JPH02134877A - Simple assembly type solar battery structure - Google Patents

Abstract

PURPOSE:To provide the title structure wherein many solar battery elements can easily be connected and it can easily deal with recombination effected many times by providing in a container the solar battery elements, a plurality of external connectors for connection of electric power generated from the solar battery elements to the outside, and means for switching the power supply from the solar battery elements. CONSTITUTION:The solar battery structure as a unit of a solar battery constructed by connecting plurality of solar battery elements 1 includes the solar battery elements 1, a plurality of external connectors 2-5 for connection of electric power generated from the solar battery elements 1, and means 6 for switching the power supply from the solar battery elements 1 to at least one of the connectors 2-5. For example, the solar cell elements 1 are assembled on the upper surface of a rectangular container 8, upper portion of which is protected by a transparent protective film. The external output connectors 2-5 are disposed on the exterior sidewall of the rectangular container 8, and the output connectors 2-5 are electrically connected through the output of the solar battery elements 1 and through an electrode selection switch 6 for taking out the electromotive force from the solar battery elements 1.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a solar cell that can obtain arbitrary output current and output voltage by connecting a plurality of solar cell structures. This invention relates to an easily assembled solar cell structure that can be connected and disconnected many times and reconfigured.

[Conventional technology]

Conventionally, in order to cope with the wide variety of operating voltages and operating currents for each device that supplies power, solar cells have traditionally combined multiple solar cell elements and connected them in series or parallel to achieve the desired operating voltage, Obtaining operating current.

Examples of methods for combining and connecting a plurality of solar cell elements include a method of connecting each solar cell element with a lead as shown in Figure 5, and a method of connecting each solar cell element with a conductive adhesive tube. be.

However, there are problems such as an increase in cost due to the wiring process, connection points that come loose, and difficulty in fixing to a fixed position.

In addition, if a load device that uses solar cells as a power source is specified, the number of series-parallel connections can be fixed according to the required output voltage and output current. In order to do this, it is inconvenient that a capacitive power supply must be made large and connected through an adjustment circuit that controls the output voltage.

In order to solve these problems, Japanese Patent Application Laid-Open No. 56-94675
No. 3, discloses providing male and female connectors on the side wall surface of a solar cell element. This method allows a desired output voltage and output current to be obtained by connecting a large number of solar cell elements in series or parallel, and is also excellent in terms of ease of handling.

[Problem to be solved by the invention]

However, in the case of using a solar cell structure with a conventional connector as mentioned above, the cover of the connector part is sheet-like, and if you use it with one skin removed, then when you want to break the wire, you can insert an insulating material in between. It has the disadvantage that it cannot easily handle multiple recombinations.

[Purpose of the invention]

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to realize an easily assembled solar cell structure that can easily connect a large number of solar cell elements and that can be easily reassembled many times.

[Means to solve the problem]

As a means for solving the above-mentioned problems, the present invention provides a solar cell structure that is a constituent unit of a solar cell constructed by connecting a plurality of solar cell elements, comprising: a solar cell element; and the solar cell. A single container includes a plurality of external connectors for connecting the power generated from the element to the outside, and a means for opening and closing the power supply from the solar cell element to at least one of the connectors. The present invention provides an easily assembled solar cell structure.

[Effect]

By using multiple external connectors, it is possible to combine multiple solar cell structures to form a single solar cell, and by using switches inside each structure, solar cell elements can be connected to each connector. By opening and closing the power supply, you can freely create wiring mother turns in series or parallel, and the combined solar cells can be disassembled into each solar cell structure again and reassembled. is also possible.

〔Example〕

An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 shows an embodiment of the solar cell structure of the present invention, in which a solar cell element 1 is assembled on the upper surface of a rectangular container 8, and is protected thereon by a transparent protective film (not shown). External output connectors 2, 3, 4.5 are provided on the outer side wall of the rectangular container 8.
is installed.

The output connector is electrically connected to the output of the solar cell element 1 through the electrode selection switch 6.
The electromotive force can be extracted.

In addition, the connector can be mechanically combined with other solar cell structures of the same type and electrically connected, making it possible to create a larger solar cell tunnel.

In the embodiment, a pair of anode connectors 4 and a cathode connector 5 are disposed on both the exteriors of opposing side walls forming one pair, and an anode connector 2 is further provided on one of the exteriors of the opposing side walls forming the other pair.
However, a cathode connector 3 is disposed on the other side.

Figure 2 shows the solar cell structure of the present invention, in which a pedestal 9 that also serves as a container and an auxiliary connector 7 are attached to make the mechanical connection with other solar cell structures very strong. In Figure 2, the same parts as in Figure 1 are given the same numbers.

Furthermore, when connecting a large number of solar cell structures in series or in parallel, there are cases where it is desirable to avoid electrical connection between the anode and cathode connectors 4 and 5. In that case, the electrode selection switch 6
Using this, it is possible to perform connections and disconnections, as well as connections depending on the situation, such as connecting only one of the anode and cathode. FIG. 3 is a diagram showing close reading methods according to various states of the electrode selection switch 6. In Figure 3,
The switch moving part 31 moves within the switch hole 34 and connects the wiring 33m, 33b and the conductive part 32 (a) - disconnection (d)
- It is possible to perform one-sided connections (b), (e).

For example, connect one side of the 33 m wiring to the anode of solar cell element 1.
Further, by connecting the opposite side to the anode connector 4 and similarly connecting the wiring 33b to each cathode, the electrical connection between the anode and the cathode can be opened and closed as necessary.

Further, the electrode selection switch 6 may be of a type that can be removed and replaced, and is not limited to the one shown in FIG.

Further, the rectangular container housing the solar cell element and the connecting connector section are made of a material that can withstand repeated attachment and detachment.

Specifically, it is made of composite materials such as plastics, ceramics, and ceramics, has durability, is easy to attach and detach,
A material is used that has properties necessary for a solar cell structure, such as heat resistance, light resistance, stress resistance, and heat dissipation.

Next, an embodiment in which the above-described easily assembled solar cell structure of the present invention is combined is shown in FIGS.

Note that the present invention is not limited to these examples.

Embodiment 1 FIG. 4(a) is an electrical schematic diagram of the easily assembled solar cell structure of the present invention shown in FIG. 1 or 2 described above. In the figure, 1 is a solar cell element, 2.4 is an anode connector, 3 and 5 are cathode connectors, and 6 is an electrode selection switch. 41 is an output terminal as a whole, and by connecting a load to 41, a desired electromotive force can be extracted. In this embodiment, the output voltage of the solar cell element 1 is set to 1.
Since the output voltage is designed to be 5V, it is possible to output an output voltage of 1.5V from the output terminal 41 in the single unit example shown in FIG. 4(a).

In addition, in Fig. 4(b), two structures are connected in series, and 3V
The output voltage is obtained from the output terminal 41. By increasing the structure in this way, 4.5v,
Necessary output voltages such as 6v, 9v, etc. can be obtained by a simple method.

Further, by using a component such as a lead connector (not shown) instead of the output terminal 41, electric power can be extracted more easily.

Embodiment 2 Next, when a power source with a large output current is required, the connectors 4 and 5 of each solar cell structure are connected as shown in FIG. 4(c).
The electrode selection switch 6 is brought into the connected state as shown in FIG. 3 (,). In this way, if one solar cell structure has an output current capacity of 1 mA, by connecting two solar cell structures in parallel, an output current of 2 rrIA can be obtained. It is possible to increase the number of parallel units as necessary according to the output current of the object being used.

Embodiment 3: If a larger output voltage and output current are required, for example, structures can be connected in series and in parallel as shown in Figure 4(d) to increase both the output voltage and output current. be able to. When connecting long series bodies in parallel here, the solar cell structure d111'21"15'd25 is connected to the connector 4,
Connect only one side of 5, and also connect the solar cell structure d121d
The connectors 4 and 5 of No. 22 are disconnected and the electrical connection is lost.

Therefore, in K, the electrode selection switch 6 plays an important role.'' 11 v '21sd131 In d23, set the state as shown in FIG. 3(b) or (c) and connect only the anode or cathode connector. Figure 3 (
d) state and disconnect the wires, these six solar cell structures become solar cells in which three series bodies are arranged in parallel. Furthermore, various output currents and output voltages can be obtained by arbitrarily increasing the number of series and parallel connections and appropriately setting the electrode selection switch 6).

Here, the electrode selection switch 6 of the connector not involved in the connection was disconnected for safety.

Moreover, as shown in FIG. 4(e), three sets of parallel structures each composed of two solar cell structures can be connected in series.

The selection of (-) in FIG. 4(d) is an effective method for stably supplying constant current and constant voltage when there are variations in solar cell elements, and increases the degree of freedom in combination.

〔Effect of the invention〕

According to the present invention, by using a simple assembly type solar cell structure that can be combined according to the output current and output voltage of the load used, it is possible to easily create a solar cell having the desired output current and output voltage. It is possible to handle multiple recombinations, has excellent practicality, economy, and reliability, and is also easy to handle.

[Brief explanation of the drawing]

1 and 2 are solar cell structures showing one embodiment of the present invention, and FIG. 3 is a switching diagram of an electrode selection switch 6 of the present invention. FIG. 4 shows a connection example of the solar cell structure of the present invention, and FIG. 5 shows a conventional solar cell. 1... Solar cell element, 2.4... Anode connector (external output connector), 3.5... Cathode connector (external output connector), 6... Electrode selection switch, 7... Auxiliary connector , 8... square container, 9... pedestal (container)
, 31... switch moving part, 32... conductive part, 33
&. 33b...Wiring, 34...Switch hole, 41...
Output terminals, d11-131 d21-23...Solar cell structure. Agent Patent Attorney Sekihei Yamashita

Claims (2)

[Claims] (1) In a solar cell structure that is a constituent unit of a solar cell constructed by connecting a plurality of solar cell elements, the solar cell element and a plurality of solar cell structures for connecting the generated power from the solar cell element to the outside are 1. An easily assembled solar cell structure comprising, in one container, an external connector and a means for opening and closing power supply from the solar cell element to at least one of the connectors. (2) The container is rectangular and has a pair of anode and cathode connectors on the outside of each of one pair of opposing side walls, and an anode and a cathode connector on one of the other pair of opposing side walls. 2. The easily assembled solar cell structure according to claim 1, further comprising a switch for opening and closing current from the solar cell element to the pair of connectors.