JP2006296134A - Portable solar photovoltaic power system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a compact portable solar photovoltaic power system which prevents over-discharging of an internal storage battery. <P>SOLUTION: The solar photovoltaic power system starts electric discharge of the internal storage battery after finishing electric discharge of an external storage battery, and starts charging of the external storage battery after finishing charging of the internal storage battery, namely the electric discharge of the external storage battery is performed preferentially, and the charging of the internal storage battery is performed preferentially. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a small-sized and portable solar power generation apparatus.

Conventionally, a small portable solar power generation device has been used. In a small portable solar power generation device, an internal storage battery is built in, an external storage battery is electrically connected from the outside, and an internal storage battery is built in and an external storage battery is electrically connected from the outside. There is something. However, generally, the external storage battery is used as a reserve battery for the internal storage battery.
JP 2003-92423 A JP 2003-217865 A JP 2000-259267 A Japanese Patent Laid-Open No. 11-285166 JP-A-11-98715

  In many cases, the internal storage battery is in an overdischarged state after using the conventional small portable solar power generation device. Therefore, when the solar power generation device is not used for a long period of time, unless the internal storage battery is charged once and then stored, the solar power generation device will be overdischarged until the next use. Thus, the internal storage battery cannot be used, and the life of the portable solar power generation device may be shortened.

  This invention is made | formed in view of the above-mentioned problem, The one objective is to make it possible to extend the lifetime of the portable solar power generation device using both an internal storage battery and an external storage battery.

  Moreover, when using both an internal storage battery and an external storage battery, the display part which displays both the information regarding an internal storage battery and the information regarding an external storage battery is needed. Therefore, the total number of display units increases. As a result, the portable solar power generation device is not downsized.

  Another object of the present invention is to downsize a portable solar power generation apparatus that uses both an internal storage battery and an external storage battery.

  The portable solar power generation device of the present invention has, as a basic configuration, a solar cell panel that receives sunlight and performs photoelectric conversion, and a power supply unit that receives power generated by the solar cell panel and supplies the power to the outside. And. Further, in the basic configuration, the power supply unit is configured such that an external storage battery that stores the power generated by the solar cell panel can be attached, and the power supply unit stores the power generated by the solar cell panel. The battery includes a storage battery and a control unit that performs control related to charging and discharging of the internal storage battery and charging and discharging of the external storage battery.

  In addition to the above basic configuration, in the portable solar power generation device of one aspect, when the discharge control is performed, the control unit preferentially performs the discharge control of the external storage battery, and the external storage battery The discharge control of the internal storage battery is started on the condition that the remaining amount of the power is equal to or less than the specific value.

  In general, the capacity and weight of a battery are proportional, and the weight increases as the capacity increases. On the other hand, considering the ease of carrying a portable solar power generation device, the internal storage battery is desirably small. For this reason, the capacity of the internal storage battery must be small. Therefore, when using a portable solar power generation device, an external storage battery capable of storing the power generated by the solar battery panel of the solar power generation device is required.

According to the above aspect of the present invention, at the time of discharging, the power remaining in the external storage battery is preferentially used, and remains in the internal storage battery after the remaining power of the external storage battery becomes equal to or less than a specific value. Electric power is used. Therefore, it is suppressed that an internal storage battery will be in an overdischarge state. As a result, it is prevented that the internal storage battery cannot be used. Therefore, the lifetime of the portable solar power generation apparatus using both the internal storage battery and the external storage battery can be extended.

In addition to the basic configuration described above, the portable solar power generation apparatus according to another aspect, when charge control is performed, gives priority to charge control of the internal storage battery. The charging control of the external storage battery is started on condition that the remaining power of the internal storage battery is equal to or greater than a predetermined value.

  According to another aspect of the invention described above, at the time of charging, the internal storage battery is preferentially charged, and charging of the external storage battery is started on the condition that the internal storage battery is fully charged. Therefore, it is suppressed that an internal storage battery will be in an overdischarge state. As a result, it is prevented that the internal storage battery cannot be used. Therefore, the lifetime of the portable solar power generation apparatus using both the internal storage battery and the external storage battery can be extended.

  Furthermore, in addition to the above basic configuration, the portable solar power generation apparatus according to another aspect includes a display unit that displays both information related to the external storage battery and information related to the internal storage battery in a time-divided manner, and a display unit. And an internal / external storage battery display unit that displays whether information about the internal storage battery is displayed or information about the external storage battery is displayed.

  According to still another aspect of the present invention, a large amount of information can be displayed even if the total number of display units is small. Therefore, the portable solar power generation device used by both the internal storage battery and the external storage battery can be reduced in size.

  Hereinafter, a solar power generation apparatus according to an embodiment of the present invention will be described with reference to the drawings.

  First, the structure of the solar power generation device according to the embodiment will be described with reference to FIGS.

  As shown in FIG. 1, the solar power generation device 27 of the embodiment receives the solar cell panel 1 that receives sunlight on the light receiving surface and functions as a power generation unit, and receives the electric power generated by the solar cell panel 1. And a power supply unit 26 that supplies power to the outside. The power supply unit 26 and the solar cell panel 1 are detachable from each other.

  An internal storage battery 8 is built in the power supply unit 26. The internal storage battery 8 is charged with power generated by the solar battery panel 1. As shown in FIG. 3, the power supply unit 26 is attached to the solar cell panel 1 along the direction indicated by the arrow 29 while fitting with the two ridges 28 on the back surface of the solar cell panel 1. As a result, as shown in FIG. 2, the connection terminal 30 provided on the back surface of the solar cell panel 1 and the connection terminal of the power supply unit 26 are electrically connected. Therefore, the internal storage battery 8 is in a state where the power generated by the solar battery panel 1 can be charged. On the other hand, as shown in FIG. 2, the external storage battery 23 is detachably electrically connected to the back surface of the power supply unit 26, and the power generated by the solar battery panel 1 can be charged in the external storage battery 23. . In addition, the electric power supply part 26 is comprised so that it can be electrically connected with the external storage battery 23 via the external connection terminal 7 mentioned later. The power supply unit 26 is electrically connected to an adapter 100 for connecting each of the DC 12V load 24 and the AC 100V load 25.

  Although FIG. 1 shows a solar power generation device 27 composed of one flat plate, it may be a solar power generation device in which two flat plates are foldably joined as shown in FIG. .

  Next, the internal configuration of the power supply unit 26 according to the embodiment will be described with reference to FIG.

  As shown in FIG. 5, a charging control unit 3 that controls charging from the solar battery panel 1 to the internal storage battery 8 and the external storage battery 23 is provided. Moreover, the solar power generation device 27 includes a DC (Direct Current) / AC (Alternative Current) inverter 9 that converts DC power output from the internal storage battery 8 or the external storage battery 23 into AC power.

  The solar power generation device 27 includes a solar cell voltage detection unit 2 that detects the output voltage of the solar cell panel 1, an internal / external storage battery voltage detection unit 6 that detects the output voltage of the internal storage battery 8 and the output voltage of the external storage battery 23, and It has.

  A signal capable of specifying the output voltage detected by each of the solar cell voltage detection unit 2 and the internal / external storage battery voltage detection unit 6 is transmitted to the charge control unit 3 and the charge / discharge control unit 5. Further, the solar power generation device 27 detects an abnormality in the power output from the DC / AC inverter 9 to the AC 100V load, and is output from the internal storage battery 8 or the external storage battery 23 to the DC load 12V by the charge / discharge control unit 5. A load abnormality detection circuit 200 that detects an abnormality of the power to be detected. The load abnormality detection circuit 200 outputs an abnormality detection signal to the charge / discharge control unit 5 when detecting a load abnormality. The DC / AC inverter 9 converts DC power output from the internal storage battery 8 or the external storage battery 23 into AC power.

  The power supply unit 26 is a display unit controlled by the display driving unit 4 and includes one light emitting element (charging LED (Light Emit Diode) 13). It consists of a charge amount display unit 10 for displaying the amount of power charged in the storage battery 23 and two light emitting elements (full LED 15 and empty LED 14), and the internal storage battery 8 or the external storage battery 23 depending on whether or not they are lit. And a storage battery remaining amount display unit 11 for displaying the remaining amount of electric power remaining in the battery.

  The power supply unit 26 includes an internal / external storage battery display unit 12. The internal / external storage battery display unit 12 includes an external LED 16 indicating that the display relating to the external storage battery 23 is being performed and an internal LED 17 indicating that the display regarding the internal storage battery 8 is being performed.

  The charge amount display unit 10 and the storage battery remaining amount display unit 11 are provided in the display unit 32. As shown in FIG. 2, the display unit 32 is provided on a surface located on the side opposite to the light receiving surface of the solar cell panel 1 when the power supply unit 26 is attached to the solar cell panel 1.

  Further, as shown in FIG. 6, the display unit 32 includes a single light emitting element, and a DC (Direct Current) 12 V display unit 19 that is lit when DC power is supplied to a DC 12 V load. An AC 100V display unit 18 that is made up of light emitting elements and lights up when AC power is supplied to an AC (Alternative Current) 100V load, an AC output switch 21 that determines whether or not to output AC power, and discharge control. A main power switch 20 is provided for determining whether to perform charging control.

  In the solar power generation device 27 of the present embodiment, as shown in Table 1 and Table 2, the effective control differs depending on whether the main power switch 20 is ON or OFF.

  When the main power switch 20 is ON, the control shown in Table 1 is performed. That is, the output voltage of the solar cell panel 1 detected by the solar cell voltage detection unit 2 is greater than 11V, and the output voltage of any one of the internal storage battery 8 and the external storage battery 23 is equal to or higher than the discharge stop voltage (11V). In this case, the charge / discharge control unit 5 performs both control for charging and control for discharging.

  Moreover, when the output voltage of the solar cell panel 1 is 11 V or less and any one of the internal storage battery 8 and the external storage battery 23 is larger than the discharge stop voltage (11 V), the charge / discharge control unit 5 stops the control for charging and performs only the control for discharging.

  Moreover, when the output voltage of the solar cell panel 1 is larger than 11V, and each output voltage of the internal storage battery 8 and the external storage battery 23 is below a discharge stop voltage (11V), the charge / discharge control part 5 is Control for charging is performed, and control for discharging is stopped.

  Moreover, when the output voltage of the solar cell panel 1 is 11 V or less and the respective output voltages of the internal storage battery 8 and the external storage battery 23 are the discharge stop voltage (11 V) or less, the charge / discharge control unit 5 Then, control for the standby mode for stopping both charging and discharging is performed. In the standby mode, each element in the power supply unit 26 is in a stopped state, and the main power switch 20 is once turned off when turned on, and then turned on.

  When the main power switch 20 is OFF, the control shown in Table 2 is performed. That is, when the output voltage of the solar cell panel 1 is larger than 11V, the charging control unit 3 performs control for charging. Moreover, when the output voltage of the solar cell panel 1 is 11 V or less, the charging control unit 3 executes control for the standby mode.

  In the standby mode, when the main power switch 20 is OFF, control for turning on the main power switch 20 is executed.

  Note that when the main power switch 20 is ON and the AC output switch 21 is OFF, DC power is supplied to the DC load 24. When the main power switch 20 is ON and the AC output switch 21 is ON, AC power is supplied to the AC load 25.

  Further, the display drive unit 4 is based on the detection signal transmitted from the internal / external storage battery voltage detection unit 6, the light emission mode of the storage battery remaining amount display unit 11, that is, the LED of lighting, blinking, and extinguishing. The light emission mode is controlled. Thereby, as shown in Table 3, the remaining amount of power stored in the internal storage battery 8 or the remaining amount of power stored in the external storage battery 23 is displayed on the storage battery remaining amount display unit 11.

  However, in the solar power generation device 27 of the present embodiment, as shown in Tables 3 and 4, when the main power switch 20 is ON, that is, when discharging and when the main power switch 20 is OFF, The battery level display differs depending on the charging time.

  When the main power switch 20 is ON (during discharging), the display driving unit 4 performs control as shown in Table 3.

  The display drive unit 4 is in a state in which charging control is stopped because it is in a fully charged state, and in a normal state in which the voltage of the internal storage battery 8 or the external storage battery 23 is 11.5 V or more and can be charged and discharged. In some cases, in the remaining battery level display unit 11, the full (green) LED 15 is turned on and the empty (red) LED 14 is turned off.

  When the voltage of the internal storage battery 8 or the external storage battery 23 is less than 11.5 V and the remaining amount of the storage battery is low, the display driving unit 4 turns off the full LED (green) 15 in the storage battery remaining amount display unit 11. And the sky (red) LED 14 blinks. In addition, the display drive unit 4 is used when the voltage range of the internal storage battery 8 or the external storage battery 23 is less than 11.5V, and in the overdischarge prevention state (the output voltage of the internal storage battery 8 or the external storage battery 23 is 11 V or less of the discharge stop voltage). ), The full (green) LED 15 is turned off and the empty (red) LED 14 is turned on in the storage battery remaining amount display section 11.

  Further, when the main power switch 20 is OFF (during charging), the display driving unit 4 executes control as shown in Table 4.

  As shown in Table 4, when the internal storage battery 8 or the external storage battery 23 is fully charged and the charging is stopped, the display drive unit 4 is full (green) in the storage battery remaining amount display unit 11. The LED 15 is turned on and the empty (red) LED 14 is turned off. The display drive unit 4 is in a state in which the internal storage battery 8 or the external storage battery 23 can be discharged (the output voltage of the internal storage battery 8 or the external storage battery 23 is greater than the discharge stop voltage 11 V), and the voltage of the internal storage battery 8 or the external storage battery 23 Is 12.4 V or more, the full (green) LED 15 is blinked and the empty (red) LED 14 is turned off in the storage battery remaining amount display unit 11. The display drive unit 4 is in a state where the internal storage battery 8 or the external storage battery 23 can be charged (the output voltage of the solar battery panel 1 is 11 V or more), and the voltage of the internal storage battery 8 or the external storage battery 23 is 11.5 V or more. When it is less than 4, the full LED (green) 15 is turned off and the empty (red) LED 14 is blinked in the storage battery remaining amount display unit 11. Further, the display drive unit 4 is in a state where the internal storage battery 8 or the external storage battery 23 can be charged, and when the voltage of the internal storage battery 8 or the external storage battery 23 is less than 11.5 V, and when the internal storage battery 8 or the external storage battery 23 is When the battery is in an overdischarge prevention state (the output voltage of the internal storage battery 8 or the external storage battery 23 is equal to or less than the discharge stop voltage 11 V) and cannot be discharged, the full (green) LED 15 is turned off in the storage battery remaining amount display unit 11. The empty (red) LED 14 is turned on.

  Moreover, the display drive part 4 controls the light emission mode of the light emitting diode 13 of the charge amount display unit 10, that is, the LED mode such as lighting, blinking, and extinguishing based on the detection signal of the solar cell voltage detection unit 2. To do. Thereby, as shown in Table 5, the charge amount of the electric power charged by the solar cell panel 1 is displayed on the charge amount display unit 10.

  As shown in Table 5, when the current corresponding to the charge amount exceeds 2.4 A, the display drive unit 4 has a charge amount of power charged from the solar cell panel 1 to the internal storage battery 8 or the external storage battery 23. The charge LED (yellow) 13 of the charge amount display unit 10 is turned on as “large”. In addition, when the current corresponding to the charge amount is 1.2 A or more and less than 2.4 A, the display drive unit 4 has a charge amount of power charged from the solar cell panel 1 to the internal storage battery 8 or the external storage battery 23. The charge LED (yellow) 13 of the charge amount display unit 10 is blinked at a high speed as being “medium”. Further, when the current corresponding to the charge amount is 0.4 A or more and less than 1.2 A, the display drive unit 4 has a charge amount of power charged from the solar cell panel 1 to the internal storage battery 8 or the external storage battery 23. The charge LED (yellow) 13 of the charge amount display unit 10 is blinked at a slow speed as being “small”. In addition, when the current corresponding to the charge amount is less than 0.4 A, the display drive unit 4 indicates that the charge amount of power charged from the solar cell panel 1 to the internal storage battery 8 or the external storage battery 23 is “None”. As a certain thing, charge LED (yellow) 13 of the charge amount display part 10 is extinguished.

  In addition, as shown in Tables 6 and 7, the contents displayed by the remaining battery level display unit 11 and the charge amount display unit 10 differ depending on whether the internal / external storage battery switch 22 is ON or OFF. That is, the display unit 32 displays one of the internal storage battery 8 and the external storage battery 23 in a time-division manner. Therefore, the total number of displays provided in the display unit 32 is reduced, and the display unit 32 can be downsized.

  Before the internal / external storage battery switch 22 is pressed, that is, when the internal / external storage battery switch 22 is ON, as shown in Table 6, the internal LED 17 of the internal / external storage battery display unit 12 is lit. At the same time, information on the remaining amount of electric power of the internal storage battery 8 is displayed by the display of the storage battery remaining amount display unit 11, and the power generation amount of the solar cell panel 1 is displayed by the display of the charge amount display unit 10.

  As shown in Table 6, when the control for charging the internal storage battery 8 is performed and the control of the external storage battery 23 is stopped, the charge LED (yellow) 13 of the charge amount display unit 10 is displayed. Lights up.

  When the control of the internal storage battery 8 is stopped and the control for charging the external storage battery 23 is being performed, the charge LED (yellow) 13 of the charge amount display unit 10 is turned off.

  When the control for discharging the internal storage battery 8 is performed and the control of the external storage battery 23 is stopped, the charge LED (yellow) 13 of the charge amount display unit 10 is turned off.

  When the control of the internal storage battery 8 is stopped and the control for discharging the external storage battery 23 is being performed, the charge LED (yellow) 13 of the charge amount display unit 10 is turned off.

  Further, when the control for charging the internal storage battery 8 is performed and the control for discharging the external storage battery 23 is performed, the charge LED (yellow) 13 of the charge amount display unit 10 is displayed. Light.

  Further, when the control for discharging the internal storage battery 8 is performed and the control for charging the external storage battery 23 is performed, the charge LED (yellow) 13 of the charge amount display unit 10 is displayed. Turns off.

  When the control of the internal storage battery 8 is stopped and the control of the external storage battery 23 is stopped, the charge LED (yellow) 13 of the charge amount display unit 10 is turned off.

  On the other hand, when the internal / external storage battery changeover switch 22 is pressed, that is, when the internal / external storage battery changeover switch 22 is OFF, as shown in Table 7, the internal / external storage battery display unit While LED16 lights, the information regarding the residual amount of the electric power of the external storage battery 23 is displayed by the display of the storage battery remaining amount display part 11, and the electric power generation amount of the solar cell panel 1 is displayed by the display of the charge amount display part 10.

  As shown in Table 7, when the control for charging the internal storage battery 8 is performed and the control of the external storage battery 23 is stopped, the charge LED (yellow) 13 of the charge amount display unit 10 is displayed. Goes off.

  When the control of the internal storage battery 8 is stopped and the control for charging the external storage battery 23 is being performed, the charge LED (yellow) 13 of the charge amount display unit 10 is lit.

  When the control for discharging the internal storage battery 8 is performed and the control of the external storage battery 23 is stopped, the charge LED (yellow) 13 of the charge amount display unit 10 is turned off.

  When the control of the internal storage battery 8 is stopped and the control for discharging the external storage battery 23 is being performed, the charge LED (yellow) 13 of the charge amount display unit 10 is turned off.

  Further, when the control for charging the internal storage battery 8 is performed and the control for discharging the external storage battery 23 is performed, the charge LED (yellow) 13 of the charge amount display unit 10 is displayed. Turns off.

  Further, when the control for discharging the internal storage battery 8 is performed and the control for charging the external storage battery 23 is performed, the charge LED (yellow) 13 of the charge amount display unit 10 is displayed. Light.

  Further, when the control of the internal storage battery 8 is stopped and the control of the external storage battery 23 is stopped, the charge LED (yellow) 13 of the charge amount display unit 10 is turned off.

  In addition, each of the solar cell voltage detection unit 2 and the internal / external storage battery voltage detection unit 6 receives an abnormality signal indicating an abnormality related to charging of the solar cell panel 1 and an abnormality related to storage of the internal storage battery 8 or the external storage battery 23, respectively. Depending on the content of the abnormality, any one or more of the plurality of LEDs are blinked, and as shown in Table 8, what kind of abnormality is occurring is displayed on the entire display unit 32.

  When an abnormal voltage is generated in the solar cell panel 1, the display driving unit 4 turns on the DC12V display unit (blue) 19 and the sky (red) LED 14. Further, when an abnormal voltage is generated in the internal storage battery 8, the display driving unit 4 turns on the internal LED 17. Further, when an abnormal voltage is generated in the external storage battery 23, the display driving unit 4 turns on the external LED 16. Further, when an abnormal voltage is generated in the DC power output to the DC load 24, the display driving unit 4 turns on the empty LED (red) 15 and the external LED 16. Further, when an abnormal voltage is generated in the AC power output to the AC load 25, the display driving unit 4 turns on the empty LED (red) 15 and the internal LED 17. Moreover, the display drive part 4 makes empty (red) LED14 light, when the temperature abnormality of the internal storage battery 8 has generate | occur | produced. Moreover, the display drive part 4 makes charge LED (yellow) 13 light, when the temperature abnormality of an oscillation transformer has generate | occur | produced. Moreover, the display drive part 4 makes full (green) LED15 of the storage battery residual amount display part 11 light, when abnormality has generate | occur | produced in the short circuit detection of AC load 25. FIG.

  When a plurality of the above-described abnormalities occur, the abnormal display is displayed according to the priority order. The order of priority is as follows: internal storage battery 8 temperature abnormality, oscillation transformer temperature abnormality, AC load output voltage abnormality, AC load short circuit detection abnormality, external storage battery 23 voltage abnormality, internal storage battery 8 voltage abnormality, solar battery panel 1 Voltage abnormality and DC output voltage abnormality. In order to return from the abnormal display state to the usable state, the power switch 21 may be changed from ON to OFF.

  Next, the charge / discharge control processing according to the embodiment will be described with reference to FIGS.

  In the charge / discharge control process, first, as shown in FIG. 7, it is determined whether or not the main power switch 20 is turned on in S1. If the main power switch 20 is not turned on in S1, the charging mode process is executed in S2. Thereafter, the process of S1 is repeated. If the main power switch 20 is turned on in S1, the charging mode process is executed in S3. Thereafter, the process of S1 is repeated. That is, the main power switch 20 is a changeover switch for switching between the charge mode and the discharge mode.

  In the charging mode process, the charging control unit 3 executes a process as shown in FIG. First, in S21, it is determined whether or not the output voltage of the solar cell panel 1 detected by the solar cell voltage detector 2 is greater than 11V. In S21, if the output voltage of the solar cell panel 1 is larger than 11V, the solar cell panel 1 is in a chargeable state, so the process of S22 is executed. In S22, it is determined whether or not the output voltage of the internal storage battery 8 detected by the internal / external storage battery voltage detection unit 6 is greater than 15.0V, that is, whether or not the internal storage battery 8 is fully charged. If it is determined in S22 that the internal storage battery 8 is not fully charged, the internal storage battery 8 is charged in S23, and then the process of S1 is performed again. If it is determined in S22 that the internal storage battery 8 is fully charged, whether or not the output voltage of the external storage battery 23 detected by the internal / external storage battery voltage detection unit 6 is 14.8 V or more in S24. That is, it is determined whether or not the external storage battery 23 is fully charged. If it is determined in S24 that the external storage battery 23 is not fully charged, the external storage battery 23 is charged in S25, and the process of S1 is performed. If it is determined in S24 that the external storage battery 23 is fully charged, the process of S1 is repeated again without charging the external storage battery 23. Moreover, if the voltage of the solar cell panel 1 is 11V or less in S21, after each solar power generation device 27 is set to the standby mode in S26, the process of S1 is repeated.

  Further, in the discharge mode process, the charge / discharge control unit 5 executes a process as shown in FIG. First, in S31, it is determined whether or not the voltage of the solar cell panel 1 detected by the solar cell voltage detector 2 is greater than 11V. If it is determined in S31 that the voltage of the solar battery panel 1 is greater than 11V, whether or not the output voltage of the external storage battery 23 detected by the internal / external storage battery voltage detection unit 6 is 11.0V or less in S32. That is, it is determined whether or not the external storage battery 23 is in an overdischarged state. If it is determined in S32 that the external storage battery 23 is not in an overdischarged state, the external storage battery 23 is discharged in S33, and further, the same processes as S22 to S25 of the charge mode process are executed. That is, the internal storage battery 8 is charged together with the discharge of the external storage battery 23.

  If it is determined in S32 that the external storage battery 23 is in an overdischarged state, whether or not the output voltage of the internal storage battery 8 detected by the internal / external storage battery voltage detection unit 6 is 11.0 V or less in S34. That is, it is determined whether or not the internal storage battery 8 is in an overdischarged state. If it is determined in S34 that the internal storage battery 8 is not in an overdischarged state, the internal storage battery 8 is discharged in S35, and further, the same processing as S22 to S25 of the charging mode processing is executed. Thereafter, the process of S1 is repeated again. If it is determined in S34 that the internal storage battery is in an overdischarged state, a process for stopping the discharge is performed in S36, that is, the discharge of both the external storage battery 23 and the internal storage battery 8 is stopped. The process of S1 is performed.

  In S31, if it is determined that the output voltage of solar cell panel 1 is 11 V or less, charging of both external storage battery 23 and internal storage battery 8 is stopped in S37. Next, in S38, it is determined whether or not the output voltage of the external storage battery 23 is 11.0 V or less, that is, whether or not the external storage battery 23 is in an overdischarged state. If it is determined in S38 that external storage battery 23 is not in an overdischarged state, in S39, external storage battery 23 is discharged, and then the process in S31 is performed again. If it is determined in S38 that the external storage battery 23 is in an overdischarged state, in S40, whether or not the output voltage of the internal storage battery 8 is 11.0 V or less, that is, the internal storage battery 8 is in an overdischarged state. Is determined. If it is determined in S40 that internal storage battery 8 is not in an overdischarged state, internal storage battery 8 is discharged in S41. Thereafter, the process of S1 is performed again. If it is determined in S40 that internal storage battery 8 is in an overdischarged state, in S42, solar power generation device 27 is set to the standby mode, and then the process of S1 is performed.

  As described above, in the discharge mode, the external storage battery 23 is preferentially discharged, and the output voltage of the internal storage battery 8 is below a specific value, that is, the remaining power of the internal storage battery 8 is below a specific value. The internal storage battery 8 is discharged on the condition that the Therefore, the internal storage battery 8 is prevented from being overdischarged.

  Further, in the charging mode, it is determined whether or not the output voltage of the internal storage battery 8 is equal to or higher than a predetermined value, and charging of the external storage battery 23 is performed on condition that the output voltage of the internal storage battery 8 is equal to or higher than the predetermined value. Done. That is, after the internal storage battery 8 is preferentially charged, the external storage battery 23 is charged.

  Therefore, according to the charge / discharge control process described above, the internal storage battery 8 is suppressed from being overdischarged. As a result, according to the portable solar power generation device of the present embodiment, the life of the portable solar power generation device is extended by extending the life of the internal storage battery 8.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

It is a perspective view at the time of use of the solar power generation device of an embodiment. It is a figure which shows the display part of the external storage battery attached to the back surface of the solar power generation device of embodiment. It is a figure which shows the site | part to which it is a back surface of the solar cell panel of embodiment, and an electric power supply part is attached. It is a figure which shows the other example of the solar power generation device of embodiment. It is a block diagram which shows the system configuration | structure of the solar power generation device of embodiment. It is a figure which shows the display part of the solar power generation device of embodiment. It is a flowchart for demonstrating the charge / discharge control process of the solar power generation device of embodiment. It is a flowchart for demonstrating the charge mode process of the solar power generation device of embodiment. It is a flowchart for demonstrating the discharge mode process of the solar power generation device of embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Solar cell panel, 2 Solar cell voltage detection part, 3 Charge control part, 4 Display drive part, 5 Charge / discharge control part, 6 Internal / external storage battery voltage detection part, 8 Internal storage battery, 10 Charge amount display part, 12 / External storage battery display section, 15 Storage battery remaining capacity display section, 20 Main power switch, 23 External storage battery, 27 Solar power supply device.

Claims (3)

A solar panel that receives sunlight and performs photoelectric conversion;
An electric power supply unit that receives electric power generated by the solar cell panel and supplies the electric power to the outside;
The power supply unit
An external storage battery that stores the power generated by the solar cell panel is configured to be mounted, and
An internal storage battery for storing the power generated by the solar panel;
A control unit that performs control related to charging and discharging of the internal storage battery and charging and discharging of the external storage battery,
When the discharge control is performed, the control unit preferentially performs the discharge control of the external storage battery, on the condition that the remaining amount of power of the external storage battery is below a specific value, Portable solar power generation device that starts discharge control of internal storage battery. A solar panel that receives sunlight and performs photoelectric conversion;
An electric power supply unit that receives electric power generated by the solar cell panel and supplies the electric power to the outside;
The power supply unit
An external storage battery that stores the power generated by the solar cell panel is configured to be mounted, and
An internal storage battery for storing the power generated by the solar panel;
A control unit that performs control related to charging and discharging of the internal storage battery and charging and discharging of the external storage battery,
When charge control is being performed, the control unit preferentially performs charge control of the internal storage battery, and on the condition that the remaining power of the internal storage battery is equal to or greater than a predetermined value, A portable solar power generation device that starts charging control of an external storage battery. A solar panel that receives sunlight and performs photoelectric conversion;
An electric power supply unit that receives electric power generated by the solar cell panel and supplies the electric power to the outside;
The power supply unit
An external storage battery that stores the power generated by the solar cell panel is configured to be mounted, and
An internal storage battery for storing the power generated by the solar panel;
A control unit for performing control related to charging and discharging of the internal storage battery and charging and discharging of the external storage battery;
A display unit that displays both information on the external battery and information on the internal battery in a time-sharing manner;
A portable solar power generation apparatus including: an internal / external storage battery display unit that displays whether the display unit displays information about the internal battery or information about the external battery.

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