CN108105838B - Graphene heating glass assembly based on photoelectric function - Google Patents

Abstract

The invention belongs to the technical field of heating, and particularly relates to a graphene heating glass assembly based on a photoelectric function. It has solved the unreasonable scheduling problem of prior art design. This graphite alkene heating glass subassembly based on photoelectric function includes glass, is equipped with the photovoltaic wafer at the glass surface, is equipped with a plurality of graphite alkene conductive heating membrane that are the interval and set up at glass's internal surface, the photovoltaic wafer on be connected with the wire just the direction electrically link with parallelly connected or the graphite alkene conductive heating membrane electricity of establishing ties. The invention has the advantages that: low cost and heat insulation function.

Description

Graphene heating glass assembly based on photoelectric function

Technical Field

The invention belongs to the technical field of heating, and particularly relates to a graphene heating glass assembly based on a photoelectric function.

Background

In today's cold winter, indoor heating is generally performed.

Indoor heating is achieved by means of electric heating, floor heating and the like.

At present, the existing heating mode at least has the following technical problems:

firstly, the energy consumption is high and the use cost is high.

Second, it does not possess thermal-insulated function of current window, leads to indoor warm braw to take place the loss phenomenon easily.

Disclosure of Invention

The present invention has been made in view of the above problems, and an object of the present invention is to provide a graphene heating glass module based on a photoelectric function, which is low in cost and has a heat insulating function.

In order to achieve the purpose, the invention adopts the following technical scheme: this graphite alkene heating glass subassembly based on photoelectric function includes glass, is equipped with the photovoltaic wafer at the glass surface, is equipped with a plurality of graphite alkene conductive heating membrane that are the interval and set up at glass's internal surface, the photovoltaic wafer on be connected with the wire just the direction electrically link with parallelly connected or the graphite alkene conductive heating membrane electricity of establishing ties.

The photovoltaic wafer converts light energy into electric energy, the graphene conductive heating film can be powered, the graphene conductive heating film not only has a good energy-saving effect, but also further improves the comfort of heating, and the photovoltaic wafer is lower in cost and more convenient to use.

Through the design of the structure, the heat insulation effect can be achieved, and a good heat insulation function can be achieved.

The graphene conductive heating film has no danger of electric leakage and electric shock, and is waterproof, anticorrosive, fireproof and extremely high in safety.

In the graphene heating glass assembly based on the photoelectric function, the graphene conductive heating film is arranged along the width direction of the glass.

The design of this scheme, it can avoid sunshine to be sheltered from the indoor dark that leads to completely.

In the graphene heating glass assembly based on the photoelectric function, the graphene conductive heating film is arranged along the vertical direction of the glass.

The design of this scheme, it can avoid sunshine to be sheltered from the indoor dark that leads to completely.

In the graphene heating glass assembly based on the photoelectric function, the graphene conductive heating film is an elastic graphene conductive heating film.

I.e. having a stretch in the warp and weft direction.

In foretell graphite alkene heating glass subassembly based on photoelectric function, graphite alkene electrically conductive heating film including insulating fire-retardant layer, be equipped with graphite alkene layer simultaneously on insulating fire-retardant layer, be equipped with the insulating layer of reflecting light between insulating fire-retardant layer and graphite alkene layer.

The structure is designed to be safer and more reliable to use.

In the graphene heating glass assembly based on the photoelectric function, the graphene conductive heating film is adhered to the inner surface of the glass.

Of course, mechanical connections, such as screws, etc., are also possible.

In the graphene heating glass assembly based on the photoelectric function, the photovoltaic wafer comprises a plurality of blocks, and the photovoltaic wafer and the graphene conductive heating film are arranged in a one-to-one correspondence manner.

The design of this structure, it can enlarge the generated energy, uses more stably and reliably.

In the graphene heating glass assembly based on the photoelectric function, the outer edge of the glass is provided with the wire passing groove or the wire passing hole, and the wire is clamped in the wire passing groove or penetrates through the wire passing hole.

In the graphene heating glass assembly based on the photoelectric function, the photovoltaic wafers are arranged in parallel or in series.

In foretell graphite alkene heating glass subassembly based on photoelectric function, this subassembly still overlaps the frame that establishes in glass circumference including the cover, is equipped with the wiring groove in the frame.

In the graphene heating glass module based on the photoelectric function, a built-in battery is provided on the outer frame or in the wiring groove, and the lead wire is connected to the built-in battery.

In the graphene heating glass assembly based on the photoelectric function, the graphene conductive heating film is further connected with a mains supply wire.

In the graphene heating glass component based on the photoelectric function, a super-hydrophilic self-cleaning coating layer is arranged on one surface, far away from the glass, of the photovoltaic wafer.

In the graphene heating glass assembly based on the photoelectric function, the photovoltaic wafers are distributed in an array.

In the graphene heating glass assembly based on the photoelectric function, the graphene conductive heating films are distributed in an array manner.

In the graphene heating glass component based on the photoelectric function, the photovoltaic wafer is any one of a weak light photovoltaic wafer and a common photovoltaic wafer.

Compared with the prior art, this graphite alkene heating glass subassembly based on photoelectric function's advantage lies in:

1. the photovoltaic wafer converts light energy into electric energy, the graphene conductive heating film can be powered, the graphene conductive heating film not only has a good energy-saving effect, but also further improves the comfort of heating, and the photovoltaic wafer is lower in cost and more convenient to use.

Through the design of the structure, the heat insulation effect can be achieved, and a good heat insulation function can be achieved.

2. The structure is simple.

Drawings

FIG. 1 is a schematic diagram of the structure provided by the present invention.

Fig. 2 is a schematic diagram of the structure provided by the present invention.

Fig. 3 is a schematic structural diagram of a graphene conductive heating film provided by the invention.

Fig. 4 is a schematic structural diagram with an outer frame according to the present invention.

Fig. 5 is a schematic structural diagram of the second embodiment of the present invention.

Fig. 6 is a schematic structural diagram of the rubber ring provided by the invention.

In the figure, glass 1, a photovoltaic wafer 2, a graphene conductive heating film 3, an insulating flame-retardant layer 31, a graphene layer 32, a reflective insulation layer 33, a wire 4 and an outer frame 5.

Detailed Description

The following are specific embodiments of the present invention and are further described with reference to the drawings, but the present invention is not limited to these embodiments.

Example one

As shown in fig. 1 to 4, the graphene heating glass assembly based on the photoelectric function includes glass 1, and the glass 1 is any one of ordinary glass and tempered glass, or is double-layer glass.

The assembly further comprises an outer frame 5 which is sleeved on the circumferential direction of the glass 1, and a wiring groove is arranged in the outer frame 5. The outer frame 5 is made of stainless steel or other materials.

Be equipped with photovoltaic wafer 2 at 1 surface of glass, be equipped with a plurality of graphite alkene conductive heating film 3 that are the interval setting at the internal surface of glass 1, the graphite alkene conductive heating film 3 of this embodiment sets up along 1 width direction of glass.

The voltage of the graphene conductive heating film 3 is 3-265V.

Through the design of above-mentioned structure, it can realize converting light energy into the electric energy, and the electric energy then can supply power for graphite alkene conductive heating film 3, then after the power supply graphite alkene conductive heating film 3 dispel the heat, promptly, realize the effect of heating.

Not only is the cost low, but also the loss of the heating air flow is greatly reduced, a good heat preservation effect is achieved, and meanwhile, the structure of the glass can be strengthened.

The photovoltaic wafer 2 is connected with a lead 4, and the guide is electrically connected with the parallel or serial graphene conductive heating film 3.

The photovoltaic wafer 2 may also be arranged within a double glazing.

The graphene conductive heating film 3 of the embodiment is an elastic graphene conductive heating film.

I.e. it can be extended and retracted in both its warp and weft directions.

Specifically, the graphene conductive heating film 3 of this embodiment includes the insulating flame-retardant layer 31, and one side of the insulating flame-retardant layer 31 is provided with the graphene layer 32, and a reflective insulation layer 33 is provided between the insulating flame-retardant layer 31 and the graphene layer 32. An insulating flame retardant layer 31 is attached to the inner surface of the glass.

Through the design of above-mentioned structure, it can reduce thermal loss by a wide margin, plays fine heat preservation function.

The graphene conductive heating film 3 is adhered to the inner surface of the glass 1. By means of an insulating glue or the like.

The photovoltaic wafer 2 comprises a plurality of blocks, and the photovoltaic wafer 2 and the graphene conductive heating film 3 are arranged in a one-to-one correspondence manner.

The outer edge of the glass 1 is provided with a wire passing groove or a wire passing hole, and the wire 4 is clamped in the wire passing groove or is arranged in the wire passing hole in a penetrating mode.

The designed wire passing groove or wire passing hole can facilitate wiring and avoid short circuit of a line.

The photovoltaic wafers 2 of the present embodiment are arranged in parallel or in series.

And a super-hydrophilic self-cleaning coating layer is arranged on one surface of the photovoltaic wafer 2 far away from the glass. Which can achieve maintenance-free function.

As shown in fig. 6, a rubber ring sleeved on the circumferential direction of the glass is arranged on the inner wall of the outer frame 5, an outer convex annular portion is arranged on the outer wall of the rubber ring, and an annular positioning groove for the outer convex annular portion to be clamped in is arranged on the inner wall of the outer frame 5.

The convex annular part is provided with an arc-shaped positioning concave surface.

Secondly, the inner wall of the rubber ring is provided with a plurality of annular sealing lips which are inclined towards the same direction and are arranged at intervals, and when the rubber ring is sleeved on the circumferential direction of the glass, the annular sealing lips are mutually attached.

The inner wall of the rubber ring is also provided with two flanges which are arranged at intervals, and the annular sealing lip is positioned between the two flanges.

In addition, be equipped with the containing barrel on glass 1's internal surface one side, be equipped with the pivot of vertical setting in the containing barrel, be connected with the graphite alkene conductive heating film 3 that a plurality of intervals that one end and pivot are connected set up in the pivot, and the other end and the control lever of graphite alkene conductive heating film 3 are connected.

A torsion spring is arranged between the rotating shaft and the containing barrel.

Furthermore, the glass is double-layer glass, and the photovoltaic wafer 2 is positioned in the double-layer glass.

Moreover, the outer frame is formed by connecting four aluminum profiles which are sequentially connected end to end.

Example two

As shown in fig. 5, the structure and principle of the present embodiment are substantially the same as those of the first embodiment, and therefore, the description is not repeated herein, but the differences are:

the graphene conductive heating film 3 is arranged along the vertical direction of the glass 1.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications or additions may be made to the described embodiments or alternatives may be employed by those skilled in the art without departing from the spirit or ambit of the invention as defined in the appended claims.

Claims (9)

1. The graphene heating glass assembly based on the photoelectric function comprises glass (1) and is characterized in that a photovoltaic wafer (2) is arranged on the outer surface of the glass (1), a plurality of graphene conductive heating films (3) which are arranged at intervals are arranged on the inner surface of the glass (1), a lead (4) is connected to the photovoltaic wafer (2), and the lead (4) is electrically connected with the graphene conductive heating films (3) which are connected in parallel or in series;

the glass is characterized by also comprising an outer frame (5) sleeved on the circumference of the glass (1), wherein a wiring groove is arranged in the outer frame (5); a super-hydrophilic self-cleaning coating layer is arranged on one surface of the photovoltaic wafer (2) far away from the glass;

the inner wall of the outer frame is provided with a rubber ring sleeved on the circumferential direction of the glass, the outer wall of the rubber ring is provided with an outward convex annular part, and the inner wall of the outer frame is provided with an annular positioning groove for the outward convex annular part to be clamped in; the convex annular part is provided with an arc positioning concave surface;

the inner wall of the rubber ring is provided with a plurality of annular sealing lips which are inclined towards the same direction and are arranged at intervals, and the annular sealing lips are mutually attached when the rubber ring is sleeved on the circumferential direction of the glass;

the inner wall of the rubber ring is also provided with two flanges which are arranged at intervals, and the annular sealing lip is positioned between the two flanges.

2. The graphene heating glass assembly based on the photoelectric function according to claim 1, wherein the graphene conductive heating film (3) is arranged along the width direction of the glass (1).

3. The graphene heating glass assembly based on the photoelectric function according to claim 1, wherein the graphene conductive heating film (3) is arranged along a vertical direction of the glass (1).

4. The graphene heating glass assembly based on the photoelectric function according to claim 1, 2 or 3, wherein the graphene conductive heating film (3) is an elastic graphene conductive heating film.

5. The graphene heating glass assembly based on the photoelectric function according to claim 4, wherein the graphene conductive heating film (3) comprises an insulating flame-retardant layer (31), a graphene layer (32) is arranged on one side of the insulating flame-retardant layer (31), and a reflective insulation layer (33) is arranged between the insulating flame-retardant layer (31) and the graphene layer (32).

6. The graphene heating glass assembly based on the photoelectric function according to claim 1, wherein the graphene conductive heating film (3) is adhered to the inner surface of the glass (1).

7. The graphene heating glass assembly based on the photoelectric function according to claim 1, wherein the photovoltaic wafer (2) comprises a plurality of blocks, and the photovoltaic wafer (2) and the graphene conductive heating film (3) are arranged in a one-to-one correspondence manner.

8. The graphene heating glass assembly based on the photoelectric function according to claim 1, wherein a wire passing groove or a wire passing hole is formed in the outer edge of the glass (1), and the lead (4) is clamped in the wire passing groove or is arranged in the wire passing hole in a penetrating mode.

9. The graphene heating glass assembly based on photoelectric function according to claim 7, wherein the photovoltaic wafers (2) are arranged in parallel or in series.

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