KR102123207B1 - pair glass - Google Patents

Abstract

The present invention relates to new structural double glazed glass, which can be prevented from being broken by typhoons. According to the present invention, in the double glazed glass, when a second glass panel (22) is vibrated by the typhoons or strong winds at a predetermined strength or more, a support bar (50) is moved to central portions of first and second glass panels (21, 22) and an adhering member (52) adheres to the first and second glass panels (21, 22). Therefore, the second glass panel (22) can be prevented from being excessively vibrated to be broken.

Description

Double-layer glass{pair glass}

The present invention relates to a multilayer structure of a new structure that can be prevented from being broken by a typhoon.

In general, the window glass panel provided in the building uses a double-layer glass to improve the sound insulation and heat insulation effect.

1 to 3 show such a double-layer glass, the rim member 10 and the first and second glass panels 21 and 22 arranged to be in close contact with both sides of the rim member 10, and the agent It is composed of a sealing member 30 applied to the circumferential surfaces of the first and second glass panels 21 and 22 to hermetically seal the space between the first and second glass panels 21 and 22.

The rim member 10 is composed of a rectangular rim shape consisting of a horizontal member 11 spaced apart from each other up and down, and a vertical member 12 extending in the vertical direction to support both ends of the horizontal member 11, The horizontal member 11 and the vertical member 12 use a bar made of synthetic resin material.

The first and second glass panels 21 and 22 are formed in a rectangle slightly larger in size than the frame member 10.

The sealing member 30 is configured by applying a general silicone adhesive or the like to the periphery of the first and second glass panels 21 and 22.

And, as described above, after the multilayer glass is produced, the air inside the multilayer glass is discharged to make the inside of the multilayer glass vacuum, or another gas such as nitrogen is injected into the multilayer glass.

Such a double-layer glass has characteristics that are superior in thermal insulation and sound insulation compared to a single-ply glass.

On the other hand, such a double-layer glass is installed on the frame provided in the building, or is installed on a window frame provided with a roller on the lower side, and is coupled to the window frame to be opened and closed.

However, in such a multi-layer glass, the first and second glass panels 21 and 22 are separated from each other, and only the circumference is supported by the rim member 10, such that a high wind pressure is applied, such as a typhoon, or an impact is generated. When applied, there was a problem that the second glass panel 22 could be broken.

Therefore, there is a need for a new method to solve this problem.

Patent No. 10-1330462,

The present invention has been made to solve the above problems, and an object thereof is to provide a multilayer glass having a new structure that can be prevented from being broken by a typhoon.

The present invention for achieving the above object, the border member 10, and the first and second glass panels (21,22) disposed to be in close contact with both sides of the border member 10, the first and first 2 is applied to the circumferential surface of the glass panel (21,22) includes a sealing member (30) for hermetically sealing the space between the first and second glass panels (21,22), the first glass panel (21 ) In the double-layer glass is installed to be located in the interior, the border member 10 is a horizontal member 11 spaced apart from each other up and down, and vertical members extending in the vertical direction to support both ends of the horizontal member 11 (12), a pair of slide blocks 40 slidably coupled to the adjacent surface of the horizontal member 11 in the lateral direction, and extending in the vertical direction, the upper and lower ends coupled to the slide block 40 Support bar 50, slide drive means 60 connected to the slide block 40 to slide the slide block 40 and the support bar 50 in the lateral direction, and the second glass panel 22 It is provided in the vibration detection sensor 71 for detecting the vibration of the second glass panel 22, and is provided in the first glass panel 21 to detect that the steam is standing on the indoor side of the first glass panel 21 The fogging detection means 72 to be provided, and the inside of the first glass panel 21, a photometric measurement sensor 73 for measuring the indoor light intensity, the vibration detection sensor 71 and the fogging detection means 72 ) And a control means (74) that receives signals from the photometric sensor (73), controls the operation of the slide drive means (60) and the support bar (50), and is provided with input means (74a) for user input. ), the support bar 50 is provided so as to extend in the vertical direction, the upper and lower ends are fixed to the slide block 40, and a space portion 51a extending in the vertical direction is formed inside and the front and rear surfaces of the The through-hole 51b connected to the space portion 51a is formed to extend in the vertical direction, and the bar body 51 is coupled to the through-hole 51b so as to be retractable in the front-rear direction and protrudes from the first and second On the inner surface of the glass panel (21,22) The lifting member 53 which is in close contact with the lifting member 53 which is in close contact with the inside of the space portion 51a and is formed of a rod shape extending in the vertical direction, and is connected to the lifting rod 53 for lifting It includes a lifting driving means 54 for elevating the steel bar 53, and a heater 55 provided on a surface in close contact with the first glass panel 21 in the contact member 52, the contact member 52 ) The inner surface of the protrusion 52b is formed, the lifting rod 53 is in close contact with the protrusion 52b of the contact member 52 when the lifting rod 53 is raised, the contact member 52 When the cam surface 53a is formed to protrude to the outside of the bar body 51, the control means 74 receives the signal from the vibration detection sensor 71, and when the outer panel vibrates more than a predetermined strength, By controlling the slide driving means 60, the position of the slide block 40 is adjusted so that the support bar 50 is located at the center of the first and second glass panels 21 and 22, and the lifting driving means ( By raising the lifting rod 53 by controlling 54), the contact member 52 protrudes forward and backward, and is in close contact with the inner and outer side surfaces of the first and second glass panels 21 and 22, so that the second glass panel 22 When receiving the signals of the fogging detection means 72 and the photometric sensor 73, frost is frosted on the first glass panel 21, and when the luminance of the room rises above a predetermined luminance, the heater 55 ) Is turned on to heat the first glass panel 21.

In the double-layer glass according to the present invention, when the second glass panel 22 is vibrated by a typhoon or strong wind or the like, the support bar 50 moves to the central portions of the first and second glass panels 21 and 22. And, the adhesive member 52 is in close contact with the first and second glass panels 21 and 22, and thus has the advantage of preventing the second glass panel 22 from being excessively vibrated and broken.

1 is a front view showing a conventional multilayer glass,
Figure 2 is a perspective view showing an exploded state of a conventional multilayer glass,
Figure 3 is a side cross-sectional view showing a conventional multilayer glass,
Figure 4 is a front view showing a multilayer glass according to the present invention,
Figure 5 is a side cross-sectional view showing a support bar of a multilayer glass according to the present invention,
Figure 6 is a cross-sectional plan view showing a multilayer glass according to the present invention,
Figure 7 is a cross-sectional side view showing a vacuum sensor and a fog sensor and a photometric sensor of the double-layer glass according to the present invention,
8 is a circuit diagram of a multilayer glass according to the present invention,
9 to 11 is a reference diagram showing the operation of the multilayer glass according to the present invention.

Hereinafter, the present invention will be described in detail based on the attached exemplary drawings.

4 to 11 show a double-layer glass according to the present invention, the rim member 10 and the first and second glass panels 21 and 22 arranged to be in close contact with both sides of the rim member 10 and , It is conventional that the sealing member 30 is applied to the circumferential surfaces of the first and second glass panels 21 and 22 to hermetically seal the space between the first and second glass panels 21 and 22. Same as

At this time, the frame member 10 is composed of a horizontal member 11 spaced apart from each other up and down, and a vertical member 12 extending in the vertical direction to support both ends of the horizontal member 11.

Further, a guide rail 11a extending in a lateral direction is provided on an adjacent surface of the horizontal member 11.

In addition, the multi-layered glass configured as described above is installed in the building such that the first glass panel 21 faces the interior.

In addition, according to the present invention, a pair of slide blocks 40 slidably coupled to the adjacent surface of the horizontal member 11 and extending in the vertical direction, the upper and lower ends coupled to the slide block 40 Support bar 50, slide drive means 60 connected to the slide block 40 to slide the slide block 40 and the support bar 50 in the lateral direction, and the second glass panel 22 It is provided in the vibration detection sensor 71 for detecting the vibration of the second glass panel 22, and is provided in the first glass panel 21 to detect that the steam is standing on the indoor side of the first glass panel 21 The fogging detection means 72 to be provided, and the inside of the first glass panel 21, a photometric measurement sensor 73 for measuring the indoor light intensity, the vibration detection sensor 71 and the fogging detection means 72 ) And a control means (74) that receives signals from the photometric sensor (73), controls the operation of the slide drive means (60) and the support bar (50), and is provided with input means (74a) for user input. ) Is further provided.

4 and 5, the slide block 40 is slidably coupled to the guide rail 11a of the horizontal member 11 in the lateral direction.

4 to 6, the support bar 50 is provided to extend in the vertical direction, the upper and lower ends are fixed to the slide block 40, and a space portion 51a extending in the vertical direction is formed therein. The front and rear surfaces of the through-hole 51b connected to the space part 51a are formed to extend in the vertical direction, and the through-hole 51b is coupled to the through-hole in the front-rear direction so as to be protruded. The first and second glass panels 21 and 22 are formed of a contact member 52 that is in close contact with the inner surfaces, and a rod shape extending in the vertical direction, so as to be liftably coupled to the interior of the space portion 51a. A steel rod 53, a lifting driving means 54 connected to the lifting rod 53 to elevate the lifting rod 53, and a surface in close contact with the first glass panel 21 in the contact member 52 It is composed of a heater 55 provided in.

The bar body 51 is composed of a rectangular cross-sectional shape, and the through holes 51b are formed on both side surfaces.

The contact member 52 is made of a high-strength synthetic resin material, and is slidably coupled to the through-hole 51b on the outer surface so that the contact portion 52a in close contact with the through-hole 51b protrudes outward. do.

The lifting rod 53 is provided between the contact member 52.

At this time, a protruding portion 52b is formed on the inner surface of the contact member 52, and when the elevating rod 53 is raised on the elevating rod 53, it is in close contact with the protruding portion 52b of the contact member 52. A cam surface 53a is formed so that the contact member 52 protrudes outward of the bar body 51.

Therefore, as shown in FIGS. 10 and 11, when the lifting rod 53 is raised, the contact member 52 is the outside of the bar body 51 by the action of the protruding portion 52b and the cam surface 53a. Will be pushed out.

The elevating driving means 54 is provided on the inner upper side of the space portion 51a to use a solenoid device connected to the upper end of the elevating rod 53, and normally, as shown in FIG. 5, the elevating rod ( 53) is lowered, and when the power is applied, as shown in FIG. 11, the lifting rod 53 is raised upward.

The heater 55 is configured in a strip shape extending in the vertical direction and uses a planar heating element provided on the outer surface of the contact member 52 contact portion 52a.

The slide driving means 60 is provided on the horizontal member 11 so as to extend in the lateral direction, as shown in FIG. 4, and the central portion is a lead screw screwed to penetrate the slide block 40 in the lateral direction ( 61), and is connected to the lead screw 61 is composed of a drive motor 62 for reversing the lead screw 61 forward and reverse.

At this time, the slide driving means 60 is composed of two is connected to each one of the slide block 40 on the upper and lower sides.

Therefore, when the lead screw 61 is rotated in the forward and reverse directions with the driving motor 62, the slide block 40 slides laterally by the screw action of the lead screw 61, so that the support bar 50 is laterally rotated. It is adjusted to position.

The vibration sensor 71 is provided on the outer surface of the second glass panel 22, as shown in Figures 4 and 7, the second glass panel 22 is vibrated by the wind, the second The strength at which the glass panel 22 is vibrated is measured and output to the control means 74.

As shown in Figure 4, the fogging detection means 72 is fixed to the interior side of the vertical member 12 of the frame member 10 so as to be in close contact with the inner surface of the first glass panel 21, When the light is irradiated to the outside of the first glass panel 21, and light is reflected on the fogging generated on the indoor side of the first glass panel 21, it is received to generate fogging on the first glass panel 21. It is configured to detect things.

The anti-fog detection means 72 is capable of detecting not only the fogging on the first glass panel 21, but also the frost on the inner surface of the first glass panel 21. Since it is generally used, detailed descriptions thereof will be omitted.

The photometric sensor 73 is fixed to the inside of the vertical member 12 of the frame member 10 so as to be in close contact with the inner surface of the first glass panel 21.

The operation of the multilayer glass structured as described above is as follows.

First, as shown in Figures 4 to 6, the support bar 50 is located on one side of the inner side of the double-layer glass, the contact member 52 is in a state retracted into the interior of the bar body 51, the The control means 74 receives the signal from the vibration detection sensor 71, and controls the slide driving means 60 when the second glass panel 22 vibrates over a predetermined strength due to typhoons or strong winds. 9, the support bar 50 is moved to the central portion of the first and second glass panels 21 and 22, and as shown in FIG. 10, the lifting and driving means 54 ) To raise the lifting rod 53, as shown in FIGS. 10 and 11, the contact member 52 of the support bar 50 protrudes forward and backward, and the contact member 52 is removed. The first and second glass panels 21 and 22 are brought into close contact with the inner surfaces.

Thus, when the contact member 52 is in close contact with the inner surfaces of the first and second glass panels 21 and 22, when the second glass panel 22 is vibrated, the vibration of the second glass panel 22 is By being transmitted to the first glass panel 21 and absorbing the vibration of the second glass panel 22, it is possible to prevent the second glass panel 22 from being excessively vibrated and broken.

In addition, when the control means 74 receives the signal of the fogging detection means 72 and detects that there is steaming or frost on the indoor side of the first glass panel 21, the photometric measurement sensor ( 73) when the light intensity in the room is greater than or equal to a predetermined light intensity by receiving the signal of 73), as shown in FIGS. After being brought into close contact with (21,22), the heater 55 is turned on, and the slide driving means 60 is operated to adjust the lateral position of the support bar 50, thereby allowing the heater 55 to The first glass panel 21 is heated to remove fogging and frost.

That is, when the indoor light intensity is less than or equal to the predetermined light intensity, it can be determined that there is no person in the room, so that the user of the room lights up the indoor light to turn on the heater 55 only when the room light is above the predetermined light intensity, thereby eliminating It turns on the heater to prevent wasting electricity.

At this time, the user can control the position of the support bar 50 by operating the input means 74a and input a control command, or manually turn on the heater 55 to heat the inner glass.

When the second glass panel 22 is configured to vibrate at a predetermined strength or higher due to typhoons or strong winds, the supporting glass 50 is moved to the central portions of the first and second glass panels 21 and 22. , The adhesive member 52 is in close contact with the first and second glass panels 21 and 22, so that the second glass panel 22 is prevented from being excessively vibrated and broken.

In addition, when the first glass panel 21 is steamed or frosty, the contact member 52 is in close contact with the first and second glass panels 21 and 22, and the contact member 52 is By heating the first glass panel 21 by turning on the provided heater 55, there is an advantage in that it is very convenient to use, since it can remove fogging and frost.

10. Border member 21,22. First and second glass panels
30. Sealing member 40. Slide block
50. Support bar 60. Slide driving means
71. Vibration detection sensor 72. Kim Seorim detection means
73. Photometric sensor 74. Control means

Claims (1)

Border member 10 and,
First and second glass panels (21,22) disposed to be in close contact with both sides of the frame member (10),
It includes a sealing member 30 is applied to the circumferential surface of the first and second glass panels (21,22) to hermetically seal the space between the first and second glass panels (21,22),
In the double-layer glass is installed so that the first glass panel 21 is located indoors,
The rim member 10 includes a horizontal member 11 spaced apart from each other up and down, and a vertical member 12 extending in the vertical direction to support both ends of the horizontal member 11,
A pair of slide block 40 is slidably coupled to the adjacent surface of the horizontal member 11,
And a support bar 50 extending in the vertical direction and the upper and lower ends coupled to the slide block 40,
The slide block 40 is connected to the slide block 40 and the slide driving means 60 for sliding the support bar 50 in the lateral direction,
A vibration detection sensor 71 provided on the second glass panel 22 to sense vibration of the second glass panel 22;
It is provided on the first glass panel 21, the fogging detection means 72 for detecting that the steam is standing on the indoor side of the first glass panel 21,
A photometric sensor 73 provided inside the first glass panel 21 to measure the luminous intensity on the indoor side,
Receive the signals of the vibration detection sensor 71, the fogging detection means 72 and the photometric measurement sensor 73, control the operation of the slide driving means 60 and the support bar 50, so that the user can input It further comprises a control means (74) provided with an input means (74a),
The support bar 50 is
It is provided so as to extend in the vertical direction, the upper and lower ends are fixed to the slide block 40, a space portion 51a extending in the vertical direction is formed inside, and a through hole 51b connected to the space portion 51a at the front and rear surfaces. The bar body 51 is formed to extend in the vertical direction,
The through-hole (51b) is coupled to the front and rear in a revolving direction, and the contact member (52) in close contact with the inner surfaces of the first and second glass panels (21, 22) when protruding,
The lifting rod 53 is formed of a rod shape extending in the vertical direction and is movably coupled to the inside of the space portion 51a,
An elevation driving means 54 connected to the elevation rod 53 and elevating the elevation rod 53;
The contact member 52 includes a heater 55 provided on a surface in close contact with the first glass panel 21,
The protrusion 52b is formed on the inner surface of the contact member 52,
When the lifting rod (53) is raised to the lifting rod (53), it is in close contact with the protrusion (52b) of the contact member (52) so that the contact member (52) protrudes outward from the bar body (51). 53a) is formed,
The control means 74 receives the signal of the vibration detection sensor 71, and when the outer panel vibrates to a predetermined strength or more, the control drive means 60 controls the slide bar 60 so that the support bar 50 is the first. And adjusting the position of the slide block 40 so as to be located at the center of the second glass panels 21 and 22, and controlling the lifting driving means 54 to raise the lifting rod 53, thereby bringing the contact member 52 into account. ) Protrudes forward and backward so as to adhere to the inner and outer side surfaces of the first and second glass panels 21 and 22 to support the second glass panel 22, the fogging detection means 72 and the photometric sensor 73 When receiving the signal of the frost on the first glass panel 21 and the luminance of the room rises above a predetermined light level, the heater 55 is turned on to heat the first glass panel 21. Double-layer glass.

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