CN112459672A - Compression-resistant door and window - Google Patents

Abstract

The invention relates to the technical field of doors and windows, in particular to a compression-resistant door and window. The invention relates to a compression-resistant door and window, which comprises: the door and window unit comprises a first glass, a second glass, a third glass and a fourth glass which can be spliced with each other; form through splicing the door and window unit by four glass, and first concatenation seam department after the concatenation sets up the cylinder rubber stick, and set up wind-guiding portion in windward side department, wind-guiding portion includes wind-guiding groove and first pressure seat, and, second concatenation seam department after the concatenation sets up the second and presses the seat, and the second presses and has the clearance between the glass of seat and windward side, the accessible transmits direct pressure for the second crossbeam rather than the bellying that submits, direct pressure direct action has been avoided effectively on the glass face, the wind resistance and the direct compressive property of door and window unit have been improved effectively.

Description

Compression-resistant door and window

Technical Field

The invention relates to the technical field of doors and windows, in particular to a compression-resistant door and window.

Background

In the related art, the household doors and windows or the building doors and windows are single-layer glass or are simple in structure, and are easy to break when being subjected to impact and strong wind pressure. Especially in coastal cities, the times of strong wind are more, and if the pressure resistance of household doors and windows or building doors and windows is poorer, window glass is easy to be broken, and personal safety problems are possibly caused.

Although the pressure-resistant door and window disclosed in the related art has good pressure resistance, the size of the door and window is large, and when the door and window bears wind pressure, the size is enlarged, so that the stressed area is increased, and the door and window still has certain inapplicability to the wind pressure resistance.

Disclosure of Invention

The present invention is directed to solving at least one of the problems of the prior art. Therefore, an object of the present invention is to provide a door/window with improved compression resistance by effectively reducing wind force and direct pressure through its own structure.

According to the embodiment of the invention, the pressure-resistant door and window is characterized by comprising the following components:

the door and window unit comprises a first glass, a second glass, a third glass and a fourth glass which can be spliced with each other;

the first glass, the second glass, the third glass and the fourth glass are identical in shape and comprise mirror glass and common glass which form an inner space, and the peripheries of the mirror glass and the common glass are sealed through sealing gaskets to form the sealed inner space; inert gas is filled in the inner space;

the first glass, the second glass, the third glass and the fourth glass are spliced with one another to form a first splicing seam and a second splicing seam;

the first splicing seam is located in the transverse direction of the door and window unit, and the second splicing seam is located in the vertical direction of the door and window unit;

a cylindrical rubber rod close to a wind bearing surface is arranged in the first splicing seam, a wind guide part is arranged along the windward surface of the first splicing seam, and the wind guide part comprises a wind guide groove and a first pressing seat; a first cross beam is arranged on the leeward side of the first splicing seam;

the windward side of the second splicing seam is provided with a second pressing seat, the height of the first pressing seat is larger than that of the first pressing seat, the leeward side of the second splicing seam is provided with a second cross beam, the second cross beam is provided with a protruding portion extending into the second splicing seam, the width of the protruding portion is smaller than that of the second splicing seam, the second pressing seat abuts against the protruding portion, and a gap is formed between the second pressing seat and the windward side.

Furthermore, rubber pads are arranged on the first pressure seat and the windward side of the window unit.

Furthermore, a notch is formed in one side, facing the windward side of the window unit, of the first pressing seat, and the rubber pad is arranged in the notch and bears the shape of an I.

Further, a rubber cushion block is arranged between the second pressing seat and the protruding portion, and the second pressing seat abuts against the protruding portion through the rubber cushion block.

Furthermore, the common glass is the windward side, and the mirror glass is the leeward side.

Further, the inert gas is nitrogen or dry air.

Furthermore, the second cross beam comprises a third cross beam and a fourth cross beam, and the third cross beam and the fourth cross beam are connected through fastening screws.

The invention provides a compression-resistant door and window, which is formed by splicing four pieces of glass, a cylindrical rubber rod is arranged at a first spliced seam after splicing, a wind guide part is arranged at a windward side, the wind guide part comprises a wind guide groove and a first pressing seat, the glass can rotate around the cylindrical rubber rod, the integral rigidity of the door and window unit is changed, the wind guide part can be reversed and guided to two sides of the door and window unit compared with the strong wind direction blown from the windward side, the wind power is effectively reduced, the wind resistance is improved, meanwhile, a second pressing seat is arranged at a second spliced seam after splicing, a gap is formed between the second pressing seat and the windward side glass, the direct pressure can be transmitted to a second cross beam through a protruding part submitted by the second pressing seat, the direct pressure is effectively prevented from directly acting on the glass surface, the direct compression resistance of the door and window unit is effectively improved, and the door and window unit is filled with inert gas, so that the door and window has the advantages of sound insulation, sun protection, beautiful appearance and the like.

Additional aspects and advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

fig. 1 is a schematic view illustrating an overall structure of a compression-resistant door window according to an embodiment of the present invention;

FIG. 2 is a schematic side view of a compression-resistant door window according to an embodiment of the present invention;

fig. 3 is a partial enlarged view at a in fig. 2;

FIG. 4 is a top view of a compression resistant door and window according to an embodiment of the present invention;

fig. 5 is a partially enlarged view at B in fig. 4.

Reference numerals:

a first glass 10; a second glass 11; a third glass 12; a fourth glass 13; a sealing strip 14;

ordinary glass 21; mirror glass 22; an inner space 23;

a first splice seam 30; a cylindrical rubber rod 31; an air guide part 32; a first cross member 33; the air guide groove 321; a first press base 322; notches 323; a rubber pad 34;

a second splice seam 40; a second pressure seat 41; the second cross member 42; a rubber pad 43; and a protrusion 421.

Detailed Description

Embodiments of the present invention will be described in detail below, the embodiments described with reference to the drawings being illustrative, and the embodiments of the present invention will be described in detail below.

A compression-resistant door window according to an embodiment of the present invention will be described with reference to fig. 1 to 4.

As shown in fig. 1 to 4, the door and window according to the embodiment of the present invention includes a door and window unit.

Specifically, the door and window unit comprises a first glass 10, a second glass 11, a third glass 12 and a fourth glass 13 which can be spliced with each other, in some embodiments of the invention, the first glass 10, the second glass 11, the third glass 12 and the fourth glass 13 are the same in shape, and the first glass 10, the second glass 11, the third glass 12 and the fourth glass 13 respectively comprise a mirror glass 22 and a common glass 21, the mirror glass 22 and the common glass 21 are superposed to form an air filling layer with a hollow interior, wherein the mirror glass 22 has a decorative effect, the surface is formed with decorative colors and patterns, the mirror glass 22 is common in buildings such as office buildings, the appearance is attractive and elegant, and the shielding effect is also provided, but the mirror glass 22 absorbs heat seriously, so that the indoor temperature rise of the mirror glass 22 is high, and the common glass 21 is transparent common glass 21, although not decorative, the heat absorbing properties are inferior to the mirror glass 22.

The peripheries of the mirror glass 22 and the common glass 21 are sealed by a sealing gasket to form the sealed inner space 23, and the inner space 23 is sealed by the peripheral sealing strips 14, so that the inner space 23 can be vacuumized or the inner space 23 is filled with inert gas.

Illustratively, the inner space 23 is filled with a layer of dry air, or evacuated to add an inert gas (nitrogen), approximately 8mm thick. The glass not only has the performance of sound insulation, but also has the characteristics of heat insulation, energy conservation, wind resistance, external impact resistance and the like. On the other hand, because the moisture permeability of the hollow glass is very low, the frosting phenomenon can not occur when the hollow glass is used in an environment with large internal and external temperature difference.

For example, for the soundproof effect, the soundproof effect can be reduced by about 30 db or more after installing soundproof windows, for example, by using 5 to 8mm thick plain glass 21. The sound insulation effect of the double-layer glass is about 40%, and the sound insulation effect of the three-layer glass is almost hundred percent. The plastic-steel door and window with good sealing performance can save energy by 30-50%, and can reduce indoor noise to 1/3 outside, and the indoor noise is maintained at about 30 decibels.

Illustratively, dew points also rise at the exterior surface of the compression resistant door window. For example, when the outdoor air speed is 5m/s, the indoor temperature is 20 ℃, and the relative humidity is 60%, the 5mm glass starts to dewing when the outdoor temperature is 8 ℃, the 16mm (5+6+5) hollow glass starts to dewing when the outdoor temperature is-2 ℃ under the same conditions, and the 27mm (5+6+5+6+5) three-layer hollow glass starts to dewing when the outdoor temperature is-11 ℃.

Another important function of the pressure-resistant glass is pressure resistance and typhoon resistance, specifically:

the first glass 10, the second glass 11, the third glass 12 and the fourth glass 13 are spliced with each other to form a first splicing seam 30 and a second splicing seam 40; the first splicing seam 30 is located in the transverse direction of the door and window unit, and the second splicing seam 40 is located in the vertical direction of the door and window unit; namely, the first splicing seam 30 is a transverse symmetry axis of the door and window unit, and the second splicing seam 40 is a vertical symmetry axis of the door and window unit.

In order to clearly describe the technical scheme disclosed in the present application, positions of the first glass 10, the second glass 11, the third glass 12 and the fourth glass 13 of the window and door unit are exemplarily determined, in the embodiment of the present invention, the glass at the upper right corner of the window and door unit is denoted as the first glass 10, the glass at the upper left corner is denoted as the second glass 11, the glass at the lower left corner is denoted as the third glass 12, and the glass at the lower right corner is denoted as the fourth glass 13, so as to conveniently and clearly describe the technical scheme disclosed in the present embodiment.

Specifically, a cylindrical rubber rod 31 close to the wind bearing surface is arranged in the first splicing seam 30, a wind guiding portion 32 is arranged along the windward side of the first splicing seam 30, and the wind guiding portion 32 comprises a wind guiding groove 321 and a first pressing seat 322; a first cross beam 33 is arranged on the leeward side of the first splicing seam 30; because the cylindrical rubber rod 31 is arranged in the first splicing seam 30, when one of the first glass 10, the second glass 11, the third glass 12 and the fourth glass 13 bears wind power, the glass bearing the wind power rotates along the cylindrical rubber rod 31 to buffer the wind power, so that a gap for wind circulation is formed among the glasses, and the wind power is reduced. Further, the wind guiding portion 32 arranged along the first splicing seam 30 can receive wind from the windward side and guide the direction of the wind, so that the wind blows to the two sides of the door and window unit along the wind guiding plate, the force of the wind directly blowing to the glass is reduced, and the wind pressure resistance function is achieved.

The first beam 33 is used for splicing and fixing the first glass 10, the second glass 11, the third glass 12 and the fourth glass 13, and is used for splicing and fixing a plurality of door and window units to form a door and window with a large area.

Specifically, the windward side of the second splicing seam 40 is provided with a second pressing seat 41, and the height of the first pressing seat 322 is greater than that of the first pressing seat 322, so that when the windward side bears direct pressure, the second pressing seat 41 bears the pressure first, and the first pressing seat 322 directly contacting with the glass is prevented from contacting.

Moreover, the leeward side of the second splicing seam 40 is provided with a second beam 42, the second beam 42 is provided with a protruding portion 421 extending into the second splicing seam 40, the width of the protruding portion 421 is smaller than the width of the second splicing seam 40, the second pressure seat 41 abuts against the protruding portion 421, a gap is formed between the second pressure seat 41 and the windward side, so that when the second pressure seat 41 bears pressure, the borne pressure protruding portion 421 can be transmitted to the second beam 42, the second beam 42 is of a hollow structure, the hollow structure can offset a part of the pressure from the protruding portion 421, and therefore the bearing capacity of the second pressure seat 41 is ensured to be weakened, and the gap is formed between the second pressure seat 41 and the windward side of the glass, so that the pressure borne by the second pressure seat 41 cannot be directly transmitted to the windward side of the glass, and a good bearing effect on the glass is achieved.

Furthermore, rubber pads 34 are arranged between the first pressure seat 322 and the windward side of the window unit, and the rubber pads 34 have a certain buffering effect on the pressure between the first pressure seat 322 and the window unit, so that the pressure resistance of the pressure-resistant door/window is further improved.

Furthermore, one side of the first pressure seat 322 facing the windward side of the window unit is provided with a notch 323, the rubber pad 34 is arranged in the notch 323, the rubber pad 34 is in an I shape, the rubber pad 34 is convenient to mount in the design, the rubber pad 34 can be mounted in the notch 323, the first pressure seat 322 and the rubber pad 34 are directly attached to the window unit, mounting convenience is improved, and in the second aspect, the rubber pad 34 can be effectively placed to fall off, and mounting stability of the rubber pad 34 is improved.

Further, in order to effectively increase the buffering acting force between the first pressing seat 322 and the protruding portion 421, a rubber cushion block 43 is disposed between the second pressing seat 41 and the protruding portion 421, and the second pressing seat 41 abuts against the protruding portion 421 through the rubber cushion block 43, so that when the second pressing seat 41 bears the pressure, the pressure can firstly counteract and buffer a part of the pressure through the rubber cushion block 43, and the pressure resistance of the pressure-resistant glass is effectively improved.

Further, ordinary glass 21 is the windward side, mirror glass 22 is the leeward side, because mirror glass 22 has better decorative effect, but the heat absorption performance is better, and breakable, this design is through designing ordinary glass 21 into the windward side, mirror glass 22 designs into the leeward side, and it has inert gas to fill between the two, consequently, guaranteed that this window unit has better aesthetic property, and weakened mirror glass 22's heat absorption performance through inert gas, guarantee that indoor temperature can not rise too high, the comfort level has been improved, and, set up breakable mirror glass 22 into inside, make this window unit have better pressure resistant effect.

Further, the inert gas is nitrogen or dry air, and the internal space 23 is filled with a dry air layer, or the inert gas (nitrogen) is added in a vacuum manner, so that the sound insulation performance is achieved, and the characteristics of heat insulation, energy saving, wind resistance, external impact resistance and the like are achieved. On the other hand, because the moisture permeability of the hollow glass is very low, the frosting phenomenon can not occur when the hollow glass is used in an environment with large internal and external temperature difference.

Further, the second cross beam 42 comprises a third cross beam and a fourth cross beam, and the third cross beam and the fourth cross beam are connected through fastening screws, so that the second cross beam 42 is divided into two parts, the second cross beam 42 can deform due to pressure bearing of the protruding portion 421, strength of glass is affected, and performance of the window unit is further improved through split design.

Other constructions and operations of the compression resistant door and window according to embodiments of the present invention are known to those of ordinary skill in the art and will not be described in detail herein.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be considered as limiting the present invention.

In the description of the present invention, "the first feature" and "the second feature" may include one or more of the features.

In the description of the present invention, the first feature being "on" or "under" the second feature may include the first and second features being in direct contact, and may also include the first and second features being in contact with each other not directly but through another feature therebetween.

In the description of the invention, "above", "over" and "above" a first feature in a second feature includes the first feature being directly above and obliquely above the second feature, or simply means that the first feature is higher in level than the second feature.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an illustrative embodiment," "an example," "a specific example," or "some examples" or the like mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example.

While embodiments of the invention have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the claims and their equivalents.

Claims (7)

1. A compression resistant door and window, comprising:

the door and window unit comprises a first glass, a second glass, a third glass and a fourth glass which can be spliced with each other;

the first glass, the second glass, the third glass and the fourth glass are identical in shape and comprise mirror glass and common glass which form an inner space, and the peripheries of the mirror glass and the common glass are sealed through sealing gaskets to form the sealed inner space; inert gas is filled in the inner space;

the first glass, the second glass, the third glass and the fourth glass are spliced with one another to form a first splicing seam and a second splicing seam;

the first splicing seam is located in the transverse direction of the door and window unit, and the second splicing seam is located in the vertical direction of the door and window unit;

a cylindrical rubber rod close to a wind bearing surface is arranged in the first splicing seam, a wind guide part is arranged along the windward surface of the first splicing seam, and the wind guide part comprises a wind guide groove and a first pressing seat; a first cross beam is arranged on the leeward side of the first splicing seam;

the windward side of the second splicing seam is provided with a second pressing seat, the height of the first pressing seat is larger than that of the first pressing seat, the leeward side of the second splicing seam is provided with a second cross beam, the second cross beam is provided with a protruding portion extending into the second splicing seam, the width of the protruding portion is smaller than that of the second splicing seam, the second pressing seat abuts against the protruding portion, and a gap is formed between the second pressing seat and the windward side.

2. The door and window of claim 1, wherein a rubber pad is provided between the first pressing seat and the window unit at the windward side.

3. The door and window of claim 2, wherein a notch is formed in a side of the first pressing seat facing the windward side of the window unit, and the rubber pad is arranged in the notch and bears an I shape.

4. The door and window of claim 1, wherein a rubber pad is disposed between the second pressing seat and the protrusion, and the second pressing seat abuts against the protrusion through the rubber pad.

5. The compression-resistant door and window of claim 1, wherein the ordinary glass is windward and the mirror glass is leeward.

6. The compression resistant door and window of claim 1 wherein the inert gas is nitrogen or dry air.

7. The compression-resistant door and window of claim 1, wherein the second beam comprises a third beam and a fourth beam, and the third beam and the fourth beam are connected through a fastening screw.

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