CN212073202U - Energy-saving glass with built-in aerogel composite board - Google Patents

Abstract

The utility model discloses an energy-conserving glass of built-in aerogel composite sheet, including glass main part, silica crystallization layer, nano-ceramics anti-corrosion coating, airtight cavity and epoxy glass steel elastic layer, the bottom in the glass main part outside is provided with the stainless steel back up coat, and the inside of stainless steel back up coat evenly is provided with the stainless steel strip, and the top of stainless steel strip runs through the lateral wall of stainless steel back up coat and the internal connection of glass main part. The utility model discloses an elasticity proportion fibre that sets up in epoxy glass steel elasticity in situ portion is equidistant setting, elasticity proportion fibrous one side overlaps with the fibrous one side of next elasticity proportion, and elasticity proportion fibre is narrow vertical setting about wide, the whole pressure that brings of glass can be alleviated to the elasticity proportion fibre that this glass epoxy glass steel elasticity in situ portion set up when using, make glass's toughness stronger, make glass wholly be difficult to produce under the stronger condition of pressure and break, the life of device has been increased.

Description

Energy-saving glass with built-in aerogel composite board

Technical Field

The utility model relates to an energy-conserving glass technical field specifically is an energy-conserving glass of built-in aerogel composite sheet.

Background

Energy-saving glass usually can keep warm and insulate against heat, and the kind is heat absorption glass, heat reflection glass, low radiation glass, cavity glass, vacuum glass and ordinary glass etc. and energy-saving glass must possess two energy-conserving characteristics: the heat preservation and the heat insulation performance of the glass are to reach the level matched with the local wall, the heat insulation performance of the glass is to be adapted to the sunlight irradiation characteristics of the place of a building, and the existing energy-saving glass still has certain problems and defects in the using process, and the specific problems are as follows:

1. the existing energy-saving glass ensures that the whole glass is easy to break under the condition of strong pressure, thereby shortening the service life of the device;

2. the existing energy-saving glass can not use the structural domain inside the glass sealing device to match with the vent hole when necessary, can not finish the vacuum extraction of the glass internal mechanism, can not finish the compaction of the glass internal materials, and can weaken the hardness degree of the device;

3. the existing energy-saving glass has weak fire resistance, the flame retardant degree of the device is not good, and the burning resistance of the glass is reduced.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an energy-conserving glass of built-in aerogel composite sheet to solve and to provide in the above-mentioned background art make glass wholly produce easily under the stronger condition of pressure and break, shortened the life of device, the fire behavior is more weak, and the device's fire-retardant degree is not good, reduces this glass's resistant fever performance scheduling problem.

In order to achieve the above object, the utility model provides a following technical scheme: an energy-saving glass with a built-in aerogel composite board comprises a glass main body, a silicon dioxide crystallization layer, a nano ceramic anti-corrosion layer, a closed chamber and an epoxy glass reinforced plastic elastic layer, wherein a stainless steel reinforcing layer is arranged at the bottom of the outer side of the glass main body, stainless steel strips are uniformly arranged inside the stainless steel reinforcing layer, the top ends of the stainless steel strips penetrate through the side wall of the stainless steel reinforcing layer and are connected with the inside of the glass main body, the epoxy glass reinforced plastic elastic layer is uniformly arranged at the bottom of the outer side of the stainless steel reinforcing layer, elastic proportion fibers are arranged inside the epoxy glass reinforced plastic elastic layer, a mixed glass adhesive layer is arranged at the top ends of the elastic proportion fibers, the elastic proportion fibers are wrapped outside the mixed glass adhesive layer, a UV crystal adhesive layer is uniformly arranged at the top end of the glass main body, and rubber pads are arranged at the top ends and the bottom, the bottom end of the rubber pad is connected with an inner connecting rod, borosilicate fireproof glass is uniformly arranged at the top of the UV crystal adhesive layer, borosilicate particles are uniformly arranged inside the borosilicate fireproof glass, a silicon dioxide crystal layer is uniformly arranged at the top of the borosilicate fireproof glass, silicon dioxide particles are uniformly arranged inside the silicon dioxide crystal layer, a nano ceramic anti-corrosion layer is uniformly arranged at the top end of the silicon dioxide crystal layer, a closed cavity is uniformly arranged inside the nano ceramic anti-corrosion layer, fixed burrs are uniformly arranged on two sides of the outside of the closed cavity, an air vent is arranged in the middle of the inside of the closed cavity, glass sealing devices are arranged at the top end and the bottom end of the air vent, an inner hose is arranged at the middle of the inside of each glass sealing device, and telescopic rods are arranged at the top end and the bottom end of each glass sealing, first installation is installed to the bottom of telescopic link and is detained, and the top of telescopic link is installed the second installation and is detained, the intermediate position that first installation was detained and the second installation is detained runs through there is rotatory screw rod, and the bottom of rotatory screw rod and stop nut's internal connection.

Preferably, the top end and the bottom end of the silica particles are both connected with the inner side wall of the silica crystal layer, and the top end of the silica particles penetrates through the side wall of the silica crystal layer to be connected with the inside of the nano-ceramic anti-corrosion layer.

Preferably, the nano ceramic interwoven net is arranged in the nano ceramic anti-corrosion layer at equal intervals, the grooves are formed in the top end and the bottom end of the nano ceramic interwoven net at equal intervals, and the nano ceramic interwoven net arranged in the nano ceramic anti-corrosion layer can be used for preventing the surface layer of the glass from being corroded.

Preferably, the diameter of the inside of the closed chamber is larger than that of the vent hole, the vent hole penetrates through the inside of the closed chamber and is connected with the top end and the bottom end of the outside of the closed chamber, the vent hole in the closed chamber can facilitate the air in the glass closed chamber to be pumped out, and the tightness of the device is enhanced.

Preferably, the elasticity proportion fibre that the inside of epoxy glass steel elastic layer set up is equidistant setting, and the fibrous one side of elasticity proportion overlaps with the fibrous one side of next elasticity proportion, and elasticity proportion fibre is narrow vertical setting about wide, and the whole pressure that brings of glass can be alleviated to the inside elasticity proportion fibre that sets up of epoxy glass steel elastic layer when this glass uses for glass's toughness is stronger.

Preferably, the inside borosilicate granule that sets up of borosilicate fire prevention glass is equidistant setting, and the top and the bottom of borosilicate granule all with the quartzy inside wall that glues the layer of UV be connected, the device is at the in-process that uses, the fire behavior is stronger for the device's fire-retardant degree is better.

Preferably, the rubber pads that the quartzy viscose layer of UV inside set up are crisscross setting, and the rubber pad top that the bottom set up is connected with the bottom of connecting interior pole, has strengthened this glass's resistant burning performance, can also utilize stainless steel back up coat and stainless steel strip to place this glass blasting under the roast of high temperature.

Preferably, the bottom of interior hose is connected with the top of air vent, and the bottom of interior hose is connected with the air vent of airtight cavity bottom, and the setting of interior hose can strengthen linking with the air vent.

Compared with the prior art, the beneficial effects of the utility model are that:

(1) according to the energy-saving glass with the built-in aerogel composite board, the elastic proportion fibers arranged in the epoxy glass fiber reinforced plastic elastic layer are arranged at equal intervals, one side of each elastic proportion fiber is overlapped with one side of the next elastic proportion fiber, and the elastic proportion fibers are longitudinally arranged in a manner that the upper part is wide and the lower part is narrow;

(2) according to the energy-saving glass with the built-in aerogel composite board, the airtight chambers are uniformly arranged in the glass, the air vents are arranged in the airtight chambers, the pressure in the airtight chambers can be reduced through the air vents, and the vacuum pumping effect of the internal mechanism of the glass can be completed by mutually matching the inner hoses and the air vents in the structural domain glass sealing device in the glass sealing device when necessary, so that the internal materials of the glass are more compact, and the hardness degree of the device is enhanced;

(3) according to the energy-saving glass with the built-in aerogel composite board, borosilicate particles are arranged in borosilicate fireproof glass at equal intervals, the top ends and the bottom ends of the borosilicate particles are connected with the inner side wall of the UV crystal adhesive layer, and the device is high in fire resistance in the using process, so that the device is high in flame retardant degree, the burning resistance of the glass is enhanced, and the glass can be blasted by using the stainless steel reinforcing layer and the stainless steel bars under the high-temperature baking and burning;

(4) this kind of energy-conserving glass of built-in aerogel composite sheet, through all being connected with the inside wall on silica crystallization layer at silica granule's top and bottom, and silica granule's top runs through the lateral wall on silica crystallization layer and the internal connection on nano-ceramics anti-corrosion coating, and this glass's of realization top layer has stronger corrosion resistance, prevents that the device from being corroded by liquid at the in-process of using, reinforcing device practicality to the life of extension device in the at utmost.

Drawings

Fig. 1 is a schematic side view of the cross-sectional structure of the present invention;

fig. 2 is an enlarged schematic structural view of a point a in fig. 1 according to the present invention;

FIG. 3 is a schematic view of the glass sealing device according to the present invention, showing a partially enlarged top view;

fig. 4 is a schematic top view of the present invention.

In the figure: 1. a glass body; 2. a crystalline layer of silicon dioxide; 201. silica particles; 3. a nano-ceramic anti-corrosion layer; 301. interweaving a nano ceramic net; 4. closing the chamber; 401. fixing burrs; 402. a vent hole; 5. a glass sealing device; 501. a telescopic rod; 502. rotating the screw; 503. a first mounting buckle; 504. a second mounting buckle; 505. a limit nut; 6. an epoxy glass fiber reinforced plastic elastic layer; 601. elastic proportional fiber; 602. mixing the glass adhesive film layer; 7. a stainless steel reinforcement layer; 701. a stainless steel strip; 8. borosilicate fire-resistant glass; 801. borosilicate particles; 9. UV crystal adhesive layer; 901. connecting the inner rod; 902. a rubber pad; 10. an inner hose.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides an embodiment: an energy-saving glass with a built-in aerogel composite board comprises a glass main body 1, a silicon dioxide crystallization layer 2, a nano ceramic anti-corrosion layer 3, a closed chamber 4 and an epoxy glass fiber reinforced plastic elastic layer 6, wherein a stainless steel reinforcing layer 7 is arranged at the bottom of the outer side of the glass main body 1, stainless steel strips 701 are uniformly arranged inside the stainless steel reinforcing layer 7, the top ends of the stainless steel strips 701 penetrate through the side wall of the stainless steel reinforcing layer 7 and are connected with the inner part of the glass main body 1, the epoxy glass fiber reinforced plastic elastic layer 6 is uniformly arranged at the bottom of the outer side of the stainless steel reinforcing layer 7, elastic proportion fibers 601 are arranged inside the epoxy glass fiber reinforced plastic elastic layer 6, a mixed glass adhesive film layer 602 is arranged at the top end of the inner part of the elastic proportion fibers 601, the elastic proportion fibers 601 are wrapped outside the mixed glass adhesive film layer 602, the elastic proportion fibers 601 arranged, one side of the elastic proportion fiber 601 is overlapped with one side of the next elastic proportion fiber 601, and the elastic proportion fiber 601 is arranged in the longitudinal direction with a wide top and a narrow bottom,

during the use, the whole pressure that brings of glass can be alleviated to the inside elasticity proportion fibre 601 that sets up of epoxy glass steel elastic layer 6 when this glass uses for glass's toughness is stronger, makes glass whole be difficult to produce under the stronger condition of pressure and breaks, has increased the life of device.

The top end of the glass main body 1 is uniformly provided with a UV crystal adhesive layer 9, the top end and the bottom end inside the UV crystal adhesive layer 9 are both provided with rubber pads 902, the bottom end of the rubber pads 902 is connected with a connecting inner rod 901, the top end and the bottom end of the UV crystal adhesive layer 9 are both uniformly provided with borosilicate fireproof glass 8, borosilicate particles 801 are uniformly arranged inside the borosilicate fireproof glass 8, the borosilicate particles 801 arranged inside the borosilicate fireproof glass 8 are arranged at equal intervals, the top end and the bottom end of the borosilicate particles 801 are both connected with the inner side wall of the UV crystal adhesive layer 9, the rubber pads 902 arranged inside the UV crystal adhesive layer 9 are arranged in a staggered mode, the top end of the rubber pads 902 arranged at the bottom end is connected with the bottom end of the connecting inner rod 901, the borosilicate particles 801 arranged inside the borosilicate fireproof glass 8 are arranged at equal intervals, and the top end and the bottom end of the borosilicate particles 801 are both connected with the inner side wall of the,

when the glass explosion-proof device is used, the fire resistance of the device is high in the using process, the flame retardant degree of the glass explosion-proof device is high, the burning resistance of the glass is enhanced, and the glass explosion can be carried out by utilizing the stainless steel reinforcing layer 7 and the stainless steel strip 701 under the high-temperature baking and burning.

Borosilicate fire prevention glass 8 top evenly is provided with silica crystallization layer 2, and the inside of silica crystallization layer 2 evenly is provided with silica granule 201, and the top and the bottom of silica granule 201 all are connected with the inside wall of silica crystallization layer 2, and the top of silica granule 201 runs through the inside connection of the lateral wall of silica crystallization layer 2 and nano ceramic anti-corrosion layer 3.

The top of silica crystallization layer 2 evenly is provided with nanometer ceramic anti-corrosion coating 3, and the inside of nanometer ceramic anti-corrosion coating 3 is equidistant to be provided with airtight chamber 4, and the inside diameter of airtight chamber 4 is greater than the diameter of air vent 402, and air vent 402 runs through the inside of airtight chamber 4 and is connected with the outside top and the bottom of airtight chamber 4.

During the use, the airtight chamber 4 is uniformly arranged in the glass, the vent 402 is arranged in the airtight chamber 4, the pressure in the airtight chamber 4 can be reduced by the vent 402, and the inner hose 10 in the structural domain glass sealing device 5 in the glass sealing device 5 can be used to match with the vent 402 to complete the vacuum pumping effect of the glass internal mechanism when necessary, so that the glass is more compact in internal materials, and the hardness of the device is enhanced.

Fixed burrs 401 are arranged on two sides of the outer portion of the closed chamber 4 at equal intervals, vent holes 402 are formed in the middle position of the inner portion of the closed chamber 4, glass sealing devices 5 are mounted at the top ends and the bottom ends of the vent holes 402, inner hoses 10 are arranged in the middle position of the inner portion of the glass sealing devices 5, the bottom ends of the inner hoses 10 are connected with the top ends of the vent holes 402, and the bottom ends of the inner hoses 10 are connected with the vent holes 402 in the bottom of the closed chamber 4.

The provision of the inner hose 10 may enhance engagement with the vent 402 in use.

The top and the bottom of glass sealing device 5 all install telescopic link 501, and first installation is detained 503 in the bottom of telescopic link 501, and the top of telescopic link 501 is installed the second installation and is detained 504, and the rotatory screw rod 502 has been run through to the intermediate position that 503 and second installation were detained 504 in the first installation, and the internal connection of the bottom of rotatory screw rod 502 and stop nut 505.

The working principle is as follows: when in use, firstly, the nano ceramic anti-corrosion layer 3 arranged in the device is matched with the nano ceramic interwoven net 301 to strengthen the corrosion resistance of the whole device, the glass is uniformly provided with the closed chambers 4, the closed chambers 4 are internally provided with the vent holes 402, the pressure in the closed chambers 4 can be reduced by the vent holes 402, and when necessary, the inner hose 10 in the structural domain glass sealing device 5 in the glass sealing device 5 can be matched with the vent holes 402 to complete the vacuum extraction effect of the mechanism in the glass, so that the materials in the glass are more compact, the hardness of the device is strengthened, and the elastic proportion fiber 601 arranged in the epoxy glass fiber reinforced plastic elastic layer 6 can relieve the pressure brought by the whole glass when the glass is used, so that the toughness of the glass is stronger, and the whole glass is not easy to break under the condition of stronger pressure, the life of the device has been increased, borosilicate granule 801 at the inside borosilicate granule that sets up of borosilicate fire prevention glass 8 is equidistant setting, and borosilicate granule 801's top and bottom all are connected with the quartzy inside wall that glues layer 9 of UV, and the device is at the in-process that uses, and the fire behavior is stronger for the flame retardant efficiency of the device is better, has strengthened this glass's resistant burning performance, can also utilize stainless steel back up coat 7 and stainless steel strip 701 to place this glass blasting under the roast burning of high temperature.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (8)

1. The utility model provides an energy-conserving glass of built-in aerogel composite sheet, includes glass main part (1), silica crystallization layer (2), nano-ceramic anticorrosion layer (3), airtight cavity (4) and epoxy glass steel elastic layer (6), its characterized in that: the glass comprises a glass main body (1), and is characterized in that a stainless steel reinforcing layer (7) is arranged at the bottom of the outer side of the glass main body (1), stainless steel strips (701) are uniformly arranged inside the stainless steel reinforcing layer (7), the top ends of the stainless steel strips (701) penetrate through the side wall of the stainless steel reinforcing layer (7) to be connected with the inner part of the glass main body (1), epoxy glass fiber reinforced plastic elastic layers (6) are uniformly arranged at the bottom of the outer side of the stainless steel reinforcing layer (7), elastic proportional fibers (601) are arranged inside the epoxy glass fiber reinforced plastic elastic layers (6), a mixed glass adhesive layer (602) is arranged at the top end of the inner part of the elastic proportional fibers (601), the elastic proportional fibers (601) are wrapped outside the mixed glass adhesive layer (602), a UV crystal adhesive layer (9) is uniformly arranged at the top end of the glass main body (1), and rubber pads (902) are arranged at the, the bottom end of a rubber pad (902) is connected with a connecting inner rod (901), borosilicate fireproof glass (8) is uniformly arranged at the top of a UV crystal adhesive layer (9), borosilicate particles (801) are uniformly arranged in the borosilicate fireproof glass (8), a silicon dioxide crystal layer (2) is uniformly arranged at the top of the borosilicate fireproof glass (8), silicon dioxide particles (201) are uniformly arranged in the silicon dioxide crystal layer (2), a nano ceramic anti-corrosion layer (3) is uniformly arranged at the top end of the silicon dioxide crystal layer (2), a closed chamber (4) is uniformly arranged in the nano ceramic anti-corrosion layer (3) at intervals, fixing burrs (401) are uniformly arranged on two sides of the outside of the closed chamber (4), vent holes (402) are arranged in the middle of the inside of the closed chamber (4), and glass sealing devices (5) are arranged at the top end and the bottom end of the vent holes (402), hose (10) in glass sealing device (5) inside intermediate position is provided with, and telescopic link (501) are all installed to the top and the bottom of glass sealing device (5), and first installation is installed to the bottom of telescopic link (501) and is detained (503), and the top of telescopic link (501) installs the second installation and detain (504), rotatory screw rod (502) have been run through to the intermediate position that (504) were detained in first installation knot (503) and second installation, and the internal connection of the bottom of rotatory screw rod (502) and stop nut (505).

2. The energy-saving glass with the built-in aerogel composite board as claimed in claim 1, wherein: the top end and the bottom end of the silicon dioxide particles (201) are connected with the inner side wall of the silicon dioxide crystallization layer (2), and the top end of the silicon dioxide particles (201) penetrates through the side wall of the silicon dioxide crystallization layer (2) and is connected with the inside of the nano ceramic anti-corrosion layer (3).

3. The energy-saving glass with the built-in aerogel composite board as claimed in claim 1, wherein: the nanometer ceramic anti-corrosion layer (3) is internally provided with nanometer ceramic interwoven nets (301) at equal intervals, and the top ends and the bottom ends of the nanometer ceramic interwoven nets (301) are provided with grooves at equal intervals.

4. The energy-saving glass with the built-in aerogel composite board as claimed in claim 1, wherein: the diameter of the inside of the closed chamber (4) is larger than that of the vent hole (402), and the vent hole (402) penetrates through the inside of the closed chamber (4) and is connected with the top end and the bottom end of the outside of the closed chamber (4).

5. The energy-saving glass with the built-in aerogel composite board as claimed in claim 1, wherein: the elastic proportional fibers (601) arranged in the epoxy glass fiber reinforced plastic elastic layer (6) are arranged at equal intervals, one side of each elastic proportional fiber (601) is overlapped with one side of the next elastic proportional fiber (601), and the elastic proportional fibers (601) are longitudinally arranged in a manner that the upper part is wide and the lower part is narrow.

6. The energy-saving glass with the built-in aerogel composite board as claimed in claim 1, wherein: borosilicate granule (801) of borosilicate fire prevention glass (8) inside setting are the equidistant setting, and the top and the bottom of borosilicate granule (801) all are connected with the inside wall of quartzy viscose layer of UV (9).

7. The energy-saving glass with the built-in aerogel composite board as claimed in claim 1, wherein: rubber pads (902) arranged inside the UV crystal adhesive layer (9) are arranged in a staggered mode, and the top ends of the rubber pads (902) arranged at the bottom are connected with the bottom end of the inner connecting rod (901).

8. The energy-saving glass with the built-in aerogel composite board as claimed in claim 1, wherein: the bottom end of the inner hose (10) is connected with the top end of the vent hole (402), and the bottom end of the inner hose (10) is connected with the vent hole (402) at the bottom of the closed chamber (4).

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