effectively buffer and damp the external force of the earthquake transmitted to the Miseogi Chang.

Hereinafter, the configuration of the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 shows the appearance of the present invention is applied Miseogi-chang. In FIG. 1, the Miseogi window having an earthquake-resistant unit of the present invention is a vertical window frame 10 and a horizontal window frame 20, a vertical window frame 30 and a horizontal window frame 40, and a vertical earthquake-resistant unit 50 And the horizontal seismic unit 60 and the window glass 700 is applied to the Miseogi window.

Figure 2 is a view showing in detail the configuration of the seismic unit Miseogichang to which the present invention is applied, Figure 3 is an exploded view of the components of the seismic unit of the present invention shown in Figure 2 is disassembled.

As shown in Figs. 2 and 3, the earthquake-resistant unit of the present invention is constituted by including elements as described below.

The present invention provides an earthquake-resistant frame 100 composed of first and second earthquake-resistant frames 110 and 130, an earthquake-resistant reinforcing material 200, an inner cap 300, an insulating fastening member 400, and an outer frame 500 ), and it relates to a Miseogi window configured to include an outer cap 600,

The seismic unit of the present invention is configured by sequentially combining the inner cap 300, the seismic frame 100, the heat insulating fastening member 400, the outer frame 500 and the outer cap 600 in the direction from the indoor side of the building to the outdoor side. . The earthquake-resistant unit of the present invention can be basically implemented through a special configuration of the earthquake-resistant frame 100 and the earthquake-resistant reinforcement 200, the inner cap 300, the insulating fastening member 400, the outer frame 500, and An additional seismic effect can be expected through the configuration in which the outer cap 600 is further provided.

The seismic frame 100 is composed of two frames manufactured separately, that is, the first seismic frame 110 and the second seismic frame 130 are coupled to each other, and is mainly manufactured by injection method using an aluminum material. will be. The earthquake-resistant frame 100 is installed in the vertical or horizontal direction between the vertical window frame 10 and the horizontal window frame 20 and the wall, as shown in FIG. 1 to support the vertical window frame 10 or the horizontal window frame 20, or It will serve to support both the vertical and horizontal window frames (10, 20).

The earthquake-resistant frame 100, which is a key element constituting the earthquake-resistant units 50 and 60 of the present invention, is specifically configured as follows.

As shown in Figures 2 and 3, the seismic frame 100 of the present invention is divided into a first seismic frame 110 and a second seismic frame 130, and when these two are combined, the seismic resistance of a long rectangular shape The frame 100 is made. The first earthquake-resistant frame 110 forms one side of the earthquake-resistant frame 100 , and the second earthquake-resistant frame 130 forms the other side thereof.

Here, the configuration of the earthquake-resistant frame 100 of the present invention, that is, the first earthquake-proof frame 110 and the second earthquake-proof frame 130 will be described in detail.

First, the first seismic frame 110 includes a first bent part 111 , a flat part 112 , a support protrusion 113 , a second bent part 114 , and an extended coupling part 120 . is done by

The flat portion 112 is a portion made of the longest linear shape in the first earthquake-resistant frame 110, and a first bent portion 111 at one end thereof is toward the inside of the frame or toward the second earthquake-resistant frame 130 side. It is formed by being bent at a right angle, and the second bent part 114 is formed by being bent at a right angle in the same direction at the other end thereof.

The first and second bent portions 111 and 114 are formed one at each end of the flat portion 112 to form one side of the entire seismic frame 100 together with the flat portion 112 .

A support protrusion 113 protruding to the inside of the seismic frame is provided at a position adjacent to the second bent part 114 of the flat part 112 . The support protrusion 113 is formed at a position matching the length of the earthquake-resistant reinforcement 200 inserted into the earthquake-resistant frame 100 to serve to support the earthquake-resistant reinforcement 200 . The first bent portion 111 , the second bent portion 114 , and the support protrusion 113 are formed to be bent or protruded in the same direction, that is, at a right angle toward the inner side of the frame. The support protrusion 113 and the earthquake-resistant reinforcement 200 are coupled to each other through the fixing piece P1.

The extension coupling portion 120 of the first seismic frame 110 is bent and extended from the end of the first bent portion 111 . One or more elastic protrusions 129 are provided in the extended coupling part 120 extending from the first bent part 111 in the indoor direction. The elastic protrusion 129 is inserted into the elastic protrusion insertion groove 139 formed in the first bent portion 131 of the second earthquake-resistant frame 130 so that the first and second earthquake-resistant frames are elastically coupled.

2 and 3, the extended coupling part 120 extends from the end of the first bent part 111 and is bent and extended in the outdoor direction by the thickness of the first bent part 111 and 131, and again 1 is bent so as to be parallel to the bent portions 111 and 131 and is formed. When configured in this way, the extended coupling portion 120 and the first bent portion 131 of the second earthquake-resistant frame 130 do not collide with each other even during an earthquake.

The first bent part 111 and the earthquake-resistant reinforcement 200 are coupled to each other through the fixing piece P1, and as a result, the extended coupling part 120 is also coupled to the earthquake-resistant reinforcement 200. As a result, the effect is generated.

When configured as above, in a normal state, the elastic protrusion 129 of the extended coupling part 120 is inserted into the elastic protrusion insertion groove 139 of the second earthquake-proof frame 130, and the first and second earthquake-resistant frames 110 , 130) remain elastically coupled to each other.

The first bent part 111 and the extended coupling part 120 may be formed to have the same thickness or the extended coupling part 120 may be formed to be thicker.

A plurality of coupling protrusions for coupling the earthquake-resistant frame 100 and the heat insulating fastening member 400 to each other are formed on the other side of the extended coupling part 120 , that is, on the outdoor side part. That is, the extension coupling part 120 has two coupling protrusions 1 121 and 2 coupling protrusions 122 respectively formed in the direction of the heat insulating fastening member 400, and is formed through a pair of coupling protrusions 1 and 2. Each of the fastening protrusions 410 of the heat insulating fastening member 400 is inserted into each of the fastening protrusion insertion grooves 123 , thereby coupling the heat insulating fastening member 400 and the first earthquake-resistant frame 110 to each other. The thermal insulation fastening member 400 is made of a material such as polyamide having excellent thermal insulation and strong bonding strength.

Next, the second earthquake-resistant frame 130 includes a first bent portion 131 , a flat portion 132 , a support protrusion 133 , and a second bent portion 134 . The second earthquake-resistant frame 130 is made of a symmetrical shape as a whole and the first earthquake-resistant frame 110, there is a difference in that the extended coupling portion 120 is not provided.

The flat portion 132 is a portion of a straight line formed longest in the second earthquake-resistant frame 130, and a first bent portion 131 at one end of the second earthquake-resistant frame 130 toward the inside of the frame or the first earthquake-resistant frame 110 side. It is formed by being bent at a right angle to the direction, and the second bent part 134 is formed by bending at a right angle in the same direction at the other end thereof. The first bent portion 131 is coupled to each other with the earthquake-resistant reinforcement 200 through the fixing piece (P1).

The first and second bent portions 131 and 134 are formed at both ends of the flat portion 132 to form the other side of the entire seismic frame 100 together with the flat portion 132 .

At one side of the first bent portion 131 of the second earthquake-resistant frame 130, one or more elastic projection insertion grooves 139 into which the elastic projections 129 formed in the extended coupling portion 120 of the first earthquake-resistant frame 110 are inserted. ) is provided. When the first and second seismic frames are coupled to each other, the elastic protrusion 129 is inserted into the elastic protrusion insertion groove 139, so that the first and second seismic frames 110 and 130 are in contact with each other in an elastically coupled state.

A support protrusion 133 protruding to the inside of the earthquake-resistant frame is provided at a position adjacent to the second bent part 134 of the flat part 132 . The support protrusion 133 is formed at a position to match the length of the earthquake-resistant reinforcement 200 inserted into the earthquake-resistant frame 100 , and serves to support the earthquake-resistant reinforcement 200 . The first bent portion 131 , the second bent portion 134 , and the support protrusion 133 are formed to be bent or protruded in the same direction. The support protrusion 133 and the earthquake-resistant reinforcement 200 are firmly coupled to each other through the fixing piece P1.

The present invention is provided with the earthquake-resistant reinforcement 200 as a key component for earthquake resistance, and the earthquake-resistant reinforcement 200 will be described in detail below.

As shown in Figs. 2 to 7, the earthquake-resistant reinforcement 200 is a means of an elastic metal material having a long rectangular cross-sectional shape as a whole, and both sides of the earthquake-resistant reinforcement 200 as shown in Fig. 3, that is, the side An earthquake-resistant elastic part 210 220 is provided in the center of the 1 230 and the side 2 240, respectively. An earthquake-resistant elastic part 1 210 is provided at the center of the side part 1 230, which is a part corresponding to the outdoor side of the earthquake-resistant reinforcement, and the earthquake-resistant elastic part 1 210 is provided at the center of the side part 2 240, which is a part corresponding to the indoor side of the earthquake-resistant reinforcement material. Part 2 220 is provided.

The seismic reinforcing material 200 of the present invention is made of a metal material such as cold rolled steel, and when an earthquake shock or stress is transmitted to the windows and doors, to absorb the external force applied to the seismic frame 100 in a buffering or damping manner. it is to do In the Miseogichang of the present invention, when the external force caused by the earthquake is within the elastic range of the earthquake-resistant reinforcement 200, the deformation due to the external force is primarily absorbed by the earthquake-resistant reinforcement 200 so that the impact on the earthquake-resistant frame 100 is minimized. By doing so, it is configured to effectively prevent damage to the earthquake-resistant frame (100; 110, 130) and the windows.

Here, the configuration of the seismic frame will be further described in more detail with reference to parts A and B indicated by circles in FIG. 2 . That is, in the present invention, when the first and second seismic frames 110 and 130 are coupled to each other, the first bent portion 111 end of the first seismic frame 110 and the first bent of the second seismic frame 130 . A gap d1 is formed between the ends of the part 131 , and a gap d2 is formed between the support protrusions 113 of the first earthquake-resistant frame 110 and the support protrusions 133 of the second earthquake-resistant frame 130 . do. The intervals d1 and d2 may be formed to have the same or similar length. The reason for providing such an interval between the bent parts or the support protrusions is the collision between the first bent parts 111 and 131 respectively formed on the first and second seismic frames 110 and 130 when an earthquake occurs and the support protrusions ( 113 and 133) to prevent a collision between them.

The seismic resilient parts 1 and 2 (210, 220) of the seismic reinforcing material 200 provided in the present invention are formed so that the inner diameter or the spacing between the inner both sides thereof is d3. d3 is formed so that the impact due to the deformation of the earthquake-resistant elastic parts 1 and 2 (210, 220) does not directly affect the earthquake-resistant frame, d3 is formed narrower than d1 or d2.

In the present invention, when the earthquake-resistant elastic parts 1 and 2 (210, 220) are deformed within their elastic range, the earthquake-resistant frame 100 is configured to withstand the impact of an earthquake. That is, even if an external force caused by an earthquake deforms the seismic elastic parts 1 and 2 ( 210 , 220 ), when these seismic elastic parts are deformed within the range of d3, the first and second seismic frames 110 and 130 collide with each other. Therefore, a direct impact caused by an earthquake is not transmitted to the earthquake-resistant frame 100, so that damage to the earthquake-resistant frame can be prevented. In addition, in the above case, after the earthquake has passed, each seismic resilient unit is restored to its original state, and thus the seismic frame 100 is also restored to its original state.

2 to 7, the earthquake-resistant reinforcement 200 and the first and second earthquake-resistant frames 110 and 130 are coupled to the first and second earthquake-resistant frames using a plurality of fixing pieces P1. A screw hole into which the fixing piece P1 is inserted and fixed may be formed in the earthquake-resistant reinforcement 200 and the first and second earthquake-resistant frames 110 and 130, and a direct connection piece that can penetrate the earthquake-resistant frame and the earthquake-resistant reinforcement is used. It is also possible to directly couple these two elements by using the fixing piece P1 without forming a screw hole.

A preferred position in which the fixing piece P1 is inserted is the center of the portion in which the first bent portions 111 and 131 and the side portion 1 230 of the earthquake-resistant reinforcement 200 are in surface contact, as shown in FIG. 2, and the support protrusion 113, 133) and the second side of the earthquake-resistant reinforcement (240) is the center of the surface contact. When coupled with the fixing piece (P1) at this position, the earthquake-resistant reinforcement 200 and the earthquake-resistant frame 100 can be firmly coupled.

Miseogi window of the present invention is provided with an inner cap 300 for closing the indoor end of the earthquake-resistant unit (100). The inner cap 300 closes between the first and second seismic frames 110 and 130 on the indoor side of the seismic frame 100 , and includes the second bent part 114 of the first seismic frame 110 and It is inserted between the second bent portions 134 of the second seismic frame 130 and is a component made of an aluminum material.

The inner cap 300 is configured to include a straight end portion 310, a bent portion 320, and an insertion protrusion 330 as shown in FIG. The straight line closing part 310 is a part of a straight shape that closes between the second bent part 114 of the first earthquake-resistant frame 110 and the second bent part 134 of the second earthquake-resistant frame 130, and a straight-line closing part. Both ends of the 310 are provided with bent portions 320 bent vertically toward the outdoor side, respectively. One insertion protrusion 330 is formed in each of the bent portions 320 on both sides. Each insertion protrusion 330 is elastic in the protrusion insertion grooves 115 and 135 respectively formed in the corners where the second bent portions 114 and 134 and the flat portions 112 and 132 of the first and second earthquake-resistant frames meet. It is designed to be inserted.

The inner cap 300 of the present invention is configured to have a thinner thickness than the seismic frame 100 . The earthquake-resistant frame 100 applied to the present invention, that is, the first and second earthquake-resistant frames 110 and 130 uses an aluminum material having a thickness of about 2.5 mm used in a typical window frame, and the first bent part 111, 131) may be made of an aluminum material having a thickness of about 2.5 to 3.0 mm. The extended coupling part 120, which is slightly elastically deformed by an external force of an earthquake, etc., uses the same aluminum material, but may be configured to be thicker than the first bent part.

The inner cap 300 of the present invention is a means for performing a secondary function for preventing damage to the earthquake-resistant frame 100 in addition to the function of closing the interior side of the earthquake-resistant frame 100 . That is, the inner cap 300 is intended to be damaged first before the earthquake-resistant frame is damaged when an external force due to an earthquake acts on the earthquake-resistant frame 100, and for this purpose, its thickness, in particular. The thickness of the straight end portion 310 is formed to be about 1.5mm thinner than the earthquake-resistant frame 100 by about 1mm.

The thermal insulation fastening member 400 is a means for coupling the earthquake-resistant frame 100 and the external frame 500 in an insulating state.

Insulation fastening member 400 may be formed of the same shape or symmetrical shape on both sides, one side of which is coupled to the extended coupling part 120 of the first earthquake-resistant frame 110 and the other side is coupled to the external frame 500 . . 2 and 3, the extended coupling portion 120 of the first seismic frame 110 and the first assembly 510 of the outer frame 500 are coupled to each other with the heat insulating fastening member 400 interposed therebetween, The extended coupling part 120 and the first assembly 510 each coupled to the heat insulating fastening member 400 may have the same coupling part. The heat insulating fastening member 400 is provided with a plurality of fastening protrusions 410 , and the fastening protrusions 410 are respectively the fastening protrusion insertion groove 123 of the extended coupling part 120 and the fastening protrusion of the first assembly 510 . It is inserted into the insertion groove 511 to couple the earthquake-resistant frame 100 and the external frame 500 .

The outer frame 500 provided in the present invention includes a first assembly 510 made of an aluminum material coupled to the heat insulating fastening member 400, a second assembly 520 made of a material such as Azone having a heat insulating function, and aluminum It is configured to include a third assembly 530 made of a material. The third assembly 530 is a portion coupled to the outer cap 600 . The outer frame 500 provided between the insulating fastening member 400 and the outer cap 600 is configured so that the shock of the earthquake is not directly transmitted. However, when the shock of the earthquake is transmitted to the Miseogi window, the external frame (outer frame) due to the external force of the earthquake transmitted from the earthquake-resistant frame 100 through the insulating fastening member 400, and the effect of the earthquake transmitted through the outer cap 600 500) are also indirectly affected by earthquakes.

The outer cap 600 is coupled to the outer frame 500 on the outdoor side of the building to finish the exterior of the earthquake-resistant units 50 and 60, and is mainly made of aluminum material. A straight end portion 610 formed in a straight shape is provided on the outside of the outer cap 600 . A heat reflective insulating material 620 for reflecting heat transferred from the outdoors to the indoor side may be provided inside the outer cap 600 .

Even in the case of the outer cap 600, it is possible to receive an impact according to the external force of the earthquake transmitted through the wall (W). In this case, the straight end portion 610 of the outer cap 600 is deformed or damaged in a shape similar to that of the inner cap 300 , or the third assembly 530 of the outer frame 500 and the insulating fastening member 400 . Deformation in the form of loosening the bond between them can occur.

As described above, the outer cap 600 of the present invention is responsible for a secondary function of buffering a part of the external force transmitted to the earthquake-resistant frame 100 in addition to the function of closing the outdoor side of the earthquake-resistant unit. That is, when an external force caused by an earthquake acts on the seismic frame 100, the outer cap 600 is first damaged before the seismic frame is damaged or is separated from the outer frame 500 to buffer a part of the external force applied to the windows and doors. is configured to The outer cap 600, in particular, the straight end portion 610 of the outer cap is formed with a thickness of about 1.5 mm, which is about 1 mm thinner than the earthquake-resistant frame 100, similarly to the inner cap 300.

The present invention is configured to absorb most of the shock of the earthquake through the seismic frame 100 formed by being separated into two frames (first and second seismic frames; 110 and 130) to cushion or damp the shock applied to the Miseogi window. and is configured so that additional buffering or damping effects can be expected through the inner cap 300 and the outer cap 600 .

On the other hand, the seismic unit (50, 60) of the present invention is configured to be provided between the window frames (10, 20) and the wall (W) of the Miseogi window, the width of the seismic frame 100 may be limited. Therefore, unlike the previous description, when it is difficult to insert the fixing piece into the center of the surface contact portion, the first and second earthquake-resistant frames 110 and 130 and the earthquake-resistant reinforcement 200 are in surface contact with the fixing piece at an appropriate position. By inserting (P1), the earthquake-resistant reinforcement 200 and the earthquake-resistant frame 100 can be coupled to each other.

The seismic unit of the present invention is to be provided between the vertical or horizontal window frames (10, 20) and the wall (W) of the Miseogi window, and must be firmly coupled to the window frames (10, 20). To this end, the present invention is configured to use another fixing piece (P2) having a long length that can couple the window frame and the seismic unit.

That is, the present invention has a length that can be combined with one of the first or second seismic frames 110 and 130 of the seismic unit after penetrating the upper and lower or left and right parts of the window frame, as shown in FIGS. 2 to 7 and the like. It is configured to fix the earthquake-resistant unit to the window frames (10, 20) using the fixing piece (P2).

The fixing piece (P2) is inserted at an appropriate distance from each other to combine the window frame and the earthquake-resistant unit. The fixing piece P2 may be inserted at a distance of about 50 cm in the longitudinal direction of the window frame.

The present invention, as shown in the accompanying drawings, is configured around a mise window provided with an insulating part 15 for blocking heat transfer made through the window frames 10 and 20, and thus the fixing piece ( P2) is also formed so as to be able to combine the vertical or horizontal window frames 10 and 20 and the seismic units 50 and 60 through a length as much as the thickness of the insulating portion 15.

On the other hand, the seismic unit of the present invention can be applied to a non-seogi window that is not provided with a thermal insulation unit 15 between the window frame and the wall. When the seismic unit of the present invention is applied to the seismic window configured in this way, it is possible to couple the window frames 10 and 20 and the seismic units 50 and 60 to each other by using a fixing piece of a short length. In this case, it is possible to use another fixing piece (P2) having a length similar to that of the fixing piece (P1).

The earthquake-resistant elastic parts 1 and 2 (210, 220) applied to the earthquake-resistant unit of the present invention may be formed in a single semicircular or U-shaped shape as shown in FIGS. 2 and 3, and in FIG. 10 showing another embodiment Likewise, it may be formed in a plurality of U-shaped or W-shaped shapes. Even when the seismic resilient part has a shape as shown in FIG. 10, the range of deformation should be set to be similar to d3 of the previous embodiment to prevent damage to the seismic frame and protect the windows.

In the present invention, when the seismic reinforcing material 200 is deformed due to the impact of an earthquake, the seismic frame 100 has a significant portion of the impact buffered or damped by the elasticity of the seismic resilient parts 1 and 2 (210, 220). However, the external force applied to the second bent portions 114 and 134 of the first and second seismic frames, which are parts without elastic elements, and the straight end portion 310 of the inner cap 300, is not buffered or damped, and the impact can be received, and in this case, the thin inner cap 300 may be damaged first due to the impact. If the inner cap is damaged first, sufficient free space is created between the second bent part 114 and the second bent part 134, so that no further damage occurs in this part, and thus the second bent part ( 114, 134) can be prevented from being damaged.

When an earthquake-induced shock is transmitted to the Miseogi-chang equipped with the earthquake-resistant unit of the present invention configured as described above, the external force of the earthquake on the Miseogi-chang is substantially buffered or attenuated as described below, and the window glass 700 ) and the window frames 10 and 20 and the earthquake-resistant unit 100 are prevented or reduced from being damaged or damaged.

8 is for explaining the phenomenon that the earthquake-resistant unit of the present invention is deformed or partially damaged under the influence of an earthquake, and this view is a first earthquake-resistant frame 110 and a second earthquake-resistant frame 130 under the influence of an external force caused by an earthquake ) indicates a state in which the interval between them is greatly narrowed compared to the normal time. This figure shows that although the gap between the first and second seismic frames 110 and 130 is considerably narrowed, they are still in a non-contact state.

In this state, the elastic protrusion 129 of the extension coupling portion 120 of the first earthquake-resistant frame 110 is separated from the elastic projection insertion groove 139 of the first bent portion 131 of the second earthquake-resistant frame 130 . That is, when an external force large enough to deform the earthquake-resistant elastic part 1 or 2 (210, 220) is transmitted to the earthquake-resistant frame 100, the elastic protrusion 129 of the extended coupling part 120 is formed by the first bent part ( 131), the position is changed as shown in FIG. 8 while momentarily separated from the elastic protrusion insertion groove 139. As shown in FIG. However, despite this deformation, the first and second earthquake-resistant frames 110 and 130 do not collide with each other, and as a result, damage to the window frame or the earthquake-resistant frame 100 can be prevented.

In addition, if the shock of the earthquake is not strong enough to completely deviate from the elastic range of the seismic elastic part 1 or 2 (210, 220) of the present invention, even if the seismic elastic part is momentarily deformed as shown in FIG. 8, the external force of the earthquake disappears. When the seismic resilient portion is immediately restored to its original state, therefore, the first seismic frame 110 and the second seismic frame 130 are also returned to the normal coupled state.

On the other hand, as shown in FIG. 8, when the seismic elastic part is deformed, the inner cap 300, which is relatively weak to external impact, may be damaged. That is, as shown in Figure 8, when an external force sufficient to deform the first and second seismic elastic parts 210 and 220 acts on the Miseogi window, the inner cap 300 that was closing the indoor side of the seismic unit is It may be damaged preferentially, and also, the third assembly 530 of the outer frame 500 may be separated from the outer cap 600 , or the outer cap 600 may be damaged. On the other hand, a part of the shock transmitted to the seismic frame 100 is attenuated in the process in which the above operation is generated in the inner cap 300 and the outer cap 600, and at the same time, the second bending of the first and second seismic frames The parts 114 and 134 are freed from the influence of external force, and the external force transmitted to the window through the outer cap 600 is also partially attenuated.

As described above, the earthquake-resistant unit of the present invention includes elements such as the earthquake-resistant elastic part 1 210, the earthquake-resistant elastic part 2 220, the inner cap 300, the outer frame 500, and the outer cap 600. This buffers or attenuates the impact of the earthquake, thereby effectively preventing the damage of windows and seismic frames.

Figure 4 is a view taken from the horizontal seismic unit 60 of the vertical cross-sectional view of the present invention is applied to the Miseogi window, Figure 5 shows the entire vertical cross-sectional view (part of the glass window is omitted). 4 and 5 show a state in which the seismic unit of the present invention is applied to the horizontal window frame (20).

Figure 6 is a view taken from the vertical seismic unit 50 of the horizontal cross-sectional view of the present invention is applied to the Miseogi window, Figure 7 is a view showing the entire horizontal cross-sectional view (part of the glass window is omitted). 6 and 7 show a state in which the seismic unit of the present invention is applied to the vertical window frame (10).

9 is a view showing another embodiment of the seismic unit of the present invention.

In the configuration according to the embodiment described above of the present invention, any one of the first or second earthquake-resistant frames 110 and 130 of the earthquake-resistant unit is the frame of the vertical or horizontal window frame (10, 20) of the Miseogi window and a fairly large area. It is designed to be in contact with In this case, even though the seismic units 50 and 60 and the window frames 10 and 20 are each provided with a configuration for thermal insulation, the cold air or heat transmitted from the outside of the window frame is transmitted to the room through the seismic frame in contact with the window frame on the outdoor side. transmitted, it is possible to reduce the thermal insulation effect of the miscellaneous window

9 is an embodiment derived to solve this problem, and in the embodiment of FIG. 9, the seismic insulation for insulation between the window frames 10 and 20 frames and the seismic frame 100 of the seismic units 50 and 60 A heat insulating material 150 is provided. When the configuration of this embodiment is applied, heat transfer between the window frame and the earthquake-resistant unit can be effectively blocked.

On the other hand, in FIG. 9, the heat-resistant insulation material 150 is formed over the entire area of the earthquake-resistant frame in contact with the window frame, but only the portion of the window frame frame in contact with the outdoor side of the heat insulating unit 15 and the earthquake-resistant frame is in contact with the insulation insulation 150. ) may be provided, and even in this case, a heat loss prevention effect similar to that of FIG. 9 can be expected.

11 is a view showing a part of the state in which the seismic units 50 and 60 of the present invention are applied to the vertical and horizontal window frames 10 and 20 of the Miseogi window, and FIG. 12 is the seismic unit 50 and 60 of the present invention. It is a drawing showing the overall appearance of the applied Miseogi window.

When the seismic unit of the present invention configured as above is applied to the Miseogi Chang, the following effects can be expected.

First, the present invention can effectively prevent the damage of the window by allowing the shock of the earthquake applied to the vertical or horizontal direction to be buffered or attenuated through the seismic unit. In particular, it is possible to effectively protect Miseogi Chang from an earthquake that is not strong enough to significantly destroy a building, but an earthquake that can deform windows and doors.

In particular, the present invention can effectively buffer or attenuate the impact transmitted to the windows through the earthquake-resistant unit using the elastic force of the earthquake-resistant reinforcement inserted inside the earthquake-resistant frame that is formed separately from the earthquake, thereby preventing the damage of the seismic window caused by the earthquake. can be greatly reduced.

In addition, when the configuration of the present invention is applied, even if some damage occurs to the seismic unit due to an earthquake, if the deformation of the seismic unit due to the earthquake is within the elastic range of the seismic reinforcing material, the seismic frame is not damaged or damaged and the surrounding Only the components of the earthquake-resistant unit are damaged, and the earthquake-resistant unit can be repaired again by replacing the damaged surrounding components centering on the undamaged earthquake-resistant frame. Therefore, it is possible to repair the earthquake-resistant unit without replacing the earthquake-resistant frame, which is a core component of the earthquake-resistant unit, and it is possible to significantly reduce the cost for repair or restoration of windows.

As described above with respect to the present invention in detail, the scope of the present invention is not limited to the contents described above, but can be variously modified or modified within the technical spirit and scope of the present invention. Therefore, modifications or variations obvious to those of ordinary skill in the art and matters corresponding to the scope equivalent thereto should be construed as belonging to the scope of the patent rights of the present invention.

10: vertical window frame 15: insulation part
20: horizontal window frame 30: vertical window frame
40: horizontal window frame 50: vertical seismic unit
60: horizontal seismic unit
100: seismic frame 110: first seismic frame
111: first bent part 112: flat part
113: support projection 114: second bent part
115: projection insertion groove 120: extension coupling part
121: coupling protrusion 1 122: coupling protrusion 2
123: fastening protrusion insertion groove 129: elastic protrusion
130: second seismic frame 131: first bent part
132: flat portion 133: support projection
134: second bent part 135: projection insertion groove
139: elastic protrusion insertion groove 150: heat-resistant insulating material
200: seismic reinforcement
210: earthquake-resistant elastic part 1 220: earthquake-resistant elastic part 2
230: side 1 240: side 2
300: inner cap 310: finished straight part
320: bent part 330: insertion protrusion
400: insulation fastening member 410: fastening protrusion
500: outer frame 510: first assembly
511: fastening projection insertion groove 520; 2nd assembly
530: third assembly
600: outer cap 610: finished straight part
620: heat reflective insulation
700: glass window P1: fixed piece
P2 : Fixing piece W : Wall

Claims (10)

In the Miseogi window provided with an earthquake-resistant unit,
The seismic unit includes a seismic frame 100 consisting of a first seismic frame 110 and a second seismic frame 130;
an earthquake-resistant reinforcement 200 provided on the inside of the earthquake-resistant frame 100;
an inner cap 300 for closing the inner end of the seismic unit;
It is configured to include an outer cap (600) for closing the outer end of the earthquake-resistant unit;
A thermal insulation fastening member 400 fastened to the outdoor side of the earthquake-resistant frame 100,
It is configured to further include an outer frame 500 coupled between the heat insulating fastening member 400 and the outer cap 600,
The first seismic frame 110 has a first bent part 111, a flat part 112, a support protrusion 113, and a second bent part 114 are sequentially connected to each other, and the first bent part ( 111) at the end of the extended coupling portion 120 is formed,
The second seismic frame 130 is formed by sequentially connecting a first bent part 131, a flat part 132, a support protrusion 133, and a second bent part 134,
The earthquake-resistant reinforcing material 200 is provided with an earthquake-resistant elastic part in the center of both sides, respectively,
The seismic frame 100 and the seismic reinforcing material 200 are seismic windows provided with a seismic unit, characterized in that coupled to each other through a plurality of fixing pieces (P1).
The method according to claim 1,
An elastic protrusion 129 is formed on one side of the extended coupling part 120, and an elastic protrusion insertion groove 139 is formed in the first bent part 131, the earthquake-resistant frame 100 and the earthquake-resistant reinforcement ( 200) is coupled, the resilient protrusion 129 is configured to be inserted into the resilient protrusion insertion groove 139, the seismic unit provided with a miseogi window.
The method according to claim 1,
The straight end portion 310 of the inner cap 300 provided between the second bent portion 114 of the first earthquake-resistant frame 110 and the second bent portion 134 of the second earthquake-resistant frame 130 . ) and the thickness of the straight end portion 610 of the outer cap 600 coupled to the outer frame 500, the seismic frame flat portions 112 and 132 and the first and second bent portions ( 111, 131, 114, 134) compared to the thickness is formed to be about 1mm thinner, Miseogi Chang with an earthquake-resistant unit.
The method according to claim 1,
The flat parts 112 and 132 have the longest straight shape in the earthquake-resistant frame 100, and the first bent parts 111 and 131 are at one end thereof, and the second bent part is at the other end thereof. (114, 134) is formed by bending at right angles to the inside of the frame,
Among the flat parts 112 and 132 , the support protrusions 113 and 133 protruding inwardly protrude toward the inside of the frame at positions aligned with the length of the earthquake-resistant reinforcement 200 inserted inside the earthquake-resistant frame 100 . Miseogi Chang with an earthquake-resistant unit, characterized in that it is formed.
3. The method according to claim 2,
The extension coupling part 120 extends from the end of the first bent part 111 in the outdoor direction by the thickness of the first bent part 111 and 131 , and then the first bent part 111 and 131 . ) is bent so as to be parallel to the
A plurality of coupling protrusions are formed on the other side of the extended coupling part 120, and the fastening protrusions 410 of the heat insulating fastening member 400 are inserted into the fastening protrusion insertion grooves 123 formed by the plurality of coupling protrusions. The seismic frame 100 and the heat insulating fastening member 400 is characterized in that configured to be coupled to each other, a seismic unit provided with a Miseogi window.
6. The method according to any one of claims 1 to 5,
The seismic unit is configured by being coupled to any one of the first seismic frame 110 or the second seismic frame 130 and the vertical window frame 10 or the horizontal window frame 20 of the Miseogi window,
The plurality of fixing pieces (P1) are the first bent portions (111, 131) and the center of the portion in which the side portion 1 230 of the earthquake-resistant reinforcement 200 is in surface contact and the support protrusions 113 and 133 and the The side part 2 240 of the earthquake-resistant reinforcement 200 is inserted into the center of the surface-contacting part, and is configured to couple the earthquake-resistant frame 100 and the earthquake-resistant reinforcement 200 with each other,
The seismic unit and the vertical or horizontal window frame (10, 20) of the Miseogi window is coupled through a plurality of other fixing pieces (P2), after the fixing piece (P2) passes through any one of the vertical or horizontal window frame Miseogi Chang with a seismic unit, characterized in that configured to pass through any one of the first or second seismic frame.
7. The method of claim 6,
Miseogi window having an earthquake-resistant unit, characterized in that a diagnostic insulation material 150 is provided between a vertical or horizontal window frame coupled to the earthquake-resistant unit and the first or second earthquake-resistant frame (110, 130).
8. The method of claim 7,
An interval d1 between the ends of the first bent portions 111 and 131 formed in the first and second earthquake-resistant frames 110 and 130, respectively, is formed in the first and second earthquake-resistant frames 110 and 130, respectively. Between the formed support protrusions (113, 133) is configured to be a gap d2,
The inner diameter of the first and second earthquake-resistant elastic parts 210 and 220 respectively provided on the side of the earthquake-resistant reinforcement 200 or the distance between them is configured to be an interval d3,
The interval d3 is set within an elastic range in which the first or second earthquake-resistant elastic part 210 or 220 can prevent damage to the earthquake-resistant frame 100,
The intervals d1 and d2 are formed with the same or similar length,
The interval d3 is characterized in that formed narrower than the interval d1 or d2, Miseogi Chang with a seismic unit.
9. The method of claim 8,
The seismic reinforcing material 200, each of the seismic resilient portions formed in the center of both sides, is formed in one semi-circular or U-shape, or a plurality of U-shaped or W-shaped Miser having an earthquake-resistant unit spear.
10. The method of claim 9,
When the earthquake-resistant elastic part 1 210 and the earthquake-resistant elastic part 2 220 provided on the side of the earthquake-resistant reinforcement 200, respectively, are deformed due to the external force of the earthquake within the range of the interval d3, the first , 2 seismic frames (110, 130) characterized in that configured so as not to collide with each other, Miseogi Chang with a seismic unit.

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