CN219825741U - Vacuum low-carbon power generation shading glass - Google Patents

Abstract

The utility model discloses vacuum low-carbon power generation shading glass, and relates to the technical field of glass curtain walls; the vacuum low-carbon power generation shading glass comprises: the transparent solar cell layer, the toughened vacuum glass layer, the sound insulation layer, the dimming layer and the first toughened glass substrate are sequentially laminated from outside to inside; the sound insulation layer and the dimming layer are clamped between the tempered vacuum glass layer and the first tempered glass substrate through the adhesive film. According to the utility model, the transparent solar cell panel, the toughened vacuum glass, the sound insulation film, the dimming film and the toughened glass substrate are used as layer structures to form the vacuum low-carbon power generation shading glass, so that the transparency requirement of the vacuum low-carbon power generation shading glass is ensured, the overall attractiveness of the vacuum glass is improved, and the photovoltaic productivity, heat preservation, sound insulation, energy conservation, eavesdropping prevention and shading/light transmission control are realized. And secondly, the glass in the utility model is completely toughened glass plates, so that the risk of fragmentation is avoided, and the reliability of the vacuum low-carbon power generation shading glass in the processes of production, preparation, transportation, construction and the like is ensured.

Description

Vacuum low-carbon power generation shading glass

Technical Field

The utility model belongs to the technical field of glass curtain walls, and particularly relates to vacuum low-carbon power generation shading glass.

Background

In public building design, a large amount of glass curtain wall is used, and the heat preservation and energy conservation of the whole building are generally influenced, so that the operation cost in the later stage of the building is greatly increased. Conventional building curtain wall systems generally cannot meet the composite functional requirements of capacity, heat preservation, sound insulation, energy conservation, attractive appearance, light transmission and the like.

Disclosure of Invention

In view of the above, an objective of the present utility model is to provide a vacuum low-carbon power generation shading glass, so as to solve the problem that the conventional building curtain wall system in the prior art cannot meet the requirement of the composite function.

In some illustrative embodiments, the vacuum low-carbon power generation shading glass comprises: the transparent solar cell layer, the toughened vacuum glass layer, the sound insulation layer, the dimming layer and the first toughened glass substrate are sequentially laminated from outside to inside; the sound insulation layer and the dimming layer are clamped between the tempered vacuum glass layer and the first tempered glass substrate through adhesive films.

In some alternative embodiments, the transparent solar cell layer and the tempered vacuum glass layer are combined through a hollow structure or a sandwiching structure.

In some alternative embodiments, the transparent solar cell layer and the toughened vacuum glass layer are combined through a hollow structure, and specifically comprises: the transparent solar cell layer is hermetically combined with the toughened vacuum glass layer through surrounding spacer bars; wherein, the molecular sieve contacted with the air in the hollow structure is fixed on the spacing bar.

In some alternative embodiments, the transparent solar cell layer is a thin film solar cell panel or a crystalline silicon solar cell panel.

In some alternative embodiments, the vacuum low-carbon power generation shading glass further comprises: a heat dissipation layer containing a transparent cooling medium is formed between the second toughened glass substrate between the toughened vacuum glass layer and the sound insulation layer and the toughened vacuum glass layer; the sound insulation layer and the dimming layer are clamped between the second toughened glass substrate and the first toughened glass substrate through adhesive films.

In some alternative embodiments, the heat dissipation layer includes heat dissipation channels that allow the transparent cooling medium to circulate.

In some alternative embodiments, the tempered vacuum glass layer is a single layer structure or a double layer structure.

In some alternative embodiments, a getter is disposed within the tempered vacuum glass layer.

In some alternative embodiments, the vacuum low-carbon power generation shading glass further comprises: the solar cell controller is electrically connected with the transparent solar cell layer; the solar storage battery is electrically connected with the solar battery controller; the solar inverter is electrically connected with the solar storage battery, is used for converting direct current into alternating current and is electrically connected with an alternating current bus; the solar inverter is electrically connected with the dimming layer; wherein, electrochromic film is selected for the light modulation layer.

In some alternative embodiments, a nano-photocatalyst layer is disposed on a side of the transparent solar cell layer away from the tempered vacuum glass layer.

Compared with the prior art, the utility model has the following advantages:

according to the utility model, the transparent solar cell panel, the toughened vacuum glass, the sound insulation film, the dimming film and the toughened glass substrate are used as layer structures to form the vacuum low-carbon power generation shading glass, so that the transparency requirement of the vacuum low-carbon power generation shading glass is ensured, and the overall attractiveness of the vacuum glass is improved; realizing light Fu Channeng of the vacuum glass by using a solar panel; the heat preservation, sound insulation and energy conservation of the vacuum glass are realized by utilizing the toughened vacuum glass layer; the sound insulation layer is utilized to further improve the sound insulation effect of the vacuum glass, so that the eavesdropping prevention effect is achieved; the light shielding/light transmission control of the vacuum glass is realized by using the light modulation film. And secondly, the glass in the utility model is completely toughened glass plates, so that the overall structural strength of the vacuum low-carbon power generation shading glass is improved, the risk of fragmentation is avoided, and the reliability of the vacuum low-carbon power generation shading glass in the processes of production, preparation, transportation, construction and the like is ensured.

Drawings

FIG. 1 is a schematic illustration of a vacuum low-carbon power generation shading glass according to an embodiment of the present utility model;

FIG. 2 is a schematic diagram of a second embodiment of a vacuum low-carbon power generation shading glass according to the present utility model;

FIG. 3 is a structural example III of a vacuum low-carbon power generation shading glass in an embodiment of the utility model;

fig. 4 is a structural example four of a vacuum low-carbon power generation light shielding glass in an embodiment of the present utility model;

FIG. 5 is a block diagram of an example of a control system for a vacuum low-carbon power generation glass according to an embodiment of the present utility model;

fig. 6 is a structural example two of a control system of a vacuum low-carbon power generation shading glass in an embodiment of the utility model.

Detailed Description

Reference will now be made in detail to the various embodiments of the present disclosure, examples of which are illustrated in the accompanying drawings. When described in connection with these embodiments, it should be understood that the embodiments are not intended to limit the disclosure to these embodiments. On the contrary, the present disclosure is intended to cover alternatives, modifications and equivalents, which may be included within the spirit and scope of the disclosure as defined by the appended claims. Furthermore, in the following detailed description of the present disclosure, numerous specific details are set forth in order to provide a thorough understanding of the present disclosure. However, it is understood that the present disclosure may be practiced without these specific details. In other instances, well-known methods, procedures, components, and circuits have not been described in detail so as not to unnecessarily obscure aspects of the present disclosure.

It should be noted that, all the technical features in the embodiments of the present utility model may be combined with each other without conflict.

The embodiment of the utility model discloses vacuum low-carbon power generation shading glass, and particularly as shown in fig. 1-4, fig. 1 is a structural example I of the vacuum low-carbon power generation shading glass in the embodiment of the utility model; fig. 2 is a structural example two of a vacuum low-carbon power generation shading glass in an embodiment of the utility model; FIG. 3 is a structural example III of a vacuum low-carbon power generation shading glass in an embodiment of the utility model; fig. 4 is a structural example four of a vacuum low-carbon power generation light shielding glass in an embodiment of the present utility model; the vacuum low-carbon power generation light shielding glass 100 includes: the transparent solar cell layer 1, the toughened vacuum glass layer 2, the sound insulation layer 3, the dimming layer 4 and the first toughened glass substrate 5 are sequentially stacked from outside to inside; the sound insulation layer 3 and the dimming layer 4 are clamped between the tempered vacuum glass layer and the first tempered glass substrate through an adhesive film 6.

The inner side and the outer side in the embodiment of the utility model refer to the inner side or the outer side of the building when the vacuum glass is installed and constructed, or whether the solar cell layer directly irradiates sunlight, namely the solar cell layer directly irradiates sunlight, and the inner side is the other side far away from the sunlight.

In the embodiment of the present utility model, the sound insulation layer 3 and the light modulation layer 4 are clamped between the tempered vacuum glass layer and the first tempered glass substrate by using a glue film, for example, three layers of glue films or liquid glue films (i.e., a first glue film 601, a second glue film 602 and a third glue film 603) are used to realize compounding.

Preferably, the vacuum low-carbon power generation shading glass in the embodiment of the utility model can further comprise: a third tempered glass substrate 7, which is located between the sound insulation layer 3 and the light modulation layer 4, for example, the sound insulation layer 3 is clamped between the tempered vacuum glass layer 2 and the third tempered glass substrate 7 through a fourth adhesive film 604 and a fifth adhesive film 605, and the light modulation layer 4 is clamped between the third tempered glass substrate 7 and the first tempered glass substrate 5 through a fifth adhesive film 606 and a seventh adhesive film 607.

The vacuum low-carbon power generation shading glass in the embodiment is characterized in that the sound insulation layer and the dimming layer are compounded through the toughened vacuum glass layer, the third toughened glass substrate and the first toughened glass substrate, the sound insulation layer and the dimming layer are prevented from being directly compounded, the bonding strength between the sound insulation layer and the dimming layer is low, and the problem of easy tearing and breakage is solved.

According to the utility model, the transparent solar cell panel, the toughened vacuum glass, the sound insulation film, the dimming film and the toughened glass substrate are used as layer structures to form the vacuum low-carbon power generation shading glass, so that the transparency requirement of the vacuum low-carbon power generation shading glass is ensured, and the overall attractiveness of the vacuum glass is improved; realizing light Fu Channeng of the vacuum glass by using a solar panel; the heat preservation, sound insulation and energy conservation of the vacuum glass are realized by utilizing the toughened vacuum glass layer; the sound insulation layer is utilized to further improve the sound insulation effect of the vacuum glass, so that the eavesdropping prevention effect is achieved; the light shielding/light transmission control of the vacuum glass is realized by using the light modulation film. And secondly, the glass in the utility model is completely toughened glass plates, so that the overall structural strength of the vacuum low-carbon power generation shading glass is improved, the risk of fragmentation is avoided, and the reliability of the vacuum low-carbon power generation shading glass in the processes of production, preparation, transportation, construction and the like is ensured.

The transparent solar cell layer in the embodiment of the utility model can be a thin film solar cell panel or a crystalline silicon solar cell panel. The thin film solar panel has low cost, small thickness and easy mounting; while the crystalline silicon solar cell panel has a larger thickness, the photoelectric conversion rate is higher than that of the thin film solar cell panel. Fig. 1 shows a bonding structure of a crystalline silicon solar cell panel, and fig. 3 shows a bonding structure of a thin film solar cell panel.

At present, the transmittance of the transparent solar cell layer on the market can reach more than 70%, but the cost is high, so the transparent solar cell layer in the embodiment of the utility model can be a transparent solar cell panel with the transmittance of 10-50%, has low cost and is suitable for large-scale laying.

In addition, the transparent solar cell layer mainly depends on the light-transmitting substrate, the transparent line/electrode (transparent material or structure such as indium tin oxide, metal mesh, etc.) to realize the light transmittance, and this part is well known in the art and will not be described herein.

The tempered vacuum glass layer 2 in the embodiment of the utility model is exemplified by tempered vacuum glass, which means a vacuum glass structure formed by using 2 or more tempered glass plates, and has structural strength far higher than that of common vacuum glass, easy assembly and high assembly reliability, and is not easy to damage in the process of being overlapped and combined with the transparent solar cell layer 1 and other tempered glass plates (such as the first tempered glass plate 5). On the other hand, the structural strength of the toughened glass plate is far higher than that of common glass, so that the number of supporters between glass plates can be reduced when the toughened glass plate is used for manufacturing a vacuum glass structure, and the transparency and the aesthetic feeling of the vacuum glass are improved.

Preferably, the getter 203 directly contacting the vacuum environment is arranged in the tempered vacuum glass layer 2 in the embodiment of the present utility model, so as to maintain the vacuum state in the tempered vacuum glass layer; specifically, at least one toughened glass plate in the toughened vacuum glass layer is provided with a storage window 204, and the getter 203 is fixed in the storage window 204.

For example, for the tempered vacuum glass layer 2 with a single-layer structure, the tempered vacuum glass layer 2 is obtained by sealing the periphery of 2 tempered glass plates (namely, a third tempered glass plate 201 and a fourth tempered glass layer 202), a through object placing window 204 is formed on any one of the 2 tempered glass plates, a getter 203 is fixed in the object placing window 204, an airtight cover plate 205 is arranged on one side, away from the other tempered glass plate, of the tempered glass plate to seal the object placing window 204, an airtight protection cover 206 is arranged outside the airtight cover plate 205, and the getter 203 is in direct contact with the vacuum environment inside the airtight cover plate.

In some embodiments, an air-permeable protection cover 210 is disposed on a side of the tempered glass plate away from the other tempered glass plate to seal the placement window 204, so as to prevent the getter 203 from falling out of the placement window 204, and affect the aesthetic feeling of the vacuum glass.

For example, for the tempered vacuum glass layer 2 with a double-layer structure, the tempered vacuum glass layer 2 is obtained by sequentially laminating 3 tempered glass plates (namely, a fifth tempered glass layer 207, a sixth tempered glass layer 208 and a seventh tempered glass layer 209) through peripheral sealing, a through object placing window 204 is arranged on the tempered glass layer in the middle, the getter 203 is fixed in the object placing window 204, and two sides of the tempered glass plates are respectively provided with an air-permeable protection cover (not shown) to seal the object placing window 204, so that the getter 203 is ensured to be in direct contact with the vacuum environment on two sides of the tempered glass plates.

Preferably, the getter is enclosed in a breathable film, which is glued directly to the inner wall of the storage window, so as to achieve the fixation of the breathable film, the breathable protection cover can be omitted, and the structure is simple, easy to implement and aesthetic.

The transparent solar panel and the toughened vacuum glass are two products in the cross-field, the transparent solar panel and the toughened vacuum glass are purchased and integrated respectively by an integrator, in the integration process, in order to further improve the heat preservation, energy conservation and sound insulation performance of the vacuum glass, the two products are generally subjected to vacuum combination in a vacuum furnace, so that a new vacuum layer is formed between the two parts, and the performance of the vacuum glass is improved, but the toughened vacuum glass adopts a toughened glass plate with higher strength, but the structural strength of the conventional transparent solar panel is weaker, and the transparent solar panel is easy to break or deform in the vacuum combination process and has lower reliability; on the other hand, the vacuum combination process needs to be provided with a vacuum operation furnace, and has high cost, great difficulty and difficult implementation.

For this reason, the transparent solar cell layer 1 and the tempered vacuum glass layer 2 in the embodiment of the present utility model may be combined by a hollow structure or a sandwiching structure.

The adhesive-sandwiched structure is that an adhesive film (such as a third adhesive layer 8) is formed on at least one surface of the transparent solar cell layer 1 opposite to the toughened vacuum glass layer 2, and the two layers are combined in an adhesive manner; preferably, the bonding mode of the adhesive clamping structure is particularly suitable for selecting a thin film solar panel, and the thin film solar panel has weak structural strength and is easy to deform, so that the bonding is not facilitated by using a hollow structure or a vacuum structure. It should be understood by those skilled in the art that the crystalline silicon solar panel may be bonded to the tempered vacuum glass layer by a lamination method. Preferably, the adhesive film in this embodiment may be an adhesive film, and is attached to the surface of the tempered vacuum glass layer by means of a film coating, so that the adhesive film is combined with the transparent solar cell layer 1.

The hollow structure is to seal and combine the transparent solar cell layer 1 and the tempered vacuum glass layer 2 by surrounding spacer 901 and sealant 902 in a non-vacuum environment. In this embodiment, an air layer is formed between the transparent solar cell layer 1 and the tempered vacuum glass layer 2 instead of a vacuum layer, and the air layer is not as good as the vacuum layer, but has a certain effect on heat preservation and energy saving, and can also meet the use requirements of the vacuum glass. On the other hand, the hollow structure between the transparent solar cell layer 1 and the toughened vacuum glass layer 2 is realized by utilizing the spacer 901 in combination with the sealant 902, and the transparent solar cell layer 1 is not damaged easily due to the fact that a large negative pressure effect does not exist on the transparent solar cell layer 1, so that the thickness of the hollow layer can be adjusted according to the needs of a user, and the whole thickness of the whole vacuum glass is adjusted according to the mode of adjusting the thickness of the spacer 901, thereby meeting the actual requirements of different building assemblies and improving the adaptation flexibility of the vacuum glass.

Preferably, the molecular sieve 903 contacting with the air in the hollow structure is fixed on the spacer 901, and the molecular sieve 903 faces the air layer inside and directly contacts with the air, so as to absorb the water molecule substances in the air, avoid generating water vapor, and influence the transparency and the aesthetic feeling of the vacuum glass.

Illustratively, the sound insulation layer 3 in the embodiment of the present utility model is used for blocking or disturbing the transmission of sound at two sides of the sound insulation layer, so as to play a role in sound insulation and anti-eavesdropping; although the vacuum layer has a certain sound insulation effect, some supporters still exist in the vacuum layer to play a role in supporting, so that a certain discount is generated on the sound insulation effect due to the existence of the supporters, and the sound insulation layer 3 in the embodiment of the utility model can further improve the sound insulation effect of the vacuum low-carbon power generation shading glass, even the effect of preventing eavesdropping, and the sound insulation requirement of the vacuum low-carbon power generation shading glass is ensured.

Specifically, the sound insulation layer 3 in the embodiment of the utility model can be a PVB interlayer film, which not only has good sound insulation effect, but also has certain heat preservation and ultraviolet ray isolation performances, so that the performances of the vacuum low-carbon power generation shading glass are enhanced or supplemented.

Preferably, the sound insulation layer 3 in the embodiment of the present utility model may also be a sound insulation layer with a multi-layer structure, which specifically may include: the transparent soundproof cotton material layer, the outside bonding on transparent soundproof cotton material layer is connected with transparent butyl rubber material layer, and the outside bonding on transparent butyl rubber material layer 302 is connected with transparent acoustic celotex board material layer, and the outside bonding on transparent acoustic celotex board material layer is connected with transparent fiber acoustic celotex board material layer, and the outside bonding on transparent fiber acoustic celotex board material layer is connected with transparent acoustic celotex felt material layer.

The multilayer structure of the present example provides a sound barrier layer that is superior in sound insulation, uv resistance, etc. to conventional PVB interlayer films.

The dimming layer 4 in the embodiment of the utility model can be an electrochromic film, and has the advantages of low price, stable performance, long service life and the like compared with other dimming films.

The transparent solar cell layer 1 in the embodiment of the utility model can be provided with a nano photocatalyst layer 10 at one side far away from the toughened vacuum glass layer 2; the nano photocatalyst layer 10 can be made of titanium dioxide material, so that the working efficiency of the solar cell layer is improved.

Optionally, the vacuum low-carbon power generation shading glass in the embodiment of the utility model can further comprise: the heat dissipation layer 11 is used for reducing the temperature of the vacuum low-carbon power generation shading glass and avoiding the problem of overheating or scalding caused by touching of a user; in addition, the heat dissipation layer 11 can also prevent the dimming layer from being affected by high temperature.

For example, the heat dissipation layer 11 in the embodiment of the present utility model may be disposed on one side of the tempered vacuum glass layer 2 close to the solar cell layer 1 (not shown, the structural design of which only needs to satisfy the interlayer of 2 tempered glass plates), or the heat dissipation layer 11 may be disposed on one side of the tempered vacuum glass layer 2 far from the solar cell layer 1.

Specifically, the heat dissipation layer 11 realizes its layer structure through sealing strips around through 2 toughened glass plates.

Preferably, the vacuum low-carbon power generation shading glass can further comprise: a second tempered glass substrate 12 between the tempered vacuum glass layer 2 and the sound insulation layer 3, and a heat dissipation layer 11 containing a transparent cooling medium is formed between the tempered vacuum glass layer 2; the sound insulation layer 3 and the dimming layer 4 are clamped between the second toughened glass substrate 12 and the first toughened glass substrate 5 through adhesive films.

As is well known, solar panels absorb and generate a large amount of heat during the operation, and even though the heat is blocked by tempered vacuum glass, the heat can have a great influence on the glass at the inner side, so that the user can feel overheated or even scalded. The above problems can be effectively reduced through the heat dissipation layer 11, but in terms of protecting a user, when the heat dissipation layer 11 is arranged on one side of the toughened vacuum glass layer 2 close to the solar cell layer 1, the heat dissipation efficiency requirement for the heat dissipation layer is high, which is not beneficial to energy conservation and emission reduction, so the applicant finds that the heat dissipation efficiency of the heat dissipation layer 11 can be reduced on the premise that the heat dissipation layer 11 avoids high temperature to reduce user experience or cause user injury due to the heat insulation effect of the toughened vacuum glass layer 2 by designing the heat dissipation layer 11 on one side of the toughened vacuum glass layer 2 away from the solar cell layer 1.

Preferably, the heat dissipation layer 11 in the embodiment of the present utility model includes a heat dissipation channel that allows the transparent cooling medium to circulate. That is, the sealing strip at the periphery of the heat dissipation layer 11 is provided with a pipe orifice 1101 (i.e. at least comprising a circulation inlet and a circulation outlet) and is communicated with a circulation system (not shown) of the cooling medium, and the circulation system is used for circulating and cooling the cooling medium in the heat dissipation layer 11. The circulation system in the embodiment has simple structure, only needs one pump in terms of driving force, and has low cost and easy implementation.

Further, a circulation inlet and a circulation outlet on the heat dissipation layer 11 are located at the upper side of the vacuum glass 100 to ensure sufficient circulation of the cooling medium in the heat dissipation layer 11.

Preferably, the circulation inlet and the circulation outlet on the heat dissipation layer 11 in the embodiment of the present utility model are of a matched structure, so that the heat dissipation channels can be combined to work integrally when the vacuum glass 100 in the embodiments of the present utility model is assembled.

As shown in fig. 5-6, the vacuum low-carbon power generation light shielding glass 100 according to the embodiment of the present utility model may further include: a circuit control system and an ac bus 300 for construction; wherein the circuit control system may comprise: a solar cell controller 21 electrically connected to the transparent solar cell layer 1; a solar battery 22 electrically connected to the solar battery controller 21; the solar inverter 23 is electrically connected to the solar battery 22, converts the direct current into alternating current, and is electrically connected to the ac bus 300 for construction. Wherein the dimming layer 4 may provide an operating power through the ac bus 300 for construction.

Alternatively, in the case where the heat dissipation layer 11 in the embodiment of the present utility model is configured with the cooling medium circulation system 24, the cooling medium circulation system 24 may also provide the working power through the ac bus 300 for construction.

In this embodiment, the transparent solar cell layer 1 is directly used as a building power supply, and the dimming layer 4 and/or the cooling medium circulation system 24 supply power by using a power interface laid by a building, so that the influence of the vacuum glass 100 on the self power line system of the building during the construction of the building can be reduced as much as possible, and the original power line system does not need to be modified in a large scale.

In some embodiments, the solar inverter 23 in the vacuum low-carbon power generation shading glass 100 according to the embodiment of the present utility model may be a solar inverter with a multiplexing function, which has a first output end and an ac bus 300 for building; it also has a second output terminal electrically connected to the dimming layer 4.

Optionally, in the case that the heat dissipation layer 11 in the embodiment of the present utility model is matched with the cooling medium circulation system 24, the solar inverter may further include: the third output is electrically connected to the cooling medium circulation system 24.

Alternatively, the solar inverter with the multiplexing function in the embodiment of the present utility model may also select a plurality of solar inverters with a single-path conversion function (for example, the first solar inverter 23 and the second solar inverter 25) to implement the multiplexing adjustment function. In some embodiments, the solar inverter may be used with corresponding voltage regulating converters (e.g., the first voltage regulating converter 26 and the second voltage regulating converter 27) to achieve devices with different operating voltage requirements.

The solar cell controller 21 in the embodiment of the utility model is also called a solar charge-discharge controller or a solar controller, and is an automatic control device for controlling a plurality of solar cell arrays to charge a storage battery and the storage battery to supply power to an inverter load in a solar power generation system. Preferably, the solar cell controller 21 in the embodiment of the present utility model may be a commercially available MPPT type solar controller.

In the embodiment, the transparent solar cell layer can not only realize energy production, but also provide electric energy for the vacuum glass and power supply for a building implementing the vacuum glass, so that energy conservation and environmental protection are further combined with building lighting.

The vacuum low-carbon power generation shading glass provided by the embodiment of the utility model can be suitable for any relevant scene, and is particularly suitable for glass curtain walls for buildings.

Those of skill would further appreciate that the various illustrative logical blocks, modules, circuits, and algorithm steps described in connection with the embodiments disclosed herein may be implemented as electronic hardware, computer software, or combinations of both. To clearly illustrate this interchangeability of hardware and software, various illustrative components, blocks, modules, circuits, and steps have been described above generally in terms of their functionality. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the overall system. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the present disclosure.

Claims (10)

1. A vacuum low-carbon power generation shading glass, which is characterized by comprising:

the transparent solar cell layer, the toughened vacuum glass layer, the sound insulation layer, the dimming layer and the first toughened glass substrate are sequentially laminated from outside to inside; the sound insulation layer and the dimming layer are clamped between the tempered vacuum glass layer and the first tempered glass substrate through adhesive films.

2. The vacuum low-carbon power generation shading glass according to claim 1, wherein the transparent solar cell layer and the toughened vacuum glass layer are combined through a hollow structure or a sandwich structure.

3. The vacuum low-carbon power generation shading glass according to claim 2, wherein the transparent solar cell layer and the toughened vacuum glass layer are combined through a hollow structure, and specifically comprises:

the transparent solar cell layer is hermetically combined with the toughened vacuum glass layer through surrounding spacer bars; wherein, the molecular sieve contacted with the air in the hollow structure is fixed on the spacing bar.

4. The vacuum low-carbon power generation shading glass according to claim 1, wherein the transparent solar cell layer is a thin film solar cell panel or a crystalline silicon solar cell panel.

5. The vacuum low-carbon power generation light shielding glass of claim 1, further comprising: a heat dissipation layer containing a transparent cooling medium is formed between the second toughened glass substrate between the toughened vacuum glass layer and the sound insulation layer and the toughened vacuum glass layer; the sound insulation layer and the dimming layer are clamped between the second toughened glass substrate and the first toughened glass substrate through adhesive films.

6. The vacuum low-carbon power generation light shielding glass of claim 5, wherein the heat dissipation layer comprises a heat dissipation channel allowing the transparent cooling medium to circulate.

7. The vacuum low-carbon power generation shading glass according to claim 1, wherein the tempered vacuum glass layer is of a single-layer structure or a double-layer structure.

8. The vacuum low-carbon power generation light shielding glass according to claim 1, wherein a getter is provided in the tempered vacuum glass layer.

9. The vacuum low-carbon power generation light shielding glass of claim 1, further comprising: the solar cell controller is electrically connected with the transparent solar cell layer; the solar storage battery is electrically connected with the solar battery controller; the solar inverter is electrically connected with the solar storage battery, is used for converting direct current into alternating current and is electrically connected with an alternating current bus; the solar inverter is electrically connected with the dimming layer; wherein, electrochromic film is selected for the light modulation layer.

10. The vacuum low-carbon power generation shading glass according to claim 1, wherein a nano photocatalyst layer is arranged on one side of the transparent solar cell layer away from the toughened vacuum glass layer.