| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 320163000 | Having solid-state control device | 78 |
| 20100052624 | BATTERY CHARGING SYSTEMS WITH CONTROLLABLE CHARGING CURRENTS - A charging path includes a charging switch for transferring a charging current from an input terminal to an output terminal. The charging path further includes a first enable terminal coupled to the charging switch. The first enable terminal receives a first enable signal to control the charging switch to operate in either a first mode, a second mode, or a third mode, based on a status of the output terminal. More specifically, in the first mode, the charging switch is fully turned off. In the second mode, an equivalent resistance of the charging switch is determined by a control terminal of the charging switch. In the third mode, the charging switch is turned off. | 03-04-2010 |
| 20110204854 | APPARATUS FOR TRANSFERRING ENERGY USING ONBOARD POWER ELECTRONICS AND METHOD OF MANUFACTURING SAME - An apparatus comprises a first energy storage device configured to output a DC voltage, a first bi-directional voltage modification assembly coupled to the first energy storage device, and a charge bus coupled to the first energy storage device and to the first bi-directional voltage modification assembly. The apparatus also comprises high-impedance voltage source coupleable to the charge bus and a controller configured to monitor a transfer of charging energy supplied from the high-impedance voltage source to the first energy storage device. The controller is also configured to compare the monitored transfer of charging energy with a threshold value and, after the threshold value has been crossed, control the first bi-directional voltage modification assembly to modify one of a voltage and a current of the charging energy supplied to the first energy storage device. | 08-25-2011 |
| 20110193532 | CONTROL DEVICE AND METHOD FOR CHARGE CONTROL - A device controls charging a battery with power supplied from a power supply located outside of a vehicle through a charge cable. The device includes a first microcomputer and a second microcomputer. The first microcomputer is configured to turn on a charge mode signal upon detecting a change in a pilot signal output through the charge cable, and to turn off the charge mode signal when a charge completion signal output from the second microcomputer is turned off. The second microcomputer is configured to charge the battery through the charge cable when the charge mode signal is turned on, and to turn off the charge completion signal when the charging is complete. When the charge completion signal is turned on at the time of the first microcomputer turning off the charge mode signal due to sudden fluctuations, the charge mode signal is turned on again. | 08-11-2011 |
| 20120217936 | POWER MANAGEMENT CIRCUIT - The present invention discloses a power management circuit, including: a first voltage regulator, which converts an input voltage to an output voltage; a second voltage regulator coupled between the output voltage and a battery; and a voltage difference control circuit, which receives the output voltage and a voltage of the battery, and outputs a voltage difference control signal to control the first voltage regulator. The voltage difference control circuit includes: a battery reference voltage determination circuit, which generates a battery reference voltage related to the battery voltage, and an error amplifier, which receives the output voltage and the battery reference voltage and generates the voltage difference control signal. | 08-30-2012 |
| 20090091300 | Collapsing Adaptor Battery Charger - A method and apparatus is disclosed to charge a battery. A wall adapter may provide a power to a battery charger in a collapsed mode of operation. In the collapsed mode of operation, the wall adapter may provide the battery charger with a collapsed power. The battery charger may provide a charging current and/or voltage in a constant current charge mode of operation and/or a constant voltage charge mode of operation using the collapsed power. When operating in the constant current charge mode of operation, the battery charger provides the charging current and/or voltage having a constant current until the voltage of the battery is less than or substantially equal to a constant charge voltage. Alternatively, when operating in the constant voltage charge mode of operation, the battery provides the charging current and/or voltage having a constant voltage until the voltage of the battery is less than or substantially equal to a float voltage. | 04-09-2009 |
| 20090289605 | CHARGE-CONTROLLING SEMICONDUCTOR INTEGRATED CIRCUIT AND CHARGING APPARATUS - Disclosed a charge-controlling semiconductor integrated circuit comprising: a current-controlling MOS transistor connected between a voltage input terminal and an output terminal and controls flowing current; a substratum voltage switching circuit connected between the voltage input/output terminal and a substratum to which an input/output voltage is applied; and a voltage comparison circuit to compare the input/output voltage, wherein the charge-controlling semiconductor integrated circuit controls the substratum voltage switching circuit based on an output of the voltage comparison circuit, the voltage comparison circuit includes an intentional offset in a first potential direction, and in a preceding stage of a first input terminal of the voltage comparison circuit, a level shift circuit to shift the output voltage to an opposite potential direction is provided, and to a second input terminal of the voltage comparison circuit, the input voltage is input. | 11-26-2009 |
| 20130113439 | Method and Device for Charging a Battery - A method for charging a battery, in particular a lithium ion battery, be performing the following: charging the battery using a constant charging current in a first phase, charging the battery using a constant charging voltage in a subsequent second phase, ending the charging as a function of a specifiable boundary value of the charging current in the second phase. In this context, the following operations are provided: comparing a guide voltage specified for setting the constant voltage to at least one stored switch-off value determined as a function of the boundary value, and ending the charging when the guide voltage reaches the switch-off value. Also described is a device for charging the battery. | 05-09-2013 |
| 20100171468 | CHARGER PROTECTION CIRCUITRY - The present invention provides charger protection circuitry for a rechargeable battery, and a method of protecting a charger cable during charging of a rechargeable battery. A switch controller is used to turn a switch element on and off in dependence on a direction of current flow through the charger protection circuitry during charging and otherwise. If current is flowing in the first direction the switch controller turns on the switch element such that the auxiliary current tripping element is bypassed, whereby the main current tripping element controls interruption of current flow. If instead current is flowing in a second direction opposite to the first direction, the switch controller turns off the switch element, whereby the auxiliary current tripping element is connected into the current flow path to control interruption of current flow. | 07-08-2010 |
| 20100127670 | BATTERY CHARGING SYSTEM HAVING HIGH CHARGE RATE - A charger including a regulator, a controller and a compensation-adjusting unit for accurately charging to a battery device is provided. The regulator provides a charging current to the battery device. The controller is coupled to the regulator for controlling the charging current. The compensation-adjusting unit is coupled to the regulator and the battery device for receiving a first reference voltage. In a first operation mode, the compensation-adjusting unit outputs the first reference voltage to the regulator. In a second operation mode, the controller instructs the regulator to transiently generate a first charging current and a second charging current. Responsive to the first and the second charging currents, the output voltage of the battery device presents a first output voltage and a second output voltage. The compensation-adjusting unit pre-estimates a parasitic resistance of the battery device by detecting the first and the second output voltage, thus compensating the first reference voltage. | 05-27-2010 |
| 20100033139 | POWER ADAPTER FOR BATTERY CHARGER AND METHOD THEREOF - A power adapter includes a charging unit configured to charge a rechargeable battery, a sensing unit configured to detect the voltage of the rechargeable battery, a switch unit connected between the external power source and the charging unit, and a control unit. The control unit is configured to compare the detected voltage with a fully-charged reference voltage which is provided for indicating the rechargeable battery is fully-charged during the charging process, and control the switch unit to turn on if the detected voltage is lower than the fully-charged reference voltage and control the switch unit to turn off if the detected voltage is equal to or higher than the fully-charged reference voltage. When the switch unit is turned on, the charging unit charges the rechargeable battery. When the switch unit is turned off, the charging unit stops charging the rechargeable battery. | 02-11-2010 |
| 20090189572 | Charge control circuit, charging device, and connection checking method - Electrical connection between a charging device and a secondary battery is checked during a wait time in which a charge mode of the charging device is selected. When the electrical connection is not successfully established, a charge current is not supplied from the charging device to the secondary battery. | 07-30-2009 |
| 20110267010 | BATTERY CHARGING APPARATUS - The battery charging apparatus is made with small and low-cost components. It includes a first transistor (T | 11-03-2011 |
| 20090278509 | BATTERY CHARGING AND ISOLATION SYSTEM FOR GAS ENGINE - A control system is adapted to control an internal combustion engine, which has a battery for electric start operation and a mechanical starter for manual start operation. The control system includes a transformer configured to generate a high voltage output for providing a spark, and a power regulation circuit having an input adapted to receive the high voltage output and generate a low voltage supply. A battery charging circuit includes a switching element adapted to receive the low voltage supply and operatively couple the low voltage supply to the battery to charge the battery. The battery charging circuit includes a disconnecting circuitry diode operatively coupled to the switching element so that if a voltage level of the battery falls below a predetermined value, the disconnecting circuitry diode turns off the transistor to electrically disconnect the battery from the low voltage supply and disable the electric start operation. The mechanical starter is configured to start the engine if the battery is insufficiently charged to drive the electric motor to start the engine. | 11-12-2009 |
| 20080303487 | Battery Protection Method and Structure Therefor - In one embodiment, a circuit is formed to couple a battery to a charging voltage at least a portion of a time when the charging voltage is greater than zero volts and is less than a first voltage value. The circuit is also formed to decouple the battery from the charging voltage approximately when the charging voltage is greater than the first voltage and also approximately when the charging voltage is no greater than zero volts. | 12-11-2008 |
| 20110012565 | CHARGING CIRCUIT WITH APPLICATION SYSTEM THEREOF - A charging circuit with an application system thereof provides an error amplifier to control a transistor switch for controlling the charging power source to charges the battery. When the voltage difference between the power source and load terminals of the transistor switch drops along with the transistor switch being turned on, the output voltage of the error amplifier changes as well to increase the turning-on resistance of the transistor switch such that the voltage difference between the power source and load terminals is capable of maintaining at a value above a certain reference level for avoiding the unstable state resulting from the charging circuit being turned on and off frequently. | 01-20-2011 |
| 20090015210 | Non-contact electric power transmission apparatus - The object is to provide a safe non-contact electric power transmission apparatus reducing unnecessarily consumed electric power, while intermittently-operated or otherwise restrained electric power transmission is not performed, and heat is not generated when a metal such as a foreign object is placed. In a non-contact electric power transmission apparatus having: a power supplying unit | 01-15-2009 |
| 20090051328 | BATTERY CHARGING APPARATUS - The battery charging apparatus is made with small and low-cost components. It includes a first transistor (T | 02-26-2009 |
| 20110227543 | Converter and method for extracting maximum power from piezo vibration harvester | 09-22-2011 |
| 20100181968 | BATTERY CHARGER WITH OVERVOLTAGE PROTECTION CIRCUITRY - A battery charger with an overvoltage protection circuitry is electrically coupled to a power source and a battery. The battery charger with the overvoltage protection circuitry includes a switching circuit. The switching circuit comprises a first switching element, a second switching element, a Zener diode, and a resistor. The first switching element includes a first terminal coupled to the power source, a control terminal, and a second terminal coupled to the battery. The second switching element includes a first terminal coupled to the control terminal of the first switching element, a control terminal, and a second terminal coupled to the first terminal of the first switching element. The Zener diode includes a cathode coupled to the control terminal of the second switching element and an anode grounded. The resistor includes a first terminal coupled to the control terminal of the first switching element and a second terminal grounded. | 07-22-2010 |
| 20100171469 | Charging Circuit Having Smooth Charging Transition Mode - A charging circuit includes a current mirror block configured to charge a load in response to a control voltage applied thereto, and a charge controller configured to generate the control voltage in response to comparison result values obtained by comparing a current sensing value and a voltage sensing value of the current mirror block with respective reference values. The comparison result value are applied to the gates of MOS transistors connected in series. The charge controller is configured to switch a charge mode from a constant current charge mode to a constant voltage charge mode when the charge state of the load reaches a predetermined state. | 07-08-2010 |
| 20110127971 | CHARGING CIRCUIT - A charging circuit integrated into a chip, comprising a charging unit, a switch unit, a biasing unit, a voltage-dividing unit, and a comparing unit. The charging unit is connected between a power supply input and a load for outputting a constant current based on a constant bias voltage supplied by the power supply input in order to charge the load. The switch unit is connected between the charging unit and the power supply input for turning on or cutting off the charging unit. The voltage-dividing unit generates a first signal to the comparing unit according to a voltage of the load. The biasing unit outputs a second signal having a constant voltage to the comparing unit. The comparing unit compares the first signal with the second signal for cutting off or turning on the switch unit, bringing the charging unit to charge or stop charging the load, respectively. | 06-02-2011 |
| 20100308776 | BATTERY CHARGER - A charger for lithium battery pack has a voltage input terminal, a current control module and a voltage output terminal including a voltage-rising module and a voltage-detecting module connected with the voltage-rising module and the voltage input terminal. | 12-09-2010 |
| 20110025277 | SWITCHING BATTERY CHARGING SYSTEMS AND METHODS - Embodiments of the present invention include techniques for charging a battery using a switching regulator. Some embodiments include programmable switching battery chargers that can be configured using digital techniques. Other embodiments include switching battery chargers that modify the battery current based on sensed circuit conditions such as battery voltage or input current to the switching regulator. In one embodiment, the present invention includes a USB battery charger. | 02-03-2011 |
| 20110241628 | POWER MANAGEMENT UNIT FOR PORTABLE ELECTRONIC DEVICES - A power management unit (PMU) for supplying electrical energy to a circuitry of a portable electronic device includes a power supply module, a power detection module connected to the power supply module, and a power control module connected to the power detection module and the circuitry. The power supply module includes a battery, a charge controller, and an adapter. The power detection includes a detection resistor connected to the battery, the charge controller, and the adapter. The battery or the adapter provides electrical energy to the circuitry. The adapter further charges the battery to charge the battery when it is used to provide electrical energy to the circuitry. The charge controller detects the current for charging the battery via the detection resistor, and regulates the current for charging the battery when the charging current exceeds a predetermined value. | 10-06-2011 |
| 20090256529 | BATTERY CHARGING CONTROL CIRCUIT - The present disclosure provides a battery charging control circuit. The charging control circuit includes: a constant-current charging unit and a trickle charging unit. The charging control circuit further includes a branch switch, a control unit, and a detection unit. The branch switch is connected between a power source and the rechargeable battery for enabling or disabling the constant-current charging unit. The control unit is between the constant-current charging unit and the branch switch for controlling the branch switch. The detection unit is used to detect a state of the rechargeable battery. If the detection unit detects the state of the rechargeable battery is correspond to a predetermined state, then the control unit controls the branch switch to disable the constant-current charging unit and enable the trickle charging unit. | 10-15-2009 |
| 20100244784 | BATTERY CHARGING SYSTEMS - A circuit for charging a battery may include a switch operable for conducting a current flowing through the switch, and a first amplifier coupled to the switch and operable for adjusting the current according to an amount of power dissipation associated with the switch. | 09-30-2010 |
| 20100277132 | DC-DC CONVERTER - A DC-DC converter includes an inductor, a capacitor, an output voltage detection circuit, and a synchronous rectification circuit including a rectifier-side synchronous rectifier element and a commutator-side synchronous rectifier element. The commutator-side synchronous rectifier element is turned on so as to pass a current through a closed loop composed of the commutator-side synchronous rectifier element, the inductor, and a second secondary battery. The characteristic evaluation of the second secondary battery is performed on the basis of the decrease in a detection voltage Vout of an output voltage Vo. As a result, it is possible to determine the effective capacity or characteristic degradation state of the second secondary battery with a circuit to charge the second secondary battery without using a dedicated circuit. | 11-04-2010 |
| 20090096429 | Control Unit For Triggering a Personal Protection Arrangement - A control unit for triggering the personal protection arrangement, including a first semiconductor module that is configured to make available various supply voltages and to charge an energy reserve, and including at least one second semiconductor module that is likewise configured to charge the energy reserve, the first and the second semiconductor module each having a semiconductor support. | 04-16-2009 |
| 20100295515 | Integrated PMOS Transistor and Schottky Diode and Charging Switch Circuit Employing The Integrated Device - The present invention discloses an integrated PMOS transistor and Schottky diode, comprising a PMOS transistor which includes a gate, a source, a drain and a channel region between the source and drain, wherein the source, drain and channel region are formed in a substrate, and a parasitic diode is formed between the drain and the channel region; and a Schottky diode formed in the substrate and connected in reverse series with the parasitic diode, the Schottky diode having one end connected with the parasitic diode and the other end connected with the source. | 11-25-2010 |
| 20110163728 | POWER MANAGEMENT CIRCUIT OF RECHARGEABLE BATTERY STACK - A system includes a sensing module and a switching module. The sensing module is configured to sense output voltages of first and second cells connected in series in a rechargeable battery stack. The switching module is configured to alternately connect a capacitance across the first cell and the second cell at a switching frequency when a difference in the output voltages is greater than or equal to a first threshold. The switching module is further configured to stop alternately connecting the capacitance when the difference is less than or equal to a second threshold, wherein the first threshold is greater than the second threshold. | 07-07-2011 |
| 20110175577 | POWER CONVERTER - A power conversion controller includes: a correction-value calculating unit that calculates a correction value DE | 07-21-2011 |
| 20110133702 | CIRCUIT AND METHOD OF OPERATION FOR AN ELECTRICAL POWER SUPPLY - A battery charging circuit comprising: a semiconductor switch having an output connected to a rechargeable battery; a battery charge controller for receiving power from an external source, and supplying output power to a portable device and the input of the semiconductor switch, the current output of the battery charge controller being controllable; and a voltage sensing circuit for: measuring the voltage drop across the battery charge controller; and responding to the voltage drop across the battery charge controller by modulating the semiconductor switch to reduce the quantity of current supplied to the rechargeable battery when the voltage drop is too great; whereby the total power dissipated by the battery charge controller is controlled, the portable device receiving the power it needs to operate and the rechargeable battery receiving any additional available power. | 06-09-2011 |
| 20110068750 | UNIVERSAL SERIAL BUS BATTERY - A universal serial bus battery includes a universal serial bus interface, a battery, a charger, a comparator, a first switch, and a second switch. The comparator is configured for comparing the voltage at the universal serial bus interface and the voltage of the battery, and to produce an ON signal when the voltage at the serial bus interface exceeds the voltage of the battery, or to produce an OFF signal otherwise. The first switch is configured for establishing an electrical connection between the USB interface and the charger upon receiving the ON signal or cutting off the connection upon receiving the OFF signal. The second switch is configured for establishing a connection between the universal serial bus interface and the battery when the connection between the USB interface and the charger is terminated by the first switch. | 03-24-2011 |
| 20090174371 | CHARGING CONTROL DEVICE FOR VEHICLE USE - A charging control device includes a control unit and a switching circuit. The control unit has an input end connected to a vehicle battery for receiving a battery voltage signal therefrom. The switching circuit includes at least two switch units, each of which is connected between an alternator and the vehicle battery and includes a conducting unit. The conducting unit includes a silicon controlled rectifier (SCR) connected to the control unit and the alternator. The control unit controls the SCR of each switch unit to switch from a non-conducting state to a conducting state with reference to the battery voltage signal such that each switch unit permits supply of electricity from the alternator to the vehicle battery when the battery voltage signal is lower than a predetermined threshold, and interrupts supply of the electricity from the alternator to the vehicle battery when otherwise. | 07-09-2009 |
| 20120306456 | CHARGING CIRCUIT - A charging circuit employed in an electronic apparatus is operable to charge a portable electronic device. The charging circuit includes a charging control microchip including two control terminals, a southbridge microchip, a logic control circuit, and a basic input/output system (BIOS). The southbridge microchip and the BIOS are both electronically connected to the logic control circuit to control the logic control circuit to set or reset voltage of the two control terminals, then the charging control microchip is switched to a charging mode or a data transmission mode according to the voltage of the two control terminals. | 12-06-2012 |
| 20100194354 | CHARGING MONITOR - A charging monitor has: a switch that is disposed between a load section having a storage battery and an external AC power supply supplying a current to the load section via a plurality of lines and interrupts the supply of the current from the external AC power supply to the load section; a current detection circuit that outputs a detection signal corresponding to a difference in level between currents flowing through the lines; a suppression circuit that suppresses a DC component contained in the detection signal; a filter circuit that filters a plurality of frequency components contained in the detection signal so that attenuation increases as a frequency becomes high; a rectifier smoothing circuit that rectifies and smoothens an output signal obtained when the detection signal passes through the filter circuit and the suppression circuit; and an electric leakage determination circuit that detects an electric leakage and shuts off the switch when the level of the signal smoothened by the rectifier smoothing circuit exceeds a preset reference level. | 08-05-2010 |
| 20120043944 | METHOD AND APPARATUS FOR AVERAGE CURRENT CONTROL - A method and apparatus for controlling a converter circuit within the electrical accumulator unit based on a comparison between an actual average converter current and a desired average converter current. | 02-23-2012 |
| 20090102432 | BATTERY CHARGER - An exemplary battery charger includes an input interface arranged to connect to a DC power source, having a positive terminal and a negative terminal; an output interface arranged to connect to a battery, having a positive terminal and a negative terminal; a switch circuit connected between the positive terminals of the input interface and the output interface, comprising a control terminal; a detecting resistor connected between the negative terminals of the input interface and the output interface; a detecting circuit connected between the negative terminals of the input interface and the output interface to detect a voltage across the detecting resistor and output a digital signal; and a processor receiving the voltage signal to determine whether the battery is fully charged and generate a voltage signal to the control terminal of the switch circuit via an inverting circuit for turning off the switch circuit when the battery is fully charged. | 04-23-2009 |
| 20120206111 | SYSTEM FOR CONTROLLING CHARGING OF BATTERY AND BATTERY PACK COMPRISING THE SAME - A system for controlling charging of a battery and a battery pack including the system are disclosed. The system includes a comparison unit that compares an actual output voltage value of a charger with an expected supply voltage value of the charger, and a control unit that resets a taper current value according to the comparison result. | 08-16-2012 |
| 20120206110 | REVERSE CURRENT PREVENTION CIRCUIT, CHARGING CIRCUIT INCORPORATING REVERSE CURRENT PREVENTION CIRCUIT, AND CONSTANT-VOLTAGE CIRCUIT INCORPORATING REVERSE CURRENT PREVENTION CIRCUIT - A reverse current prevention circuit, connected to an input terminal, an output terminal, and a driver transistor, including a current detection circuit to detect a current flowing through the driver transistor, and convert the detected current into a detection voltage; a proportional voltage generator to generate a proportional voltage proportional to a difference voltage between an input voltage at the input terminal and an output voltage at the output terminal; an inversely-proportional voltage generator to generate an inversely-proportional voltage inversely proportional to the difference voltage between the input voltage and the output voltage; and a comparison circuit to compares the generated voltages. When the detection voltage, the proportional voltage, and the inversely-proportional voltage are equal, the comparison circuit determines that the indication of the reverse current is detected and prevents the reverse current flowing from the output terminal to the input terminal. | 08-16-2012 |
| 20130009608 | RECARGEABLE BATTERY UNIT AND CHARGING METHOD - The present invention relates in particular to a battery unit with at least one battery cell and a switch unit that is designed so as to alter the internal resistance of the battery unit. | 01-10-2013 |
| 20120112707 | POWER CONTROL MODULE FOR BATTERY PACK - A battery management system is disclosed for control of individual cells in a battery pack. The battery management system includes a cell, a micro controller, a bleed off resistor, an analog circuit which includes a powered gate. In practice the powered gate which resides in the analog circuit is smartly configured such that in the event the micro controller becomes unresponsive while the bleed off resistor is connected to a cell the powered gate will open thereby disconnecting the bleed off resistor from the cell. | 05-10-2012 |
| 20110089908 | CIRCUITRY FOR BALANCING CHARGING OF SERIES CONNECTED BATTERY CELLS - For a circuit for preventing overcharging of a battery cell, the overcharging protecting circuit having a voltage detector for monitoring the voltage across the battery cell, a polarity protection circuit for protecting the voltage detector from a reverse polarity connection of the battery cell to the voltage detector is disclosed. The polarity protection circuit comprises a semiconductor device coupled across voltage detection inputs of the voltage detector. The semiconductor device is adapted to shunt current across the voltage detection inputs of the voltage detector when the battery cell is connected in reverse polarity to the voltage detector. | 04-21-2011 |
| 20120081081 | SYSTEM AND METHOD FOR CONVERTING AN AC INPUT VOLTAGE TO A REGULATED OUTPUT CURRENT - A converter according to one embodiment converts an AC voltage to a regulated output current provided to a DC load of a Z-type configuration. A filter capacitor is provided to average current flowing through the load. The converter includes a rectifier network for rectifying the AC voltage and for providing a rectified voltage, and a smoothing capacitor for smoothing the rectified voltage. The converter includes a hysteretic current mode controller which controls a switching transistor based on sensed voltage and sensed current provided through an inductor coupled in series with the load. The transistor is turned on when current reaches a low valley level and is turned off when the current reaches a peak level. Operation toggles in this manner while a sensed voltage is above a predetermined level. A valley fill network may be provided to keep sensed voltage from falling below the predetermined minimum level. | 04-05-2012 |
| 20100231178 | POWER SUPPLY DEVICE - The power supply device contains a first auxiliary device and a first rectifier connected to a DC voltage source; a second auxiliary device that receives electric power via the first rectifier; a first DC/DC converter that uses the DC voltage source as an input source; an electricity storage device connected to an output terminal of the first DC/DC converter; and second DC/DC having an output terminal connected to the first rectifier, which uses the electricity storage device as an input source. When the DC voltage source has output voltage higher than a predetermined value, electric power is fed from the DC voltage source to the second auxiliary device and the electricity storage device is put on charge by the first DC/DC converter. When the output voltage gets lower than the predetermined value, the second DC/DC converter starts to operate, preventing decrease in voltage to be applied to the second auxiliary device. | 09-16-2010 |
| 20110273145 | CHARGE CONTROL CIRCUIT - A challenge to be met by an aspect of the present invention is to provide a charge control circuit that prevents occurrence of a decrease in battery capacity even when a battery stays in a connection with an external power supply and that induces neither battery deterioration nor overcharge. A first switch ( | 11-10-2011 |
| 20110309802 | CLOSED LOOP CHARGER FOR LEAD-ACID BATTERIES - Embodiments of apparatus and methods for charging a battery are disclosed. The apparatus may comprise a connector configured to electrically couple to a battery, an adjustable current source capable of supplying current to the connector at a plurality of charge rates, and a resistor network configured to bias the adjustable current source to supply current at one of the plurality of charge rates in response to a digital input signal. The method may comprise receiving a digital input signal having a plurality of bits, the digital input signal indicating a desired charge rate for the battery, configuring a resistor network in response to the digital input signal, biasing an adjustable current source using the configured resistor network, and supplying current to the battery at the desired charge rate using the adjustable current source. | 12-22-2011 |
| 320164000 | Detection of current and voltage amplitude | 31 |
| 20110175578 | Power Management Unit For A Wireless Device - A method and apparatus is disclosed to restore or recharge one or more cells of a battery. A switching module sources an element charging current from a first input voltage to the battery when a charging control signal is at a first logical level or sinks an element discharging current from the battery to a second input voltage when the charging control signal is at a second logical level. A controller module provides the charging control signal based upon a comparison of a reference voltage and a control voltage pulse, the control voltage pulse being generated by the controller module in response to a replica current, the replica current being proportional to the element charging current. A feedback module compares a voltage of the battery to a reference voltage to provide a charging error signal. A reference voltage generator module provides the reference voltage in response to the charging error signal, the reference voltage being proportional to a constant current and a duty-cycle of the switching charger when the charging error signal indicates a first mode of operation or a scaled representation of the constant current when the charging error signal indicates a second mode of operation. | 07-21-2011 |
| 20100090662 | CHARGER SYSTEM FOR RECHARGEABLE LITHIUM BATTERIES UTILIZING POWER SUPPLY TERMINAL AS INITIAL CHARGING MEANS, AND COMPLETING CHARGING VIA INTERNAL CONSTANT-VOLTAGE CHARGER - The present invention discloses a charger system for rechargeable lithium batteries, which comprises a power supply terminal, a first switch device, a second switch device, a charging unit, a DC/DC converter, and a controller. The power supply terminal provides power with two ends thereof respectively coupled to the first switch device and a protection circuit. The first switch device is coupled to the second switch device. The first switch device and the second switch device are respectively coupled to the protection circuit. The charging unit is coupled to the protection circuit and the second switch device and has a plurality of charging bays. The charging bays respectively receive lithium batteries and are respectively parallel coupled to constant-voltage chargers to charge the lithium batteries. The DC/DC converter is coupled to the constant-voltage chargers. The controller is coupled to the DC/DC converter, the charging unit and the protection circuit respectively. | 04-15-2010 |
| 20130082665 | Charger Calibrating Device and Calibrating Method Thereof - A charger calibrating device and a calibrating method thereof. The device comprises a control module and a processing module. The control module controls a charger to be calibrated to perform a first stage charging and a second stage charging on an electronic device. The processing module performs an adjusting process according to the second stage charging time for adjusting the high level period of the PWM signal in the charging circuit of the charger. In the adjusting process, generating an updated high level period by adding or decreasing a preset adjusting amplitude, and decrease the preset adjusting amplitude by half to generate an updated adjusting amplitude. The processing module terminates the calibrating process after repeating the aforementioned calibrating loop a preset number of times. | 04-04-2013 |
| 20130049705 | REGULATOR, BATTERY CHARGING APPARATUS AND BATTERY CHARGING SYSTEM - A regulator comprises a rectifying circuit that rectifies an alternating current output from an output terminal of each phase of the three-phase alternating-current generator “ | 02-28-2013 |
| 20090302805 | CHARGE-CONTROLLING SEMICONDUCTOR INTEGRATED CIRCUIT - Disclosed is a charge-controlling semiconductor integrated circuit including: a current-controlling MOS transistor; a current detection circuit including a 1/N size current-detecting MOS transistor; and a gate voltage control circuit, wherein the current detection circuit includes an operational amplifier circuit, a bias condition of the current-detecting MOS transistor becomes same as the current-controlling MOS transistor based on an operational amplifier circuit output, voltage drops in lines from drain electrode to a corresponding input point of the operational amplifier circuit become the same by a parasitic resistance, and when the output of the operational amplifier circuit is applied to a control terminal of the bias condition controlling transistor, the drain voltages become the same potential, and the line from the drain electrode of the current-detecting MOS transistor to the input point is formed to be redundantly arranged inside the chip so that a parasitic resistance becomes a predetermined value. | 12-10-2009 |
| 20120223682 | System and Method of Charging a Battery Using a Switching Regulator - In one embodiment the present invention includes a system and method of charging a battery using a switching regulator. In one embodiment, a switching regulator receives an input voltage and input current. The output of the switching regulator is coupled to a battery to be charged. The switching regulator provides a current into the battery that is larger than the current into the switching regulator. As the voltage on the battery increases, the current provided by the switching regulator is reduced. The present invention may be implemented using either analog or digital techniques for reducing the current into the battery as the battery voltage increases. | 09-06-2012 |
| 20130099758 | APPARATUS AND METHOD FOR CONTROLLING CHARGE CURRENT IN PORTABLE TERMINAL - An apparatus and method enable a charging power supply for a battery charge in a portable terminal regardless of the charge capacity of a charge cable for an external power supply. The apparatus for controlling a charge current in the portable terminal includes a detector for detecting power supplied to a battery and a charge capacity of a charge cable when the charge cable is connected to supply external power, and a charge integrated circuit (IC) for resetting a charge capacity of the portable terminal according to the capacity of the charge cable and controlling the power supplied to the battery according to an operation of the detector, when the charge capacity of the charge cable detected by the detector is not equal to the charge capacity of the portable terminal. | 04-25-2013 |
| 20120249086 | STATE OF CHARGE DETERMINATION SYSTEMS AND METHODS - In one embodiment, a method implemented by a processor, comprising receiving voltage values corresponding to a battery system, receiving charge values corresponding to charge flowing through the battery system, and determining a state of charge based on specified anchoring points of a charge integration, the anchoring points based on the received voltage and time. | 10-04-2012 |
| 20110279095 | UNIVERSAL SERIAL BUS DEVICE AND RELATED METHOD - A universal serial bus device includes: a core circuit having a first pin and a second pin, and having an input impedance looking into the core circuit from the first pin and the second pin; and a charging control circuit, coupled to the core circuit, arranged for selectively providing a voltage source to one of the first pin and the second pin; wherein the input impedance of the core circuit is configured to make the voltage source substantially intact when the voltage source is coupled to one of the first pin and the second pin. | 11-17-2011 |
| 20090256530 | BATTERY CHARGING CONTROL CIRCUIT - The present invention provides a charging control circuit for a rechargeable battery. The charging control circuit includes: a constant-current charging unit and a trickle charging unit. The charging control circuit further includes a branch switch, a detection switch, a control unit, and a detection unit. The branch switch is connected between a power source and the rechargeable battery for enabling or disabling the constant-current charging unit, the detection switch is turned on or off depending on the enable or disable state of the constant-current charging unit. The control unit is connected between the detection switch and the branch switch for controlling the branch switch to turn on or off depending on the off or on state of the detection switch. | 10-15-2009 |
| 20090160408 | BATTERY CHARGING DEVICE, THREE-PHASE VOLTAGE GENERATING CIRCUIT, THREE-PHASE VOLTAGE GENERATION METHOD AND DELAY ANGLE CONTROL METHOD - In the battery charging device of the present invention, a U, V, W phase voltage generating circuit detects a voltage signal of a U phase sub-coil of a three-phase alternating current generator, and generates a signal of a triangular wave that is in synchronization with the U phase. Moreover, a first triangular wave is generated in synchronization with a phase from 0° to 180° of the U phase rectangular wave, and a second triangular wave is generated in synchronization with a phase from 180° to 360° of the U phase. In addition, a V phase rectangular wave is generated in which the level is inverted at a voltage point of two thirds the peak voltage of the first triangular wave, and in which the level is inverted at a voltage point of two thirds the peak voltage of the second triangular wave, and a W phase rectangular wave is generated in which the level is inverted at a voltage point of one third the peak voltage of the first triangular wave, and in which the level is inverted at a voltage point of one third the peak voltage of the second triangular wave. | 06-25-2009 |
| 20080309294 | PORTABLE TELECOMMUNICATIONS DEVICE - A portable telecommunications device comprises a charging interface for connection to an external power supply, a voltage and current ratio converter configured to convert an input voltage at the charging interface into an output voltage for charging a battery; and a controller configured to control the converter. | 12-18-2008 |
| 20120105015 | Battery Pack Overcharge Protection System - An overcharge protection device (OPD) is provided that may be used alone, or in combination with conventional charging protection systems, to protect a battery pack from the occurrence of a potentially damaging overcharging event. The OPD is designed to be coupled to, and interposed between, the terminals of the battery pack. During normal system operation, the OPD has no effect on the operation of the charging system or the battery pack. During an overcharging event, if overcharging is not prevented by another conventional system, the OPD of the invention creates a short across the terminals of the battery pack causing a battery pack fuse designed to provide battery pack short circuit protection to blow, thereby interrupting the current path from the charger to the battery pack and preventing the battery pack from being overcharged. | 05-03-2012 |
| 20080315846 | BATTERY PACK, BATTERY CHARGER AND CHARGING METHOD - A battery pack, a battery charger, a method for charging a battery pack are provided. The battery pack includes a secondary battery, a switch element for controlling charging and discharging the secondary battery, a controller for controlling the switch element, and a communication unit for performing with a battery charger. During charging, an initial charging is switched to a quick charging when a voltage of the secondary battery reaches a predetermined voltage, and the battery charger judges the battery pack as abnormal when the voltage does not reach the predetermined voltage within a timeout period after the initial charging is started. At least one of the timeout period and the predetermined is stored. At least one of the timeout period and the predetermined voltage to be read out is transmitted through the communication unit to the battery charger. | 12-25-2008 |
| 20090051329 | METHOD AND CHARGE-UP CIRCUIT CAPABLE OF ADJUSTING CHARGE-UP CURRENT - A charge-up circuit includes a charge-up transistor configured to supply a charge-up current to a secondary battery in accordance with a control signal, a detection resistor connected in series with the charge-up transistor to detect the charge-up current, a current-to-voltage conversion circuit configured to generate and output a monitor voltage in accordance with the charge-up current based on each voltage at both end terminals of the detection resistor, a reference voltage generator configured to generate a predetermined reference voltage and including a voltage adjusting mechanism to generate the reference voltage from the constant voltage so that the charge-up current becomes a desired current, and a charge-up current control circuit configured to control the charge-up transistor so that the monitor voltage becomes the reference voltage. | 02-26-2009 |
| 20100253293 | SWITCH EMBEDDED INTEGRATED CIRCUIT AND METHOD FOR BATTERY PROTECTION - A switch embedded integrated circuit for battery protection includes a first pin to be connected with one terminal of a battery, a second pin to be connected with a load or charger, a third pin to be connected with another terminal of the battery, a MOSFET having a body diode thereof and connected between the first and second pins, a control logic circuit and a detection circuit. The detection circuit monitors the voltage between the first pin and the third pin to determine a detection signal for the control logic circuit to turn on or off the MOSFET and switch the direction of the body diode, thereby providing an over charging and an over discharging protection functions. | 10-07-2010 |
| 20090072796 | USB Charger Circuit - A USB charger circuit includes at least a converter, a control circuitry, a first resistor, a second resistor, an error amplifier, a sense resistor and a diode. The converter has a transistor. The control circuitry is coupled to the transistor. The control circuitry is used for producing a drive signal to the transistor. The first resistor is connected between the output node of the converter and a first node. The second resistor is connected between the first node and a second node. The error amplifier is coupled to receive a voltage divided by the first resistor and the second resistor to compare to a reference voltage. The sense resistor is connected between the second node and ground. The diode is connected between the output node of the converter and a first node. | 03-19-2009 |
| 20110234175 | PEDAL GENERATOR ASSEMBLY - A generator assembly for converting human generated mechanical energy into electrical power for charging at least one rechargeable device is provided herein. The generator assembly generally includes a housing, a primary gear supported within the housing, an input mechanism mounted to the primary gear for receiving the human generated mechanical energy, an alternator for converting the mechanical energy converting the mechanical energy into electrical power, and a charging mechanism mounted to the housing with the charging mechanism directly connected to the alternator, where the charging mechanism has at least one rechargeable interface for transferring the electrical power to the rechargeable device. A method of charging at least one rechargeable device with a generator assembly and a method of authorizing use of a generator assembly are also provided. | 09-29-2011 |
| 20080284383 | Charge Detector - The subject matter of this specification can be embodied in, among other things, an apparatus that includes a battery system, which includes at least one cell and a charge enable device to couple the at least one cell to a charging voltage. The apparatus also includes an excessive voltage detector to output a signal to control the charge enable device. The signal prevents charging of the at least one cell if an excessive charging voltage is detected based on an activation of a clamping component. | 11-20-2008 |
| 20100308777 | CIRCUIT AND METHOD OF OPERATION FOR AN ELECTRICAL POWER SUPPLY - A battery charging circuit comprising: a semiconductor switch having an output connected to a rechargeable battery; a battery charge controller for receiving power from an external source, and supplying output power to a portable device and the input of the semiconductor switch, the current output of the battery charge controller being controllable; and a voltage sensing circuit for: measuring the voltage drop across the battery charge controller; and responding to the voltage drop across the battery charge controller by modulating the semiconductor switch to reduce the quantity of current supplied to the rechargeable battery when the voltage drop is too great; whereby the total power dissipated by the battery charge controller is controlled, the portable device receiving the power it needs to operate and the rechargeable battery receiving any additional available power. | 12-09-2010 |
| 20110210704 | MULTIPLE BAY BATTERY CHARGERS AND CIRCUITRY - A multi-bay battery charger comprises a power supply ( | 09-01-2011 |
| 20120146591 | CHARGING CIRCUIT AND CHARGING METHOD EMPLOYING THE SAME - A charging circuit includes a transistor, a current regulating resistor, a field effect transistor (FET) and a main controller. The transistor includes an emitter, a base and a collector, the FET includes a source, a gate and a drain. The emitter is connected to the battery charger; the drain is connected to the battery. The main controller includes a current control unit, a charge control unit and a voltage detection unit. The current control unit transmits current signals to the base of the transistor to turn on the transistor and regulate the current values of the collector, the voltage detection unit detects the voltage of the battery and controls the charge control unit according to detection result, and the charge control unit sends a command signal to the gate to switch the FET on or off. | 06-14-2012 |
| 20080258691 | OVER VOLTAGE AND OVER CURRENT PROTECTION INTEGRATED CIRCUIT - An integrated circuit is disclosed including a primary input for receiving an input voltage, a battery voltage input for receiving a battery voltage signal and an output for providing an output voltage higher than the battery voltage. First circuitry responsive to the input voltage is provided for turning off the output voltage responsive to an input over voltage condition. Second circuitry responsive to the battery voltage signal is provided for turning off the output voltage responsive to a battery over voltage condition. Third circuitry provides for over current protection. | 10-23-2008 |
| 20090033293 | VOLTAGE CONVERTER WITH COMBINED CAPACITIVE VOLTAGE DIVIDER, BUCK CONVERTER AND BATTERY CHARGER - A voltage converter including a capacitive voltage divider combined with a buck converter and battery charger. The converter includes four capacitors, a switch circuit, an inductor and a controller. The capacitors form a capacitor loop between an input node and a reference node and include a fly capacitor controlled by the switch circuit, which is controlled by a PWM signal to half the input voltage to provide a first output voltage on a first output node, and to convert the first output voltage to the second output voltage via the inductor. The controller controls the PWM signal to regulate the second output voltage, and provides a voltage control signal to control the input voltage to maintain the first output node between a predetermined minimum and maximum battery voltage levels. A battery charge path is coupled to the reference node and battery charge mode depends upon the battery voltage. | 02-05-2009 |
| 20110316488 | Circuit Arrangement for the Energy Supply of a Battery and Associated Method - A circuit arrangement for supplying energy, comprising: a first input adapted to receive a first voltage from a first terminal of a control component, a second input adapted to receive a second voltage from a second terminal of the control component, a first output adapted to receive output a control signal to a control terminal of the control component for controlling an energy supply of an electrical load; and a power determining arrangement, comprising a switched-capacitor arrangement having an input coupled to the first and the second input of the circuit arrangement and an output coupled to the first output of the circuit arrangement. | 12-29-2011 |
| 20090021223 | BATTERY CHARGER FOR PREVENTING BOTH OVERSHOOT CHARGING CURRENT AND OVERCHARGED BATTERY VOLTAGE DURING CHARGING MODE TRANSITION - A battery charger for charging a battery through controlling a charging regulation circuit is provided. The battery charger includes a current sensing unit and an operational amplifier. The current sensing unit monitors a charging current applied to the battery when the battery charger operates under a constant current mode, thereby generating a first regulation signal to the charging regulation circuit. The operational amplifier compares a battery voltage of the battery with a first reference voltage to generate a comparison result. When the battery charger operates under the constant current mode, the comparison result controls a charging mode transition from the constant current mode to a constant voltage mode. When the battery charger operates under the constant voltage mode, the comparison result acts as a second regulation signal to control the charging regulation circuit. | 01-22-2009 |
| 20120212189 | SYSTEM AND METHOD FOR ELECTRONIC DEVICE CHARGING - An electronic device which is able to be charged via a universal serial bus (USB) interface which connects to a computer. A first voltage of a battery of the electronic device, a second voltage and an electric current of the USB interface are determined. If a difference between the first voltage and a saturation voltage of the battery is greater than a predefined value, the electronic device is charged with a first electric current. If the second voltage is not lower than a threshold voltage and the electric current of the USB interface is not lower than the electrical energy consumption of the electronic device, the first electric current is decreased. | 08-23-2012 |
| 20120133340 | CHARGING CONTROL CIRCUIT - A charging control apparatus controls charging of a battery connected to a battery terminal and supplies a voltage and a current necessary for a system circuit through an output terminal. The charging control apparatus has a switching control circuit that controls a DC-DC converter, the DC-DC converter performing DC-DC conversion with respect to an input voltage input through an input terminal and outputting an obtained output voltage to the output terminal. The charging control apparatus has an output voltage detection circuit that detects the output voltage. The charging control apparatus has a battery voltage detection circuit that detects a battery voltage of the battery terminal. The charging control apparatus has a first switch MOS transistor connected between the output terminal and the battery terminal. The charging control apparatus has a voltage control circuit that controls an operation of the first switch MOS transistor according to the battery voltage. | 05-31-2012 |
| 20120249088 | POWER STORAGE DEVICE, POWER STORAGE METHOD, AND PROGRAM - A power storage device including: a secondary battery; an acquisition unit that acquires charging period information for charging the secondary battery; and a charge control unit that calculates a charging power on the basis of the charging period information and controls charging power used for charging the secondary battery so that of the charging power is equal to the calculated charging power. | 10-04-2012 |
| 20120249087 | BATTERY PROTECTION CIRCUIT, BATTERY PROTECTION DEVICE, AND BATTERY PACK - A battery protection circuit for protecting a secondary battery composed of a first cell and a second cell, includes a reference voltage supply circuit that outputs a first reference voltage and a second reference voltage generated based on cell voltages of the first cell and the second cell, respectively; a first detection circuit that outputs a signal prohibiting charging when at least one of the cell voltages of the first cell and the second cell exceeds a predetermined overcharge indication value; a second detection circuit that outputs a signal prohibiting charging when at least one of the first reference voltage and the second reference voltage is not within a predetermined target range; and a control circuit that controls to prohibit charging when at least one of the outputs from the first detection circuit and the second detection circuit is the signal prohibiting charging. | 10-04-2012 |
| 20100231179 | POWER MANAGEMENT CIRCUIT TO MANAGE DISTRIBUTION OF RECEIVED POWER AND A PORTABLE APPARATUS HAVING THE SAME - A portable apparatus includes a system configured to receive a system current and perform a function, a charging battery configured to be charged with a charging battery current and supply power to the system, and a power management circuit configured to receive an externally supplied power, supply the system current to the system, and supply the charging battery current to the charging battery based on a sensed level of the system current, wherein the charging battery current decreases in proportion to the system current. | 09-16-2010 |
