JPH09148611A - Solar battery device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To simplify the switching of the wiring of a solar battery element in series and in parallel, and to prevent poor contact of the wiring. SOLUTION: A connector 2 is composed of a plurality of connection stands 3, a coupling guide 4 and stoppers 14 in this device. The coupling guide 4 couples the connection stands 3 in such a manner that solar battery elements 1 can be moved to the direction where they are pinchingly attached. The stoppers 14 fix the connection stands 3 to the coupling guide 4. The connector 2 of the structure connects the solar battery elements 1 between the connection stands 3 in the state wherein the connection stands 3 can be moved to the coupling guide 4, and under this state, the solar battery elements 1 and the connection stands 3 are electrically connected by fixing the connection stands 3, with which the solar battery elements 1 are connected, to the coupling guide 4 by the stoppers 14. Coupling slits 6, with which the solar battery elements 1 are coupled by inserting their end parts, are provided on the connection stands 3, and also external terminals 7, to be coupled to the solar battery elements 1, are provided.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a solar cell device mainly used for teaching materials. In particular, the present invention is
The present invention relates to a solar cell device in which a connection direction of a plurality of solar cell elements can be changed and the solar cells can be connected in series or in parallel.

[0002]

Solar cells convert light into electricity. The output of the solar cell increases as the incident light becomes stronger. The output current and output voltage of a solar cell change depending on the intensity of incident light. In order to change the relationship between the output current and output voltage of a solar cell and the connection state of a plurality of solar cells, a solar cell device has been developed in which a plurality of solar cell elements are connected in series and in parallel ( Japanese Utility Model Publication No. 6-48882).

FIG. 1 is a sectional view of the solar cell device described in this publication. The solar cell element 1 of this figure is provided with + output terminals 8A on both sides of the upper side and − output terminals 8B on both sides of the lower side in the figure. The output terminal 8 is a metal pin and is arranged in the center of a recess 9 provided on the outer periphery of the solar cell element 1.
The output terminals 8 of the adjacent solar cell elements 1 are connected by a cylindrical connection pin 10. The connection pin 10 is for inserting the output terminal 8 and making electrical connection. As shown in the figure, the solar cell device of this figure is connected in parallel by connecting the +/- output terminals 8 of the adjacent solar cell elements 1 with connection pins 10. Although not shown, when the solar cell elements 1 are rotated by 90 degrees and connected, the adjacent solar cell elements 1 are connected in series.

[0004]

The solar cell device shown in the figure can be connected in series or in parallel by rotating the solar cell element 1 by 90 degrees. In the solar cell device having this structure, it is difficult to reliably connect all the solar cell elements 1. If the connection position of the solar cell element 1 is displaced, the output terminal 8 and the like are likely to cause contact failure. This structure has a drawback that contact failure tends to occur when a large number of solar cell elements 1 are connected. That is, when a large number of solar cells are connected, the connection positions of some of the solar cell elements 1 are displaced,
This is because it becomes difficult to dispose all the solar cell elements 1 at correct positions and reliably connect the output terminals 8.

In order to connect the solar cell elements in place,
The connection structure shown in FIG. 2 is also described in the above publication. This solar cell device projects onto the surface of the fixed base 11 and connects to the contact 1.
2 are provided. The solar cell element 1 is provided with an output terminal (not shown) that can be inserted into the connection contact 12 and connected.
This device connects the output terminal of the solar cell element 1 to the connecting contact 12
Then, the solar cell element 1 can be mounted at a fixed position on the fixed base 11. With this structure, a large number of solar cell elements 1 can be mounted without displacement. However, the device of this structure
There is a drawback that it is difficult to smoothly remove the plate-shaped solar cell element 1 and reduce contact failures. Since the plate-shaped solar cell element 1 is connected close to the fixed base 11, it is difficult to easily pull it out. This is because it is connected to the fixed base 11 in a state where it is difficult to grasp. Further, if the plate-shaped solar cell element 1 is forcibly pulled out, bending stress acts, and there is a drawback that it is easily damaged. In order to prevent unreasonable force from acting on the solar cell, it is necessary to pull out the solar cell element 1 in a parallel posture, in other words, with a balanced pulling force on the left and right. For this reason, it is difficult to easily attach and detach the solar cell element 1 so that an unreasonable force does not act on the solar cell element 1. In particular, if the output terminal is strongly pressed and connected to the connection contact 12 in order to reduce the contact failure, the output terminal cannot be lightly attached and detached, and this adverse effect becomes large.

Further, the solar cell devices having the structures shown in FIGS. 1 and 2 have a drawback that it is difficult to take out an output from the middle of the solar cell elements in a state of being connected in series or in parallel. This is because the solar cell elements cannot be exposed close to each other and the output terminals cannot be exposed on the surface in the connected state.

[0007] The present invention has been developed for the purpose of solving such disadvantages. An important object of the present invention is to provide a solar cell device capable of easily and easily attaching and detaching a solar cell element in a fixed position.

Still another important object of the present invention is to provide a solar cell device which can be reliably connected in a state of being connected in series or in parallel with reduced contact failure. Furthermore, another object of the present invention is to provide a solar cell device in which the solar cell element can be attached and detached without applying excessive force.

[0009]

The solar cell device of the present invention comprises a plurality of solar cell elements 1 and a connector 2 for connecting the solar cell elements 1 in series or in parallel. By changing the direction in which the solar cell element 1 is connected to the connector 2, the connection of the solar cell element 1 can be switched in series or in parallel.

Further, in the solar cell device of the present invention, the connector 2 is constituted by the plurality of connection bases 3, the connecting guides 4, and the stoppers 14. The connector 2 connects the plurality of solar cell elements 1. The connection guide 4 connects the connection base 3 so that the connection base 3 can move in the direction in which the solar cell element 1 is sandwiched. The stopper 14 fixes the connection base 3 to the connection guide 4. In the connector 2 of this structure, the solar cell element 1 is connected between the connection bases 3 so that the connection base 3 can be moved to the coupling guide 4, and in this state, the connection base 3 connecting the solar cell elements 1 is connected. Is fixed to the coupling guide 4 with a stopper 14 so that the solar cell element 1 and the connection base 3 are electrically connected.

Further, in the solar cell device according to the second aspect of the present invention, in order to connect the solar cell elements 1 easily and surely, the end portions of the solar cell elements 1 are inserted and connected. The slit 6 is provided in the connection table 3.

Furthermore, in the solar cell device according to claim 3 of the present invention, the external terminal 7 connected to the solar cell element 1 is connected in order to extract the output from the connection point of the measurement probes connected in series or in parallel. It is provided on the stand 3.

[0013]

In the solar cell device of the present invention, the solar cell element 1 is connected via the connection base 3. That is, the solar cell elements 1 are sandwiched between the connection bases 3 and the solar cell elements 1 are connected in series or in parallel. Since the connection table 3 is mounted on the connection guide 4 so as to be movable only in the sandwiching direction, the solar cell elements 1 are not displaced at the connection portion, and the electrode terminal 17 can be securely attached at a fixed position. Electrically connected,
Poor contact can be prevented. Furthermore, when connecting the solar cell elements 1, the connection method can be easily switched between series and parallel by rotating the direction of each solar cell element 1 90 degrees. The device of this structure is suitable as a teaching device because the connection of each element can be easily changed.
In particular, it can be configured so that the direction of the elements, that is, the connection method between the elements can be visually confirmed, and the switching can be easily performed. The characteristics can be confirmed immediately.

[0014]

Embodiments of the present invention will be described below with reference to the drawings. However, the embodiments described below exemplify a solar cell device for embodying the technical idea of the present invention, and the present invention does not specify the solar cell device as the following.

Further, in this specification, in order to facilitate understanding of the claims, the numbers corresponding to the members described in the embodiments will be referred to as "claims" and " In the column of “Means of the above”. However, the members described in the claims are not limited to the members of the embodiments.

An example of the embodiment of the solar cell device of the present invention is shown in FIGS. 3 and 4. The solar cell device shown in FIGS. 3 and 4 shows a state in which two solar cell elements 1 are connected to a connector 2 having three connection bases 3. The connector 2 shown in these figures includes a connection guide 4 and a connection base 3. The connection table 3 is attached so as to be slidable on the connection guide 4. The lower surface of the connection table 3 is provided with a slide table 5 that can move the connection table 3 to an arbitrary position on the connection guide 4. The connection base 3 is slid along the connection guide 4, and the solar cell element 1 is sandwiched between the connection bases 3.
Is fixed to the fixed position of the connecting guide 4 by the stopper 14.

The connecting guide 4 shown in FIG. 3 has an elongated plate shape.
It is made of plastic, metal, etc. A plurality of connection bases 3 are slidably mounted on a plate-shaped connection guide 4 via a slide base 5. The slide base 5 has an insertion hole 13, and the connection guide 3 is inserted into the insertion hole 13 so that the connection base 3 can slide. Therefore, the connection base 3 can be added or separated from the end of the connection guide 4.

The slide base 5 is a rectangular parallelepiped having an opening on its side surface, and has an insertion hole 13 according to the size and shape of the connecting guide 4.
Is provided. The size of the opening of the insertion hole 13 is set to be slightly larger than that of the connection guide 4 so that the connection guide 4 can slide while being inserted into the insertion hole 13. In FIG. 3, since the cross section of the connecting guide 4 is rectangular, the insertion hole 13 of the sliding base 5 is also opened in a rectangular shape. Although not shown, if the connection guide has a cylindrical shape, the insertion hole has a cylindrical shape. However, in the cylindrical connection guide, the stopper rotates along the circumference, so that the connection base does not shake to the left and right,
Install keys and splines to prevent them from rotating.
The cross section of the connection guide and the insertion hole is preferably rectangular, square, or polygonal.

A fixing screw serving as a stopper 14 is provided on the slide base 5 so that the slide base 5 can be fixed so as not to move on the connection guide 4. A screw hole is provided in a part of the slide base 5, and the stopper 14 is inserted there. Stopper 14 that penetrates the slide base 5
Can be fixed so that the tip of the threaded portion is pressed against the connection guide 4 and is fixed so as not to move due to strong frictional force.
The connection base 3 having the stopper 14 of this structure can be freely slid on the connection guide 4 to easily change its position, and can be easily fixed at any position. Connection stand 3 shown in FIG.
, The stoppers 14 are provided at one position on the side surface of the slide base 5, but the stoppers 14 can be provided at a plurality of positions on the side surface, or on the opposite side surface or both surfaces. Loosen the stopper 14 when sliding the connection base 3 on the connection guide 4, and stopper 14 when fixing the connection base 3.
To fix the slide base 5.

The structure for sliding the connection base 3 on the connection guide 4 may be the structure shown in FIG. 3, the structure shown in FIG. 5 or the structure shown in FIG. In the connecting structure shown in FIG. 5, the connecting guide 4 is provided with a slit 15 having an inverted T-shaped cross section. A sliding table (not shown) provided on the lower surface of the connection table 3 is also formed in an inverted T shape so that the slit 15 and the sliding table have the same shape so that they can freely slide. In the connector of this figure, a fixing screw which is a stopper 14 is provided through the coupling guide 4. The stopper 14 is screwed into a screw hole provided in the connection guide 4 and presses the slide base to stop it. There are a plurality of stoppers, and the connection table is provided at a position where the solar cell element can be sandwiched and stopped. Further, in the connection structure shown in FIG. 6, the cross section of the connection guide 4 itself has an inverted T shape. The connection base 3 includes two plate-shaped slide bases 5 that can slide along the vertical surface of the connection guide 4. A stopper 14 is provided on the side surface of the slide base 5, and the slide base 5 is fixed to the connection guide 4 by the stopper 14.

The connection table 3 fixed to the upper part of the slide table 5 is
It is attached so as to be slidable on the connection guide 4. The slide base 5 can move on the connection guide 4 in a direction parallel to the connection guide 4, in other words, in a direction in which the connection base 3 sandwiches the solar cell element 1. Therefore, the connection base 3 fixed to the slide base 5 can also move only in the direction in which the solar cell element 1 is sandwiched, and cannot move in the direction orthogonal to the connection guide 4. The connection base 3 having this structure can surely bring the terminals into contact with each other in a predesigned state. This is because the connection position of the terminal does not shift because it cannot swing to the left or right with respect to the moving direction.

The connection base 3 has a box shape, and can be made of transparent plastic or the like so that the internal wiring can be confirmed from the outside. In the connection base 3 shown in FIG. 3, the end portion of the upper surface parallel to the sliding direction has a sloped shape in order to provide the external terminal 7. In addition, a connecting slit 6 for connecting the solar cell elements 1 is provided on a surface orthogonal to the sliding direction so that the solar cell elements 1 can be connected in series or in parallel. The connecting slits 6 are symmetrically provided on the facing surface as shown in FIG. 7.

The connecting slit 16 is provided with a connecting terminal 16 for electrically connecting the solar cell element 1. The connection terminals 16 are not provided on the entire surface of the connection slit 6, but are provided at two positions on both ends of the connection slit 6 and are insulated from each other. Each connection terminal 16 is a copper plate or the like having a length substantially equal to that of the connection base 3, and projects into the connection slit 6 on the opposing surface. Therefore, the connecting terminals 16 are continuous with the connecting slits 6 facing each other, and the connecting terminals 16 are electrically connected by the left and right connecting slits 6 as shown in FIG. , Insulated from each other. As shown in the cross-sectional view of FIG. 8, the connection terminal 16 may be a single copper plate, but the left and right connecting slits 6 may be separate members, and both may be electrically connected by a lead wire or the like. . The portion of the connection terminal 16 that protrudes into the coupling slit 6, that is, the portion that electrically contacts the solar cell element 1 is bent into a convex shape, and the electrode terminal 1 of the solar cell element 1 is formed.
It is possible to press 7 and make sure contact.

Further, the external terminal 7 can be provided by branching to the intermediate portion of the connection terminal 16. The external terminal 7 can be exposed to the outside of the connection table 3 to serve as a connection point of the measurement probe or the like, from which electric signals such as voltage and current can be detected. In the connection board 3 shown in FIG. 3, both edges of the upper surface are sloped, and the external terminals 7 are provided at about 45 each.
It is protruded every time to make it easy to connect the measurement probe from above or from the side.

The end portions of the solar cell element 1 are inserted into the connection slits 6 provided at both ends of the connection base 3, and the solar cell element 1
Both ends of the solar cell element 1 are sandwiched by the connection base 3, and the solar cell elements 1 are connected in series or in parallel. FIG. 9 shows a plan view of the solar cell element 1 and FIG. 10 shows a bottom view thereof. Solar cell element 1
Is an element which is made of amorphous silicon or the like and generates an electromotive force between the electrode terminals 17 by a photoelectromotive force. The solar cell element 1 shown in the figure is composed of one module provided with a light receiving portion on the surface, and has a square shape that is vertically and horizontally symmetrical so that the modules can be connected in the same state even when rotated by 90 degrees. At both ends of the solar cell element 1, + electrode terminals 17A and − electrode terminals 17B are provided on opposite sides so as to obtain electromotive force. The solar cell element 1 shown in FIG. 9 has polarities on its outer surface so that the + pole and the − pole can be distinguished at a glance so that it can be easily used as a teaching material.

However, in the solar cell element 1 of the present invention, the electrode terminals 17 are provided only at the corners as shown in FIG. The electrode terminals 17 provided at the corners are the connecting slits 6 of the connection base 3.
It is provided at a position, a width and a size corresponding to the connection terminal 16 so as to surely make an electrical connection with the connection terminal 16 when it is inserted into In the solar cell element 1 having this structure, the connection state can be changed by the surface of the connection base 3 which is inserted into the connection slit 6.

For example, as shown in FIG. 11, if the left side of the solar cell element 1 is connected as a + pole and the right side is a − pole, the solar cell elements 1 can be connected in series. Further, as shown in FIG. 12, if the upper side of the solar cell element 1 is connected as a + pole and the lower side is a − pole, the solar cell elements 1 can be connected in parallel. In this way, the connection state can be easily changed by changing the connecting surface of the solar cell element 1. This is because the contact portions between the electrode terminals 17 of the solar cell element 1 and the connection terminals 16 of the connection base 3 are not linear but dot-shaped. In the linear electrode, although the lines can be connected to each other, when they are rotated by 90 degrees, the line and the point are connected, and the point terminal is short-circuited with the line terminal. If it is a point-like terminal, even if it is rotated 90 degrees, it becomes a point-to-point connection and no short circuit occurs. Therefore, the connection state can be changed by arranging +-so that the combination can be changed.

The electrode terminal 17, which is a conductive surface, can be provided only on the bottom surface of the solar cell element 1 as shown in FIG.
However, although not shown, the electrode terminals may be provided on the top surface of the solar cell element, on the top surface and the bottom surface, or may be provided in a U shape so as to be continuous from the top surface to the side surface and to the bottom surface. In these cases, the connection terminals of the connection base are provided at the corresponding positions and shapes.

In the solar cell device of the present invention, the solar cell elements 1 can be connected in series or in parallel and separated as follows. The solar cell element 1 is mounted on the connection base 3. The stopper 14 is loosened so that the solar cells 1 can be sandwiched between the connection bases 3 so that the connection guide 4 can be freely slid. It is not necessary to connect the solar cell elements 1 using all of the connection bases 3, and the number of connection bases 3 according to the required number of solar cell elements 1 can be used. For example, when the experiment is performed by connecting five solar cell elements 1, six connection stands 3 are used. The unused connection table 3 is gathered at the end of the connection guide 4 and fixed appropriately. In addition, when the number of the connection bases 3 mounted on the connection guide 4 is insufficient to connect a large number of solar cell elements 1, a considerable number of connection bases 3 are easily added from the end of the connection guide 4. it can.

Next, the end portion of the solar cell element 1 is inserted into the connection slit 6 of the connection base 3. One end is inserted into the connecting slit 6, another connecting base 3 is brought closer to the other end, and the connecting slit 6 is inserted. Since the connection base 3 vertically approaches the end surface of the solar cell element 1 to be connected, the connection terminal 16 of the connection slit 6 is connected to the end portion of the solar cell element 1 at a correct position. The end portion of the solar cell element 1 inserted into the connection slit 6 is determined as to which end face it depends on whether the solar cell element 1 is connected in series or in parallel.
In other words, the side of the solar cell element 1 to be inserted into the connection slit 6 provided in the connection base 3 is determined by the wiring method. In the case of connecting in series, one side of the solar cell element 1 is a positive pole, that is, the positive electrode terminal 17A is inserted into the connecting slit 6, and the opposite side, that is, the negative electrode terminal 17B is connected to another connecting base 3. To do. Similarly, the other solar cell elements 1 are also sequentially mounted in the connection base 3 in the same direction.

Alternatively, in the case of connecting in parallel, the side having the + pole at one end and the − pole at the other end (the lower side in FIG. 9) is inserted into the connecting slit 6 by turning 90 degrees from the serial state and facing each other. Similarly, the side having the + pole and the − pole (the upper side in FIG. 9) is inserted into another connecting slit 6. The solar cell element 1 and the insertion hole are connected in the state shown in FIG.

From the temporarily fixed state, the stopper 14 is tightened to fix the connection table 3 to the connection guide 4. In this state, the solar cell element 1 is firmly fixed to the connection base 3, and the solar cell elements 1 are electrically connected to each other via the connection base 3.
The solar cell devices that are connected in series or in parallel generate light by receiving light at the light-receiving section and generating electromotive force. This state can be observed by obtaining a signal from the external terminal 7 provided on the connection table 3. For example, when connected in series, the connection blocks 3 located at both ends
An oscilloscope measuring probe can be connected to the external terminal 7 to observe the entire voltage waveform, and the voltage of each part can be measured from the external terminal 7 of the intermediate connection base 3.

When changing the connection method of the solar cell element 1 or disassembling it, the stopper 14 is loosened, the connection base 3 is displaced, and the end of the solar cell element is pulled out from the connecting slit 6, so that the solar cell element can be easily removed. 1 can be separated from the connection base 3.

The solar cell device of the present invention is most suitable for use as a teaching material. However, the present invention is not limited to use as a teaching material. In the solar cell device of the present invention, the voltage and current can be changed by changing the connection method of the solar cell elements 1, and the electromotive force can be changed by increasing or decreasing the number of solar cell elements 1 used. In addition, the intermediate connection stand 3
Output can be taken from the external terminal 7,
It can be tested that the voltage changes by changing the external terminal 7 when the solar cell elements 1 are connected in series. Further, it can be tested that the output voltage and the current do not change even if the connection of the external terminal 7 is changed in the state where the solar cell elements 1 are connected in parallel. Thereby, the output voltage can be changed from the same light amount. Due to this characteristic, it can also be used as a simple power source. It can also be used for demonstrations and exhibitions.

[0035]

According to the solar cell device of the present invention, the connection of solar cell elements can be easily changed to series or parallel with a device having a simple structure. This is because the connection base can be moved along the connection guide to connect or disconnect the solar cell element to the connection base. Further, the device of the present invention has a feature that it is possible to prevent contact failure of the connection portion in a state where the solar cell elements are connected in series or in parallel. This is because by moving the connection table along the connection guide, the solar cell elements can be sandwiched between the connection tables and electrically connected. The connection base that moves in the connection direction and is stopped by the connection guide can prevent positional displacement that causes poor contact when the solar cell element is sandwiched. Therefore, the solar cell device of the present invention realizes the features that the solar cell elements can be electrically connected in series or in parallel easily and accurately, and the failure due to poor contact can be minimized. Furthermore, in the device of the present invention, the connection base can be stopped at the position where the solar cell element is sandwiched, and the solar cell element can be connected to the connection base. Therefore, there is a feature that the solar cell element can be easily connected to the connection base without worrying about the position where the connection base is fixed.

Further, in the solar cell device according to the second aspect of the present invention, the connection base is provided with a connection slit, and the end portion of the solar cell element is inserted therein to be connected. In the solar cell device having this structure, one end of the solar cell element can be inserted into the connection slit and the other end can be inserted by bringing the connection base close to the connection guide, so that the electrodes can be reliably connected to each other at accurate positions. Therefore, it is possible to realize the feature that the solar cell elements can be connected more easily and surely in combination with the above-described connection base that slides on the connection guide and does not move in the direction of displacement. Further, since the solar cell element can be attached / detached simply by inserting / removing it into / from the connection slit, the attachment / detachment can be performed very easily, and the harmful effects such as damage and contact failure during the attachment / detachment can be minimized. In particular, if the solar cell element has a square shape, it can be connected in exactly the same manner even if it is rotated by 90 degrees, the wiring method can be easily changed, and the connection can be similarly ensured.

Furthermore, in the solar cell device according to the third aspect of the present invention, the connection stand is provided with an external terminal electrically connected to the solar cell element. Therefore, signals such as voltage and current can be taken out from the middle of the connecting portion by the external terminal. The solar cell device having this structure does not require the troublesome work such as wiring change and terminal mounting for taking out the terminals for measurement, which are conventionally required. Moreover, when changing the wiring method in series or in parallel, it was necessary to redo these operations in the conventional case. Especially, in the solar cell device that does not have a terminal exposed to the outside at the intermediate connection part,
It is difficult to measure the electrical characteristics of the middle part. The solar cell device of the present invention can measure the output voltage and current from the external terminals in the state where the solar cell elements are connected in series or in parallel, and observe the state of the output voltage and output current in each connection state. Therefore, in the device of the present invention, the confirmation of the output characteristics such as the voltage and the current due to the difference in the connection method of the solar cell elements can be easily observed at various positions. In particular, the solar cell device of the present invention, which is most suitable for teaching materials, displays the positive electrode and the negative electrode on the electrode terminals of the solar cell element, and the connection base is made transparent so that the wiring method can be seen from the outside. You can easily check the voltage, current, etc. at the external terminals of each connection board, as well as the relationship between wiring and output characteristics can be easily understood, and ideal features for teaching materials can be realized. .

In addition, the solar cell device of the present invention can be designed compact because the connector for mounting the solar cell element can be constructed with a simple structure of the connection guide and the connection base sliding here. Also, if the connection base and the connection guide can be easily connected, they can be easily attached and detached, and the number of connection bases attached to the connection guide can be easily increased or decreased according to the number of solar cell elements used. it can. Further, since the same connection bases can be used for all the connection bases, it is not necessary to pay attention to the order of arrangement even when the number of connection bases is increased or decreased, which is also convenient in design and production.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view showing a conventional solar cell device.

FIG. 2 is a perspective view showing another conventional solar cell device.

FIG. 3 is a perspective view showing a solar cell device of the present invention.

FIG. 4 is a perspective view showing a state in which a solar cell element is mounted on the solar cell device of the present invention.

FIG. 5 is a perspective view showing a solar cell device according to another embodiment of the present invention.

FIG. 6 is a perspective view showing a solar cell device according to another embodiment of the present invention.

FIG. 7 is a plan view showing the connection base of FIG.

FIG. 8 is a sectional view of the connection base of FIG.

9 is a plan view of the solar cell element shown in FIG.

FIG. 10 is a bottom view of the solar cell element of FIG.

FIG. 11 is a plan view showing a state where solar cell elements are connected in series.

FIG. 12 is a plan view showing a state where solar cell elements are connected in series.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Solar cell element 2 ... Connector 3 ... Connection stand 4 ... Connection guide 5 ... Sliding stand 6 ... Connection slit 7 ... External terminal 8 ... Output terminal 8A ... + Output terminal 8B ...
-Output terminal 9 ... Recessed portion 10 ... Connection pin 11 ... Fixed base 12 ... Connection contact 13 ... Insertion hole 14 ... Stopper 15 ... Slit 16 ... Connection terminal 17 ... Electrode terminal 17A ... + Electrode terminal 17
B ...- Electrode terminal

Claims (3)

[Claims] 1. A plurality of solar cell elements (1) and a connector (2) for connecting the solar cell elements (1) in series or in parallel, the solar cell element (1) being a connector ( In the solar cell device configured to switch the connection of the solar cell element (1) in series or in parallel by changing the connection direction to (2), the connector (2) is the solar cell element (1). Multiple connection boards to connect
(3) and a connection guide (4) that connects the connection table (3) so that the solar cell element (1) can be moved in the direction in which it is sandwiched,
The stopper (1) that secures the connection base (3) to this connecting guide (4)
4) and, connecting the solar cell element (1) between the connection table (3) so that the connection table (3) can be moved to the connection guide (4), and connecting the solar cell element (1) Fix the base (3) to the connection guide (4) with the stopper (14) and connect the solar cell element (1) and the connection base (3).
A solar cell device, wherein the solar cell device is configured to be electrically connected to. 2. The solar cell device according to claim 1, wherein the connection table (3) has a connection slit (6) for inserting and connecting an end portion of the solar cell element (1). 3. The solar cell device according to claim 1, wherein the connection table (3) has an external terminal (7) connected to the solar cell element (1).