JP2012139009A - Mobile terminal device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress deterioration of a battery pack and effectively utilize generated electric power.SOLUTION: A mobile terminal device comprises: a solar cell module 11, arranged on the outer surface of a housing 1A on a display part side, for generating electric power by photoelectric conversion based on the light incident from the outside; a battery pack 12 capable of being charged with the electric power generated by the solar cell module 11, and supplying the electric power to drive its own terminal; a voltage/current detection part 21 for detecting the current or the voltage to be output from the solar cell module 11; a temperature sensor 24 for detecting the temperature of the battery pack 12; and a CPU 13. The CPU 13 controls the supply of the electric power generated by the solar cell module 11 so as to perform charging to the battery pack 12 when the battery pack 12 is determined in a chargeable state by the CPU 13, and the CPU 13 suppresses the charging to the battery pack 12 and controls the supply of the electric power generated by the solar cell module 11 so as to drive its own terminal when the battery pack 12 is determined in a state where charging is not possible.

Description

  The present invention relates to a portable terminal device equipped with a solar cell module and a secondary battery.

2. Description of the Related Art Conventionally, a mobile phone including a solar cell module that receives light and generates power is known. In a mobile phone provided with this solar cell module, the secondary battery, which is a driving source of the mobile phone, is charged with the electric power generated by the solar cell module.
Moreover, as a mobile phone provided with a solar cell module and a secondary battery, for example, the one described in Patent Document 1 is known. In the mobile phone described in Patent Document 1, the solar cell module is disposed at a position exposed to the outside of the casing.
Moreover, in the mobile phone provided with the solar cell module, the solar cell module can favorably generate power by applying sunlight to the solar cell module.

JP 2009-10945 A

  However, in the mobile phone described in Patent Document 1, since the solar cell module is arranged outside the casing, the solar cell module is arranged when the solar cell module hits sunlight. The other casing and other devices of the mobile phone are also exposed to sunlight, and the mobile phone itself becomes hot.

In such a high temperature state, for example, when the power generated from the solar cell module is supplied to the secondary battery, the performance of the secondary battery is deteriorated because the secondary battery is also in a high temperature state. There was a fear.
In order to avoid the above-described problem, it is conceivable to stop the power generation in the solar cell module. However, in the solar cell module, there is a problem that the opportunity for power generation is missed under suitable power generation conditions.

  An object of this invention is to provide the portable terminal device which suppresses the fall of the performance of a secondary battery and uses effectively the generated electric power.

  In order to solve the above-described problem, a mobile terminal device according to the present invention includes a housing and a power generation unit that is disposed on the outer surface of the housing and generates power by photoelectric conversion based on light incident from the outside, In a portable terminal device comprising a secondary battery capable of charging the power generated by the power generation unit and capable of supplying the power to drive the terminal itself, a current or voltage output from the power generation unit is detected A second detection unit that detects a temperature of the secondary battery, and a rechargeable state of the secondary battery based on detection results of the first detection unit and the second detection unit. When determining that the determination unit, the control unit that controls the supply of electric power generated by the power generation unit, and the control unit are in a state in which the secondary battery can be charged by the determination unit, So as to charge the secondary battery When the supply of electric power generated by the electric unit is controlled and the determination unit determines that the secondary battery is not in a chargeable state, it suppresses charging of the secondary battery and drives the own terminal The supply of electric power generated by the power generation unit is controlled so as to perform the following.

  In the mobile terminal device, the determination unit can charge the secondary battery by adding a temperature increase expected from a user operation or use situation to the detection result of the second detection unit. It is preferable to determine the state.

  The portable terminal device further includes a mode setting unit that sets a mode for controlling supply of power generated by the power generation unit according to a user operation or use situation, and the control unit includes the mode setting unit. It is preferable to control the supply of electric power generated by the power generation unit according to the mode set in.

  In the mobile terminal device, the mode setting unit may detect the second detection in a state where the detection result detected by the first detection unit is equal to or greater than a predetermined threshold and the user is operating or using the mode detection unit. When the detection result detected by the unit is less than a predetermined threshold, the power generated by the power generation unit is supplied so that the power generated by the power generation unit is driven by the power generation unit. It is preferable to have a mode controlled by the control unit.

  In the mobile terminal device, the mode setting unit may detect the second detection in a state where a detection result detected by the first detection unit is equal to or greater than a predetermined threshold and the user is not operated or used. When the detection result detected by the unit is less than a predetermined threshold, the power generated by the power generation unit is supplied so that the power generated by the power generation unit is driven by the power generation unit. It is preferable to have a mode controlled by the control unit.

  In the mobile terminal device, the mode setting unit may detect the second detection in a state where the detection result detected by the first detection unit is equal to or greater than a predetermined threshold and the user is operating or using the mode detection unit. When the detection result detected by the unit is equal to or greater than a predetermined threshold, it is preferable that the control unit has a mode for controlling the power generated by the power generation unit to supply the secondary battery. .

  ADVANTAGE OF THE INVENTION According to this invention, while suppressing the fall of the performance of a secondary battery, the generated electric power can be utilized effectively.

It is a figure which shows the external appearance of the mobile telephone of one Embodiment of this invention. It is a figure which shows the temperature characteristic of a secondary battery. It is a block diagram which shows the basic composition of the mobile telephone of this embodiment. It is a functional block diagram which shows the functional structure which concerns on supply of the electric power generated from the solar cell module in the mobile telephone of this embodiment. 7 is a flowchart showing a difference in operation in FIG. 6 in a difference in use state of the mobile phone in the mobile phone according to the present embodiment. It is a flowchart which shows the operation | movement which concerns on supply of the electric power generated from the solar cell module in the mobile telephone of this embodiment.

  Hereinafter, an example of a preferred embodiment of the present invention will be described. In the present embodiment, the mobile phone 1 is described as a specific example of the mobile terminal device. However, the mobile phone 1 is not limited to this. The present invention is applicable to various mobile terminal devices such as a phone system (PDA) terminal and a PDA (Personal Digital Assistant).

FIG. 1 is a diagram showing an appearance of a mobile phone 1 according to an embodiment of the present invention.
As shown in FIG. 1A, the cellular phone 1 is composed of two casings 2 of a display unit side casing 2A and an operation unit side casing 2B, and is foldable so as to be rotatable with respect to each other via a hinge unit (not shown). This is a cellular phone 1 of the type. The mobile phone 1 is used in an unfolded state as shown in FIG. 1A when in use, and in a folded state as shown in FIG. 1B when not in use. In the present embodiment, the mobile phone 1 is described as a foldable mobile phone. However, the mobile phone 1 is not limited to this, and may be configured as, for example, a straight mobile phone.

  The display unit side body 2A has a display unit (not shown in FIG. 1) on the side (inside) that is unexposed in the folded state, and the opposite side (outside) on the inside that is also exposed in the folded state. It is provided with a solar cell module 11 (power generation unit).

  Such a cellular phone 1 has an operation unit (not shown in FIG. 1) on the same side (inside) as the display unit, a connector unit (not shown) connected to the AC adapter at the lower end, A battery pack 12 (secondary battery).

  The battery pack 12 is configured as a secondary battery that can be charged by the power supplied from the AC adapter and the power generated by the solar cell module 11.

In addition, the cellular phone 1 is placed in the folded state shown in FIG. 1B, and the solar cell module 11 is installed with the solar cell module 11 facing upward. Electric power is generated by using the light.
The mobile phone 1 is configured to be able to use the power generated by the solar cell module 11 as power for charging the battery pack 12 and power for driving the own device. The configuration for using the power for charging the battery pack 12 and the power for driving the own device will be described later.

The battery pack 12 configured as a secondary battery has the following temperature characteristics. FIG. 2 is a diagram illustrating temperature characteristics of the secondary battery. Specifically, FIG. 2A is a diagram showing characteristics in voltage, and FIG. 2B is a diagram showing characteristics in current. In the figure, the vertical axis represents the charging voltage (charging current), and the horizontal axis represents the temperature of the secondary battery.
Secondary batteries have different characteristics depending on the temperature range. The temperature range includes, for example, a first temperature range (first temperature (0 ° C.) to second temperature (10 ° C.)) that is a low temperature range, and a second temperature range (second temperature (10 ° C.) that is a standard temperature range. From the third temperature (45 ° C.) to the third temperature (45 ° C.) and the third temperature range (the third temperature (45 ° C.) to the fourth temperature (60 ° C.)).
The standard temperature range is a temperature range where charging can be performed stably.
Also, in the high temperature range, if charging is performed at the same upper limit voltage or maximum current as the standard temperature range, it is necessary to change the charging condition to the high temperature charging condition in a temperature range where there is a concern about deterioration of stability. is there.
Further, it is said that the secondary battery needs to be stopped at a temperature exceeding the high temperature range (for example, CIAJ (Communications Industries Association of Japan recommendation)).

  The mobile phone 1 equipped with the battery pack 12 having such characteristics and further provided with the solar cell module 11 has more opportunities to be exposed to sunlight and more frequently than the normal mobile phone 1. . Therefore, the mobile phone 1 is configured not to actively charge the secondary battery in a high temperature state in consideration of the characteristics of the secondary battery described above.

  The mobile phone 1 configured as described above suppresses the supply of electric power from the solar cell module 11 when the battery pack 12 is in a high temperature state, thereby reducing deterioration of the battery pack 12, and the solar cell module 11 The function to switch the electric power from the power to drive the own machine is provided.

  In the cellular phone 1, when the battery pack 12 is in a high temperature state, supply of power from the solar cell module 11 is suppressed to reduce deterioration of the battery pack 12, and power from the solar cell module 11 is reduced. The power for driving the system unit 131 (own device) can be switched.

The mobile phone 1 includes a display unit side housing 2A (housing), a solar cell module 11 (power generation unit), a battery pack 12 (secondary battery), a voltage / current detection circuit 21 (first detection unit), A temperature sensor 24 (second detection unit) and a CPU 13 (determination unit, control unit) are provided.
The solar cell module 11 is disposed on the outer surface of the display unit side body 2A, and generates power by photoelectric conversion based on light incident from the outside.
The battery pack 12 is configured to be able to charge the power generated by the solar cell module 11 and to supply this power to the driving of the terminal itself.
The voltage / current detection circuit 21 detects a current or a voltage output from the power generation unit.
The temperature sensor 24 detects the temperature of the battery pack 12.
The CPU 13 determines a chargeable state of the battery pack 12 based on the detection results of the voltage / current detection circuit 21 and the temperature sensor 24.
Further, the CPU 13 controls the supply of electric power generated by the solar cell module 11. When the CPU 13 determines that the battery pack 12 is in a chargeable state, the CPU 13 controls the supply of electric power generated by the solar cell module 11 so as to charge the battery pack 12, and the battery pack 12. If it is determined that the battery pack 12 is not in a chargeable state, the charging of the battery pack 12 is suppressed, and the supply of power generated by the solar cell module 11 is controlled so as to drive the system unit 131 (own terminal). To do.

By configuring the mobile phone 1 in this manner, when the CPU 13 determines that the battery pack 12 is in a chargeable state, the power is generated by the solar cell module 11 so as to charge the battery pack 12. By controlling the power supply, the battery pack 12 is charged in a normal state.
On the other hand, if the CPU 13 determines that the battery pack 12 is not in a chargeable state, the CPU 13 suppresses charging of the battery pack 12 and controls to drive the own terminal, for example, a solar cell module. When the battery pack 12 is exposed to sunlight for power generation at 11, and the battery pack 12 is at a high temperature, the battery pack 12 is not charged in order to suppress a decrease in the performance of the battery pack 12. The operation is performed so that the generated power is applied to the power driven by the system unit 131 (own device).
Therefore, in the mobile phone 1, it is possible to efficiently reduce the performance of the battery pack 12 and efficiently use the generated power.

In addition, the CPU 13 determines the state in which the battery pack 12 can be charged by further taking into account the temperature increase expected from the user's operation or use situation in addition to the detection result of the temperature sensor 24.
Accordingly, in the cellular phone 1, the battery pack 12 is increased in consideration of the user's operation that may cause an increase in temperature and the usage state of the cellular phone 1 (for example, the state in communication with the network). Since it is possible to avoid charging the battery pack 12 in a high temperature state in order to determine whether to charge the pack 12, it is possible to suppress a decrease in the performance of the battery pack 12.

In the mobile phone 1, the CPU 13 (mode setting unit) sets a mode for controlling the supply of electric power generated by the solar cell module 11 according to the user's operation or usage status. Moreover, CPU13 controls supply of the electric power generated by the solar cell module 11 according to the set mode.
Therefore, in the mobile phone 1, since the user can set whether to use this function, the degree of freedom of use of the mobile phone 1 can be increased.

In the CPU 13, the detection result detected by the temperature sensor 24 is less than the predetermined threshold when the detection result detected by the voltage / current detection circuit 21 is equal to or greater than the predetermined threshold and the user is operating or using the CPU 13. In this case, a mode is provided in which the power generated by the solar cell module 11 is supplied so that the power generated by the solar cell module 11 can be used for driving the terminal itself.
Therefore, in the mobile phone 1, for example, the power generated by the solar cell module 11 is sufficient to charge the battery pack 12, and the temperature of the battery pack 12 is high when the mobile phone 1 is used at that time. If not, since the power for driving the system unit 131 (own device) is used, the consumption and deterioration of the battery of the battery pack 12 can be suppressed.

  In the CPU 13, the detection result detected by the temperature sensor 24 is less than the predetermined threshold when the detection result detected by the voltage / current detection circuit 21 is equal to or greater than the predetermined threshold and the user is not operating or using the CPU 13. In such a case, there is a mode in which the power generated by the solar cell module 11 is controlled to be supplied so that the power generated by the solar cell module 11 is driven.

  Therefore, in the mobile phone 1, for example, when the power generated by the solar cell module 11 is sufficient to charge the battery pack 12, and the mobile phone 1 is not in use, the temperature of the battery pack 12 is When the temperature is not high, the battery pack 12 can be charged in a state where the deterioration to the battery pack 12 is small and the burden on the battery pack 12 is small.

Next, details of a specific configuration of the mobile phone will be described.
FIG. 3 is a block diagram showing a basic configuration of the mobile phone 1.
As shown in FIG. 3, the mobile phone 1 according to the present embodiment further includes a CPU 13 (Central Processing Unit, control unit, determination unit), a storage unit 14, an operation unit 15, and a display unit 16 as a basic configuration. A microphone 17, a speaker 18, and a communication unit 19.

The CPU 13 is a central processing unit that performs various numerical calculations, information processing, device control, and the like according to a program, and controls various parts related to power generation management of the solar cell module 11 and charge management of the battery pack 12, for example.
The storage unit 14 stores, for example, various data such as settings described later.
The operation unit 15 inputs various operations by the user. In the cellular phone 11, in response to this input operation to the operation unit 15, control by the CPU 1315 or the like is performed.
The display unit 16 is configured as a display such as an LCD (Liquid Crystal Display), for example, and is configured to display a received one-segment broadcast or display an incoming call.
The microphone 17 inputs a voice from a user during a call.
The speaker 18 outputs sound from the communication destination during a call.
The communication unit 19 transmits and receives signals related to telephone calls and data communication.
The mobile phone configured as described above is at least driven by the power supplied from the battery pack 12 and can perform a call or data communication.

  Next, a functional configuration relating to supply of electric power generated from the solar cell module 11 in the mobile phone 1 of the present embodiment will be described. FIG. 4 is a functional block diagram showing a functional configuration related to supply of electric power generated from the solar cell module 11 in the mobile phone 1 of the present embodiment.

  As shown in FIG. 4, in addition to the basic configuration described above, the mobile phone 1 includes a voltage / current detection circuit 21 (first detection unit), an LDO (Low Drop Out) circuit 22, a charging circuit 23, 1 to 4th switch part SW1, SW2, SW3, SW4, the temperature sensor 24 (2nd detection part), and the system part 131 and the switch control part 132 in CPU13 are provided.

  The voltage / current detection circuit 21 detects the voltage value and current value of the power generated by the solar cell module 11. The voltage / current detection circuit 21 is connected to the solar cell module 11 and the first switch unit SW1.

  The first switch unit SW1 is connected to the solar cell module 11, the LDO circuit 22, and the charging circuit 23. The first switch unit SW <b> 1 is a switch that switches the connection state between the solar cell module 11, the LDO circuit 22, and the charging circuit 23 by the switch control unit 132. That is, in the first switch unit SW1, the connection between the solar cell module 11 and the LDO circuit 22 and the connection between the solar cell module 11 and the LDO circuit 22 are switched.

  The LDO circuit 22 is connected to the first switch unit SW1 and the second switch unit SW2. The LDO circuit 22 is a linear voltage regulator that operates even when the input voltage slightly exceeds the desired output voltage, and the power generated by the solar cell module 11 can be used as constant voltage power. The system unit 131 can be driven by the power supplied by the LDO circuit 22.

  The second switch unit SW2 is connected to the LDO circuit 22 and the system unit 131. The second switch unit SW2 is a switch for switching the connection state between the LDO circuit 22 and the system unit 131 by the switch control unit 132.

  The charging circuit 23 is connected to the second switch unit SW2 and the third switch unit SW3. The charging circuit 23 controls charging with the battery pack 12.

  The third switch unit SW3 is connected to the charging circuit 23, the system unit 131, and the fourth switch unit SW4. The third switch unit SW3 is a switch for switching the connection state between the charging circuit 23 and the system unit 131 by the switch control unit 132.

  The fourth switch unit SW4 is connected to the third switch unit SW3 and the battery pack 12. The fourth switch unit SW4 is a switch for switching the connection state between the third switch unit SW3 and the battery pack 12 by the switch control unit 132.

  The temperature sensor 24 is a sensor that can detect the temperature of the battery pack 12.

The CPU 13 includes a system unit 131 and a switch control unit 132.
The system unit 131 is configured by the CPU 13 and drives its own device such as application control. In addition to the battery pack 12, the system unit 131 is driven by power supplied from the LDO circuit 22.
The switch control unit 132 controls switching of the first to fourth switch units SW4.

The cellular phone 1 configured as described above is switched so that the first switch unit SW1 is connected to the LDO circuit 22, and the second switch unit SW2 is switched so that the LDO circuit 22 and the system unit 131 are connected. It is done. Thereby, in the mobile phone 1, the electric power generated by the solar cell module 11 is supplied to the system unit 131. In this case, the third switch unit SW3 and the fourth switch unit SW4 are switched so as to be disconnected.
In this way, the system unit 131 that has received power supply operates to operate and use the power as power for using other functions.

In addition, the mobile phone 1 is switched so that the first switch unit SW1 is connected to the charging circuit 23, and the third switch unit SW3 is switched so that the charging circuit 23 and the fourth switch unit SW4 are connected. Thereby, in the mobile phone 1, the power generated by the solar cell module 11 is supplied to the battery pack 12. In this case, the third switch unit SW3 and the fourth switch unit SW4 are switched so as to be disconnected.
In this way, the battery pack 12 that has received the power is charged.

The cellular phone 1 configured as described above operates such that the switching of each switch unit varies depending on the detection result in the voltage / current detection circuit 21 and the usage status.
Next, the difference in operation depending on the detection result and usage status in the voltage / current detection circuit 21 of the present embodiment will be described with reference to FIGS. 5 and 6. FIG. 5 is a flowchart showing the difference in operation in FIG. 6 in the difference in use state of the cellular phone 1. FIG. 6 is a flowchart showing the operation of the mobile phone 1 according to the present embodiment.

  In step ST1, the CPU 13 checks the state. Specifically, the CPU 13 checks whether or not it is currently operating by a user operation or the like. If it is not operated by the user's operation or the like (when the user is not operating), the process proceeds to step ST3. If it is operated by a user operation or the like (during user operation), the process proceeds to step ST4.

  In step ST2, in the operation shown in FIG. 6, the CPU 13 permits the route A and operates the mobile phone 1 so as to turn on the fourth switch in the case of high temperature charging. In the case of high-temperature charging, the fourth switch unit SW4 may be configured to be turned off in consideration of a decrease in the performance of the battery pack 12.

  In step ST3, the CPU 13 operates the mobile phone 1 so as to permit the A route and the B route in the operation shown in FIG.

Next, an operation related to power supply of the mobile phone 1 will be described with reference to FIG.
This operation operates based on the conditions shown in FIG.
Hereinafter, first, a description will be given of when the user is not operating (condition of step ST2 in FIG. 5), and then, when the user is operating (condition of step ST3 of FIG. 5).

Since the mobile phone 1 is in the state of non-operation of the user shown in FIG. 5, the route A shown in FIG. 6 is permitted.
In step ST10, the solar cell module 11 performs solar cell output. Specifically, the solar cell module 11 outputs the generated power.

  In step ST11, the voltage / current detection circuit 21 checks the voltage / current. Specifically, the voltage / current detection circuit 21 detects the voltage value and current value of the power generated by the solar cell module 11.

In step ST12, the CPU 13 determines whether or not the detection value is equal to or greater than a threshold value. Specifically, the CPU 13 can determine whether or not the detected value detected by the voltage / current detection circuit 21 can be used as power for charging, and can it be used as power for driving the system unit 131 (own device). Determine whether or not.
When the detected value detected by the voltage / current detection circuit 21 can be used as power for charging and can be used as power for driving the system unit 131 (own device), permission is given at step ST2 in FIG. The process proceeds to step ST13 which is the route A.
When the detection value detected by the voltage / current detection circuit 21 cannot be used as charging power and can be used as power for driving the own device, and the detection value detected by the voltage / current detection circuit 21 is charged. If the power is not usable as power for driving and cannot be used as power for driving the system unit 131 (own device), the process proceeds to the C route, and the process returns to step ST11.

  In step ST13, the switch control unit 132 sets the first switch unit SW1 to the charging circuit 23 side, turns off the second switch unit SW2, turns on the third switch unit SW3, and turns on the fourth switch unit SW4. As described above, in the cellular phone 1, the power generated by the solar cell module 11 can be used for charging the battery pack 12 by switching each switch unit.

  In step ST14, the temperature sensor 24 checks the temperature of the battery pack 12.

In step ST15, the CPU 13 determines whether or not the temperature is equal to or higher than a threshold value. Specifically, the CPU 13 determines whether or not the temperature detected by the temperature sensor 24 in step ST14 is a high temperature or a normal temperature. Whether the temperature is high or normal temperature is determined based on whether or not the detected temperature is equal to or higher than a predetermined threshold. If the detected temperature is equal to or higher than the threshold, the temperature is determined to be high. When it is below the threshold, it is determined that the temperature is normal.
If it is determined that the temperature is high, the process proceeds to step ST16. If it is determined that the temperature is normal, the process proceeds to step ST17.

  In step ST16, the switch control unit 132 turns off the fourth switch unit SW4. However, in this step ST16, since it is based on the condition of step ST2 in FIG. 5, the fourth switch unit SW4 is turned on by high temperature charging, and the battery pack 12 is charged. In the mobile phone 1, each part of the mobile phone 1 is not operating when the user is not operating, and the battery pack 12 does not become hotter due to the operation of the mobile phone 1. For this reason, when the user is not operating, the battery is operated so as to be charged even when it is determined to be in a high temperature state. In step ST16, the switch control unit 132 may be configured to turn off the fourth switch unit SW4 in consideration of a decrease in the performance of the battery pack 12. Thereafter, the process returns to step ST11. At this time, not only the fourth switch unit SW4 is turned off, but the first switch unit SW1 is switched to the LDO circuit 22 side, the second switch unit SW2 is turned on, and the third switch unit SW3 is turned off. The power supply for driving the device itself may be supplied as a constant voltage battery.

  In step ST17, the switch control unit 132 turns on the fourth switch unit SW4. Actually, the switch control unit 132 maintains the switching state of the fourth switch unit SW4. Thereafter, the process returns to step ST11.

  Heretofore, the case where the user is not operating (condition of step ST2 in FIG. 5) has been described. Next, the user operation (condition of step ST3 in FIG. 5) will be described.

Since the mobile phone 1 is in the state of the user operation shown in FIG. 5, the A route and the B route shown in FIG. 6 are permitted.
In step ST10, the solar cell module 11 performs solar cell output. Specifically, the solar cell module 11 outputs the generated power.

  In step ST11, the voltage / current detection circuit 21 checks the voltage / current. Specifically, the voltage / current detection circuit 21 detects the voltage value and current value of the power generated by the solar cell module 11.

In step ST12, the CPU 13 determines whether or not the detection value is equal to or greater than a threshold value. Specifically, the CPU 13 can determine whether or not the detected value detected by the voltage / current detection circuit 21 can be used as power for charging, and can it be used as power for driving the system unit 131 (own device). Determine whether or not.
If the detected value detected by the voltage / current detection circuit 21 can be used as power for charging and can be used as power for driving the system unit 131 (own device), permission is given in step ST3 in FIG. Go to route A. Since the processing of the A route has been described above, the description thereof is omitted.
When the detected value detected by the voltage / current detection circuit 21 is unusable as power for charging and can be used as power for driving the system unit 131 (own device), the process proceeds to route B, and the processing is performed. Proceed to step ST18.
If the detected value detected by the voltage / current detection circuit 21 is unusable as power for charging and unusable as power for driving the system unit 131 (own device), the process proceeds to the C route and the processing is performed. The process returns to step ST11.

  In step ST18, the switch control unit 132 sets the first switch unit SW1 to the LDO circuit 22, turns off the second switch unit SW2, turns off the third switch unit SW3, and turns on the fourth switch unit SW4. Thus, by switching each switch part, in the mobile telephone 1, it will be in the state which can be used for the electric power which uses the electric power generated by the solar cell module 11 as a constant voltage battery, ie, drives an own machine.

  In step ST19, the CPU 13 is used as a constant voltage battery. That is, the CPU 13 uses the power generated by the solar cell module 11 as power for driving the system unit 131 (own device). Thereafter, the process returns to step ST11.

  Therefore, in the mobile phone, it is possible to suppress the deterioration of the performance of the battery pack and to effectively use the generated power.

  In addition, this invention is not limited to the above-mentioned embodiment, The deformation | transformation in the range which can achieve the objective of this invention, improvement, etc. are included in this invention.

  In the above-described embodiment, the present invention has been described by taking the mobile phone 1 as an example, but the present invention is not particularly limited thereto. The present invention can be generally applied to a portable terminal device including a solar cell module and a secondary battery.

1A Operation unit side case (case)
11 Solar cell module (power generation unit)
12 Battery pack (secondary battery)
13 CPU (control unit, determination unit, mode setting unit)
21 Voltage / current detection circuit (first detection unit)
22 Temperature sensor (second detector)
100 Mobile phone (mobile terminal device)

Claims (6)

A housing,
A power generation unit disposed on the outer surface of the housing and generating power by photoelectric conversion based on light incident from the outside;
In a portable terminal device comprising: a secondary battery capable of charging the electric power generated by the power generation unit and capable of supplying the charged electric power to the drive of the terminal.
A first detection unit for detecting a current or voltage output from the power generation unit;
A second detector for detecting a temperature of the secondary battery;
A determination unit that determines whether the secondary battery is in a chargeable state based on detection results of the first detection unit and the second detection unit;
A control unit for controlling the supply of power generated by the power generation unit;
The controller is
When the determination unit determines that the secondary battery is in a chargeable state, it controls supply of power generated by the power generation unit so as to charge the secondary battery, and the determination unit If it is determined that the secondary battery is not in a chargeable state, the charging of the secondary battery is suppressed and the supply of power generated by the power generation unit is controlled so as to drive the terminal. Mobile terminal device.   The determination unit is configured to determine the chargeable state of the secondary battery by further adding a temperature increase expected from a user operation or use situation to the detection result of the second detection unit. The portable terminal device described. A mode setting unit that sets a mode for controlling supply of electric power generated by the power generation unit according to a user operation or use situation,
The portable terminal device according to claim 1, wherein the control unit controls supply of electric power generated by the power generation unit according to a mode set by the mode setting unit.   The mode setting unit detects the detection result detected by the second detection unit in a state where the detection result detected by the first detection unit is equal to or greater than a predetermined threshold and is operated or used by a user. Is less than a predetermined threshold, the control unit controls a mode to supply the power generated by the power generation unit so that the power generated by the power generation unit is driven by the power generation unit. The portable terminal device according to claim 3.   The mode setting unit detects the detection result detected by the second detection unit when the detection result detected by the first detection unit is equal to or greater than a predetermined threshold and is not operated or used by a user. Is less than a predetermined threshold, the control unit controls a mode to supply the power generated by the power generation unit so that the power generated by the power generation unit is driven by the power generation unit. The portable terminal device according to claim 3.   The mode setting unit detects the detection result detected by the second detection unit in a state where the detection result detected by the first detection unit is equal to or greater than a predetermined threshold and is operated or used by a user. 4. The mobile terminal device according to claim 3, wherein when the power is greater than or equal to a predetermined threshold, the control unit controls the power generated by the power generation unit to be supplied to the secondary battery.

Images