KR102177932B1 - Window assembly with seismic performance - Google Patents

Abstract

The present invention relates to a window assembly with seismic performance. To this end, the window assembly with seismic performance comprises: a first door frame fixed to a building structure; a second door frame connected to the first door frame to be spaced apart from the first door frame by a connector; and a window coupled to a guide rail protruding from the exposed surface of the second door frame. The connector has an H shape having ribs formed on both upper and lower portions thereof to be partially extended so that the first door frame and the second door frame can be distanced from each other and partially connected to each other. Sliding pads are further coupled to the connector to ensure seismic performance in response to the vibrational displacement applied to the first door frame and the second door frame. The sliding pads are coupled to the connector to surround the rib formed on the upper and/or lower portion of the connector so that the first door frame and the second door frame can slide without damage thereto or deformation thereof in response to the vibrational displacement, and thus the seismic performance can be ensured.

Description

Window assembly with seismic performance {WINDOW ASSEMBLY WITH SEISMIC PERFORMANCE}

The present invention relates to a window assembly having seismic performance, and more particularly, by separating a door frame frame installed in a building structure into a first door frame frame and a second door frame frame around a connector inserted therein, in vertical and horizontal directions. The present invention relates to a window assembly having a seismic performance to improve the thermal efficiency of a building structure by effectively blocking heat transfer between indoor and outdoor as well as securing seismic performance in response to vibrational displacement transmitted to the door.

Window (窓戶) refers to various windows or doors installed in openings such as windows or entrances to block the interior space of a building from the outside.

In a building, these windows are essential for lighting or circulation of indoor air, and a rectangular space is provided at a predetermined position on the wall and installed inside the space during construction of the building.

The type or size of windows, or the location or number of installations, etc., are appropriately designed in consideration of the load applied to the building, as well as air conditioning, indoor heat insulation or lighting.

Usually, windows are installed on the wall between the pillars and the pillars, so the vertical loads that the windows cannot handle are not applied to the windows themselves. The vertical load of a building is mainly handled by pillars and bearing walls, and windows and doors play a role that connects the indoors and outdoors.

On the other hand, when strong wind strikes a building or an earthquake occurs, a horizontal load is applied to the building. The horizontal load is a load that shakes the building from side to side and easily collapses the building. Buildings or bridges that collapse in the event of an earthquake are almost caused by horizontal loads.

These external forces cause deformation and breakage of windows and glass breakage.

On the other hand, an example of a window system according to the prior art is disclosed in Korean Utility Model Registration No. 20-0382106 (registered on April 8, 2005, hereinafter referred to as'Patent Document 1').

However, the window system according to the prior art has a problem that it can be easily damaged when an external impact occurs because it cannot properly cope with the load applied in the vertical direction as well as the load applied in the horizontal direction due to an earthquake.

In addition, the window system according to the prior art has a problem in that the thermal efficiency of the building may be degraded because the heat insulation structure that blocks heat transfer between the outdoors and the interior is weak.

Republic of Korea Utility Model Registration No. 20-0382106

The present invention was conceived in consideration of the above problems, and the first object of the present invention is to separate the door frame frame into a first door frame frame and a second door frame frame around a connector inserted therein, thereby In addition to securing the seismic performance in response to the vibrational displacement transmitted to the door, it is intended to provide a window assembly having seismic performance to improve the thermal efficiency of the building by effectively blocking heat transfer between indoors and outdoors.

A second object of the present invention is to allow the connector interposed between the first door frame frame and the second door frame frame to be separated through an elastic means to offset the vertical vibration displacement, and the first, 2 Provides a window assembly with seismic performance that can offset left/right vibration displacement by the elastic restoring force of the elastic plate while guiding the upper/lower vibration by inserting a plurality of elastic plates extending in each connector alternately with each other. There is something.

According to a feature for achieving the above object, the first invention relates to a window assembly having seismic performance, and for this purpose, a first door frame frame fixed to a building structure; And, the first door frame frame through a connector. A second door frame frame connected to be spaced apart from each other; And a window coupled to a guide rail protruding from an exposed surface of the second door frame frame, wherein the connector is spaced apart from each other to be partially connected to the first door frame frame and the second door frame frame. It is made in the form of "工" having a rib partially extended to the first door frame frame and a sliding pad that secures seismic performance in response to the vibration displacement applied to the first door frame frame and the second door frame frame, and the sliding pad is It is combined in a form that wraps up to the ribs formed on the upper and/or lower portions, and is configured to secure seismic performance by moving the sliding position without damage or shape deformation of the first and second door frame frames in response to vibrational displacement. To do.

In the second invention, in the first invention, a plurality of connectors are coupled between the first door frame frame and the second door frame frame at regular intervals, and the spaced portions between the first door frame frame and the second door frame frame are caulked with silicone. Finished, the sliding pad is characterized in that it is configured to lower the coefficient of friction by further forming a hemispherical groove on the surface.

In the third invention, in the first invention, the connector includes first and second connectors that are separated up and down with an elastic means for canceling up and down vibration displacement, and the inside of the first and second connectors, respectively. Consisting of a pair of guide plates partially extending toward and coupling pins linked to long grooves formed on the guide plates of the first and second connectors to link the guide plates of the first and second connectors to each other, the The first and second connectors are characterized in that a plurality of elastic plate portions are alternately inserted into each other on the outer surface of the guide plate so as to offset left/right vibration displacement.

In the fourth invention, in the third invention, the elastic plate portion is formed to have a thin thickness so that elastic force is imparted, and is inserted alternately to guide the up/down vibration, while in the left/right vibration displacement, the elastic restoring force is applied. It characterized in that it is configured to be offset by.

In the fifth invention, in the third invention, the elastic means is any one selected from a coil spring or a leaf spring, the first connector and the second connector each further include a sliding pad, and the sliding pad has an elastic force. It is characterized in that it is composed of a synthetic rubber material that is configured to compensate for vibration displacement while securing a front/rear/left/right flow area between the first door frame frame and the second door frame frame.

According to the window assembly having seismic performance of the present invention, by separating the door frame into a first door frame frame and a second door frame frame around a connector inserted therein, seismic performance in response to vibrational displacement transmitted in vertical and horizontal directions There is an effect that can be secured.

In addition, there is an effect that the connector interposed between the first door frame frame and the second door frame frame is separated by means of an elastic means therebetween, thereby canceling up/down vibration displacement.

In addition, there is an effect of being able to offset the left/right vibration displacement by the elastic restoring force of the elastic plate portion while guiding the vertical vibration by alternately inserting a plurality of elastic plate portions extending from each other to the first and second connectors.

1 is a cross-sectional view of a window assembly having seismic performance according to a first embodiment of the present invention,
2 is an exploded perspective view showing the connector and the sliding pad extracted from FIG. 1,
3 is a cross-sectional view of a window assembly having seismic performance according to a second embodiment of the present invention,
4 is an operation diagram of the connector extracted from FIG. 3.

The following objects, other objects, features, and advantages of the present invention will be easily understood through the following preferred embodiments related to the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms.

Rather, the embodiments introduced herein are provided so that the disclosed content may be thorough and complete, and the spirit of the present invention may be sufficiently conveyed to those skilled in the art.

The embodiments described and illustrated herein also include complementary embodiments thereof.

In this specification, the singular form also includes the plural form unless specifically stated in the phrase. As used in the specification, "comprise" and/or "comprising" does not exclude the presence or addition of one or more other components.

Hereinafter, the present invention will be described in detail with reference to the drawings. In describing the specific embodiments below, various specific contents have been prepared to more specifically describe the invention and to aid understanding. However, readers who have knowledge in this field to the extent that they can understand the present invention can recognize that it can be used without these various specific contents. In some instances, it should be noted in advance that parts that are commonly known in describing the invention and are not significantly related to the invention are not described in order to avoid confusion in describing the invention.

Hereinafter, a window assembly having seismic performance according to the present invention will be described in detail together with the accompanying drawings.

1 is a cross-sectional view of a window assembly having seismic performance according to a first embodiment of the present invention, and FIG. 2 is an exploded perspective view showing a connector and a sliding pad extracted from FIG. 1.

As shown in FIGS. 1 and 2, the present invention separates the door frame frame installed in the building structure into a first door frame frame and a second door frame frame around a connector inserted therein, so that it is transmitted in vertical and horizontal directions. The present invention relates to a window assembly having a seismic performance to improve the thermal efficiency of a building by effectively blocking heat transfer between indoor and outdoor as well as securing seismic performance in response to vibrational displacement.

The window assembly having the seismic performance of the present invention is largely composed of four parts, which is composed of a door frame frame, an earthquake-proof unit, and a window (20).

The door frame frame is connected via a first door frame frame 10a fixed to the building structure and a connector 30 spaced apart from and inserted into the first door frame frame 10a.

Here, the first door frame frame 10a may be directly fixed to the building structure or indirectly fixed to the support frame of the curtain wall.

In addition, the second door frame frame 10b is disposed symmetrically with the first door frame frame 10a, and a plurality of connectors 30 inserted between the first door frame frame 10a and the second door frame frame 10b ) Is connected to the first door frame frame 10a.

At this time, a plurality of guide rails 11 corresponding to the number of windows are protruded on the exposed surface of the second door frame 10b to provide a structure capable of selectively combining multiple windows.

"형태와, "

"형태로 구성될 수 있다.In addition, the first door frame (10a) and the second door frame (10b) are in the form of a hollow, but the upper and lower portions are partially opened so that they can be partially coupled with the connector 30 therebetween."

"With form,"

"It can be configured in the form.

The connector 30 has ribs 311 partially extended on both sides of the upper and lower portions so that the first door frame frame 10a and the second door frame frame 10b can be partially connected to each other so as to secure seismic performance. It takes the form of "工".

The connector 30 has a structure in which a sliding pad 315 for securing seismic performance in response to a vibration displacement applied to the first door frame frame 10a and the second door frame frame 10b is further coupled.

At this time, the sliding pad 315 is coupled to the ribs 311 formed on the upper and/or lower portions of the connector 30 and is coupled to the first door frame frame 10a and the second door frame frame in response to vibration displacement. (10b) It is possible to secure seismic performance by moving the sliding position without damage or shape deformation.

In addition, the sliding pad 315 may further form a hemispherical groove 315a on the surface to lower the coefficient of friction, as well as the front/rear/left/rear between the first door frame frame 10a and the second door frame frame 10b. It is possible to move the sliding position in response to the right vibration.

In addition, the sliding pad 315 may improve heat insulation by first sealing between the first door frame frame 10a and the second door frame frame 10b, and the air layer formed through the groove 315a is heat-insulated. The effect can be further increased.

Meanwhile, since the spaced portion of the first door frame 10a and the second door frame 10b is caulked with silicon 40, the windproof effect can also be expected.

3 is a cross-sectional view of a window assembly having seismic performance according to a second embodiment of the present invention, and FIG. 4 is an operation diagram of the connector extracted from FIG. 3.

As shown in Fig. 3, the second embodiment includes the first embodiment, but the connector 30 is configured to additionally cancel vibration displacement while securing seismic performance.

To this end, the connector 30 is configured to be separated into first and second connectors 31a and 31b that are separated vertically with an elastic means 316 for offsetting the upper/lower vibration displacement therebetween.

Here, the elastic means 316 is preferably any one selected from a coil spring or a plate spring.

In addition, the first and second connectors 31a and 31b link each other with a pair of guide plates 312 partially extending toward the inside, and the guide plates 312 of the first and second connectors 31a and 31b. In order to connect, the first and second connectors 31a and 31b are configured to include a coupling pin 313 that is linked to a long groove 312a formed in the guide plate 312 of the first and second connectors 31a and 31b.

This configuration, as shown in Figure 4 (a), the first and second connectors (31a, 31b) are not separated from each other through the coupling pin 313 coupled to the long groove (312a), while securing a buffer zone while securing the elastic means ( 316) to offset the vertical vibration displacement.

In addition, the first and second connectors 31a and 31b have a configuration in which a plurality of elastic plate portions 314 are alternately inserted into each other on the outer surface of each guide plate 312 so as to offset left/right vibration displacement. .

The elastic plate portion 314 is formed to have a thin thickness so that elastic force is imparted as shown in (b) of FIG. 4, and is inserted alternately to guide the up/down vibration while in the left/right vibration displacement. It is a configuration that can be offset by the elastic restoring force.

At this time, the guide plate 312 of the first connector 31a and the second guide plate 312 of the second connector 31b are connected to each other in a state of being spaced apart from each other, so that the flow space for left/right vibration displacement Can be secured.

In addition, in the second embodiment, the first connector 31a and the second connector 31b are combined with a sliding pad 315 as in the first embodiment, and such a sliding pad 315 is a synthetic rubber having elasticity. It is composed of a material so as to compensate for vibration displacement while securing a front/rear/left/right flow area between the first door frame frame 10a and the second door frame frame 10b.

Since the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention and do not represent all the technical spirit of the present invention, various equivalents that can replace them at the time of application And it should be understood that there may be variations.

10a: first door frame frame 10b: second door frame frame
11: guide rail
20: window
30: connector 31a: first connector 31b: second connector
311: rib 312: guide plate
312a: long groove 313: coupling pin
314: elastic plate portion 315: sliding pad
315a: groove 316: elastic means
40: silicone

Claims (5)

A first door frame frame (10a) fixed to the building structure;
A second door frame frame 10b connected to be spaced apart from the first door frame frame 10a via a connector 30; And
Containing a window 20 coupled to the guide rail 11 protruding from the exposed surface of the second door frame frame 10b,
The connector 30 is formed in a "工" shape having ribs 311 partially extending on both sides of the upper and lower portions so that the first door frame frame 10a and the second door frame frame 10b can be partially connected to each other. The sliding pad 315 for securing seismic performance in response to the vibration displacement applied to the first and second door frame frames 10a and 10b is further coupled,
The sliding pad 315 is coupled to the rib 311 formed on the upper and/or lower portion of the connector 30 and is coupled to the first door frame frame 10a and the second door frame frame 10b in response to vibrational displacement. It is configured to secure seismic performance by moving the sliding position without damage or shape deformation of ).
In the connector, the connector 30 includes first and second connectors 31a and 31b separated up and down with an elastic means 316 for canceling up and down vibration displacement, and the first and second connectors, respectively. The first and second connectors to connect a pair of guide plates 312 partially extending toward the inside of 31a and 31b, and the guide plates 312 of the first and second connectors 31a and 31b. Consisting of a coupling pin 313 that is linked to the long groove 312a formed in the guide plate 312 of (31a, 31b),
The first and second connectors 31a and 31b are characterized in that a plurality of elastic plate portions 314 are alternately inserted into each other on the outer surface of the guide plate 312 so as to offset left/right vibration displacement. A window assembly with seismic performance.
The method of claim 1,
The connector 30 is coupled to a plurality of the first door frame frame (10a) and the second door frame frame (10b) at a predetermined interval, the spaced portion of the first door frame frame (10a) and the second door frame (10b) Is finished by caulking with silicone (40),
The sliding pad 315 is a window assembly having seismic performance, characterized in that it is configured to lower the coefficient of friction by further forming a hemispherical groove portion (315a) on the surface.
delete According to claim 1
The elastic plate part 314 is formed to have a thin thickness so that elastic force is imparted, and is inserted alternately to guide the up/down vibration and is configured to offset the left/right vibration displacement by the elastic restoring force. A window assembly having seismic performance, characterized in that.
The method of claim 1,
The elastic means 316 is any one selected from a coil spring or a plate spring,
Each of the first connector 31a and the second connector 31b further includes a sliding pad 315,
The sliding pad 315 is composed of a synthetic rubber material having elasticity, so as to offset the vibration displacement while securing the front/rear/left/right flow area between the first door frame frame 10a and the second door frame frame 10b. A window assembly having seismic performance, characterized in that it is configured to be able to.

Images