KR20000021315A - Dual-power supply device using solar battery in wireless terminal and method for controlling thereof - Google Patents

Abstract

PURPOSE: A dual-power supply device of a wireless terminal and a method for controlling thereof are provided to increase the using hours of a battery, by power supply using a solar battery. CONSTITUTION: A dual-power supply device using a solar battery in a wireless terminal comprises: a solar battery for converting the light from the sun into electric energy, and charging the electric energy; a light inducing sensor for detecting the electric energy, and sensing a level of light energy of solar energy; a controller for outputting a switching control signal selecting power supply of a cellular phone, according to the amount of the level; and a switch for selecting outputted voltage from a charging battery and a storage battery by the switching control signal, outputted from the controller, and applying to the power supply of the cellular phone.

Description

Dual power supply using solar cell in wireless terminal and its control method

The present invention relates to a dual power supply device and a control method of a portable wireless terminal, in particular to supply the power of the wireless terminal using a solar cell, and when the solar cell is detected as a low battery to back up to the battery to use the battery life time The present invention relates to a dual power supply device for increasing and a control method thereof.

The battery used in portable wireless terminals is about 120 hours of standby time, and the time is much shorter during actual calls. This causes the user to be inconvenient to charge the battery frequently, there is a problem that can not talk until the battery is charged when the battery is exhausted. In addition, the slot mode or power saving function is used to increase the usage time of the battery installed in the portable wireless terminal. However, since the portable wireless terminal is becoming smaller and lighter in the future, there is a limit to miniaturizing the battery compared to the portable wireless terminal. In other words, if the battery is made smaller, its capacity becomes smaller, and the usage time of the battery must be extended.

Accordingly, an object of the present invention is to provide a dual power supply device and a control method of the wireless terminal that can increase the use time of the battery mounted on the portable wireless terminal by supplying power using a solar cell.

In the dual power supply using a solar cell in the wireless terminal of the present invention for achieving the above object, a solar cell for receiving the light provided from the sun and converting it into electric field energy to charge, and the electrical energy output from the solar cell A light sensitive sensor for detecting and detecting a level of light energy of solar energy, a controller for outputting a switching control signal for selecting a power supply of the mobile phone according to the level of light energy level of the light sensitive sensor, and from the controller It is characterized by comprising a switch for selecting the voltage output from the storage battery and the charging battery by the output switching control signal applied to the power of the mobile phone.

In the dual power supply method using a solar cell in a wireless terminal equipped with a rechargeable battery of the present invention for achieving the above object, the process of outputting a voltage by converting light energy provided from the sun into electrical energy, and the electrical energy Comparing the converted voltage with the set voltage and detecting whether the voltage is equal to or less than the final voltage; and selecting and supplying power output from the charging battery when the voltage is less than or equal to the final voltage; It is characterized by consisting of a process of selecting and supplying a voltage converted into electrical energy.

Figure 1a is a view showing a front surface equipped with a solar cell of a mobile phone according to an embodiment of the present invention

Figure 1b is a view showing a side state equipped with a solar cell of a mobile phone according to an embodiment of the present invention

2 is a configuration diagram of a dual power supply device for supplying power using a solar cell according to an embodiment of the present invention.

3 is a control flowchart for supplying power using a solar cell according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1A is a view illustrating a solar cell front surface of a mobile phone according to an exemplary embodiment of the present invention, in which a solar cell 10 is mounted on an external surface of a flip 12.

1B is a view showing a side state of mounting a solar cell of a mobile phone according to an embodiment of the present invention, the solar cell 10 is mounted on the outer surface of the flip 12, and the solar cell on the top of the rear side is equipped with a rechargeable battery 14 It is a figure which shows the state which attached 10.

2 is a block diagram of a dual power supply device for supplying power using a solar cell according to an embodiment of the present invention.

The energy dust collecting unit 20 collects light energy by receiving light provided from the sun. The photoelectric conversion unit 22 converts light collected from the energy dust collecting unit 20 into electrical energy. The rechargeable battery 28 receives DC power from the outside and charges it. The photosensitive sensor 24 detects the electrical energy output from the photoelectric conversion unit 22 to sense the level of light energy of the solar energy. The controller 26 outputs a switching control signal for selecting a power supply according to the level detection amount of the light energy of the light sensitive sensor 16. The battery 28 charges the electrical energy converted from the photoelectric conversion unit 22. The switch 32 selects the voltage output from the charging battery 30 and the voltage output from the photoelectric conversion unit 22 by the switching control signal output from the control unit 26 and supplies the power to the mobile phone.

3 is a control flowchart for supplying power using a solar cell according to an embodiment of the present invention.

2 to 3, the operation of the preferred embodiment of the present invention will be described in detail.

In order to carry out the present invention, a solar cell is attached to the outside of the mobile phone, and is attached to the top of the flip 10 and the rear of the mobile phone as shown in FIGS. 1A and 1B.

The energy dust collecting unit 20 collects light energy by receiving light provided from the sun. The photoelectric conversion unit 22 converts light collected from the energy dust collecting unit 20 into electrical energy. At this time, the light sensor 24 detects the electrical energy output from the photoelectric conversion unit 22 to sense the intensity of light with respect to the solar energy. Light intensity is detected by voltage, which is photoelectrically converted electrical energy. That is, a high signal is output when the voltage output by the photoelectric conversion is higher than the set voltage, for example, and a low signal is output when the voltage is lower than the set voltage. At this time, when the high signal is input from the light sensitive sensor 24, the controller 26 determines that the power can be supplied to the solar energy, and outputs a switching control signal such that the switch 32 is connected to the common terminal c and the terminal b. Therefore, the voltage output from the battery 28 is supplied to the power of the mobile phone. However, when the low signal is output from the light sensitive sensor 24, the controller 26 determines that the power cannot be supplied by solar energy and outputs a switching control signal such that the switch 30 is connected to the common terminal c and the terminal a. Therefore, when solar energy is not supplied, the battery 30 is supplied from the rechargeable battery 30 to the power of the mobile phone.

As described above, the operation of supplying power to the mobile phone using solar energy will be described with reference to the flowchart of FIG. 3. In step 101, the controller 26 checks whether the power key provided in the key input unit is pressed to turn on the power. If the power is on, proceed to step 102. In step 102, the controller 26 checks the light sensitive sensor 24 and checks whether the solar cell 10 is powered. That is, check whether the output of the light sensor 24 is high. If the output of the light-sensitive sensor 24 is a low state instead of a high state, the solar energy is determined as a final voltage and the process proceeds to step 103. In step 103, the controller 26 outputs a switching control signal for supplying power from the rechargeable battery 28. Therefore, the switch 30 is connected to the common terminal c and the terminal a so that the voltage of the rechargeable battery 28 is supplied to the mobile phone. However, if the solar energy is not the final voltage in step 102, the control unit 26 outputs a switching control signal for supplying power to the solar cell 10. Then, the switch 30 is connected to the common terminal c and the terminal b so that the voltage output from the photoelectric conversion unit 24 or the voltage output from the battery 28 is supplied to the mobile phone. Here, the termination voltage refers to a voltage that is too low to operate when the mobile phone is powered on.

As described above, the present invention is equipped with a solar cell in the mobile phone is not always in the dark place to convert the light energy into electrical energy to charge and supply to the power of the mobile phone is installed when the battery is detected below the set voltage charging battery Since the power is managed by supplying power from the dual, there is an advantage that can increase the use time of the rechargeable battery.

Claims (4)

In a dual power supply using a solar cell in a wireless terminal, A solar cell that receives light from the sun and converts it into electrical energy for charging; A light sensitive sensor detecting electric energy output from the solar cell and detecting a level of light energy of the solar energy; A control unit for outputting a switching control signal for selecting a power supply of the mobile phone according to the level of detection amount of light energy of the light sensitive sensor; The dual power supply unit using a solar cell in a wireless terminal, characterized in that configured to switch to apply to the power of the mobile phone by selecting the voltage output from the storage battery and the charging battery according to the switching control signal output from the controller. The method of claim 1, wherein the solar cell, An energy dust collector which receives light provided from the sun and collects light energy, A photoelectric conversion unit converting light collected from the energy dust collecting unit into electrical energy and outputting a voltage; Dual power supply using a solar cell in a wireless terminal, characterized in that it comprises a storage battery for charging the electrical energy converted from the photoelectric conversion unit. The method of claim 2 The solar cell is a dual power supply using a solar cell in a wireless terminal, characterized in that mounted on the outside of the flip of the mobile phone. In the dual power control method using a solar cell in a wireless terminal equipped with a rechargeable battery, Converting light energy provided from the sun into electrical energy and outputting a voltage; Detecting whether the voltage converted into the electrical energy is lower than or equal to a final voltage, and Selecting and supplying power output from the rechargeable battery when detected below the final voltage; The method of controlling a dual power source using a solar cell in the wireless terminal, characterized in that the process of selecting and supplying the voltage converted into the electrical energy when detected above the termination voltage.