KR20170102614A - A solar power generation - Google Patents

Abstract

The present invention relates to a solar power system of a battery storage parallel switch independence type. More particularly, the present invention relates to a solar power system capable of discriminating the abnormality of a plurality of solar generators or batteries in individual units. To this end, the solar power system of a battery storage parallel switch independence type of the present invention comprises at least one pair of solar cells which is connected in parallel to each other, at least three charging switches which are connected to a line extended from the solar cell connected in parallel and having a number of 1.5n when the number of the solar cells is n, a battery which is connected to the charging switch, stores power generated from the solar cell, and has a number which is equal to the number of the solar cells, at least two discharge switches which are connected to the battery, are connected to an external line for supplying power charged in the battery to the outside, has n numbers, and a control board for controlling the on/off operation of the charging switch and the discharging switch. It is possible to charge the battery with power generated by using sunlight.

Description

Battery storage parallel switch A solar power generation system

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a battery-storing parallel switch independent photovoltaic power generation system, and more particularly, to a photovoltaic power generation system capable of discriminating an abnormality of a plurality of solar battery cells or batteries.

Instead of fossil energy that emits greenhouse gases, research and development on clean energy has progressed, and solar power generation and wind power generation are emerging as future energy sources that can replace fossil energy.

The solar power generation system uses a solar module that converts solar radiation into DC power, a DC-DC converter that boosts or drops the irregular output DC power of a solar module to a DC power of a certain magnitude, and a DC-DC converter And a microcomputer for charging and storing the boosted or reduced output DC power by controlling the battery and discharging the charged DC power to the DC load.

The charging / discharging control apparatus further comprises an electric conversion section for converting the direct current power supplied from the battery of the charge / discharge control device into the alternating current power and supplying it to the power system or supplying the alternating current load to the alternating current load.

In such a solar power generation system, durability is deteriorated due to aging of the battery due to early damage due to premature damage of the battery, and charging of the battery is substantially inevitable during a period when the amount of sunshine is low.

In addition, since a conversion device for converting a natural energy source into electricity into a solar cell module or a battery for storing electricity needs to be installed in a separate space, it is difficult to achieve miniaturization that can be integrated with a solar module.

 In this way, existing PV modules can store and generate solar energy during the daytime, but it is not possible to supply electricity directly to a place where it is needed, and it is practically impossible to supply power to a place where power is needed in time .

To this end, the battery is used to store the power generated from the solar module in the battery. The power stored in the battery is supplied to an external device, if necessary, to drive an external device.

Generally, a power generation system including a battery includes at least two solar modules and a battery. Therefore, when any one of the at least two solar power generation modules fails, the user can not identify the solar power generation module that has intentionally failed.

Further, when any one of the batteries of at least two batteries fails, the user can not intuitively identify the battery in which the failure has occurred.

Korean Patent No. 10-1377745 Korean Patent Laid-Open No. 10-2012-0117984

A problem to be solved by the present invention is to propose a method of charging a battery with electric power developed using solar light.

Another problem to be solved by the present invention is to propose a method of charging power generated in a solar cell by preference of a user or a predetermined method in preference to at least one of a plurality of batteries.

Another object of the present invention is to provide a method of using power charged in at least one of a plurality of batteries by a user's setting or a predetermined method.

Another problem to be solved by the present invention is to propose a method for determining whether to charge the battery or to supply the power generated by the solar cell to the battery according to the power state charged in the battery.

Another problem to be solved by the present invention is to propose a method of grasping the electric power produced in the solar cell and the electric power charged in the battery.

To this end, the battery-storing parallel switch independent photovoltaic power generation system of the present invention is connected to at least one pair of solar cells connected in parallel by two solar cells, the wirings extending from the solar cells connected in parallel, At least three charging switches having a number of 1.5n, charging the electric power generated by the solar cell, connected in series, and connecting the same number of the solar cells as the number of the solar cells, And a control board connected to an external wiring for supplying power charged in the battery to the outside, at least two discharge switches having n numbers and a control board for controlling on / off operations of the charge switch and the discharge switch do.

The battery-saving parallel switch independent photovoltaic power generation system according to the present invention charges electric power generated from a solar battery into a battery. In particular, when a battery is charged according to a user's setting, a solar battery condition, and a battery condition, Can be efficiently utilized.

In addition, by setting different external apparatuses for supplying power for each battery, it is possible to efficiently supply power to external apparatuses by changing the external apparatuses that supply power according to the charged state of the battery.

In addition, there is an advantage in that the power generated from the solar cell and the charging state of the battery are determined so as to charge the battery or supply the battery to the external device, thereby preventing the battery from overcharging.

Further, the control board for instructing the on / off operation of the switch has an advantage that it can operate without supplying any external power by using the power generated from the solar cell.

1 is a view illustrating a process of charging electricity generated by a solar cell into a battery in a battery-storing parallel switch independent photovoltaic power generation system according to an embodiment of the present invention.
2 is a view for explaining a process of outputting electricity charged in a battery to a battery in a battery saving parallel switch independent photovoltaic power generation system according to an embodiment of the present invention.
3 shows a switch terminal box according to an embodiment of the present invention.
FIG. 4 illustrates a battery-powered, parallel-switched stand-alone solar power generation system in accordance with an embodiment of the present invention.
FIG. 5 illustrates a battery storage parallel switch standalone solar power generation system according to an embodiment of the present invention.
6 illustrates a battery-powered, parallel-switched stand-alone solar power generation system in accordance with an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The foregoing and further aspects of the present invention will become more apparent from the following detailed description of preferred embodiments with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

1 is a view illustrating a process of charging electricity generated by a solar cell into a battery in a battery-storing parallel switch independent photovoltaic power generation system according to an embodiment of the present invention. Hereinafter, a process of charging electricity generated by a solar cell according to an embodiment of the present invention into a battery will be described in detail with reference to FIG.

1 illustrates a battery-storing parallel switch standalone photovoltaic power generation system including a solar cell, a switch, a control board, and a battery. Of course, other configurations than the above-described configuration may be included in the configuration for charging the battery with electricity produced by the solar cell proposed by the present invention.

1, the solar cell includes a first solar cell 101 to a sixth solar cell 106, and the switch includes a first switch SW1 to a ninth switch SW9, The third switch group includes the first switch SW1 to the third switch SW3 and the second switch group includes the fourth switch SW4 to the sixth switch SW6, To a ninth switch SW9. The battery also includes a first battery (401) to a sixth battery (406).

The solar cell proposed in the present invention produces electric power of 24V, 8A. That is, the solar cell proposed in the present invention produces 250 W of power.

The first solar cell 101 and the second solar cell 102 are connected in parallel, and the third solar cell 103 and the fourth solar cell 104 are connected in parallel. The fifth solar cell 105 and the sixth solar cell 106 are connected in parallel. The first solar cell 101 and the second solar cell 102 connected in parallel produce electric power of 24 V and 16 A and the third solar cell 103 and the fourth solar cell 104 connected in parallel to each other are connected to 24V and 16A And the fifth solar cell 105 and the sixth solar cell 106 connected in parallel produce electric power of 24V and 16A.

The wirings of the first solar cell 101 and the second solar cell 102 connected in parallel are connected to the input wirings of the first switch SW1 to the third switch SW3 included in the first switch group, respectively. That is, the wiring of the first solar cell 101 and the second solar cell 102 connected in parallel is connected to the input wiring of the first switch SW1, and the second switch SW2 and the third switch SW3, To the input wiring of the inverter.

The wirings of the third solar cell 103 and the fourth solar cell 104 connected in parallel are connected to the input wirings of the fourth switch SW4 to the sixth switch SW6 included in the second switch group, respectively. That is, the wiring of the third solar cell 103 and the fourth solar cell 104 connected in parallel is connected to the input wiring of the fourth switch SW4, and the fifth switch SW5 and the sixth switch SW6, To the input wiring of the inverter.

The wirings of the fifth solar cell 105 and the sixth solar cell 106 connected in parallel are connected to the input wirings of the seventh switch SW7 to the ninth switch SW9 included in the third switch group, respectively. That is, the wiring of the fifth solar cell 105 and the sixth solar cell 106 connected in parallel is connected to the input wiring of the seventh switch SW7, and the eighth switch SW8 and the ninth switch SW9, To the input wiring of the inverter.

The first battery 401 and the second battery 402 are connected in series and the third battery 403 and the fourth battery 404 are connected in series. The fifth battery 405 and the sixth battery 406 are connected in series.

The output wiring of the first switch SW1 is connected to the first battery 401 and the second battery 402 connected in series and the output wiring of the second switch SW2 is connected to the third battery 403 connected in series And the output wiring of the third switch SW3 is connected to the fifth battery 405 and the sixth battery 406 connected in series.

The output wiring of the fourth switch SW4 is connected to the first battery 401 and the second battery 402 connected in series and the output wiring of the fifth switch SW5 is connected to the third battery 403 connected in series And the output wiring of the sixth switch SW6 is connected to the fifth battery 405 and the sixth battery 406 connected in series.

The output wiring of the seventh switch SW7 is connected to the first battery 401 and the second battery 402 connected in series and the output wiring of the eighth switch SW8 is connected to the third battery SW3 connected in series And the output wiring of the ninth switch SW9 is connected to the fifth battery 405 and the sixth battery 406 connected in series.

The control board 300 operates on / off operations of the switches included in the first to third switch groups. That is, when the first switch SW1 is turned on, the electricity generated by the first solar cell 101 through the second solar cell 102 is supplied to the first battery 401 through the second battery 402 Is charged. When the second switch SW2 is turned on, the electricity generated by the first solar cell 101 to the second solar cell 102 is charged in the third battery 403 to the fourth battery 404 . When the third switch SW3 is turned on, the electricity generated by the first solar cell 101 to the second solar cell 102 is charged in the fifth battery 405 to the sixth battery 406 .

When the fourth switch SW4 is turned on, the electricity generated by the third solar cell 103 through the fourth solar battery 104 is charged in the first battery 401 to the second battery 402 . When the fifth switch SW5 is turned on, the electricity generated by the third to fourth solar cells 104 to 104 is charged in the third battery 403 to the fourth battery 404 . When the sixth switch SW6 is turned on, the electricity generated by the third to fourth solar cells 104 to 104 is charged to the fifth battery 405 to the sixth battery 406 .

When the seventh switch SW7 is turned on, the electricity generated by the fifth solar cell 105 to the sixth solar cell 106 is charged in the first battery 401 to the second battery 402 . When the eighth switch SW8 is turned on, the electricity generated by the fifth to sixth solar cells 105 to 106 is charged in the third battery 403 to the fourth battery 404 . When the ninth switch SW9 is turned on, the electricity generated by the fifth to sixth solar cells 105 to 106 is charged in the fifth battery 405 to the sixth battery 406 .

The first switch SW1 through the ninth switch SW9 perform ON / OFF operations in response to a control command of the control board 300. The electricity generated in the solar cell according to the on / . That is, the electricity generated in the solar cell according to the control command of the control board 300 may be charged in the first battery 401 to the second battery 402 or may be charged in the third battery 403 to the fourth battery 404 Or the fifth to eighth batteries 405 to 406 are charged.

2 is a view for explaining a process of outputting electricity charged in a battery to a battery in a battery saving parallel switch independent photovoltaic power generation system according to an embodiment of the present invention. Hereinafter, a process of outputting electricity charged in the battery to the outside according to an embodiment of the present invention will be described in detail with reference to FIG.

Figure 2 shows a battery saving parallel switch standalone photovoltaic system including a switch, a control board and a battery. Of course, other configurations than the above-described configuration may be included in the configuration for outputting electricity charged in the battery proposed by the present invention to the outside.

According to Fig. 2, the switch includes the tenth switch SW10 to the twelfth switch SW12. The battery also includes a first battery (401) to a sixth battery (406).

The first battery 401 and the second battery 402 are connected in series and the third battery 403 and the fourth battery 404 are connected in series and the fifth battery 405 and the fourth battery 404 are connected in series, 6 batteries 406 are connected in series.

The wires of the first battery 401 and the second battery 402 connected in series are connected to the input wires of the tenth switch SW10 and the wires of the third battery 403 and the fourth battery 404 Is connected to the input wiring of the eleventh switch SW11. The wiring of the fifth battery 405 and the sixth battery 406 connected in series is connected to the input wiring of the twelfth switch SW12.

The output wiring of the tenth switch SW10 to the output wiring of the twelfth switch SW12 is connected to the external wiring.

The control board 300 operates the on / off operations of the tenth switches SW10 to SW12. That is, when the tenth switch SW10 is turned on, electricity charged in the first battery 401 to the second battery 402 is supplied to the outside, and the eleventh switch SW11 is turned on The electricity charged in the third battery 403 through the fourth battery 404 is supplied to the outside. When the twelfth switch (SW112) performs the ON operation, electricity charged in the fifth battery (405) to the sixth battery (406) is supplied to the outside.

The tenth switches SW10 through SW12 respectively perform on / off operations according to a control command of the control board 300. The electricity charged in the battery is supplied to the outside according to the ON / OFF operation of the switch do. That is, according to a control command of the control board 300, electricity charged in the first battery 401 to the second battery 402 may be supplied to the outside or charged to the third battery 403 to the fourth battery 404 Or supplies the electric power charged in the fifth battery 405 to the sixth battery 406 to the outside.

3 shows a switch terminal box according to an embodiment of the present invention. Hereinafter, a switch terminal box according to an embodiment of the present invention will be described in detail with reference to FIG.

The switch terminal box 200 includes the first switch SW1 to the twelfth switch SW12. As described above, the first to ninth switches SW1 to SW9 are charge switches used for charging the battery, and the tenth to twelfth switches SW12 to SW12 are charged in the battery It is a discharge switch used in the process of discharging electric power.

The first switch SW1 includes an input wiring and an output wiring. The input wiring is connected to the wiring of the first solar cell 101 to the second solar cell 102 connected in parallel. The output wiring is connected to the fourth switch SW4.

The second switch SW2 includes an input wiring and an output wiring. The input wiring is connected to the wiring of the first solar cell 101 to the second solar cell 102 connected in parallel. The output wiring is connected to the fifth switch SW4.

The third switch SW3 includes an input wiring and an output wiring. The input wiring is connected to the wiring of the first solar cell 101 to the second solar cell 102 connected in parallel. The output wiring is connected to the sixth switch SW6, respectively.

The fourth switch SW4 includes an input wiring and an output wiring. The input wiring is connected to the wirings of the third to fourth solar cells 103 to 104 connected in parallel. The output wiring is connected to the seventh switch SW7.

The fifth switch SW5 includes an input wiring and an output wiring. The input wiring is connected to the wirings of the third to fourth solar cells 103 to 104 connected in parallel. The output wiring is connected to the eighth switch SW8).

The sixth switch SW6 includes an input wiring and an output wiring. The input wiring is connected to the wirings of the third to fourth solar cells 103 to 104 connected in parallel. The output wiring is connected to the ninth switch SW9).

The seventh switch SW7 includes an input wiring and an output wiring, and the input wiring is connected to wirings of the fifth solar cell 105 to the sixth solar cell 106 connected in parallel, 1 to the wires of the battery 401 to the second battery 402.

The eighth switch SW8 includes an input wiring and an output wiring. The input wiring is connected to wirings of the fifth to sixth solar cells 105 to 106 connected in parallel. The output wirings are connected in series 3 battery 403 through the fourth battery 404, respectively.

The ninth switch SW9 includes an input wiring and an output wiring. The input wiring is connected to wirings of the fifth to sixth solar cells 105 to 106 connected in parallel. The output wirings are connected in series 5 batteries 405 to the sixth battery 406. [0086]

The tenth switch SW10 includes an input wiring and an output wiring. The input wiring is connected to the wirings of the first battery 401 to the second battery 402 connected in series, and the output wiring is connected to the external wiring.

The eleventh switch SW11 includes an input wiring and an output wiring, and the input wiring is connected to the wirings of the third battery 403 to the fourth battery 404 connected in series, and the output wiring is connected to the external wiring.

The twelfth switch SW12 includes an input wiring and an output wiring, and the input wiring is connected to wirings of the fifth battery 405 to the sixth battery 406 connected in series, and the output wiring is connected to the external wiring.

FIG. 4 illustrates a battery-powered, parallel-switched stand-alone solar power generation system in accordance with an embodiment of the present invention. Hereinafter, the battery-storing parallel switch standalone solar power generation system will be described in detail with reference to FIG.

Referring to FIG. 4, the battery-storing parallel switch independent photovoltaic power generation system includes a first solar cell to a sixth solar cell, and includes first to sixth sensors, and includes a switch terminal box, 6 batteries, and includes a control board.

The first sensor 501 is connected to the wirings of the first solar cell 101 and the second solar cell 102 connected in parallel and the power generated by the first solar cell 101 and the second solar cell 102 Lt; / RTI > The second sensor 502 is connected to the wirings of the third solar cell 103 and the fourth solar cell 104 connected in parallel and the power generated by the third solar cell 103 and the fourth solar cell 104 Lt; / RTI > The third sensor 503 is connected to the wirings of the fifth solar cell 105 and the sixth solar cell 106 connected in parallel and the power generated by the fifth solar cell 105 and the sixth solar cell 106 Lt; / RTI >

The fourth sensor 504 is connected to the wires of the first battery 401 and the second battery 402 connected in series and senses the electric power charged in the first battery 401 and the second battery 402. The fifth sensor 505 is connected to the wirings of the third battery 403 and the fourth battery 404 connected in series and senses the electric power charged in the third battery 403 and the fourth battery 404. The sixth sensor 506 is connected to the wirings of the fifth battery 505 and the sixth battery 506 connected in series and senses the electric power charged in the fifth battery 505 and the sixth battery 506.

Information sensed by the first sensor 501 to the sixth sensor 506 is provided to the control board 300. The control board 300 controls the power generated by the solar cell provided from the first sensor 501 to the third sensor 503 and the power supplied from the fourth sensor 504 to the sixth sensor 506 . When it is determined that the battery is no longer required to be charged with power, the control board 300 controls the power supplied from the solar cell to be supplied to the outside without charging the battery. To this end, external wiring is connected between the solar cell wiring and the switch terminal box, that is, the point where the sensor is mounted.

According to the control command of the control board 300, the power generated by the solar cell is normally charged to the battery via the switch constituting the switch terminal box 200. However, when the battery is not required to be charged, The supplied power is supplied to the external wiring.

It is possible to distinguish external devices using the electric power stored in the battery for each battery. That is, the first battery 401 and the second battery 402 connected in series are set as a main battery, and the third battery 403 and the fourth battery 404 connected in series are set as auxiliary batteries, The fifth battery 405 and the sixth battery 406 connected to each other are set as emergency batteries. The main battery supplies power to all external devices, the secondary battery supplies power to lighting or communication related equipment, and the emergency battery supplies power to devices requiring emergency power supply in emergency situations, including emergency lights.

Therefore, the control board 300 firstly uses the electric power charged in the first battery 401 and the second battery 402 at first, and uses the electric power to supply power to all external devices. When the electric power charged in the first battery 401 and the second battery 402 is reduced below the set electric power, the control board supplies the electric power charged in the third battery 403 and the fourth battery 404 to the outside At the same time, the power supply is cut off to the rest of the equipment except for the lighting or communication related equipment. When the electric power charged in the third battery 403 and the fourth battery 404 is lower than the set electric power, the control board supplies the electric power charged in the fifth battery 405 to the sixth battery 406 to the outside And at the same time, it cuts off the power supply to the remaining devices except those requiring power supply in case of emergency.

As described above, the present invention sets priorities for the batteries to be charged with power, and supplies power to external devices corresponding to the set priorities.

FIG. 5 illustrates a battery storage parallel switch standalone solar power generation system according to an embodiment of the present invention. Hereinafter, the battery-storing parallel switch stand-alone solar power generation system will be described in detail with reference to FIG.

5, the battery-storing parallel switch independent photovoltaic power generation system includes a first solar cell to a fourth solar cell, and includes a first sensor to a fourth sensor, and includes a switch terminal box, 4 batteries, and includes a control board.

As described above, one solar cell produces electric power of 250 W, and FIG. 5 shows four solar cells. Therefore, 1 kW of electric power is produced by the battery-storing parallel switch independent photovoltaic power generation system of FIG.

5, the overall configuration and function are the same as those of FIG. 4 except that the number of components constituting the system is different.

That is, the first solar cell 101 and the second solar cell 102 are connected in parallel, and the third solar cell 103 and the fourth solar cell 104 are connected in parallel.

The wirings of the first solar cell 101 and the second solar cell 102 connected in parallel are connected to the input wiring of the first switch SW1 and the input wiring of the second switch SW2. The wiring of the third solar cell 103 and the fourth solar cell 104 connected in parallel is connected to the input wiring of the third switch SW3 and the input wiring of the fourth switch SW4.

The output wiring of the first switch SW1 is connected to the output wiring of the third switch SW3 and the output wiring of the second switch SW2 is connected to the output wiring of the fourth switch SW4. The output wiring of the third switch SW3 is connected to the wirings of the first battery 401 and the second battery 402 connected in series. The output wiring of the fourth switch SW4 is connected to the wirings of the third battery 403 and the fourth battery 404 connected in series.

The input wiring of the fifth switch SW5 is connected to the wiring of the first battery 401 and the second battery 402 connected in series and the output wiring of the fifth switch SW5 is connected to the external wiring. The input wiring of the sixth switch SW6 is connected to the wiring of the third battery 403 and the fourth battery 404 connected in series and the output wiring of the sixth switch SW6 is connected to the external wiring.

The first sensor is connected to the wirings of the first solar cell 101 and the second solar cell 102 connected in parallel and senses the electric power produced by the first solar cell 101 and the second solar cell 102 . The second sensor is connected to the wirings of the third solar cell 103 and the fourth solar cell 104 connected in parallel and senses the electric power produced by the third solar cell 103 and the fourth solar cell 104 .

The third sensor is connected to the wirings of the first battery 101 and the second battery 102 connected in series and senses the electric power charged in the first battery 101 and the second battery 102. The fourth sensor is connected to the wirings of the third battery 103 and the fourth battery 104 connected in series and senses the electric power charged in the third battery 103 and the fourth battery 104.

The control board 300 is connected to the switch terminal box 200 and controls on / off operations of the switches constituting the switch terminal box 200. Also, the control board 300 determines whether the power generated in the solar cell is stored in the battery or supplied to the outside through external wiring using the information provided from the sensor.

6 illustrates a battery-powered, parallel-switched stand-alone solar power generation system in accordance with an embodiment of the present invention. Hereinafter, the battery-storing parallel switch standalone solar power generation system will be described in detail with reference to FIG.

According to FIG. 6, the battery-storing parallel switch independent photovoltaic power generation system includes first to eighth solar cells, including first to eighth sensors, including a switch terminal box, 8 battery, and includes a control board. 6B shows the switch terminal box in particular.

As described above, one solar cell produces 250 W of power, and FIG. 6 shows eight solar cells, so that 2 kW of power is produced by the battery-storing parallel switch independent solar photovoltaic power generation system of FIG.

6, only the number of components constituting the system is different from that of FIG. 4, but the overall configuration and function are the same.

That is, the first solar cell 101 and the second solar cell 102 are connected in parallel, and the third solar cell 103 and the fourth solar cell 104 are connected in parallel. The fifth solar cell 105 and the sixth solar cell 106 are connected in parallel, and the seventh solar cell 107 and the eighth solar cell 108 are connected in parallel.

The wiring of the first solar cell 101 and the second solar cell 102 connected in parallel is connected to the input wiring of the first switch SW1, the input wiring of the second switch SW2, the input wiring of the third switch SW3, And the input wiring of the fourth switch SW4. The output wiring of the first switch SW1 is connected to the output wiring of the fifth switch SW5 and the output wiring of the second switch SW2 is connected to the output wiring of the sixth switch SW6, The output wiring of the fourth switch SW3 is connected to the output wiring of the seventh switch SW7 and the output wiring of the fourth switch SW4 is connected to the output wiring of the eighth switch SW8.

The wiring of the third solar cell 103 and the fourth solar cell 104 connected in parallel is connected to the input wiring of the fifth switch SW5, the input wiring of the sixth switch SW6, the input wiring of the seventh switch SW7, And the input wiring of the eighth switch SW8. The output wiring of the fifth switch SW5 is connected to the output wiring of the ninth switch SW9 and the output wiring of the sixth switch SW6 is connected to the output wiring of the tenth switch SW10, The output wiring of the seventh switch SW7 is connected to the output wiring of the eleventh switch SW11 and the output wiring of the eighth switch SW8 is connected to the output wiring of the twelfth switch SW12.

The wirings of the fifth solar cell 105 and the sixth solar cell 106 connected in parallel are connected to the input wiring of the ninth switch SW9, the input wiring of the tenth switch SW10, the input wiring of the eleventh switch SW11, And the twelfth switch (SW12). The output wiring of the ninth switch SW9 is connected to the output wiring of the thirteenth switch SW13, the output wiring of the tenth switch SW10 is connected to the output wiring of the fourteenth switch SW14, The output wiring of the twelfth switch SW11 is connected to the output wiring of the fifteenth switch SW15 and the output wiring of the twelfth switch SW12 is connected to the output wiring of the sixteenth switch SW16.

The wiring of the seventh solar cell 107 and the eighth solar cell 108 connected in parallel is connected to the input wiring of the thirteenth switch SW13, the input wiring of the fourteenth switch SW14, And the input wiring of the sixteenth switch SW16. The output wiring of the thirteenth switch SW13 is connected to the wiring of the first battery 401 and the second battery 402 connected in series and the output wiring of the fourteenth switch SW14 is connected to the third battery 403 And the fourth battery 404. The output wiring of the fifteenth switch SW15 is connected to the wirings of the fifth battery 405 and the sixth battery 406 connected in series, SW16 are connected to the wirings of the seventh battery 407 and the eighth battery 408 connected in series.

The input wiring of the seventeenth switch SW17 is connected to the wiring of the first battery 401 and the second battery 402 connected in series and the output wiring of the seventeenth switch SW17 is connected to the external wiring. The input wiring of the eighteenth switch SW18 is connected to the wiring of the third battery 403 and the fourth battery 404 connected in series and the output wiring of the eighteenth switch SW18 is connected to the external wiring. The input wiring of the nineteenth switch SW19 is connected to the wirings of the fifth battery 405 and the sixth battery 406 connected in series and the output wiring of the nineteenth switch SW19 is connected to the external wiring. The input wiring of the twentieth switch SW20 is connected to the wirings of the seventh battery 407 and the eighth battery 408 connected in series and the output wiring of the twentieth switch SW20 is connected to the external wiring.

The first sensor is connected to the wirings of the first solar cell 101 and the second solar cell 102 connected in parallel and senses the electric power produced by the first solar cell 101 and the second solar cell 102 . The second sensor is connected to the wirings of the third solar cell 103 and the fourth solar cell 103 connected in parallel and senses the electric power produced by the third solar cell 103 and the fourth solar cell 104 . The third sensor is connected to the wirings of the fifth solar cell 105 and the sixth solar cell 106 connected in parallel and senses the electric power produced by the fifth solar cell 105 and the sixth solar cell 106 . The fourth sensor is connected to the wirings of the seventh solar cell 107 and the eighth solar cell 108 connected in parallel and senses the electric power produced by the seventh solar cell 107 and the eighth solar cell 108 .

The fifth sensor is connected to the wirings of the first battery 401 and the second battery 402 connected in series and senses the electric power charged in the first battery 401 and the second battery 402. The sixth sensor is connected to the wirings of the third battery 403 and the fourth battery 404 connected in series and senses the electric power charged in the third battery 403 and the fourth battery 404. The seventh sensor is connected to the wirings of the fifth battery 405 and the sixth battery 406 connected in series and senses the electric power charged in the fifth battery 405 and the sixth battery 406. The eighth sensor is connected to the wires of the seventh battery 407 and the eighth battery 408 connected in series and senses the electric power charged in the seventh battery 407 and the eighth battery 408.

The control board 300 is connected to the switch terminal box 200 and controls on / off operations of the switches constituting the switch terminal box 200. Also, the control board 200 determines whether the power generated in the solar cell is stored in the battery or supplied to the outside through external wiring using the information provided from the sensor.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the scope of the present invention .

101 to 108: Solar cell 200: Switch terminal box
300: control board 401 to 408: battery

Claims (5)

At least one pair of solar cells connected in parallel to each other;
At least three charging switches connected to wiring extending from the solar cell connected in parallel and having a number of 1.5n when the number of solar cells is n;
A charging switch connected to the charging switch, charging the power generated from the solar cell, and connected in series by two, the number of which is equal to the number of the solar cells;
At least two discharge switches connected to the battery and connected to an external wiring for supplying power charged in the battery to the outside, And
And a control board for controlling on / off operations of the charging switch and the discharging switch.
The charge switch according to claim 1, wherein the charge switch includes an input wiring and an output wiring,
A switch group including at least two switches,
Wherein the input wiring of the charging switch included in the switch group is connected to the wiring extended from the same solar cell and the output wiring of the charging switch is connected to the wiring extended from the different battery. .
3. The plasma display apparatus according to claim 2, wherein the discharge switch includes an input wiring and an output wiring,
Wherein the input wiring of the discharge switch is connected to a wiring extended from a different battery, and the output wiring of the discharge switch is connected to the external wiring.
4. The solar cell according to claim 3, wherein a power generation sensor is formed between the solar cell and the charging switch, the power generation sensor measures power generated in the solar cell,
Wherein a charge sensor is formed between the battery and the discharge switch, and the charge sensor measures the electric power charged in the battery.
5. The apparatus of claim 4,
Controlling the ON / OFF operation of the charging switch according to a priority order of charging the batteries, a charging state of the battery,
Wherein the on / off operation of the discharge switch is controlled according to a priority order of the discharge for each battery, and a charging state of the battery.

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