| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 320102000 | With shuntless charging source control | 14 |
| 20080272733 | Dual Mode Portable Charger - A portable charger is disclosed including; a rechargeable battery module; a fluid energy converting device for converting kinetic energy of fluids flowing therethrough into electric power to charge the rechargeable battery module; a control circuit coupled to the rechargeable battery module; and a power output interface coupled to the control circuit for supplying power to an electronic device under the control of the control circuit when the power output interface is electrically connected to the electronic device. | 11-06-2008 |
| 20090001926 | Electrically Driven Vehicle - A electrically driven vehicle ( | 01-01-2009 |
| 20090015191 | Solar Panel With Pulse Charger - A rechargeable power assembly having at least one lithium ion cell comprising an anode, a cathode, an electrolyte gel; a pulsed balancing circuit connected to the at least one lithium ion cell for maintaining the at least one lithium ion cell in a balanced phase; at least two photovoltaic cells concurrently connected to the pulsed balancing circuit and at least one lithium ion cell, wherein the at least two photovoltaic cells are connected in series for recharging the at least one lithium ion cell; an insulating layer between the at least one lithium ion cell and the at least two photovoltaic cells, wherein the at least two photovoltaic cells each have a surface for absorbing radiation, the surfaces for absorbing radiation are disposed opposite the respective insulating layers forming an apparatus for providing usable DC current directly from an electric circuit connected to the at least one lithium ion cell. | 01-15-2009 |
| 20090079384 | Charging Control in an Electric Vehicle - A charging system for a vehicle rearranges the bank of battery cells between a series connection for delivering voltage to a load, e.g. a motor; and a parallel connection for being charged. The battery bank can thus be charged by a 12 volt battery charger. The charger can be a plug in charger, or can be a solar cell. For example, the solar cell can be moved to cover a windshield or other surface of the vehicle whenever the vehicle is shut down. | 03-26-2009 |
| 20090079385 | Solar powered battery charger using switch capacitor voltage converters - The invention provides a charging device that uses switched capacitor voltage converters to charge a battery using solar power. The charger uses boosting topology to efficiently use solar module photovoltaic power. The boosting topology enables a lower voltage to be used resulting in reduced cutting and soldering of photovoltaic cells. The battery charger has overcharge protection and uses inductor-less circuitry. | 03-26-2009 |
| 20090284217 | SOLAR POWER CHARGING DEVICE WITH SELF-PROTECTION FUNCTION - A solar power charging device with a self-protection function is provided, which includes a solar cell, a rechargeable battery, and a diode. The solar cell defines an open-circuit voltage Voc and an operating voltage Vop, in which the Voc is slightly higher than the Vop. The rechargeable battery defines a battery voltage, an operating voltage of load Vload, and a maximum charging voltage Vf, in which the Vf is substantially equal to the V | 11-19-2009 |
| 20100109601 | PORTABLE SOLAR ELECTRICAL GENERATOR AND WATER FILTRATION AND DESALINATION SYSTEM - A portable solar power collection and storage system integrated into a body affixed to a towable trailer vehicle, which in a preferred configuration may require no complicated setup steps or even no setup steps at all, and may be not wind vulnerable due to integrated body construction with substantially contained rather than extended solar panel(s). The system may further include water pumping and treatment equipment. | 05-06-2010 |
| 20100123428 | Battery-Charging Device for a Stand-Alone Generator System having a MPPT Function and Method Thereof - A battery-charging device, having a maximum power point tracking (MPPT) function, for a stand-alone generator system includes a DC/DC power converter and a control circuit used to control the DC/DC power converter. The method applied in the device includes: performing a MPPT function to supply a continuous current when electric power generated from the electrical power source of the stand-alone generator system is low; operating a pulse charging function and continuing the MPPT function when the electric power generated from the electrical power source of the stand-alone generator system is high and not greater than the summation of load power and a maximum charging power of the pulse charging method for the battery; terminating the MPPT function while the electric power is greater than the summation of load power and the maximum charging power of the pulse charging method for the battery; operating a constant-voltage charging mode when the battery voltage is greater than a predetermined constant charging voltage. | 05-20-2010 |
| 20100201305 | METHOD OF FORMING A CONTROL CIRCUIT AND DEVICE - In one exemplary embodiment, a control circuit includes a comparator circuit that compares a solar cell voltage and a battery voltage and responsively activates a charging control signal if the solar cell voltage is greater than the battery voltage. If the solar cell voltage is not greater than the battery voltage, the comparator circuit de-activates the charging control signal. | 08-12-2010 |
| 20100264869 | Maximum Power Point Tracking Charge Controller with Coupled Inductor Multi-phase Converter - A maximum power point tracking (MPPT) charge controller for photovoltaic (PV) systems employs a maximum power point tracking algorithm for tracking the maximum power point voltage of a PV array at which the PV array produces maximum power voltage, and a buck converter for converting the maximum power voltage to the voltage required to charge one or more batteries. The buck converter includes multiple buck converter phase configurations phase shifted from one another. Each of the buck converter phase configurations has a phase inductor, and the phase inductors are combined on a single core to form a coupled inductor. One of the buck converter phase configurations is intentionally temporarily shut down when the output power is low. A first switch or a second switch of the buck converter phase configuration that is intentionally temporarily shut down is turned on to conduct electrical current when predetermined conditions are satisfied. A method of controlling battery charging in a photovoltaic system involves operating a coupled inductor multi-phase buck converter of a charge controller so that one of the buck converter phase configurations is intentionally temporarily shut down when the power output is below a predetermined value. | 10-21-2010 |
| 20120086387 | CHARGING CONTROL SYSTEM AND DEVICE - A charging control system for charging a secondary battery from a solar battery, including a first path for transmitting power from the solar battery to the secondary battery, a second path for sensing the voltage of the secondary battery, and a comparison unit for comparing the solar battery voltage with the sensed voltage of the secondary battery. The first path includes a first interrupter, controlled by the comparison unit, which interrupts the first path to prevent discharge of the secondary battery through the solar battery when the solar battery voltage falls below the secondary battery voltage. The second path includes a second interrupter that interrupts the second path after the first path is interrupted, to prevent the secondary battery from discharging through the second path when not being charged through the first path. | 04-12-2012 |
| 20130015807 | System and Method for Using Capacitors in Wireless Networks - A battery-free wireless network is provided with one or more series or parallel capacitive networks. One or more solar panels are used to charge the capacitive networks and one or more charging circuits are used to control the charging of the capacitive networks. One or more DC-DC converters maybe used to provide a voltage to a wireless router, switch or other network device, the timer/clock circuitry, and a user interface. In those instances when it is desired that the timer/clock circuitry remain powered at all times, the timer/clock circuitry is preferentially preserved at the expense of the network device such that if, for any reason, the capacitive network is drained after running the network device, there will still be sufficient power stored in the capacitive network to maintain the timer/clock circuitry. | 01-17-2013 |
| 20130093380 | SOLAR CHARGE CONTROLLER WITH TIME-VARIABLE CHARGING STATES AND TIME-EQUAL SHUNTING STATES - Solar powered battery charging circuitry is provided. A charge controller receives electrical energy from a photovoltaic panel. Timer circuitry provides a control signal. A duty cycle of the control signal is determined by way of comparing a time-varying capacitor voltage to a lesser threshold voltage and a greater threshold voltage. The control signal is characterized by time-variable charging states and time-equal shunting states. Transfer of electrical energy from the photovoltaic panel to the storage battery is regulated by a shunting element using the control signal. | 04-18-2013 |
| 20150372328 | OPERATION METHOD OF FUEL CELL SYSTEM AND FUEL CELL SYSTEM - An operation method of a fuel cell system includes providing a turbo pump to supply an oxidant gas to a fuel cell to generate power through a reaction between a fuel gas and the oxidant gas. A branch valve to regulate a flow rate of the oxidant gas which flows through a branch passage that connects an oxidant gas supply passage and an oxidant off-gas discharge passage is provided. The turbo pump and the branch valve are controlled to regulate a flow rate of the oxidant gas to be supplied to the fuel cell in an extremely low power generation mode in which an extremely low generation power is requested. The extremely low generation power is less than or equal to a predetermined generation power corresponding to a minimum flow rate of the oxidant gas that is supplied by the turbo pump. | 12-24-2015 |
