CN203859718U - Solar terminal control system - Google Patents

Abstract

The utility model discloses a solar terminal control system, and aims at providing the system which can convert solar energy into electric energy and work normally when commercial power is off. The solar terminal control system comprises a remote controller (1), a solar power supply module (2), a control device (3) and a wireless network base station (4), wherein the solar power supply module (2) is electrically connected with the control device (3), the control device (3) is connected with an electrical appliance, the remote controller (1) transmits an instruction to the wireless network base station (4), the wireless network base station (4) receives the instruction and transmits the instruction to the control device (3), and under the effect of the control device (3), a power supply loop of the solar power supply module (2) is connected to supply power to the electrical appliance. The solar terminal control system is mainly applied to the field of terminal control.

Description

A kind of solar energy terminal control system

Technical field

The utility model relates to a kind of solar energy terminal control system.

Background technology

Along with scientific and technical development, the continuous progress of automated control technology, also from strength to strength, gradually there are many control system of utilizing remote terminal to control whole work system in the function of control system.Whole system adopts mains supply to power, once there is the situations such as power failure, whole system cannot normally be worked.

Utility model content

Technical problem to be solved in the utility model is to overcome the deficiencies in the prior art, and a kind of solar energy terminal control system that solar energy can be converted to electric energy and can run well the in the situation that of civil power power-off is provided.

The technical scheme that the utility model adopts is: the utility model comprises described in remote controller, solar-electricity source module, controller and wireless network base stations that solar-electricity source module is electrically connected with described controller, described controller is electrically connected with electrical equipment, described remote controller sends instruction to described wireless network base stations, described wireless network base stations receives instruction and is conveyed to described controller, under the effect of described controller, the current supply circuit of described solar-electricity source module is connected and to electric power supply.

Described solar-electricity source module comprises solar panel, storage battery, upper cover, lower cover and circuit board, and described circuit board is positioned at the space that described upper cover and described lower cover surround, and described solar panel and described circuit board are all connected with described storage battery.

Described solar panel can be copper-indium-gallium-selenium alloy thin-film solar cell panel, unijunction amorphous silicon thin-film solar cell plate, double junction non-crystal silicon thin-film solar cell panel, monocrystalline silicon solar panel or polycrystalline silicon solar panel.

Described copper-indium-gallium-selenium alloy thin-film solar cell panel comprises substrate, deposits successively native oxide zinc rete, magnesium fluoride layer, nickel film and the aluminium lamination of the first molybdenum layer, the second molybdenum layer, copper-indium-gallium-selenium alloy layer, cadmium sulfide layer, native oxide zinc layer, adulterated al on described substrate.

Described unijunction amorphous silicon thin-film solar cell sheet comprises amorphous silicon substrate, deposits successively layer of transparent conducting film, p layer, i layer, n layer and back electrode on described amorphous silicon substrate.

Described double junction non-crystal silicon thin-film solar cell panel comprises amorphous silicon substrate, deposits successively layer of transparent conducting film, p layer, i layer, n layer, p layer, i layer, n layer and back electrode on described amorphous silicon substrate.

Described upper cover and lower cover outside are respectively arranged with decorative panel.

The beneficial effects of the utility model are: because the utility model comprises remote controller, solar-electricity source module, described in controller and wireless network base stations, solar-electricity source module is electrically connected with described controller, described controller is electrically connected with electrical equipment, described remote controller sends instruction to described wireless network base stations, described wireless network base stations receives instruction and is conveyed to described controller, under the effect of described controller, the current supply circuit of described solar-electricity source module is connected and to electric power supply, described solar-electricity source module is converted to electric energy and is stored in described sun-generated electric power solar continuous, described solar-electricity source module is electrical equipment and the power supply of described controller, so also can normally work in the whole solar energy terminal control system of the situation that there is no civil power.

Brief description of the drawings

Fig. 1 is the principle schematic of the utility model embodiment.

Fig. 2 is the structural representation of solar cell in the utility model reality.

Embodiment

Be illustrated in figure 1 a kind of solar energy terminal control system, it comprises described in remote controller 1, solar-electricity source module 2, controller 3 and wireless network base stations 4 that solar-electricity source module 2 is electrically connected with described controller 3, described controller 3 is electrically connected with electrical equipment, described remote controller 1 sends instruction to described wireless network base stations 4, described wireless network base stations 4 receives instruction and is conveyed to described controller 3, under the effect of described controller 3, the current supply circuit of described solar-electricity source module 2 is connected and to electric power supply.

Described solar-electricity source module 2 comprises solar panel 21, storage battery 22, upper cover 23, lower cover 24 and circuit board 25, described circuit board 25 is positioned at the space that described upper cover 23 and described lower cover 24 surround, described solar panel 21 and described circuit board 25 are all electrically connected with described storage battery 22, and described upper cover 23 and lower cover 24 outsides are respectively arranged with decorative panel 26.

Described solar panel 21 can be copper-indium-gallium-selenium alloy thin-film solar cell panel, unijunction amorphous silicon thin-film solar cell plate, double junction non-crystal silicon thin-film solar cell panel, monocrystalline silicon solar panel or polycrystalline silicon solar panel.

Described copper-indium-gallium-selenium alloy thin-film solar cell panel comprises substrate, on described substrate, deposit successively the first molybdenum layer, the second molybdenum layer, copper-indium-gallium-selenium alloy layer, cadmium sulfide layer, native oxide zinc layer, the native oxide zinc rete of adulterated al, magnesium fluoride layer, nickel film and aluminium lamination, described the first molybdenum layer is transition zone, make molybdenum layer and described soda lime glass substrates have good adhesion, described the second molybdenum layer is as back electrode, the resistance that connects layer to reduce the back of the body is beneficial to follow-up absorbed layer and forms good ohmic contact, described copper-indium-gallium-selenium alloy layer is by copper, indium, the alloy material of gallium and four kinds of compositions of selenium is made, the P type part during thereby the P-N that forms copper-indium-galliun-selenium film solar cell ties, described cadmium sulfide layer is that resilient coating is the N type part in copper-indium-galliun-selenium film solar cell P-N knot, described cadmium sulfide layer also can use zinc sulfide layer to replace, the native oxide zinc rete of the described adulterated al on described native oxide zinc layer top is Window layer, to increase the light penetration of thin-film solar cells, the antireflection layer that described magnesium fluoride layer is copper-indium-galliun-selenium film solar cell, aluminium lamination top electrode on described nickel film.The substrate of described copper-indium-gallium-selenium alloy thin-film solar cell panel can be glass, stainless steel, plastics, Polyimide polyimides and PET polyethylene terephthalate etc., and copper-indium-gallium-selenium alloy thin-film solar cell panel of the present utility model adopts receives lime glass substrate.

Described unijunction amorphous silicon thin-film solar cell sheet comprises amorphous silicon substrate, on described substrate, first to deposit layer of transparent conducting film (TCO), then on nesa coating, deposit successively p layer (being generally amorphous silicon carbide alloy a-SiC:H), i layer (intrinsic layer), n layer and back electrode (being generally aluminium or silver).

Described double junction non-crystal silicon thin-film solar cell panel comprises amorphous silicon substrate, on described substrate, first to deposit layer of transparent conducting film (TCO), then on nesa coating, deposit successively p layer (being generally amorphous silicon carbide alloy a-SiC:H), i layer (intrinsic layer), n layer, p layer (being generally amorphous silicon carbide alloy a-SiC:H), i layer (intrinsic layer), n layer and back electrode (being generally aluminium or silver).

Described monocrystal solar panel and described polycrystalline silicon solar panel carry out successively the metallization of shallow diffusion, oxidation, grooving, cleaning, diffusion for the second time and battery on the substrate of monocrystalline silicon or polysilicon at whole silicon face after removal damage layer and making herbs into wool.

Described solar-electricity source module 2 is also electrical appliance and described controller 3 and described electric power supply by the solar continuous electric energy that is converted to, thereby also can normally work in the whole solar energy terminal control system of the situation that there is no civil power.

In the present embodiment, described remote controller 1 is for sending the intelligent mobile phone of APP signal.

Claims (7)

1. a solar energy terminal control system, it is characterized in that: it comprises remote controller (1), solar-electricity source module (2), controller (3) and wireless network base stations (4), described solar-electricity source module (2) is electrically connected with described controller (3), described controller (3) is electrically connected with electrical equipment, described remote controller (1) sends instruction to described wireless network base stations (4), described wireless network base stations (4) receives instruction and is conveyed to described controller (3), under the effect of described controller (3), the current supply circuit of described solar-electricity source module (2) is connected and to electric power supply.

2. a kind of solar energy terminal control system according to claim 1, it is characterized in that: described solar-electricity source module (2) comprises solar panel (21), storage battery (22), upper cover (23), lower cover (24) and circuit board (25), described circuit board (25) is positioned at the space that described upper cover (23) and described lower cover (24) surround, and described solar panel (21) and described circuit board (25) are all electrically connected with described storage battery (22).

3. a kind of solar energy terminal control system according to claim 2, is characterized in that: described solar panel (21) can be copper-indium-gallium-selenium alloy thin-film solar cell panel, unijunction amorphous silicon thin-film solar cell plate, double junction non-crystal silicon thin-film solar cell panel, monocrystalline silicon solar panel or polycrystalline silicon solar panel.

4. a kind of solar energy terminal control system according to claim 3, it is characterized in that: described copper-indium-gallium-selenium alloy thin-film solar cell panel comprises substrate, on described substrate, deposit successively native oxide zinc rete, magnesium fluoride layer, nickel film and the aluminium lamination of the first molybdenum layer, the second molybdenum layer, copper-indium-gallium-selenium alloy layer, cadmium sulfide layer, native oxide zinc layer, adulterated al.

5. a kind of solar energy terminal control system according to claim 3, it is characterized in that: described unijunction amorphous silicon thin-film solar cell sheet comprises amorphous silicon substrate, deposits successively layer of transparent conducting film, p layer, i layer, n layer and back electrode on described amorphous silicon substrate.

6. a kind of solar energy terminal control system according to claim 3, it is characterized in that: described double junction non-crystal silicon thin-film solar cell panel comprises amorphous silicon substrate, on described amorphous silicon substrate, deposit successively layer of transparent conducting film, p layer, i layer, n layer, p layer, i layer, n layer and back electrode.

7. a kind of solar energy terminal control system according to claim 2, is characterized in that: described upper cover (23) and lower cover (24) outside are respectively arranged with decorative panel (26).