JP3285316B2 - Terminal box for solar cell module - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a terminal box mounted on a solar cell main body so as to take out an output of the solar cell main body in a solar cell module installed on a roof of a house or the like.

[0002]

2. Description of the Related Art An example of a solar cell module which receives sunlight and generates electricity is shown in FIGS. The solar cell module 60 has a solar cell body 61 having a rectangular flat plate shape. This solar cell body 6
1 has a superstrate structure in which a plurality of solar cells arranged in a matrix are electrically connected in series or in parallel by an interconnector or the like. As shown in FIGS. 16 and 17, a white tempered glass plate 6 is provided on the front surface side of the solar cell main body 61 via a filler 62 formed in a thin plate shape by a transparent resin.
3 are stacked. A weather-resistant film 65 is also laminated on the back surface side of the solar cell main body 61 via a filler 64 formed of a transparent resin into a thin flat plate shape. Then, the solar cell body 61 is formed by the white strengthened glass plate 63 and the weather-resistant film 65 so that each filler 6
The solar cell body 66 is sandwiched between the solar cell bodies 2 and 64 to form a flat plate-shaped solar cell body 66 as a whole.

[0003] The solar cell main body 66 has a frame 6
7. Each frame 67
The frame member 67a on the long side along the longitudinal direction and the frame member 67a on the short side along the width direction, each side edge portion,
It is fitted via a buffer 67c (see FIG. 16).
Each of the frame members 67a of the frame 67 is formed by extruding aluminum which has been subjected to alumite treatment and clear coating. As shown in FIG. 15, adjacent frame members 67a are connected to each other by screws 67b, and a plurality of screw holes 67d for fixing the frame member 67a on each long side to the gantry are provided in each frame member 67a. ing.

[0004] As shown in FIG.
A terminal box 70 is provided on the back surface at one end of the terminal box 70. The terminal box 70 has a pair of output cables 6 for taking out the electric output of the solar cell body 61.
8 are connected. At the distal end of each output cable 68, a plug 68a of a waterproof connector and a socket 68b of a waterproof connector are provided, respectively.

[0005] For example, as shown in FIG. 18, a large number of such solar cell modules 60 are attached to a gantry arranged on a roof of a house so as to be adjacent to each other in a vertical direction and a horizontal direction. Each of the solar cell modules 60 arranged in the vertical direction is electrically connected and systematized, and one output cable 68 of the solar cell module 60 located at the end is connected to the array output cable 78. ing.

[0006] Adjacent solar cell modules 60 are
The respective output cables 68 are electrically connected to each other by connecting them. FIG. 19A is a side view of a connector for connecting the output cables 68 to each other. The plug 68a of the waterproof connector of the output cable 68 of one solar cell module 60 is inserted into the socket 68b of the waterproof connector provided at the end of the output cable 68 of the other solar cell module 60. Then, as shown in FIG. 19 (b), one of the plug 68a and the socket 68b of the waterproof connector is rotated and locked, whereby the connector is brought into a joined state.

The output cable 68 extending from the terminal box 70 is drawn out to the front side of the solar cell module 60, and extends from the terminal box 70 provided in the adjacent solar cell module 60 as shown in FIG. Each of the output cables 68 and the plug 68a and the socket 68b of the waterproof connector are connected to each other and are accommodated in a space between the two solar cell modules 60.

FIG. 21 is a schematic view showing a state where the solar cell module 60 is mounted on the roof of a house. Each solar cell module 60 includes a gantry 7 arranged on a roof of a house.
3, are arranged in the vertical and horizontal directions and mounted in a matrix. The output of each solar cell module 60 attached to the gantry 73 is
8 to the junction box 74 and further to the junction box 7
4 to the inverter 75. The inverter 75 converts DC power generated by each solar cell module 60 into AC power. The AC power converted by the inverter 75 is supplied from the indoor switchboard 76 to 2
Is supplied to the home via one of the watt-hour meters of the measuring unit 77, and the surplus electric power is supplied to the other of the measuring unit 77. It is supplied to the outside as commercial power through the meter.

FIG. 22 is a plan view of a terminal box 70 provided on the back surface of the solar cell main body 66. The terminal box 70 has a protective case 71 into which a pair of output lead frames 69 of an interconnector provided on the solar cell main body 66 is inserted. A terminal block 75 is provided on one side edge of the protection case 71.
The output lead frames 69 inserted into the protection case 71 are electrically connected to a pair of relay plates 76 provided on the upper surface of the terminal block 75, respectively. Each relay plate 76 is electrically connected to a screw 72 screwed to the center of the protective case 71 via each relay wire 77.

In the protective case 71, the front ends of a pair of output cables 68 electrically connected to the solar cell body 66 of the adjacent solar cell module 60 are inserted, respectively. The distal end is electrically connected to each screw 72 provided at the center of the protective case 71. Each output cable 68 is fixed in the protective case 71 by a saddle bracket 73. Each screw 72 is electrically connected to each terminal of the bypass diode 74.

FIG. 23 is a perspective view showing another example of a conventional terminal box. In this terminal box 80, a relay plate 82 is attached to a bottom surface portion 81 a of a protective case 81, and a terminal block 83 is screwed to the bottom surface portion 81 a of the protective case 81 so as to cover the relay plate 82. I have. On the upper surface of the terminal block 83, a large number of terminals 86 formed by screws are provided. The relay plate 82 is provided with a pair of conductors 84 to which an output lead frame of an interconnector provided on the solar cell main body 66 is connected.
Each conductor 84 is electrically connected to a predetermined terminal 86 provided on the terminal block 83 via a relay wire 85.

The terminal box 80 is attached to the solar cell main body 66 of the solar cell module 60, and each output lead frame of the interconnector is
An output cable electrically connected to each conductor 84 provided on the relay plate 82 by soldering or the like and electrically connected to the solar cell main body of the adjacent solar cell module is connected to the terminal block 83. Predetermined terminal 8 at
6 are electrically connected to each other.

[0013]

In the terminal box 70 shown in FIG. 22, for each screw 72 attached to the protective case 71, each output lead frame 69 and each output cable 68 are connected to each terminal of the bypass diode 74. Have to be connected, and the connection work is troublesome. Further, it is necessary to fix the end of each output cable 68 inserted into the protection case 71 to the inside of the protection case 71 by the saddle metal fitting 73, and the work for that is also troublesome. Further, in the protective case 71, an output lead frame 69, a bypass diode 74, each screw 7
2. Each relay wire 77, saddle metal fittings 73, etc. are arranged to form a complicated structure.

As shown in FIG. 20, the plug 68a and the socket 68b of the waterproof connector of each output cable 68 of the adjacent solar cell module 60 are drawn out to the front side of the solar cell module 60 and subjected to connection processing. Must be accommodated in the space between the solar cell modules 60, and an operation for that is also necessary.

In the terminal box 80 shown in FIG. 23 as well, each conductor 84 of the relay board 82 and each terminal 86 of the terminal block 83 must be connected by a relay wire 85.
It is also necessary to attach the terminal block 83 formed separately from the terminal block 83 to the inside of the protective case 81, which requires a complicated operation.

The present invention is intended to solve such a problem. The purpose of the present invention is to easily perform wiring work inside, mounting work to a solar cell main body, etc. An object of the present invention is to provide a terminal box of a solar cell module that can be easily electrically connected.

[0017]

According to a first aspect of the present invention, there is provided a terminal box for a solar cell module, wherein a peripheral portion of a solar cell main body formed in a plate shape by a plurality of solar cells is surrounded by a frame. In the solar cell module, a terminal box attached to the solar cell main body so as to take out the output of the solar cell main body, wherein a plurality of output lead frames in the interconnector of the solar cell main body are inserted therein. A protective case disposed on the back surface of the solar cell main body portion and a connector plug attached to an output cable for electrically connecting adjacent solar cell main body portions are provided in the frame so as to be inserted. Connected to each output lead frame so as to be electrically connected to the plug. A connector socket provided in the protective case, disposed between the output lead frame
And a bypass diode .

The terminal box of the solar cell module according to claim 2, wherein the solar cell module is attached to the solar cell main body so as to take out the output of the solar cell main body formed in a plate shape by a plurality of solar cells. A protective case disposed on the back surface of the solar cell main body so that a plurality of output lead frames of the interconnector of the solar cell main body are inserted therein, a bypass diode, and each output lead. A first connection portion electrically connected to the frame , the bypass diode
The second connecting portions fraction is de terminal electrically connected to, and,
An output cable that electrically connects adjacent solar cell bodies
A third connection portion electrically connected to the cable, and a pair of flat connection fittings respectively attached in the protective case.

The terminal box of the solar cell module according to the third aspect is composed of a plurality of solar cells in a flat plate shape.
The output of the solar cell body
Terminal block of the solar cell module attached to the pond main body
An interconnect of the solar cell main body.
Multiple output leadframes are inserted inside
Protective case placed on the back of the solar cell body
And a first contact electrically connected to each output lead frame.
Electrical connection between the connecting part and adjacent solar cell
Connection that is electrically connected to the output cable that connects to the
Parts, each in the protective case
And a pair of flat connection fittings mounted and attached.
And, wherein the fitting is provided between the first connecting portion and a third connecting portion, wherein the stress relief has become possible expansion is provided.

According to a fourth aspect of the present invention, in the terminal box for a solar cell module, the connection fitting is further provided with one or more connection portions.

[0021]

[0022]

[0023]

Embodiments of the present invention will be described below in detail with reference to the drawings.

FIG. 1 is a schematic plan view showing an example of a solar cell module having a terminal box according to the present invention. The solar cell module 10 includes a rectangular flat solar cell main body 11 and a frame 12 fitted to each side edge of the solar cell main body 11 and surrounding the peripheral edge. The solar cell main body 11 has a super-straight solar cell main body in which a plurality of solar cells arranged in a matrix are electrically connected in series or in parallel by an interconnector or the like. On the surface side of the solar battery cell body, a white strengthened glass plate is laminated via a filler formed of a transparent resin into a thin flat plate, similarly to a conventional solar battery module. In addition, a weather-resistant film is also laminated on the back surface side of the solar cell body via a filler formed in a thin plate shape by a transparent resin. And the solar cell body is formed by a white strengthened glass plate and a weather-resistant film.
The solar cell main body 11 has a flat plate shape as a whole, sandwiched between the respective fillers.

The frame 12 has, for example, four frame members 12a made of an extruded product of aluminum which has been subjected to anodizing and clear coating. Are fitted to the respective side edges via cushioning materials.

The terminal box 20 of the present invention is provided on the back surface of one end of the solar cell main body 11. FIG.
Is a plan view showing the internal structure of the terminal box 20. The terminal box 20 has a hollow rectangular parallelepiped protective case 21. The protective case 21 includes a frame member 12 provided on a side edge portion of the solar cell body 11 along the width direction.
a. The protective case 21 has a square bottom surface 21 a facing the back surface of the solar cell body 11.
And a peripheral surface 21b raised from the peripheral edge of the bottom surface 21a. A pair of openings 21c are provided in the bottom surface portion 21a, and a pair of output lead frames 2 in an interconnector for extracting output from each solar cell of the solar cell main body 11 are provided.
2 are inserted into the protective case 21 through the respective openings 21c.

Each output lead frame 22 is provided with a conductor 23a of a socket 23 constituting a connector.
They are connected by solder. Each socket 23 is attached so as to penetrate in the width direction through the frame member 12a to which the terminal box 20 is attached, and the protective case 21 is connected to an opening provided on the outer surface of the frame member 12a.
Through holes 21d provided in the peripheral surface portion 21b. A bypass diode 24 is provided between each output lead frame 22, and each terminal of the bypass diode 24 is connected to a conductor 23 of each socket 23.
are connected by soldering, and the bypass diode 24 and the conductor 23a of each socket 23 are directly and electrically connected.

The solar cell modules 10 are arranged on the roof of a house or the like in a state where they are arranged in a vertical direction and a horizontal direction.
0 are electrically connected to each other by an output cable 31. An output cable 31 used to electrically connect adjacent solar cell modules 10 is
A plug 32 is provided at each end, and each plug 32 is inserted into each socket 23 provided on the frame member 12a. The length of each output cable 31 is set to be slightly longer than the distance between one socket 23 located on the mutually adjacent side in each terminal box 20 provided in each adjacent solar cell module 10. .
Then, by inserting the plugs 32 provided at the respective ends of the output cable 31 into the respective sockets 23 of the adjacent solar cell modules 10, the adjacent solar cell modules 10 are electrically connected to each other.

As described above, each output lead frame 22
By directly electrically connecting the conductors 23a of the sockets 23 with the conductors 23a, the internal configuration of the protective case 21 is significantly simplified, and the wiring work is also facilitated. Moreover, the connection work between the output cable 31 and the terminal box 20 may be performed by inserting the plug 32 provided in the output cable 31 into the socket 23, and the connection work is extremely easy. Further, the respective solar cell main bodies 11 in the adjacent solar cell modules 10 are also connected by the output cable 31 along the frame member 12a of the frame 12,
The handling of the output cable 31 is also easy.

FIG. 3 is a plan view showing another example of the terminal box 20 of the present invention. The terminal box 20 includes a pair of through holes 2 provided in a peripheral surface 21 b of the protective case 21.
The output cables 33 pass through 1d.
The end of each output cable 33 is inserted directly into the protective case 21, and the end of each output cable 33 is connected to the saddle fitting 2 screwed to the bottom surface 21 a of the protective case 21.
6. An end of each output cable 33 fixed by the saddle bracket 26 has an electric wire 33a.
Each of the wires 33a is exposed from the insulating coating, and as shown in FIG.
Are provided respectively.

In the protective case 21, the solar cell body 1
1, each output lead frame 22 of the interconnector is inserted through each opening 21c, and each output lead frame 22 is a flat plate arranged along the bottom surface 21a of the protective case 21. Each connection fitting 27
Are soldered respectively. Each connection fitting 27 is attached to the bottom surface 21a of the protective case 21 by a screw 28, and as shown in FIG. 5, the first connection portion 2 extending along each output lead frame 22 by a metal plate.
7a and a second connection portion 27b protruding laterally so as to approach each other on the far side of each output lead frame 22 is formed in an L-shape. An end of each output lead frame 22 is directly connected to an end of the first connection portion 27a close to each output lead frame 22 by soldering. Therefore, the connection fitting 27 and each output lead frame 22 are connected. And are directly electrically connected. Also, the second connection portion 27
At the tip of b, each terminal of the bypass diode 24 is
Each is connected by soldering, so
The connection fitting 27 and the bypass diode 24 are directly electrically connected.

A screw hole 27c (third connection portion) is provided at a corner of each connection fitting 27, and a screw 28 is inserted into the screw hole 27c and attached to the bottom surface 21a of the protective case 21. Have been. Each screw 28 has a terminal fitting 34 attached to each output cable 33 described above.
Is inserted through the screw hole 27c of the connection fitting 27 with the inside of the screw hole 34a.
4 and the connection fitting 27 are electrically connected.

The connection fitting 27 is made of stainless steel, iron, brass,
It is composed of a metal plate of phosphor bronze, copper, silver, aluminum, alloy, or the like. Alternatively, the surface may be made of an insulating material such as a synthetic resin, and the surface thereof may be plated with tin plating, nickel plating, chromate plating, solder plating, or the like.

With this configuration, the number of components is reduced, and the internal structure of the terminal box 20 is simplified.
In addition, since wiring work in the terminal box 20 is facilitated, wiring mistakes can be reduced, and reliability is significantly improved.

FIG. 6A shows another example of the connection fitting 27. As shown in FIG. 6B, each connection fitting 27 is formed by a pair of rectangular metal pieces 27d. Each metal piece 27d has one end,
Screw holes 27c are provided, and each metal piece 27
d are arranged in an orthogonal state, the screw holes 27c are overlapped with each other, and are attached to the bottom surface 21a of the protective case 21 by screws 28 inserted into the screw holes 27c.

FIG. 7A is a plan view showing still another example of the connection fitting 27, and FIG. 7B is a sectional view taken along the line AA. The connection fitting 27 is connected to the first connection portion 2 connected to the output lead frame 22 of the interconnector.
A stress relief 27g is provided at the center of 7a. The stress relief 27g is connected to the first connection portion 2
The cross section has a wavy shape so that it can expand and contract in the longitudinal direction of 7a.

In the connection fitting 27 having such a configuration, although the output lead frame 22 of the interconnector in the solar cell module 10 and the output cable 33 are directly connected by the screw 28, the output cable 3
Since the external force applied to 3 is absorbed by the stress relief 27g, there is no possibility of transmission to the output lead frame 22. In addition, the stress relief 2 in the shape of a wave
7 g, the output lead frame 22 and the bypass diode 24 are connected to the connection fitting 27 because the surface area is increased.
When soldering, the heat radiation can be promoted.

The shape of the stress relief 27g is not limited to such a wave shape, but may be configured to protrude upward in a semicircular cross section as shown in FIG. 7 (c), and as shown in FIG. 7 (d). A configuration that forms a step, a configuration that projects downward in a square shape as shown in FIG. 7E, and a configuration that projects upward in a square shape as shown in FIG. 7F may be used.

The connection fitting 27 is shown in FIGS. 8 (a) and 8 (b).
As shown in FIG. 5, a pair of insertion portions 2 into which the terminal portion of the bypass diode 24 is inserted is provided at the tip of the second connection portion 27b.
7h may be formed by cutting and raising.
Thus, by providing the pair of insertion portions 27h, connection with the terminal portion of the bypass diode 24 becomes easy. In this case, by soldering the terminal of the bypass diode 24 inserted in each insertion portion 27h,
The connection between the connection fitting 27 and the terminal of the bypass diode 24 is further strengthened.

When it is necessary to electrically connect to three or more places by the connection fittings 27, the shape may be such that a required number of connection parts are projected. When the connection fitting 27 is electrically connected to the three connection portions, the connection portion 27e may have a shape in which the three connection portions 27e protrude as shown in FIG. Further, when it is necessary to electrically connect to the five connection portions, as shown in FIG. 9B, the five connection portions 27e may be formed in a protruding shape.

FIG. 10 shows still another example of the connection fitting 27.
Third connection part 2 connected to the exposed electric wire 33a
7f is provided in a protruding state. An insertion piece is provided in the third connection portion 27f so that the electric wire 33a is inserted. Since such a connection fitting 27 is connected to the output cable 33 in advance, the connection work with the output cable 33 in the protection case 21 becomes unnecessary, and the wiring work in the protection case 21 is further facilitated. become.

Further, the connection fitting 27 is not limited to the configuration directly connected to the output lead frame 22, but as shown in FIGS. 11 (a) and 11 (b), the first connection portion 22a has a rectangular plate shape. Screw one end of auxiliary metal fitting 29a
b, and the other end of the auxiliary fitting 29a and the first connection portion 27a are used to connect the output lead frame 2
2 may be sandwiched and held. Further, as shown in FIGS. 11C and 11D, the auxiliary fitting 29a may be attached to the connection fitting 27 by a screw 28 for attaching the connection fitting 27 to the bottom surface 21a of the protective case 21. In any case, the soldering work for electrically connecting the output lead frame 22 and the connection fitting 27 is not required, and the workability is improved.

[0043] Figure 12 is a plan view showing an example of pin box 20. In this terminal box 20, one of the output cables 33 is similar to the terminal box 20 shown in FIG.
The protective case 21 is fixed to a bottom surface 21 a of the protective case 21 by a saddle fitting 26 screwed. At the end of the output cable 33 located in the protection case 21, the electric wire is exposed from the insulating coating, and the terminal fitting 34 is attached to the electric wire. The terminal fitting 34 is attached to the bottom surface 21 a of the protective case 21 by a screw 28. The terminal fitting 34 and the screw 28 are in an electrically connected state.

In the protective case 21, the solar cell body 1
The pair of output lead frames 22 of the interconnector attached to the first connector 1 are inserted through the respective openings 21c provided on the bottom surface 21a, and each output lead frame 22 is attached to the protective case 21. Each of them is soldered to the flat connection fitting 27. The terminals of the bypass diode 24 are soldered to the respective connection fittings 27.
And the bypass diode 24 are directly electrically connected. The one connection fitting 27 is in a state of being electrically connected to the screw 28 in a state of being electrically connected to the terminal fitting 34.

At the end of the output cable 33 pulled out from the terminal box 20, a socket 35 of a waterproof connector is attached.

Protective case 21 in terminal box 20
Is provided with a cylindrical insertion hole 21e into which a plug 35 of a waterproof connector provided at an end of the output cable 33 can be fitted. A plug 36 inserted into the socket 35 of the waterproof connector is provided in the insertion hole 21e. The plug 36 is integrally supported on the inner back surface of the insertion hole 21e so as to be along the axis of the insertion hole 21e.
The plug 36 is electrically connected to the other connection fitting 27 that is not connected to the output cable 33.

As described above, one output lead frame 2
By directly electrically connecting the connector 2 and the plug 36 of the connector, the internal configuration of the protective case 21 is significantly simplified, and the wiring operation is also facilitated. Moreover, by inserting the socket 35 of the output cable 33 provided in the other solar cell module 10 into the insertion hole 21e,
Since the socket 35 and the plug 36 are electrically connected, the connection operation is extremely easy.

[0048] Figure 13 is a perspective view showing another example of the pin box. The terminal box 40 has a rectangular bottom surface portion 41 facing the back surface of the solar cell body 11.
a and a peripheral surface portion 41b raised from the peripheral edge of the bottom surface portion 41a have a protective case 41 integrally formed of synthetic resin. In this protective case 41,
A terminal block 42 integrally formed with the bottom surface 41a is provided along one side edge. Further, a pair of openings 41c is provided in the bottom surface portion 41a, and each through hole 4c is provided.
An output lead frame of an interconnector for extracting an output from each solar cell of the solar cell main body 11 is inserted through 1c. Further, each opening 41
A pair of through-holes 41d through which the output cable of the solar cell main body is inserted are also provided on the peripheral surface portion 41b close to c.

Terminal block 42 provided in protective case 41
Has a hollow rectangular parallelepiped shape, and is integrally formed with the bottom surface portion 41 a so as to protrude into the protective case 41. The upper surface of the terminal block 42 is divided into four in the longitudinal direction by three partition walls 42a vertically projecting upward. As shown in FIG. 14, a screw insertion hole 42b is provided at the center of the upper surface of the terminal block 42 divided by each partition 42a.
Are provided respectively. Also, the screw insertion hole 42
A pair of engagement holes 42c extending linearly are provided on both sides of b. Each engagement hole 42c is in a state along the width direction of the terminal block 42.

Flat terminal plates 43 are arranged on the upper surface of the terminal block 42 divided by the partition walls 42a. At the center of each terminal plate 43 disposed at each end of the terminal block 42, a screw hole 43a having a screw groove formed on the inner peripheral surface is provided.
3 is provided on each side edge portion with a locking leg 43b which is inserted and locked into each locking hole 42c arranged on the upper surface of the terminal block 42.
Each is provided in a state of projecting vertically downward.
Such a terminal plate 43 is such that each locking leg 43b is
The screw holes 43a and the screw insertion holes 42b on the upper surface of the terminal block 42 are inserted and locked in the respective locking holes 42c.
And are overlapped in a matching state. And terminal board 4
A screw 44 for connecting a wiring is screwed into the third screw hole 43a. No wiring is connected to each screw 44 for attaching each terminal plate 43 disposed at each end of the terminal block 42 to the terminal block 42, and the terminal 44 is an empty terminal.

Each terminal plate 45 arranged at the center of the upper surface of the terminal block 42 has a pair of screw holes 45 on one side.
a are provided side by side, and a screw groove is formed on the inner peripheral surface of each screw hole 45a. And each screw hole 45a
A screw 44 for wiring connection is screwed into the inside. The locking leg 45b is also provided on each side edge of each terminal plate 45.
Are respectively provided in a state of extending downward.
A screw insertion hole 42b through which a pair of screws 44 screwed into each terminal plate 45 can be inserted is provided in a pair of upper surface portions divided by a partition wall portion 42a at the center of the terminal block 42, respectively. A pair of locking holes 42c is provided with the screw insertion hole 42b interposed therebetween.

Each of the terminal plates 45 is also engaged with an engaging leg 45b inserted into the upper surface of the terminal block 42, and a screw 44 is screwed into each screw hole 45a.
Then, as shown in FIG. 13, output leads 46 are connected to the screws 44 screwed into screw holes 45a located on the outside of each terminal plate 45, respectively. Each output lead wire 46 is connected to a cable for connecting adjacent solar cell main bodies. A terminal of a bypass diode 47 is connected to a screw 44 screwed into a screw hole 45a located inside each terminal plate 45.

A conductor 48 is attached to a side edge of each terminal plate 45 opposite to the side where the screw holes 45a are provided, in a state of being electrically connected to each other by soldering or the like. ing. Each conductor 48 is connected to each output lead frame of the interconnect provided in the solar cell main body.

The terminal box 40 having such a configuration is mounted on the back surface of the solar cell main body in the solar cell module. Each output lead frame of the interconnect provided in the solar cell main body is connected to each conductor 48 of each terminal plate 45 arranged at the center of the terminal block 42 by soldering or the like.
An output cable is connected to an output lead wire 46 connected to each terminal board 45.

As described above, the wiring connection work when attaching to the solar cell main body portion may be performed at four places.
Also, since the terminal case 42 is integrally formed with the protective case 41, the work for mounting the terminal block 42 to the protective case 41 is not required, and the work for mounting the terminal box 40 is significantly facilitated.

[0056]

According to the terminal box of the solar cell module of the present invention, the electric connection work inside the protective case is remarkably facilitated, and the work for mounting the protective case is also remarkably facilitated. Electrical connection with an adjacent solar cell module can also be easily performed. Since the terminal block is formed integrally with the protective case, the work of mounting the terminal block becomes unnecessary, and workability is remarkably improved.

[Brief description of the drawings]

FIG. 1 is a plan view showing an example of a solar cell module provided with a terminal module of the present invention.

FIG. 2 is a plan view showing an example of an embodiment of the terminal box of the solar cell module of the present invention.

FIG. 3 is a plan view showing another example of the embodiment of the terminal box of the solar cell module of the present invention.

FIG. 4 is a plan view showing an end of an output cable connected to the terminal box.

FIG. 5 is a plan view showing an example of a connection fitting used for the terminal box.

6A is a plan view showing another example of the connection fitting used for the terminal box shown in FIG. 3, and FIG. 6B is an exploded view of the connection fitting.

7A is a plan view showing still another example of the connection fitting used in the terminal box shown in FIG. 3, FIG. 7B is a cross-sectional view taken along the line AA of FIG. ~ (F)
It is sectional drawing which shows the other example of a connection fitting, respectively.

8A is a plan view showing still another example of the connection fitting used for the terminal box shown in FIG. 3, and FIG. 8B is a perspective view of a main part for explaining a use state of the connection fitting. FIG.

FIGS. 9A and 9B are plan views each showing still another example of the connection fitting used in the terminal box shown in FIG. 3;

FIG. 10 is a plan view showing still another example of a connection fitting used for the terminal box shown in FIG. 3;

11A is a plan view showing still another example of a connection fitting used for the terminal box shown in FIG. 3, FIG. 11B is a side view thereof, and FIG. 11C is used for the terminal box. FIG. 10D is a plan view showing still another example of the connection fitting, and FIG.

12 is a plan view showing an example of pin box.

13 is a perspective view showing another example of the pin box.

FIG. 14 is an exploded perspective view showing a main part of the terminal box.

FIG. 15 is a perspective view showing an example of a conventional solar cell module.

16 is a sectional view taken along line BB of FIG.

FIG. 17 is an exploded perspective view of the solar cell module.

FIG. 18 is a schematic plan view showing an arrangement state of the solar cell module.

FIG. 19A is a side view of a connector for electrically connecting adjacent solar cell modules, and FIG. 19B is a side view showing the connection state.

FIG. 20 is a plan view showing a housed state of an output cable for connecting adjacent solar cell modules.

FIG. 21 is a schematic view showing an attached state of a solar cell module.

FIG. 22 is a plan view of a terminal module used for the solar cell module.

FIG. 23 is a perspective view showing another example of a conventional terminal box of a solar cell module.

[Explanation of symbols]

 REFERENCE SIGNS LIST 10 solar cell module 11 solar cell body 12 frame 12 a frame 20 terminal box 21 protective case 21 a bottom 21 b opening 21 c opening 21 e insertion hole 22 output lead frame 23 socket 23 a conductor 24 bypass diode 26 saddle fitting 27 connection Fitting 27a First connection portion 27b Second connection portion 27c Screw hole 27g Stress relief 28 screw 31 Output cable 32 Plug 33 Output cable 33a Electric wire 34 Terminal portion 35 Socket 36 Plug 40 Terminal box 41 Protective case 41a Bottom surface 41b peripheral surface 41c opening Part 42 Terminal block 42a Partition part 43 Terminal plate 44 Screw 46 Output lead wire 47 Bypass diode

Continuation of front page (72) Inventor Noriyuki Morioka 22-22 Nagaikecho, Abeno-ku, Osaka-shi, Osaka Inside Sharp Corporation (56) References JP-A-7-131045 (JP, A) JP-A-62-54972 (JP) , A) (58) Field surveyed (Int. Cl. ⁷ , DB name) H01R 9/24 H01L 31/04

Claims (4)

(57) [Claims] 1. A solar cell module comprising a plurality of solar cells, each of which has a flat plate-shaped peripheral portion surrounded by a frame, and a solar cell module configured to receive an output from the solar cell body. A terminal box attached to the battery body, comprising: a protective case disposed on a back surface of the solar cell body such that a plurality of output lead frames of the interconnector of the solar cell body are inserted therein; The connector of the connector attached to the output cable that electrically connects the solar cell bodies to each other communicates with the opening provided in the frame so as to be inserted therein, and is electrically connected to the plug. as such, the socket connector provided in the protective case while being each output lead frame and electrically connected, the output lead frame Bypass diode provided between the
Terminal box of a solar cell module characterized by comprising the over-de, a. 2. A terminal box of a solar cell module attached to a solar cell main body so as to take out an output of a solar cell main body formed in a plate shape by a plurality of solar cells, wherein the solar cell main body is provided. A protective case disposed on the back surface of the solar cell body such that a plurality of output lead frames of the interconnector are inserted therein, a bypass diode, and a first connection portion electrically connected to each output lead frame. the bypass diode second connecting portions fraction is terminal electrically connected to, and, adjacent solar cell body portions
Is electrically connected to the output cable
A terminal box for a solar cell module, comprising: a pair of flat connection fittings each having a third connection portion, each of which is mounted in the protective case. 3. A flat plate comprising a plurality of solar cells.
The output of the solar cell body
Terminal block of the solar cell module attached to the pond main body
And a plurality of interconnectors in the interconnector of the solar cell body.
Solar cell so that the output leadframe is inserted inside
A protection case disposed on the back surface of the main body, and a first connection portion electrically connected to each output lead frame;
Electrical connection between adjacent solar cell bodies.
A third connection portion electrically connected to a subsequent output cable
And each is stored in the protective case.
Comprising a pair of plate-shaped fitting which is Attach, and the fitting is provided between the first connecting portion and a third connecting portion, that stress relief is provided becomes stretchable Characteristic solar cell module terminal box. 4. The terminal box for a solar cell module according to claim 2, wherein the connection fitting further includes one or more connection portions.