CN212174865U - Novel nano energy-saving film - Google Patents

Abstract

The utility model relates to a glass pad pasting technical field specifically discloses a novel energy-conserving membrane of nanometer, including anion reaction layer, HC anti-dazzle layer, glass substrate, HC nanometer anti-infrared barrier layer, the resistant UV layer of nanometer, pressure sensitive adhesive layer and release type layer, HC anti-dazzle layer covers in the top surface of glass substrate, and HC anti-dazzle layer's top surface fixedly connected with anion reaction layer, and one side of glass substrate deviating from HC anti-dazzle layer is equipped with HC nanometer anti-infrared barrier layer, the resistant UV layer of nanometer, pressure sensitive adhesive layer and release type layer outwards in proper order; the utility model discloses an HC anti-infrared barrier layer that sets up, blocking heat energy invasion that can furthest maintains the temperature balance in the relative space, reaches real energy-conservation, consumption reduction, emission reduction's effect, has played good guard action to the environment, through the anion reaction layer that sets up for can decompose, release high concentration negative oxygen ion when the anion reaction layer meets the light, let the air in the space keep fresh along with the moment at any time.

Description

Novel nano energy-saving film

Technical Field

The utility model relates to a glass pad pasting technical field, concretely relates to novel energy-conserving membrane of nanometer.

Background

With the rapid development of Chinese economic construction and the general improvement of the living standard of people, automobiles are not in the past and step forward to families of common people, and the number of accessories on the automobiles is large, wherein the glass film is a technology for attaching the glass film to glass so as to improve the optical performance, the thermal performance and other physical properties of the glass, the glass film is mainly used in the fields of vehicle-mounted glass, building glass and the like, and the automobile film can enable drivers to have wider visual field, so that the occurrence frequency of accidents is effectively reduced.

At present, people are more and more conscious of environmental protection, and people want to use all methods, the environment is improved, in the current life, when the weather is too hot or too cold, people can turn on the air conditioner indoors to control the indoor temperature within a proper range, because the existing glass film has unsatisfactory heat insulation effect, the outside cold air or hot air is easy to transmit to the indoor through the glass, the air conditioner is modulated to a high power mode, and it takes a long time to change the indoor temperature, in which case a large amount of power is consumed, and the air conditioner can also remove a plurality of pollutants in a high-power mode, is not beneficial to protecting the environment, and the ventilation can be realized only when the current glass window needs to be opened, and the indoor air quality is inevitably reduced under the condition that the air conditioner is opened for a long time, so that the normal life of people is influenced.

SUMMERY OF THE UTILITY MODEL

The utility model provides a novel energy-conserving membrane of nanometer to prior art not enough, the utility model provides a possesses advantages such as energy-concerving and environment-protective, fresh air, has solved the unsatisfactory problem of traditional glass pad pasting heat preservation effect.

The utility model discloses a novel energy-conserving membrane of nanometer, prevent dazzling layer, glass substrate, HC nanometer anti-infrared barrier layer, the resistant UV layer of nanometer, pressure sensitive adhesive layer and from the type layer including anion reaction layer, HC prevents dazzling the layer and covers in the top surface of glass substrate, HC prevents dazzling the top surface fixedly connected with anion reaction layer on layer, glass substrate deviates from HC and prevents dazzling one side fixedly connected with HC nanometer anti-infrared barrier layer on layer, HC nanometer anti-infrared barrier layer's the resistant UV layer of bottom fixedly connected with nanometer, the bottom veneer on the resistant UV layer of nanometer is fixed with from the type layer.

The utility model discloses a novel energy-conserving membrane of nanometer, wherein pressure sensitive adhesive layer is the film form structure that the acrylic ester was made, pressure sensitive adhesive layer's thickness is 0.01mm to 0.015mm, pressure sensitive adhesive layer's top and bottom adhere to respectively in the bottom on the resistant UV layer of nanometer and the top from the type layer.

The utility model discloses a novel energy-conserving membrane of nanometer, wherein the resistant UV layer of nanometer is the film form structure that the anti UV plastics of high transparent PC were made, the thickness on the resistant UV layer of nanometer is 0.006mm to 0.009mm, the top coating on the resistant UV layer of nanometer has nanometer anti-aging coating, anti-aging coating's thickness is 0.001mm to 0.004 mm.

The utility model discloses a novel energy-conserving membrane of nanometer, wherein from the film form structure that the type layer was made for PET silicone oil, from the thickness on type layer be 0.005mm to 0.008 mm.

The utility model discloses a novel energy-conserving membrane of nanometer, wherein HC prevents dazzling the film form structure that the layer was made for the polyester substrate, HC prevents dazzling the thickness on layer and is 0.008mm to 0.01 mm.

The utility model discloses a novel energy-conserving membrane of nanometer, wherein the transmittance on the resistant UV layer of nanometer is 15% or 35% or 75%, the thickness on the resistant UV layer of nanometer is 0.005mm to 0.007 mm.

The thickness of the glass substrate is 0.05mm to 0.055mm, the thickness of the negative ion reaction layer is 0.003mm to 0.007mm, and the thickness of the HC nanometer infrared-resistant barrier layer is 0.01mm to 0.015 mm.

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

the utility model discloses a HC anti-infrared barrier layer that sets up, the heat energy separation effect can reach 95% at most, is far above other like products in the market, and furthest blocks the heat energy invasion, maintains the temperature balance in the relative space, and the application makes air conditioner power needn't open very big also can enjoy nice and cool penetrating under the air conditioner environment, reaches real energy-conservation, consumption reduction, emission reduction's effect, has played good guard action to the environment.

The utility model discloses an anion reaction layer that sets up for anion reaction layer can decompose, release high concentration negative oxygen ion when meeting light, lets the air in the space keep fresh along with carving at any time, and high concentration negative oxygen ion can also assist the inside formaldehyde that remains in decomposition space simultaneously, effectively degrades indoor peculiar smell.

The utility model discloses a pressure sensitive adhesive layer that sets up for energy-conserving membrane body has the adhesive capacity of high strength, can prevent when the accident from taking place that the piece that bursts the production causes secondary damage to the human body, with risk control in minimum range.

The utility model discloses a resistant UV layer of nanometer that sets up for energy-conserving membrane can imitate the invasion and attack that blocks ultraviolet entirely, avoids the ultraviolet ray to cause the injury to skin, can effectually prevent that people's skin from becoming black, long spot, anaphylaxis and a series of problems such as skin ageing take place.

Utility model has greatly prolonged the service life of this energy-conserving membrane through the nanometer ageing resistance coating that sets up, and the function utility that can not reduce glass membrane itself also shines through the sunshine of the year of a month.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the application and together with the description serve to explain the application and not to limit the application. In the drawings:

fig. 1 is a schematic view of the explosion structure of the present invention.

In the figure: 1. a negative ion reaction layer; 2. an HC antiglare layer; 3. a glass substrate; 4. an HC nano infrared resistant barrier layer; 5. a nano anti-aging coating; 6. a nano UV resistant layer; 7. a pressure sensitive adhesive layer; 8. and a release layer.

Detailed Description

In the following description, numerous implementation details are set forth in order to provide a more thorough understanding of the present invention. It should be understood, however, that these implementation details should not be used to limit the invention. That is, in some embodiments of the invention, details of these implementations are not necessary. In addition, some conventional structures and components are shown in simplified schematic form in the drawings.

In addition, the descriptions related to "first", "second", etc. in the present invention are only for description purposes, not specifically referring to the order or sequence, and are not intended to limit the present invention, but only to distinguish the components or operations described in the same technical terms, and are not to be construed as indicating or implying any relative importance or implicit indication of the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions in the embodiments may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

Example 1: please refer to fig. 1, the utility model discloses a novel energy-conserving membrane of nanometer, including anion reaction layer 1, HC prevents dazzling layer 2, glass substrate 3, HC nanometer anti-infrared barrier layer 4, the resistant UV layer of nanometer 6, pressure sensitive adhesive layer 7 and from type layer 8, HC prevents dazzling layer 2 and covers in glass substrate 3's top surface, HC prevents dazzling layer 2's top surface fixedly connected with anion reaction layer 1, glass substrate 3 deviates from HC and prevents dazzling layer 2's the anti-infrared barrier layer of one side fixedly connected with HC nanometer 4, HC nanometer anti-infrared barrier layer 4's bottom fixedly connected with nanometer is resistant UV layer 6, the bottom veneer of nanometer is fixed with from type layer 8.

The pressure sensitive adhesive layer 7 is a film-shaped structure made of acrylic ester, the thickness of the pressure sensitive adhesive layer 7 is 0.01mm, and the top and the bottom of the pressure sensitive adhesive layer 7 are respectively adhered to the bottom of the nanometer UV resistant layer 6 and the top of the release layer 8.

The nanometer is able to bear or endure UV layer 6 and is the film form structure that the anti UV plastics of high transparent PC were made, and the top coating on the resistant UV layer 6 of nanometer has nanometer anti-aging coating 5, and the thickness that the resistant UV layer 6 of nanometer is 0.006mm, and the thickness of nanometer anti-aging coating 5 is 0.001 mm.

The release layer 8 is a film-shaped structure made of PET silicone oil, and the thickness of the release layer 8 is 0.005 mm.

The HC anti-glare layer 2 is a film-shaped structure made of a polyester substrate, and the thickness of the HC anti-glare layer 2 is 0.008 mm.

The thickness of the glass substrate 3 is 0.05mm, the thickness of the negative ion reaction layer 1 is 0.003mm, and the thickness of the HC nanometer infrared resistant barrier layer 4 is 0.01 mm.

The transmittance of the nano UV-resistant layer 6 was 15%, and the thickness of the nano UV-resistant layer 6 was 0.005 mm.

When the transmittance of the nano UV-resistant layer 6 is 15%, the infrared ray blocking rate is 97%, the ultraviolet ray blocking rate is 99.99%, and the negative ion release amount is more than 5000 ten thousand/cm³。

Example 2: different from embodiment 1, the thickness of pressure sensitive adhesive layer 7 is 0.012mm, the thickness that the resistant UV layer of nanometer 6 is 0.007mm, the thickness of nanometer anti-aging coating 5 is 0.002mm, the thickness from type layer 8 is 0.006mm, the thickness that layer 2 was prevented dazzling by HC is 0.009mm, the thickness of glass substrate 3 is 0.052mm, the thickness of anion reaction layer 1 is 0.004mm, the thickness of the anti-infrared barrier layer 4 of HC nanometer is 0.012mm, the transmittance that the resistant UV layer of nanometer 6 is 35%, the thickness that the resistant UV layer of nanometer 6 is 0.006 mm.

When the transmittance of the nano UV-resistant layer 6 is 35%, the infrared ray blocking rate is 95%, the ultraviolet ray blocking rate is 99.99%, and the negative ion release amount is more than 5000 ten thousand/cm³。

Example 3: different from embodiment 1, the thickness of pressure-sensitive adhesive layer 7 is 0.013mm, the thickness of the resistant UV layer 6 of nanometer is 0.008mm, the thickness of nanometer anti-aging coating 5 is 0.003mm, the thickness of release layer 8 is 0.008mm, the thickness of HC anti-glare layer 2 is 0.01mm, the thickness of glass substrate 3 is 0.055mm, the thickness of anion reaction layer 1 is 0.005mm, the thickness of HC nanometer infrared-resistant barrier layer 4 is 0.015mm, the luminousness of the resistant UV layer 6 of nanometer is 75%, the thickness of the resistant UV layer 6 of nanometer is 0.007 mm.

When the transmittance of the nano UV resistant layer 6 is 75%, the infrared ray blocking rate is 93%, the ultraviolet ray blocking rate is 99.99%, and the negative ion release amount is more than 5000 ten thousand/cm³。

The working principle is as follows: after the air conditioner is opened indoors, the HC nanometer infrared resistant barrier layer 4 can prevent external heat from penetrating through the glass surface to the maximum extent, indoor temperature balance can be maintained, the power of the air conditioner can be changed rapidly without being opened completely, the effects of energy conservation, consumption reduction and emission reduction are achieved, a good protection effect is achieved on the external environment, negative oxygen ions with high concentration can be decomposed and released after the negative ion reaction layer 1 is illuminated, the indoor oxygen concentration is improved under the condition of ventilation without opening a window, the concentration of carbon dioxide is reduced, indoor residual formaldehyde can be decomposed simultaneously, and the purpose of improving the indoor air quality is achieved.

The above description is only an embodiment of the present invention, and is not intended to limit the present invention. Various modifications and changes may occur to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the scope of the claims of the present invention.

Claims (7)

1. The utility model provides a novel energy-conserving membrane of nanometer, includes that anion reaction layer, HC prevent dazzling layer, glass substrate, HC nanometer anti-infrared barrier layer, nanometer are able to bear or endure UV layer, pressure sensitive adhesive layer and leave the type layer, its characterized in that: HC prevents dazzling the layer and covers in glass substrate's top surface, HC prevents dazzling the top surface fixedly connected with anion reaction layer on layer, glass substrate deviates from HC and prevents dazzling the anti infrared barrier layer of one side fixedly connected with HC nanometer on layer, the resistant UV layer of bottom fixedly connected with nanometer of the anti infrared barrier layer of HC nanometer, the bottom veneer on the resistant UV layer of nanometer is fixed with from the type layer.

2. The novel nano energy-saving film as claimed in claim 1, wherein: the pressure-sensitive adhesive layer is of a film-shaped structure made of acrylic ester, the thickness of the pressure-sensitive adhesive layer is 0.01 mm-0.015 mm, and the top and the bottom of the pressure-sensitive adhesive layer are respectively adhered to the bottom of the nanometer UV-resistant layer and the top of the release layer.

3. The novel nano energy-saving film as claimed in claim 1, wherein: the nanometer is able to bear or endure UV layer for the film form structure that highly transparent PC anti UV plastics were made, the thickness that the layer was able to bear or endure UV of nanometer is 0.006mm to 0.009mm, the top coating on layer is able to bear or endure UV of nanometer has nanometer anti-aging coating, anti-aging coating's thickness is 0.001mm to 0.004 mm.

4. The novel nano energy-saving film as claimed in claim 1, wherein: the release layer is a film-shaped structure made of PET silicone oil, and the thickness of the release layer is 0.005 mm-0.008 mm.

5. The novel nano energy-saving film as claimed in claim 1, wherein: the HC anti-glare layer is of a film-shaped structure made of a polyester substrate, and the thickness of the HC anti-glare layer is 0.008 mm-0.01 mm.

6. The novel nano energy-saving film as claimed in claim 1, wherein: the transmittance of the nano UV resistant layer is 15% or 35% or 75%, and the thickness of the nano UV resistant layer is 0.005 mm-0.007 mm.

7. The novel nano energy-saving film as claimed in claim 1, wherein: the thickness of the glass substrate is 0.05mm to 0.055mm, the thickness of the negative ion reaction layer is 0.003mm to 0.007mm, and the thickness of the HC nanometer infrared-resistant barrier layer is 0.01mm to 0.015 mm.

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