CN211222354U - Radiation-resistant fireproof low-E glass - Google Patents

Radiation-resistant fireproof low-E glass Download PDF

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CN211222354U
CN211222354U CN201922071242.0U CN201922071242U CN211222354U CN 211222354 U CN211222354 U CN 211222354U CN 201922071242 U CN201922071242 U CN 201922071242U CN 211222354 U CN211222354 U CN 211222354U
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glass
low
fireproof
fire
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殷文忠
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Nanjing Yingrun Door And Window Technology Co ltd
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Nanjing Yingrun Door And Window Technology Co ltd
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Abstract

The utility model discloses a radiation-resistant fireproof low-E glass, which comprises a fireproof composite film layer, a fireproof glass layer, an electromagnetic radiation shielding layer, an anti-reflection film layer and a low-E low-radiation energy-saving glass layer; this novel simple structure, it is nimble convenient to use, the commonality is good, can effectively satisfy the rationality and the reliability that have improved low-E glass structure overall arrangement on the one hand, very big reduction low-E glass maintenance operation's intensity of labour and cost to improved low-E glass and used the stability of operation, on the other hand can be when effectively simplifying low-E glass structure, play good fire prevention time long, thermal-insulated effectual, anti electromagnetic radiation effect is strong effect, and improved security and the reliability of using.

Description

Radiation-resistant fireproof low-E glass
Technical Field
The utility model relates to a low-E glass technical field, concretely relates to radiation-resistant fire prevention low-E glass.
Background
Along with the rapid development of national construction, urban high-rise buildings are more and more, public facilities such as high-speed rails, subways and the like are more and more popularized, and in order to protect the safety of people and public property, the health of people, fire safety, electromagnetic radiation prevention safety and national defense safety become more and more important; the fireproof glass can meet the lighting requirement, and has the functions of smoke insulation, heat insulation and flame retardation in case of fire, so that the fireproof glass is widely used; the fireproof characteristic of the fireproof glass can provide precious time for rescue in the case of fire, so that the safety of personnel is protected to the maximum extent, and the guarantee is provided for reducing property loss to the maximum extent.
The fireproof glass sold in the market at present mainly comprises a single piece of fireproof glass, grouting fireproof glass, film fireproof glass, composite fireproof glass and the like; although they play a positive role in preventing fires, they are poor in integrity after more than 2.0h, which is detrimental to post-disaster recovery.
The existing anti-electromagnetic radiation glass is wire mesh laminated glass consisting of an interlayer rubber sheet and a blackened wire mesh between two layers of organic glass, the surface color of the glass can be yellowed when the glass is exposed in the air for a long time in the use process, the reduction of the silver streak resistance is obvious, and the organic glass has low surface hardness and is easy to scratch.
Therefore, there is a need in the art for a fireproof and electromagnetic radiation resistant glass with long fireproof time, good heat insulation effect and electromagnetic radiation resistance.
SUMMERY OF THE UTILITY MODEL
To the not enough that exists on the prior art, the utility model provides a radiation-resistant fire prevention low-E glass, this novel simple structure, it is nimble convenient to use, the commonality is good, can effectively satisfy the rationality and the reliability that have improved low-E glass structural layout on the one hand, very big reduction low-E glass maintenance operation's intensity of labour and cost, and improved low-E glass and used the stability of operation, on the other hand can be when effectively simplifying low-E glass structure, play good fire prevention time long, thermal-insulated effectual, the effect that anti-electromagnetic radiation is strong, and improved security and the reliability of using.
In order to achieve the above purpose, the utility model adopts the following technical scheme:
a radiation-resistant fireproof low-E glass comprises a fireproof composite film layer, a fireproof glass layer, an electromagnetic radiation shielding layer, an anti-reflection film layer and a low-E low-radiation energy-saving glass layer; the fireproof composite film layer is arranged on the upper surface of the electromagnetic radiation prevention shielding layer and is distributed in parallel with the axis of the electromagnetic radiation prevention shielding layer, the fireproof glass layer is positioned between the fireproof composite film layer and the electromagnetic radiation prevention shielding layer, the electromagnetic radiation prevention shielding layer is arranged on the upper surface of the low-radiation energy-saving glass layer and is distributed in parallel with the axis of the low-radiation energy-saving glass layer, and the anti-reflection film layer is positioned between the electromagnetic radiation prevention shielding layer and the low-radiation energy-saving glass layer; the thickness of the fireproof composite film layer is 0.78-1.66 nm, the thickness of the fireproof glass layer is 1.32-2.66 nm, the thickness of the electromagnetic radiation shielding layer is 0.55-1.68 nm, the thickness of the antireflection film layer is 1.23-1.56 nm, and the thickness of the low-radiation energy-saving low-emissivity glass layer is 45-108 nm; and the fireproof composite film layer, the fireproof glass layer, the electromagnetic radiation prevention shielding layer, the anti-reflection film layer and the low-e low-radiation energy-saving glass layer are all formed by gluing through sealant.
Further, be provided with the fire prevention cavity between compound rete of fire prevention and the fire prevention glass layer, the fire prevention cavity height is 1.53nm-2.33nm, fire prevention cavity internal surface both sides all are provided with fire-retardant strip, fire-retardant strip internal surface is provided with the fire prevention strip, fire prevention strip axis and the coaxial distribution of fire-retardant strip axis, be provided with the fire prevention sealing strip between fire-retardant strip surface and the fire prevention cavity contact, fire prevention sealing strip axis and the coaxial distribution of fire-retardant strip axis.
Furthermore, a fireproof sealant is arranged between the flame-retardant strip and the fireproof sealing strip, and the axis of the fireproof sealant and the axis of the flame-retardant strip are coaxially distributed.
Further, an LED luminescent glass layer is arranged between the fireproof glass layer and the electromagnetic radiation prevention shielding layer, and the thickness of the LED luminescent glass layer is 0.18-0.26 nm.
Further, a picture film layer is arranged between the fireproof glass layer and the LED light-emitting glass layer, and the thickness of the picture film layer is 0.22nm-0.45 nm.
Furthermore, a fireproof adhesive layer is arranged between the LED luminescent glass layer and the electromagnetic radiation prevention shielding layer, and the thickness of the fireproof adhesive layer is 0.26nm-0.44 nm.
Further, a flame-retardant adhesive tape layer is arranged between the electromagnetic radiation shielding layer and the antireflection film layer, and the thickness of the flame-retardant adhesive tape layer is 0.11nm-0.22 nm.
Furthermore, at least one surface glass layer is arranged on the upper surface of the fireproof composite film layer, and the surface glass layer is Low-E high borosilicate glass with the thickness of 0.5mm-2 mm.
Furthermore, at least one bottom glass layer is arranged on the lower surface of the Low-E Low-radiation energy-saving glass layer, and the bottom glass layer is Low-E microcrystalline glass with the thickness of 1.2mm-3 mm.
Furthermore, the low-radiation energy-saving low-e glass layer comprises a first glass substrate, a second Si3N4 film layer, a third AZO film layer, a fourth Cu film layer and a fifth NiCr film layer which are sequentially arranged from bottom to top; the thickness of the first glass substrate is 5-8nm, the thickness of the second Si3N4 film layer and the thickness of the third AZO film layer are both 10-30nm, and the thickness of the fourth Cu film layer and the thickness of the fifth NiCr film layer are both 15-20 nm.
Adopt above-mentioned technical scheme, the beneficial effects of the utility model are that:
the utility model provides a resistant radiation fire prevention low-E glass, this novel simple structure, it is nimble convenient to use, the commonality is good, can effectively satisfy on the one hand and improve low-E glass structure layout's rationality and reliability, very big reduction low-E glass maintenance work's intensity of labour and cost to improve low-E glass and use the stability of operation, on the other hand can effectively simplify to loThe w-E glass structure simultaneously has the functions of long fireproof time, good heat insulation effect and strong electromagnetic radiation prevention effect, and improves the use safety and reliability.
Drawings
Fig. 1 is a schematic structural view of a radiation-resistant fireproof low-E glass of the present invention.
Detailed Description
For making the utility model discloses the technological means, creation characteristic, achievement purpose and efficiency that realize are easily understood and are known, combine specific implementation below, further explain the utility model discloses:
therefore, the following detailed description of the embodiments of the present invention, which is provided in the accompanying drawings, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention, and all other embodiments that can be obtained by one of ordinary skill in the art without any inventive effort based on the embodiments of the present invention are within the scope of the invention.
It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.
The terms "first," "second," "third," and the like are used solely to distinguish one from another and are not to be construed as indicating or implying relative importance.
In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; the two elements may be directly connected or indirectly connected through an intermediate medium, and the two elements may be connected through an intermediate medium.
In conjunction with FIG. 1: a radiation-resistant fireproof low-E glass comprises a fireproof composite film layer 1, a fireproof glass layer 2, an electromagnetic radiation prevention shielding layer 3, an anti-reflection film layer 4 and a low-E low-radiation energy-saving glass layer 5; the fireproof composite film layer 1 is arranged on the upper surface of the electromagnetic radiation prevention shielding layer 3 and is distributed in parallel with the axis of the electromagnetic radiation prevention shielding layer 3, the fireproof glass layer 2 is positioned between the fireproof composite film layer 1 and the electromagnetic radiation prevention shielding layer 3, the electromagnetic radiation prevention shielding layer 3 is arranged on the upper surface of the low-radiation energy-saving low-radiation glass layer 5 and is distributed in parallel with the axis of the low-radiation energy-saving low-radiation glass layer 5, and the anti-reflection film layer 4 is positioned between the electromagnetic radiation prevention shielding layer 3 and the low-radiation energy-saving low-radiation glass layer 5; the thickness of the fireproof composite film layer 1 is 0.78-1.66 nm, the thickness of the fireproof glass layer 2 is 1.32-2.66 nm, the thickness of the electromagnetic radiation prevention shielding layer 3 is 0.55-1.68 nm, the thickness of the anti-reflection film layer 4 is 1.23-1.56 nm, and the thickness of the low-radiation energy-saving low-radiation glass layer 5 is 45-108 nm; and the fireproof composite film layer 1, the fireproof glass layer 2, the electromagnetic radiation prevention shielding layer 3, the anti-reflection film layer 4 and the low-e low-radiation energy-saving glass layer 5 are all formed by gluing through sealant.
Wherein, be provided with fire prevention cavity 10 between compound rete of fire prevention 1 and the fire prevention glass layer 2, fire prevention cavity 10 highly is 1.53nm-2.33nm, fire prevention cavity 10 internal surface both sides all are provided with fire-retardant strip 20, fire-retardant strip 20 internal surface is provided with fire prevention strip 30, fire prevention strip 30 axis and the coaxial distribution of fire-retardant strip 20 axis, be provided with fire sealing strip 40 between fire-retardant strip 20 surface and the fire prevention cavity 10 contact, fire sealing strip 40 axis and the coaxial distribution of fire-retardant strip 20 axis.
Meanwhile, a fireproof sealant 50 is arranged between the flame-retardant strip 20 and the fireproof sealing strip 40, and the axis of the fireproof sealant 50 and the axis of the flame-retardant strip 20 are coaxially distributed.
In addition, an LED luminescent glass layer 60 is arranged between the fireproof glass layer 2 and the electromagnetic radiation prevention shielding layer 3, and the thickness of the LED luminescent glass layer 60 is 0.18nm-0.26 nm.
Preferably, a picture film layer 70 is arranged between the fireproof glass layer 2 and the LED light-emitting glass layer 60, and the thickness of the picture film layer 70 is 0.22nm-0.45 nm.
Preferably, a fireproof adhesive layer 80 is arranged between the LED luminescent glass layer 60 and the electromagnetic radiation shielding layer 3, and the thickness of the fireproof adhesive layer 80 is 0.26nm to 0.44 nm.
Notably, a flame-retardant adhesive tape layer 90 is arranged between the electromagnetic radiation shielding layer 3 and the antireflection film layer 4, and the thickness of the flame-retardant adhesive tape layer 0 is 0.11nm-0.22 nm.
Further optimally, the upper surface of the fireproof composite film layer 1 is provided with at least one surface glass layer 100, and the surface glass layer 100 is Low-E high borosilicate glass with the thickness of 0.5mm-2 mm.
Preferably, at least one bottom glass layer 110 is arranged on the lower surface of the Low-E Low-radiation energy-saving glass layer 5, and the bottom glass layer 110 is Low-E glass ceramics with the thickness of 1.2mm-3 mm.
It is important to explain that the low-e low-radiation energy-saving glass layer 5 comprises a first glass substrate 51, a second Si3N4 film 52, a third AZO film 53, a fourth Cu film 54 and a fifth NiCr film 55 which are sequentially arranged from bottom to top; the thickness of the first glass substrate 51 is 5-8nm, the thickness of the second Si3N4 film layer 52 and the thickness of the third AZO film layer 53 are both 10-30nm, and the thickness of the fourth Cu film layer 54 and the thickness of the fifth NiCr film layer 55 are both 15-20 nm.
This novel simple structure, it is nimble convenient to use, the commonality is good, can effectively satisfy the rationality and the reliability that have improved low-E glass structure overall arrangement on the one hand, very big reduction low-E glass maintenance operation's intensity of labour and cost to improved low-E glass and used the stability of operation, on the other hand can be when effectively simplifying low-E glass structure, play good fire prevention time long, thermal-insulated effectual, anti electromagnetic radiation effect is strong effect, and improved security and the reliability of using.
The present embodiment is not intended to limit the shape, material, structure, etc. of the present invention in any form, and all of the technical matters of the present invention belong to the protection scope of the present invention to any simple modification, equivalent change and modification made by the above embodiments.

Claims (10)

1. A radiation-resistant fireproof low-E glass is characterized in that: comprises a fireproof composite film layer, a fireproof glass layer, an electromagnetic radiation prevention shielding layer, an anti-reflection film layer and a low-e low-radiation energy-saving glass layer; the fireproof composite film layer is arranged on the upper surface of the electromagnetic radiation prevention shielding layer and is distributed in parallel with the axis of the electromagnetic radiation prevention shielding layer, the fireproof glass layer is positioned between the fireproof composite film layer and the electromagnetic radiation prevention shielding layer, the electromagnetic radiation prevention shielding layer is arranged on the upper surface of the low-radiation energy-saving glass layer and is distributed in parallel with the axis of the low-radiation energy-saving glass layer, and the anti-reflection film layer is positioned between the electromagnetic radiation prevention shielding layer and the low-radiation energy-saving glass layer; the thickness of the fireproof composite film layer is 0.78-1.66 nm, the thickness of the fireproof glass layer is 1.32-2.66 nm, the thickness of the electromagnetic radiation shielding layer is 0.55-1.68 nm, the thickness of the antireflection film layer is 1.23-1.56 nm, and the thickness of the low-radiation energy-saving low-emissivity glass layer is 45-108 nm; and the fireproof composite film layer, the fireproof glass layer, the electromagnetic radiation prevention shielding layer, the anti-reflection film layer and the low-e low-radiation energy-saving glass layer are all formed by gluing through sealant.
2. The radiation-resistant fire-resistant low-E glass according to claim 1, wherein: be provided with the fire prevention cavity between fire prevention composite film layer and the fire prevention glass layer, the fire prevention cavity height is 1.53nm-2.33nm, fire prevention cavity internal surface both sides all are provided with fire-retardant strip, fire-retardant strip internal surface is provided with the fire prevention strip, fire prevention strip axis and the coaxial distribution of fire-retardant strip axis, be provided with the fire prevention sealing strip between fire-retardant strip surface and the fire prevention cavity contact, fire prevention sealing strip axis and the coaxial distribution of fire-retardant strip axis.
3. A radiation-resistant fire-resistant low-E glass according to claim 2, wherein: and a fireproof sealant is arranged between the flame-retardant strip and the fireproof sealing strip, and the axis of the fireproof sealant and the axis of the flame-retardant strip are coaxially distributed.
4. The radiation-resistant fire-resistant low-E glass according to claim 1, wherein: an LED luminous glass layer is arranged between the fireproof glass layer and the electromagnetic radiation prevention shielding layer, and the thickness of the LED luminous glass layer is 0.18-0.26 nm.
5. A radiation-resistant fire-resistant low-E glass according to claim 1 or 4, wherein: and a picture film layer is arranged between the fireproof glass layer and the LED light-emitting glass layer, and the thickness of the picture film layer is 0.22-0.45 nm.
6. The radiation-resistant fire-resistant low-E glass as claimed in claim 5, wherein: a fireproof adhesive layer is arranged between the LED luminescent glass layer and the electromagnetic radiation prevention shielding layer, and the thickness of the fireproof adhesive layer is 0.26nm-0.44 nm.
7. The radiation-resistant fire-resistant low-E glass as claimed in claim 6, wherein: and a flame-retardant adhesive tape layer is arranged between the electromagnetic radiation prevention shielding layer and the antireflection film layer, and the thickness of the flame-retardant adhesive tape layer is 0.11nm-0.22 nm.
8. The radiation-resistant fire-resistant low-E glass according to claim 1, wherein: at least one surface glass layer is arranged on the upper surface of the fireproof composite film layer, and the surface glass layer is Low-E high borosilicate glass with the thickness of 0.5mm-2 mm.
9. The radiation-resistant fire-resistant low-E glass according to claim 1, wherein: at least one bottom glass layer is arranged on the lower surface of the Low-E Low-radiation energy-saving glass layer, and the bottom glass layer is Low-E microcrystalline glass with the thickness of 1.2mm-3 mm.
10. A radiation-resistant fire-resistant low-E glass according to claim 1 or 9, wherein: the low-radiation energy-saving low-emissivity glass layer comprises a first glass base layer, a second Si3N4 film layer, a third AZO film layer, a fourth Cu film layer and a fifth NiCr film layer which are sequentially arranged from bottom to top; the thickness of the first glass substrate is 5-8nm, the thickness of the second Si3N4 film layer and the thickness of the third AZO film layer are both 10-30nm, and the thickness of the fourth Cu film layer and the thickness of the fifth NiCr film layer are both 15-20 nm.
CN201922071242.0U 2019-11-26 2019-11-26 Radiation-resistant fireproof low-E glass Active CN211222354U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN201922071242.0U CN211222354U (en) 2019-11-26 2019-11-26 Radiation-resistant fireproof low-E glass

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN201922071242.0U CN211222354U (en) 2019-11-26 2019-11-26 Radiation-resistant fireproof low-E glass

Publications (1)

Publication Number Publication Date
CN211222354U true CN211222354U (en) 2020-08-11

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Application Number Title Priority Date Filing Date
CN201922071242.0U Active CN211222354U (en) 2019-11-26 2019-11-26 Radiation-resistant fireproof low-E glass

Country Status (1)

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CN (1) CN211222354U (en)

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