TWM514694U - Solar terminal control system - Google Patents

Description

Solar terminal control system

This creation is about a solar terminal control system, especially a solar terminal control system that can convert solar energy into electrical energy and can operate normally under the condition of mains power failure.

With the continuous development of science and technology, the continuous advancement of automation control technology, the function of the control system is becoming more and more powerful, and gradually there are many control systems that use remote terminals to control the entire working system. The whole system uses the mains power supply for power supply. Once a power outage occurs, the entire system will not be able to perform normal work.

Therefore, the object of the present invention is to provide a solar terminal control system that can convert solar energy into electrical energy and can operate normally in the event of a commercial power outage.

Therefore, the present invention includes a remote controller, a solar power module, a controller, and a wireless network base station. The solar power module is electrically connected to the controller, and the controller is electrically connected to an electric appliance, and the remote controller sends an instruction. Giving the wireless network base station, the wireless network base station receiving an instruction and communicating to the controller, under the action of the controller, the power supply loop of the solar power module is turned on and the appliance is powered .

The solar terminal control system provided by the present invention is powered by the controller, the power supply circuit of the solar power module is turned on, and the electric appliance is powered. The module continuously converts solar energy into electrical energy and stores it in the solar power source. The solar power module supplies power to the electrical appliance and the controller, so that the entire solar terminal control system can perform normal operation without the mains.

1‧‧‧Remote control

2‧‧‧Solar power module

3‧‧‧ Controller

4‧‧‧Wireless network base station

21‧‧‧ solar panels

22‧‧‧Battery

23‧‧‧Upper cover

24‧‧‧Under the cover

25‧‧‧ boards

26‧‧‧Decorative board

Figure 1 is a schematic view showing the structure of an embodiment of the present invention.

Figure 2 is a schematic view of the structure of a solar panel.

Referring to FIG. 1 and FIG. 2, the present invention provides a solar terminal control system including a remote control 1, a solar power module 2, a controller 3, and a wireless network base station 4; The controller 3 is electrically connected, the controller 3 is electrically connected to an electrical appliance, and the remote controller 1 sends an instruction to the wireless network base station 4, and the wireless network base station 4 receives an instruction and communicates to the control The power supply circuit of the solar power module 2 is turned on and supplies power to the electric appliance under the action of the controller 3.

The solar power module 2 includes a solar panel 21, a battery 22, an upper cover 23, a lower cover 24, and a circuit board 25. The circuit board 25 is located in a space surrounded by the upper cover 23 and the lower cover 24. The solar panel 21 and the circuit board 25 are electrically connected to the battery 22, and the decorative panel 26 is respectively disposed outside the upper cover 23 and the lower cover 24.

The solar panel 21 may be a copper indium gallium selenide thin film solar panel, a single junction amorphous germanium thin film solar panel, a double junction amorphous germanium thin film solar panel, a single crystal germanium solar panel or a polycrystalline germanium solar panel. .

The copper indium gallium selenide thin film solar panel includes a substrate on the substrate A first molybdenum layer, a second molybdenum layer, a copper indium gallium selenide layer, a cadmium sulfide layer, an intrinsic zinc oxide layer, an indium-doped intrinsic zinc oxide film layer, a magnesium fluoride layer, a nickel film, and aluminum are sequentially deposited. a layer, the first molybdenum layer is a transition layer, the molybdenum layer has a good bonding force with the soda lime glass substrate, and the second molybdenum layer acts as a back electrode to reduce the resistance of the backing layer to facilitate subsequent The absorbing layer forms a good ohmic contact, and the copper indium gallium selenide alloy layer is made of an alloy material of four components of copper, indium, gallium and selenium, thereby forming a P-type portion in the PN junction of the copper indium gallium selenide thin film solar cell. The cadmium sulfide layer is a buffer layer, that is, an N-type portion in a PN junction of a copper indium gallium selenide thin film solar cell, and the cadmium sulfide layer may also be replaced by a zinc sulfide layer, the upper portion of the intrinsic zinc oxide layer being The aluminum-doped intrinsic zinc oxide film layer is a window layer for increasing the light transmittance of the thin film solar cell, wherein the magnesium fluoride layer is an anti-reflection layer of a copper indium gallium selenide thin film solar cell, and the aluminum on the nickel film Upper layer electrode. The substrate of the copper indium gallium selenide thin film solar panel may be glass, stainless steel, plastic, Polyimide polyimide and PET polyethylene terephthalate, etc., the copper indium gallium selenide thin film solar energy of the utility model The panel uses a nano-calcium glass substrate.

The single junction amorphous germanium thin film solar cell sheet comprises an amorphous germanium substrate on which a transparent conductive film (TCO) is first deposited, and then a p layer (generally amorphous tantalum carbide) is sequentially deposited on the transparent conductive film. Alloy a-SiC: H), i layer (intrinsic layer), n layer and back electrode (generally aluminum or silver).

The double junction amorphous germanium thin film solar cell panel comprises an amorphous germanium substrate, a transparent conductive film (TCO) is deposited on the substrate, and then a p layer (generally amorphous tantalum carbide) is deposited on the transparent conductive film. Alloy a-SiC: H), i layer (intrinsic layer), n layer, p layer (generally amorphous niobium carbide a-SiC: H), i layer (intrinsic layer), n layer and back electrode ( Generally aluminum or silver).

The single crystal solar panel and the polycrystalline germanium solar panel After the damaged layer and the texturing are removed on the substrate of the single crystal germanium or polycrystalline germanium, shallow diffusion, oxidation, grooving, cleaning, second diffusion, and metallization of the battery are sequentially performed on the entire surface of the crucible.

The solar power module 2 continuously converts solar energy into electric energy and supplies power to the electric appliance and the controller 3 and the electric appliance, so that the entire solar terminal control system can perform normal operation without the mains.

1‧‧‧Remote control

2‧‧‧Solar power module

3‧‧‧ Controller

4‧‧‧Wireless network base station

Claims (7)

A solar terminal control system comprising a remote controller (1), a solar power module (2), a controller (3) and a wireless network base station (4), the solar power module (2) and the control The controller (3) is electrically connected, the controller (3) is electrically connected to the electrical appliance, and the remote controller (1) sends an instruction to the wireless network base station (4), the wireless network base station (4) Receiving an instruction and communicating to the controller (3), under the action of the controller (3), the power supply circuit of the solar power module (2) is turned on and supplies power to the appliance. The solar terminal control system of claim 1, wherein the solar power module (2) comprises a solar panel (21), a battery (22), an upper cover (23), a lower cover (24), and a circuit board (25) The circuit board (25) is located in a space surrounded by the upper cover (23) and the lower cover (24), and the solar panel (21) and the circuit board (25) are electrically connected to the battery (22). The solar terminal control system according to claim 2, wherein the solar panel (21) is a copper indium gallium selenide thin film solar panel, a single junction amorphous germanium thin film solar panel, and a double junction amorphous germanium thin film solar cell. Plate, single crystal germanium solar panels or polycrystalline germanium solar panels. The solar terminal control system of claim 3, wherein the copper indium gallium selenide thin film solar cell panel comprises a substrate on which a first molybdenum layer, a second molybdenum layer, a copper indium gallium selenide alloy layer are sequentially deposited, A cadmium sulfide layer, an intrinsic zinc oxide layer, an indium-doped intrinsic zinc oxide film layer, a magnesium fluoride layer, a nickel film, and an aluminum layer. The solar terminal control system of claim 3, wherein the single junction amorphous germanium thin film solar cell panel comprises an amorphous germanium substrate, and the amorphous germanium substrate is sequentially deposited with a transparent conductive film, a p layer, an i layer, and n Layer and back electrode. The solar terminal control system according to claim 3, wherein the double junction amorphous germanium thin film solar cell panel comprises an amorphous germanium substrate, and the amorphous germanium substrate is sequentially deposited with a transparent conductive film, a p layer, an i layer, and n. Layer, p layer, i layer, n layer and back electrode. The solar terminal control system of claim 2, wherein the outer cover (23) and the lower cover (24) are respectively provided with a decorative plate (26).