The present invention relates to a mouse, and more particularly to a mouse that can use solar power to charge a secondary battery.
With rapid development of electronic and information industries, computers and the peripheral device thereof become essential parts in our daily lives. For example, mice are important peripheral devices of computers for establishing contact between the personal computers and the users. For helping the user well operate the computer, many novel mice with expanded functions are developed in views of humanization and user-friendliness.
Recently, a solar powered mouse has been developed. Such a solar powered mouse uses solar energy as the main power source. Referring to
The conventional solar powered mouse 10, however, still has some drawbacks. For example, because of the relatively large area of the solar energy module 13, the overall appearance of the solar powered mouse 10 is aesthetically undesirable. In addition, the efficiency of absorbing solar energy or other light beams by the solar energy module 13 is usually insufficient. That is, the speed of generating electric energy by the solar energy module 13 is ultimately smaller than that of consuming electric energy by the solar powered mouse 10 over a prolonged use period. Therefore, the electric energy is not enough to work the solar powered mouse 10. Since no battery is included in the solar powered mouse, the solar powered mouse 10 can not work until the accumulated electric energy of the solar energy module 13 is sufficient to drive the solar powered mouse 10. It is very troublesome for the user to operate the solar powered mouse because the electric energy fails to be continuously supplied.
Therefore, there is a need of providing an improved solar powered mouse to obviate the drawbacks encountered from the prior art.
The present invention relates to a mouse, and more particularly to a mouse that can use solar power and manage a charging process of a mouse battery.
In accordance with an aspect of the present invention, there is provided a solar powered mouse. The solar powered mouse includes a mouse body, an optical sensor, an internal light source, a secondary battery, a lens and a power management device. By sensing movement of the mouse body, the optical sensor generates a cursor control signal. The internal light source emits internal light beams to be received by the optical sensor. The secondary battery is used for powering the mouse. The lens is arranged on the mouse body such that external light beams are permissible to enter an interior of the mouse body through the lens. The power management device is disposed within the mouse body for charging the secondary battery. The power management device includes a solar energy module, a voltage detector and a charging module. The a solar energy module disposed on a position permissible to receive the internal light beams and the external light beams, so that the internal light beams and the external light beams are converted by the solar energy module into output electricity. The voltage detector is used for detecting a voltage level Vs of the output electricity. The charging module is electrically connected to the voltage detector. The charging module is activated to charge the secondary battery with the output electricity if the voltage level Vs is greater than or equal to a preset voltage value Vth.
In an embodiment, the solar powered mouse further includes two click buttons and a scroll wheel between the two click buttons, wherein the lens is arranged adjacent to the scroll wheel.
In an embodiment, the solar powered mouse further includes a diode, which is interconnected between the charging module and the secondary battery, for allowing unidirectional current flow between the charging module and the secondary battery.
Preferably, the internal light source is a light emitting diode (LED).
In an embodiment, the power management device further includes a capacitor between the solar energy module and the voltage detector.
In an embodiment, if the surplus capacity of the secondary battery is greater than or equal to a predetermined battery capacity value, the charging module charges the capacitor with the output electricity. Whereas, if the surplus capacity of the secondary battery is smaller than the predetermined battery capacity value, the charging module charges the secondary battery with the output electricity.
The above objects and advantages of the present invention will become more readily apparent to those ordinarily skilled in the art after reviewing the following detailed description and accompanying drawings, in which:
For obviating the drawbacks encountered from the prior art, the present invention provides an improved solar powered mouse. A battery is mounted within the mouse body for offering electric energy to power the mouse. In comparison with the conventional technique of directly using the solar energy to power the mouse, the solar energy is used to charge the battery within the solar powered mouse of the present invention.
Referring to
In addition to the external light beams, any light energy from diverse light sources can be used in the solar powered mouse 100 of the present invention.
Please refer to
Hereinafter, the operations of charging the solar powered mouse with light energy (e.g. solar energy) will be illustrated with reference to
After the internal or external light beams are absorbed by the solar energy module 109, the light energy is converted by the solar energy module 109 into electric energy, i.e. the output electricity. The output electricity is transmitted to the voltage detector 110 through the diode 114. The voltage detector 110 detects the voltage level Vs of the output electricity and compares the voltage level Vs with the preset voltage value Vth. If the voltage level Vs is greater than or equal to the preset voltage value Vth, an enabling signal is issued from the voltage detector 110 to the charging module 111. In response to the enabling signal, the charging module 111 is activated to charge the secondary battery 112. Whereas, if the voltage level Vs is smaller than the preset voltage value Vth, no enabling signal is issued. During the secondary battery 112 is charged by the charging module 111, the output electricity flows through the diode 114, which is arranged between the charging module 111 and the secondary battery 112. The diode 114 allows the output electricity to flow in the direction from charging module 111 to the secondary battery 112 while preventing backflow toward the charging module 111.
The procedure of comparing the voltage level Vs with the preset voltage value Vth by the voltage detector 110 can facilitate discriminating whether the output electricity has been accumulated to a level sufficient to charge the secondary battery 112. The voltage level Vs which is smaller than the preset voltage value Vth indicates that the accumulated output electricity has not yet sufficient to charge the secondary battery 112.
In this embodiment, when the output electricity has been accumulated to a level sufficient to charge the secondary battery 112 (i.e. the condition that the voltage level Vs is greater than or equal to the preset voltage value Vth is satisfied), the output electricity is transmitted from the charging module 111 to directly charge the secondary battery 112, regardless of whether the battery capacity of the secondary battery 112 is exhausted. It is found that the secondary battery 112 is readily subject to battery aging from over charge/discharge because the charging module 111 charges the secondary battery 112 as long as the voltage level Vs of the output electricity is above the preset voltage value Vth. For minimizing over charge/discharge of the secondary battery, a further embodiment is provided.
During operation of the solar powered mouse 200, the internal or external light beams passing through the lens are received by the power management device 208. The light energy is converted by the solar energy module 209 into electric energy, i.e. the output electricity. The voltage detector 210 detects the voltage level Vs of the output electricity and compares the voltage level Vs with the preset voltage value Vth. If the voltage level Vs is greater than or equal to the preset voltage value Vth, an enabling signal is issued from the voltage detector 210 to the charging module 211. In response to the enabling signal, the charging module 211 is activated to charge the secondary battery 212. Whereas, if the voltage level Vs is smaller than the preset voltage value Vth, no enabling signal is issued. In this embodiment, a predetermined battery capacity value has been previously stored in the charging module 211. Since the charging module 211 is electrically connected to the secondary battery 212, the surplus capacity of the secondary battery 212 can also be detected by the charging module 211. In a case that the charging module 211 is activated and the surplus capacity of the secondary battery 212 is smaller than the predetermined battery capacity value, the charging module 211 will charge the secondary battery 212. On the other hand, if the surplus capacity of the secondary battery 212 is greater than or equal to the predetermined battery capacity value, it is meant that the surplus capacity of the secondary battery 212 is enough and the secondary battery 212 needs not to be charged. Under this circumstance, the power consumption of the charging module 211 is minimized and the output electricity is temporarily stored in the capacitor 213. Until the surplus capacity of the secondary battery 212 is smaller than the predetermined battery capacity value, the output electricity temporarily stored in the capacitor 213 will charge the secondary battery 212. Due to the two diodes 214 of the power management device 208, the current flow is unidirectional.
As previously described, the conventional solar powered mouse can not work until the accumulated electric energy of the solar energy module is sufficient to drive the solar powered mouse. It is very troublesome for the user to operate the conventional solar powered mouse because the electric energy fails to be continuously supplied. In contrast, since the solar powered mouse of the present invention uses the electric energy of the battery as the main energy source and the solar energy as the auxiliary energy source, the present solar powered mouse can normally work if the solar energy is insufficient.
While the invention has been described in terms of what is presently considered to be the most practical and preferred embodiments, it is to be understood that the invention needs not be limited to the disclosed embodiment. On the contrary, it is intended to cover various modifications and similar arrangements included within the spirit and scope of the appended claims which are to be accorded with the broadest interpretation so as to encompass all such modifications and similar structures.
Number | Date | Country | Kind |
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097101888 | Jan 2008 | TW | national |