JP2612620B2 - Solar panel - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a solar panel having an optical signal receiving function.

[Conventional technology]

Conventionally, photovoltaic power generation systems using solar cells are clean and energy free of pollution and noise.For example, from electric products such as clocks and calculators, to unmanned radio wave repeaters, power generation systems on house roofs, and large-scale Applications to various fields such as power generation systems have been devised.

On the other hand, JP-A-59-154562 discloses an electronic device with a solar cell that uses a solar cell as a power source and also uses the solar cell as an optical information input element. In this technology, a solar cell of a small electronic device such as an electronic desk calculator is provided with an optical signal receiving function as well as a power generating function, and is provided with an information receiving capability by light.

FIG. 2 shows a schematic equivalent circuit diagram of a conventional solar cell panel having an optical signal receiving function.

In the solar cell panel 203 shown in the figure, the solar cell 101 receives the sunlight 102, and the generated energy is stored in the storage battery B1. Further, a backflow prevention diode D1 is connected to prevent backflow of current from the storage battery B1 to the solar cell 101 when the solar cell 101 is not generating power. Further, when the solar cell 101 receives the AC signal light 102, a resistor R2 for detecting the AC signal is connected in series.

The energy generated by the solar cell panel 203 is output through an output terminal OUT. The received optical signal is output from the signal output terminal Sig.

[Problems to be solved by the invention]

However, when an optical signal is received by a general power photovoltaic panel other than a small electronic device as in the above-described conventional example, the output power of which is larger than a certain level, the following problems occur. there were.

That is, since the detection of the optical signal must be performed simultaneously with the output of the electric power, as shown in FIG.
The backflow prevention diode D1, the solar cell 101, and the optical signal detection resistor R2 all need to be connected in series. For this reason, there is a problem that power loss occurs in the backflow prevention diode D1 and the optical signal detection resistor R2.

[Object of the invention]

An object of the present invention is to solve the problems in a solar cell panel having a function of receiving an optical signal, together with the conventional photovoltaic function as described above, to simultaneously perform optical power generation and optical signal reception, and further reduce power loss. An object of the present invention is to realize a solar cell panel that also serves as a small optical signal receiver.

[Means and actions for solving the problem]

The present inventor overcame the above-mentioned problems in the conventional optical signal receiver / photovoltaic cell panel and made intensive studies to achieve the above object of the present invention. It has been found that the power loss can be reduced by constituting a signal detection resistor.

Further, the present inventor, the signal voltage detected by the backflow prevention diode, RC built into the solar cell panel
By introducing the circuit into the circuit, separating only the AC component, and further amplifying the separated AC component by an amplifier built in the solar cell and supplied with power and operated by the output of the solar cell panel, The knowledge that a signal with little noise can be obtained was obtained.

That is, the present invention provides, as a means for solving the above-mentioned problem, an optical signal comprising a solar cell, a storage battery for storing power generation energy of the solar cell, and a backflow prevention diode connected in series to the solar cell and the storage battery. In the solar cell panel having a receiving function, the backflow prevention diode is used as an optical signal detection resistor by utilizing a voltage drop in the backflow prevention diode to separate the optical signal. It is intended to provide a solar panel having an optical signal receiving function.

A solar battery, a storage battery for storing power generation energy of the solar battery, a backflow prevention diode connected in series to the solar battery and the storage battery, an output terminal for connecting the solar battery and the storage battery to a load, and the solar battery. An RC circuit for separating the DC component and the AC component of the generated power,
An amplifier that operates upon being supplied with power from the output terminal and amplifies the separated AC component, and guides a voltage drop in the backflow prevention diode to the RC circuit, thereby reducing the DC component. By the solar panel with the optical signal receiving function characterized by separating the AC component,
This is to solve the above-mentioned problem.

Hereinafter, the means of the present invention will be described in more detail with reference to embodiments of the drawings, but the present invention is not limited thereto.

FIG. 1 is a schematic equivalent circuit diagram showing one example of a solar cell panel having an optical signal receiving function of the present invention.

In the solar cell panel 103 shown in the figure, the solar cell 101 receives the sunlight 102, and the generated energy is stored in the storage battery B1. Further, a backflow prevention diode D1 is connected to prevent backflow of current from the storage battery B1 to the solar cell 101 when the solar cell 101 is not generating power.

Further, when the solar cell 101 receives the AC signal light 102, the backflow prevention diode also functions as a resistor for detecting the AC signal. The signal detected by the backflow prevention diode is further separated only by an AC component by an RC circuit (R1, C1). Further, this AC signal is connected to the amplifier A1, amplified, and output to the signal output terminal Sig.

The amplifier A1 is supplied using the output of the solar cell panel as a power supply.

As described above, according to the present invention, the conventional optical signal detecting resistor R2 can be omitted, thereby reducing power loss.

Further, by incorporating an RC component for AC component separation and an amplifier, a more accurate optical signal can be detected.

Furthermore, by using the power generated by the solar cell as the power supply of the amplifier, an amplifier with less noise can be obtained.

The solar cell of the above-described device provided by the present invention may be a unit cell, a cell in which a plurality of cells are connected in series or in parallel, or any unit that has the ability to generate power by sunlight and the ability to receive signal light. good. Examples of such a solar cell include a single-crystal silicon solar cell, a polycrystalline silicon solar cell, an amorphous silicon-based solar cell, and a compound semiconductor solar cell.

Further, the storage battery provided by the present invention may be any storage device that can store the output of a solar cell, and examples thereof include a lead storage battery and a nickel-cadmium storage battery.

〔Example〕

Hereinafter, the present invention will be further described with reference to Examples of the solar cell panel of the present invention, but the present invention is not limited thereto.

Embodiment 1 FIG. 1 shows a schematic equivalent circuit of a solar cell panel having an optical signal receiving function of the present invention.

In the figure, an amorphous silicon solar cell (30 × 60 cm ² , 10 W) was used as the solar cell 101, and a lead storage battery (12 V, 200 Wh) was used as the storage battery B 1. As a load, an electronic timepiece (power consumption 10 mW) having a nighttime illuminator (10 W fluorescent lamp) was attached to the output terminal OUT. Signal output terminal Sig
Was connected to a personal computer having an I / O interface with an A / D converter.

The solar cell panel 103 of the present embodiment thus configured is
It was installed on the roof of a house on a hot summer day. Solar cell 101 during the day
The power generated in the above was supplied to the above-mentioned watch, and the surplus power was stored in the storage battery B1. At this time, the maximum output of the solar cell panel 103 was 15 V and 0.6 A. The amount of power generated per day was about 25 watt-hours, of which the power consumed by the watch was negligible compared to the power stored in battery B1, and most of the power was stored in battery B1.

Since the solar cell 101 does not generate power at night, power was supplied to the load by the storage battery B1, and the clock was illuminated for about three hours at night.

On the other hand, when the solar cell panel was irradiated with the sunlight 102, the signal light was also irradiated at the same time, and it was tested whether the optical signal could be received by the personal computer.

As a light source of the optical signal, using a helium neon laser of 3mW, installed in a place 300m away from the solar panel,
This was modulated into a pulse code by a liquid crystal shutter. This signal light was applied to the solar cell panel 103, a signal received by the solar cell 101 was taken out from a signal output terminal Sig, and transmitted to a personal computer via an I / O interface. As a result, the signal transmitted by the helium neon laser could be faithfully received by the personal computer.

Example 2 In this example, in the device of the schematic equivalent circuit shown in FIG. 1, the light receiving area of the solar cell panel 103 was increased by three times, and the output of the solar cell 101 was set to 15 V and 1.8 A. In accordance with that, the capacity of the storage battery B1 was 12 V and 600 Wh. As a load, an electronic timepiece (power consumption 10 mW) having a nighttime illuminator (10 W LED) was attached to the output terminal OUT. The same one as in Example 1 was attached to the signal output terminal Sig.

The apparatus of the present embodiment thus configured was mounted on the roof of a house on a summer day.

In the present embodiment, in the daytime, the power generated by the solar cell 101 is supplied to the above-described clock, and the surplus power is stored in the storage battery B1. At this time, the maximum output of the solar cell panel 103 was 15 V and 1.8 A. The amount of power generated per day is about 75 watt-hours,
Of these, the power consumed by the watch was negligibly smaller than the power stored in the storage battery B1, and most of the power was stored in the storage battery B1.

Since the solar cell 101 does not generate power at night, power was supplied to the load by the storage battery B1, and the clock was illuminated for about 9 hours at night.

On the other hand, when the solar cell panel 103 was irradiated with the sunlight 102, a signal light was also irradiated at the same time, and it was tested whether a light signal could be received by a personal computer.

As a light source of the optical signal, a 10 mW argon ion laser was used, installed at a position 1 km away from the solar cell panel 103, and modulated into a pulse code by a liquid crystal shutter. The signal light was applied to the solar cell panel 103, and the signal received by the solar cell 101 was transmitted to the personal computer via the I / O interface. As a result, the signal transmitted by the argon ion laser could be faithfully received by the personal computer.

(Example 3) In this example, the amorphous silicon solar cell 101 shown in Example 2 was replaced with a polycrystalline silicon solar cell, and the other configuration was the same as that in Example 2.

The same load and information equipment as in the second embodiment were connected to the apparatus of the present embodiment, and power generation during the day and illumination and light signals during the night were received.

As a result, also in this example, a sufficient electromotive force by the solar cell could be obtained, and the signal transmitted by the argon ion laser could be faithfully reproduced by the personal computer.

〔The invention's effect〕

As is clear from the above embodiments, the solar cell panel having the optical signal receiving function of the present invention has a simple structure because the conventionally installed backflow prevention diode is used as a resistor for separating an AC signal. It can be provided at low cost with few failures.

Further, the number of elements connected in series is smaller than that of a conventional solar cell panel in which an optical signal detection resistor is connected in series with a backflow prevention diode, so that power loss can be reduced.

Further, since an amplifier for amplifying the AC signal is built in the panel, and the power supplied to the amplifier is connected from the output of the solar cell panel, it is possible to reduce a problem due to noise supplied to the power supply.

[Brief description of the drawings]

FIG. 1 is a schematic equivalent circuit diagram of a solar cell panel having an optical signal receiving function according to the present invention. FIG. 2 is a schematic equivalent circuit diagram of a conventional solar cell panel having an optical signal receiving function. In the figure, 101: solar cell 102: sunlight and signal light 103, 203: solar cell panel B1: storage battery D1: reverse current prevention diode R2: light signal detection resistor

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁶ Identification code Agency reference number FI Technical display location H04B 10/26

Claims (6)

(57) [Claims] 1. A solar cell panel having a function of receiving an optical signal, comprising a solar cell, a storage battery for storing power generation energy of the solar cell, and a backflow prevention diode connected in series to the storage battery. A solar cell panel, wherein a diode is used as an optical signal detecting resistor by utilizing a voltage drop in the backflow prevention diode to separate the optical signal. 2. A solar cell, a storage battery for storing power generation energy of the solar cell, a backflow prevention diode connected in series to the solar cell and the storage battery, and an output terminal for connecting the solar cell and the storage battery to a load. An RC circuit for separating a DC component and an AC component of the power generated by the solar cell, and an amplifier that operates by being supplied with power from the output terminal and amplifies the separated AC component. A solar cell panel that separates the DC component and the AC component by introducing a voltage drop in the backflow prevention diode to the RC circuit. 3. A solar cell for receiving a light beam having a signal light, and a power storage means for storing power generation energy of the solar cell;
A solar cell panel having a load connected to the power storage means, and a backflow prevention diode connected in series to the solar cell and the power storage means, wherein a voltage drop of the backflow prevention diode is detected to separate the signal. A solar cell panel comprising: 4. The solar cell according to claim 1, wherein the solar cell is at least one selected from a monocrystalline silicon solar cell, a polycrystalline silicon solar cell, an amorphous silicon solar cell, and a compound semiconductor solar cell. Item 4. A solar cell panel according to item 3. 5. The solar cell panel according to claim 3, wherein said power storage means is a lead storage battery or a nickel-cadmium storage battery. 6. The solar cell panel according to claim 3, wherein said signal separating means comprises an RC circuit.