Class / Patent application number | Description | Number of patent applications / Date published |
320141000 | Pulse modulation | 68 |
20080197811 | Circuits and methods for battery charging - Circuits and methods for battery charging are disclosed. In one embodiment, the battery charging circuit comprises an AC to DC converter, a charging control switch, and a charger controller. The AC to DC converter provides a charging power to a battery pack. The charging control switch is coupled between the AC to DC converter and the battery pack. The charging control switch transfers the charging power to the battery pack. The charger controller detects a battery status of the battery pack and controls the charging control switch to charge the battery pack in a continuous charging mode or a pulse charging mode according to the battery status. The charger controller also controls the AC to DC converter to regulate the charging power according to the battery status. | 08-21-2008 |
20090009141 | System and method for battery charging - A charging circuit includes a pulse generator and a controller coupled to the pulse generator. The pulse generator is used to generate a plurality of pulses to control a charging switch. The controller is used to control a pulse density of the plurality of pulses. A charging current flowing through the charging switch can be adjusted according to the pulse density. | 01-08-2009 |
20090251106 | NON-ISOLATED CHARGER WITH BI-POLAR INPUTS - Systems and methods are provided for an uninterruptable power supply having a positive DC bus, a neutral DC bus, and a negative DC bus. The uninterruptible power supply includes a battery charger circuit having an inductor, a first charger output, and a second charger output. A first switch connected to a first end of the inductor is configured to couple the positive DC bus with the first charger output. A second switch connected to a second end of the inductor is configured to couple the negative DC bus with the inductor. The neutral DC bus can be coupled to the second charger output. The battery charger circuit can be configured to draw power from at least one of the positive DC bus and the negative DC bus to charge a battery coupled to the first charger output and the second charger output. | 10-08-2009 |
20100066309 | Method for pulsed charging of a battery in an autonomous system comprising a supercapacitance - The autonomous system comprises an intermittent power source delivering a direct current. A supercapacitance is connected in parallel with the battery and the power source respectively via a first switch and a second switch. Charging of the battery comprises pulsed current charging managed by a control circuit. During a current pulse, the amplitude of the current and the amplitude of the voltage increase at the terminals of the battery are measured. The dynamic internal resistance of the battery is determined from said amplitudes. A maximum acceptable current threshold is determined according to a maximum voltage threshold, to said dynamic internal resistance and to the no-load voltage at the battery terminals. At the next current pulse, the value of the charging current is limited by controlling the closing time of the second switch. | 03-18-2010 |
20130106366 | CONSTRUCTION AND OPERATION OF AN OILFIELD MOLTEN SALT BATTERY | 05-02-2013 |
20130141053 | DESULFATION DEVICE AND DESULFATION METHOD - A desulfation device | 06-06-2013 |
20140139192 | Method and Circuitry to Adaptively Charge a Battery/Cell - The present inventions, in one aspect, are directed to techniques and/or circuitry to adaptively charge a battery/cell using data which is representative of a change in terminal voltage of the battery/cell. In another aspect, the present inventions are directed to techniques and/or circuitry to adaptively charge a battery/cell using data which is representative of a partial relaxation time of the battery/cell. In yet another aspect the present inventions are directed to techniques and/or circuitry to adaptively charge a battery/cell using data which is representative of an overpotential or full relaxation time of the battery/cell. In another aspect the present inventions are directed to techniques and/or circuitry to adaptively charge a battery/cell using data which is representative of a state of charge and/or data which is representative of a state of health of the battery/cell. | 05-22-2014 |
20150102779 | Device and Method for Charging a Battery - A method for charging a battery is provided, wherein current pulses are supplied to the battery, wherein each pulse is followed by a rest period during which no current is supplied to the battery, and wherein the state of charge of the battery is determined during the rest period. | 04-16-2015 |
20160190823 | OPTIMAL BATTERY CHARGING METHOD AND CIRCUIT - An optimal battery charging method and circuit for automatically regulating an output current to an energy storage load includes the steps of using a first-status current and a second-status current of the output current to obtain the energy storage load, analyzing the second-status voltage and the first-status voltage to obtain an equivalent resistance parameter of the energy storage load, and using the equivalent resistance parameter to compute a charging power loss of the energy storage load to regulate an output cycle of the output current, so that the energy storage load can be charged at constant temperature to achieve the effect of high charging efficiency. | 06-30-2016 |
320142000 | Phase controlled | 1 |
20100026245 | SINGLE-PHASE PHASE LOCKED LOOP SUITABLE FOR USE IN A HYBRID VEHICLE CHARGING SYSTEM AND METHOD FOR CHARGING A HYBRID VEHICLE FROM A SINGLE-PHASE POWER SOURCE - Apparatus for charging an electric vehicle or a hybrid vehicle are provided. Particularly, apparatus for charging a hybrid vehicle from a single-phase standard (110 volt, single-phase, 60 Hz in the U.S.) are provided. In one implementation, a single-phase phase locked loop (PLL) receives a single-phase power gird voltage and delays it by one-quarter cycle to create an orthogonal imaginary second power signal. These signals are then applied to a transform matrix within a PLL to phase lock an output signal to the incoming power grid voltage. | 02-04-2010 |
320145000 | Pulse-width modulation | 58 |
20080197812 | Topology and method for dynamic charging current allocation - In one embodiment, a battery management system includes a charger controller for controlling a charging current of a battery according to a status of a load which is powered by the battery, and a counter coupled to the charger controller for determining a charging time according to such status. Advantageously, a first charging current is selected when the load is off. A second charging current that is less than the first charging current is selected when the load is on. Furthermore, a frequency of the counter is set to a first frequency when the load is off. The frequency is set to a second frequency that is less than the first frequency when the load is on. | 08-21-2008 |
20080258687 | High Efficiency PWM Switching Mode with High Accuracy Linear Mode Li-Ion Battery Charger - A battery charger includes: a step-down switching converter connected to provide power at a predetermined average current from an input voltage V+ to an output node V | 10-23-2008 |
20080258688 | Battery Charging Systems and Methods with Adjustable Current Limit - Embodiments of the present invention include techniques for charging a battery using a regulator. In one embodiment, the present invention includes an electronic circuit comprising a regulator having an input coupled to a power source for receiving a voltage and a current and an output for providing an output current, an input voltage detection circuit coupled to the power source, and an adjustable current limit circuit for controlling the input or output current of the regulator, wherein input voltage detection circuit monitors the voltage from the power source and the adjustable current limit circuit changes the input or output current of the regulator to optimize the power drawn from power source. | 10-23-2008 |
20080297118 | Battery charging circuit - A battery charging circuit includes a power supply circuit being connected via a switching element and a current-limiting resistor to a battery to subject the battery to a trickle charge, and a control circuit turning on and off the switching element on a given duty to subject the battery to the trickle charge by means of a pulsed charge. The control circuit includes an on-timing adjustment circuit detecting a battery voltage to control the duty of turning on and off the switching element. The on-timing adjustment circuit makes a duty ratio smaller in a state of a low battery voltage than in a state of a high battery voltage and turns on and off the switching element to perform the trickle charge by means of the pulsed charge. | 12-04-2008 |
20090001937 | Power management systems with controllable adapter output - A power management system includes a battery pack having a battery controller and includes an adapter operable for charging the battery pack and powering a system load. The adapter generates a power recognition signal indicative of a maximum adapter power and receives a control signal. The battery controller in the battery pack receives the power recognition signal and generates the control signal to adjust an output power of the adapter according to a status of the battery pack and a status of the system load. | 01-01-2009 |
20090015207 | Multi-Cell Charger with Individual Cell Control - The present invention discloses a battery charger and a method for charging a plurality of batteries. The battery charger includes: a current source for supplying a source current which has a charge current portion and a diverted current portion; bypass sections; voltage clamp sections; sense sections; a feedback section for processing information from the sense sections; and a controller for modifying the source current based on the information from the feedback section. Each bypass section is connected to a battery for diverting the diverted current. Each voltage clamp section is connected to the bypass section for clamping a voltage across the battery when the voltage increases to a predetermined level. Each sense section is connected to the bypass section for determining the diverted current and/or the charge current. | 01-15-2009 |
20090027011 | BATTERY CHARGER - A batter charger for charging a secondary batter using a power supply circuit which converts an AC input into a DC output, includes a first resistor for detecting constant-current control and a second resistor for detecting end of charging. The first resister and the second register are inserted in series in a current path of the charging current. The power supply circuit has output characteristics of a constant-current control characteristic and a constant-voltage control characteristic. The constant-current control is performed using a first detection voltage generated at the first resistor, and the constant-voltage control is performed by comparing a second detection voltage generated at a series resistor composed of the first resistor and the second resistor with a reference voltage using a comparator, and detecting an end of charging indicated by the second detection voltage fallen below the reference voltage. | 01-29-2009 |
20090066295 | METHOD FOR CHARGING NON-AQUEOUS ELECTROLYTE SECONDARY BATTERY - A method for charging a non-aqueous electrolyte secondary battery including the step of repeating pulse charging and charging pause, in which a pulse charging time is arbitrarily set between a lower limit value and an upper limit value, the lower limit value being an inverse time Tx of a frequency Fx of the high frequency side at which an imaginary part of an alternating current impedance of the non-aqueous electrolyte secondary battery is a first local maximum value, or of a frequency adjacent to Fx, and the upper limit value being an inverse time Ty of a frequency Fy at the low frequency side at which an imaginary part of the alternating current impedance of the non-aqueous electrolyte secondary battery is a second local maximum value, or of a frequency adjacent to Fy. | 03-12-2009 |
20090072794 | Apparatus for charging on-vehicle battery and apparatus for controlling generating operation of on-vehicle generator - An on-vehicle charging apparatus charges a battery mounted on the vehicle. In the apparatus, a generator generates electric power to output voltage for charging the battery and a controller, which is located outside the generator, outputs a pulse signal for controlling a generated state of the generator. A reception device receives the pulse signal outputted from the controller. The received signal is subjected to filtering at a filter, where pulse signals whose cycles are different from a predetermined cycle are removed. Further, using the outputted pulse signal from the filter, a duty ratio of the pulse signal is calculated. A voltage outputted from the generator is regulated based on the calculated duty ratio. | 03-19-2009 |
20090206796 | SYSTEM AND METHOD FOR CHARGING BATTERIES - A high frequency battery charger includes a converter, drive logic, and control logic. The converter transforms a DC voltage into a high frequency AC voltage. The drive logic controls a conversion of the high frequency AC voltage through a train of pulses. The control logic adjusts the output of the converter to maximize a charging cycle of a battery. The method of transforming an AC input into a direct current output used to charge a rechargeable battery includes transforming an AC input into a first DC output; transforming the first DC output into a high frequency AC output; transforming the high frequency AC output into a second DC output; and passing a charging current to an external load when the load is correctly connected to an output. | 08-20-2009 |
20090273317 | INTELLIGENTIZED HIGH-FREQUENCY CHARGER FOR BATTERIES - An intelligentized high-frequency charger for batteries includes a monolithic processor control circuit, a charging control circuit and a detection circuit electrically connected to the said monolithic processor control circuit respectively. The said monolithic processor control circuit includes a monolithic processor, an auxiliary power supply circuit and a key display circuit electrically connected to the said monolithic processor respectively. The said charging control circuit includes a PWM circuit, a drive circuit, a rectifier and filter circuit, an output control circuit and a current sampling circuit. The detection circuit includes a cell detection circuit, a reverse connection detection circuit, a cell voltage detection circuit and an auto pole circuit. | 11-05-2009 |
20090322287 | CHARGING SYSTEM - A method for controlling a charging system having multiple loads is disclosed. Power is supplied from an AC/DC adapter to a first charger, a second charger, and system loads. The first charger is operated at a setting value having smaller power consumption than a setting value necessary for a first battery pack when output power of a power source reaches a first threshold value during a time when the first battery pack is required to be charged in a standard charging mode. The first charger is operated at a setting value according to a specific charging mode even when the output power of the power source reaches the first threshold value during a time when the first battery pack is required to be charged in the specific charging mode. A second charger is operated at a setting value having smaller power consumption than a setting value necessary for a second battery pack when the output power of the power source reaches a second threshold value larger than the first threshold value. | 12-31-2009 |
20100060240 | Method for managing charging of a rechargeable battery - The management method comprises a charging phase (F | 03-11-2010 |
20100066310 | SYSTEM AND METHOD FOR CHARGING AND PULSATING BATTERIES - A battery charging and pulsating system including a battery having a positive terminal and a negative terminal, a charger electrically connected to the positive and the negative terminals of the battery, the charger including a controller, a pulsator electrically connected to the positive and the negative terminals of the battery, the pulsator including a controller, and a voltage measuring circuit electrically connected to the positive and the negative terminals of the battery, the voltage measuring circuit being adapted to measure a voltage across the positive and the negative terminals of the battery, wherein the controller of the pulsator is adapted to activate the pulsator when the measured voltage is at least one of (1) at or below a predetermined threshold voltage and (2) at or above a predetermined gassing voltage. | 03-18-2010 |
20100072951 | NON-AQUEOUS ELECTROLYTE SECONDARY BATTERY CHARGING METHOD, ELECTRONIC DEVICE, BATTERY PACK, AND CHARGING DEVICE - The present invention aims to quickly charge a non-aqueous electrolyte secondary battery including a heat-resistant layer between a negative electrode and a positive electrode. A method according to the present invention for charging a non-aqueous electrolyte secondary battery including a heat-resistant layer between a negative electrode and a positive electrode is provided with a step of performing pulse charge on the secondary battery, a step of detecting a change amount of a cell voltage associated with a change in the concentration polarization of the non-aqueous electrolyte as a polarization voltage, and a step of terminating the pulse charge when the polarization voltage increases to or above a predetermined threshold value. According to the present invention, it is possible to quickly charge the non-aqueous electrolyte secondary battery including the heat-resistant layer between the negative electrode and the positive electrode at such a borderline level as not to cause overcharge. | 03-25-2010 |
20100090657 | CIRCUIT ARRANGEMENT FOR THE PARALLEL OPERATION OF BATTERY CHARGERS - Circuit arrangement for the parallel operation of battery, wherein each battery charger comprises respective pairs of direct current output terminals for connection to the battery to be charged, and between said pairs of output terminals a repetitive sequence of pulsating direct current voltage can be measured, and the peak values of the pulsating direct current voltage is higher than the nominal terminal voltage of the battery (B), and each battery charger (Ch | 04-15-2010 |
20100148730 | Cable Voltage Drop Compensation For Battery Chargers - A battery charger may be configured to charge a battery by way of a charging cable. A DC gain of a voltage control loop of the battery charger may be limited to a predetermined value to compensate for voltage drop on the charging cable. For example, a DC gain of an error amplifier on the voltage control loop may be limited to a predetermined value for cable voltage drop compensation. The error amplifier may use a reference signal that is generated as a function of the error signal. The DC gain of the error amplifier may be limited by connecting a resistor to form an RC circuit on an output node of the error amplifier. | 06-17-2010 |
20100156355 | SYSTEM AND METHOD FOR CHARGING A PLUG-IN ELECTRIC VEHICLE - A battery charging system and method for charging a plug-in electric vehicle with power from an external power source, such as a standard 110 volt or 220 volt AC wall outlet. The method senses various internal and external conditions and uses this information to charge the plug-in electric vehicle in an optimum fashion that reduces charging time yet avoids damage to components of the charging system. In one embodiment, the battery charging system includes an external power source, a battery charger with sensors for monitoring the external power source and the charger, a battery unit with sensors for monitoring the battery, a battery charging control module for processing the information, and a user interface that allows user-specified custom charging constraints. All of these components, with the exception of external power source, may be located on the vehicle. | 06-24-2010 |
20100164437 | BATTERY FORMATION AND CHARGING SYSTEM AND METHOD - Method and system for forming or charging batteries or power cells. The system includes control processor; input switch coupled to a power supply, charging switch coupled to the battery, filter network between the input and charging switches, battery temperature sensor, input voltage sensor, and charging voltage and current sensors. The control processor monitors the sensors and controls the switches to deliver a charging waveform to the battery selected to perform an efficient charging of the battery. The method includes applying a charging current pulse, having a current value and a pulse width, to the battery at a repetition rate; monitoring battery temperature; determining whether to change the current value, repetition rate or pulse width; and changing them when determined. Battery resistance can be a determinant. A sensor on a battery post can monitor battery temperature. A hardware temperature sensor can monitor system temperature and be used to detect system resonance. | 07-01-2010 |
20100213901 | SECONDARY BATTERY CHARGE CONTROL METHOD AND CHARGE CONTROL CIRCUIT - A secondary battery charge control method includes: a charge control step of executing charging by supplying a charge current to a secondary battery; a charge information acquisition step of acquiring information relating to the charging executed in the charge control step; a storage step of storing the information acquired in the charge information acquisition step as charge data; and a charge inhibition determination step of determining whether to inhibit the charging in the charge control step on the basis of the charge data of a previous cycle that have been stored in the storage step when charging in the charge control step is started again after charging in the charge control step has been completed. | 08-26-2010 |
20100213902 | Use of High Frequency Transformer to Charge HEV Batteries - A system for charging a high voltage battery that includes a low DC voltage battery, a DC-to-AC converting circuit, a controller, a AC-to-DC converting circuit and a high DC voltage battery. The low voltage battery outputs a low DC voltage signal. The DC-to-AC converting circuit receives the low DC voltage signal to convert into a chopped DC voltage signal. The DC-to-AC converter outputs a high AC voltage signal corresponding to the chopped DC voltage signal. The controller controls a duty cycle of the chopped DC voltage signal. The AC-to-DC converting circuit converts the high AC voltage signal into a high DC voltage signal. The high voltage battery charges using the high DC voltage signal. A method for charging a high voltage battery is also provided. | 08-26-2010 |
20100219795 | PULSE CHARGE METHOD FOR NONAQUEOUS ELECTROLYTE SECONDARY BATTERY AND PULSE CHARGE CONTROL DEVICE - A pulse charge method for a nonaqueous electrolyte secondary battery, includes: a charge control step of pulse charging by supplying a pulsed current periodically to the nonaqueous electrolyte secondary battery; a battery voltage detection step of measuring a battery voltage of the nonaqueous electrolyte secondary battery; a comparison step of comparing the battery voltage, measured in the battery voltage detection step when the pulsed current is supplied, with a predetermined set voltage; and a charge end control step of ending the pulse charging when a comparison result shows that the measured battery voltage is equal to or higher than the set voltage. | 09-02-2010 |
20100225280 | BATTERY CHARGER USING PHASE SHIFT DOUBLE FORWARD CONVERTING CIRCUIT - A technique for dynamically adjusting an output voltage of forward converter circuits for a battery charging operation is provided. The technique allows for varying voltage at the charging battery by manipulating the duty cycles of two forward converter circuits. The present disclosure provides methods and systems for increasing synchronized duty cycles in a pair of forward converter circuits in response to a changing battery charge state that requires a higher voltage output then changing a phase shift between the duty cycles in response to further increases in output voltage demand. The present disclosure also provides methods and systems for setting a phase shift between duty cycles in a pair of forward converter circuits based on battery rating and then altering pulse width in response to changing battery charge state. The invention provides a controller designed to receive input signals and generate output pulse width modulation signals that control the duty cycle width and phase shift of the outputs of the forward converter circuits in response to these signals. Methods of accommodating for the time needed for the transformer core to reset via leading edge or lagging edge compensation are provided. | 09-09-2010 |
20100231174 | CIRCUITS AND METHODS FOR BATTERY CHARGING - A circuit for charging a battery pack includes a power converter and a charger controller. The power converter is operable for receiving an input power, and for providing a charging power for charging the battery pack. The power converter provides galvanic isolation between input circuitry and output circuitry of the circuit. The input circuitry shares a first ground potential with the input power, and the output circuitry shares a second ground potential with the charging power. The charger controller in the input circuitry includes a modulator for generating a driving signal to drive the power converter and control the charging power. | 09-16-2010 |
20100270979 | BATTERY CHARGER AND METHOD FOR CHARGING A BATTERY - The present invention relates to a battery charger for charging a battery ( | 10-28-2010 |
20100320973 | CHARGE CONTROL CIRCUIT - When a control circuit detects from a signal CPO | 12-23-2010 |
20100327816 | Intelligent Voltage and Current Controlled PWM Microcontroller Type Battery Charger - An intelligent voltage and current controlled PWM microcontroller type battery charger includes an electromagnetic interference filter, a bridge rectifier, a transformer and a switching power supply of a rectifier as a main structure and operates with a microcontroller unit of a PWM controller for charging various chargeable batteries. The microcontroller unit operated with a battery charging protection block include a battery charging loop circuit connected to two PWM controllers for modulating outputs if constant voltage values and constant current values to control a feedback of the switching power supply. A current detection block, a voltage detection block and a temperature protection block are operated with the microcontroller unit. A battery charging protection block and a delay startup battery charging protection system are connected to the microcontroller unit. The invention can achieve the effects of charging different types of batteries, saving energy, reducing carbon and protecting environment. | 12-30-2010 |
20110031934 | Power management unit for a wireless device - A method and apparatus is disclosed to regulate an input voltage to provide a regulated output power. The regulated output power may include a smooth direct current (DC) component and an undesired alternating current (AC) component, the smooth DC component being an average of the regulated output power. A buck regulator module of the present invention regulates the smooth DC component to approximate a reference voltage. The buck regulator module additionally replicates the undesired AC component embedded within the regulated output power. A replicated undesired AC component is combined with the regulated output power to reduce the undesired AC component embedded within the output power. | 02-10-2011 |
20110057623 | SYNERGISTIC SYSTEM BETWEEN BATTERY CHARGER AND BATTERY - A synergistic system made up of a control unit having the function of identifying and monitoring the battery, and transmitting the information regarding the actual state of its energy conditions to a battery charger, made to attain energy saving and well as a greater functionality and efficiency of the identified battery. | 03-10-2011 |
20110084667 | CIRCUITS AND METHODS FOR CONTROLLING A CURRENT FLOWING THROUGH A BATTERY - A circuit for controlling a current flowing through a battery includes a driver and a filter coupled to the driver. The driver can generate a pulse signal in a first operating mode and generate a first signal in a second operating mode to control the current through the battery. The filter can filter the pulse signal to provide a filtered DC signal to adjust an on-resistance of a switch in series with the battery based on a duty cycle of the pulse signal in the first operating mode. The filter can receive the first signal and provide a second signal to drive the switch in a linear region in the second operating mode. | 04-14-2011 |
20110109275 | CHARGING CIRCUIT, AND BATTERY PACK AND CHARGING SYSTEM EQUIPPED WITH SAME - A charging circuit includes: a battery connection terminal for connection to a secondary battery; a power supply connection terminal for receiving, from a power supply unit which outputs a current for charging the secondary battery, the current; first and second switching elements, connected in series between the power supply connection terminal and the battery connection terminal, and turning on and off the current flowing from the power supply connection terminal to the battery connection terminal; a current detection unit for detecting the current flowing from the power supply connection terminal to the battery connection terminal; a charging control unit for supplying a pulse-shape charging current to the battery connection terminal by repeating a process of turning on the first and second switching elements, a process of turning on the first switching element and turning off the second switching element, and a process of turning off the first switching element and turning on the second switching element; and a malfunction judgment unit for judging that at least one of the first and second switching elements is malfunctioning in an interval in which only one of the first and second switching elements is turned on by the charging control unit when the current detected by the current detection unit exceeds a current threshold value set so as to enable judgment as to whether current is flowing to the battery connection terminal. | 05-12-2011 |
20110115440 | SECONDARY BATTERY CHARGE METHOD AND BATTERY CHARGER - Disclosed herein is a secondary battery charge method, including the steps of: conducting a pulsed charge control adapted to conduct a pulsed charge by repeating a cycle of a charge condition and a pause condition of a secondary battery at predetermined intervals; detecting a voltage detection adapted to detect the voltage of the secondary battery; determining a charge termination determination adapted to determine whether to terminate the charge of the secondary battery based on the battery voltage in a pause condition detected by the voltage detection step; and terminating a charge termination control adapted to terminate the pulsed charge when it has been determined by the charge termination determination step that the charge should be terminated. | 05-19-2011 |
20110121788 | Charging Device for Battery - A charging device for charging primary cells includes a transforming rectifying unit, a voltage current processing unit, a microprocessor, an agitating unit, a detecting unit and a display unit. The transforming rectifying unit transforms an input power source into a direct-current output power source, which is transformed by the voltage current processing unit into a direct-current power source and charging power source. The charging power source is used for charging the battery set. The detecting unit detects an output voltage of the battery set and produces a detecting signal. The microprocessor controls an overall charging operation of the charging device according to the detecting signal, including making the agitating unit produce a sine pulse to chemically activate the battery set to remove the carbon deposition, and making the display unit show the charging status. | 05-26-2011 |
20110127969 | Charging Circuit - The present invention is applicable to the technical field of charging electrical storage devices, and provides a charging circuit including an energy input, an input power detecting module, an electric energy storage, a boost module, a battery, a charging switch device, a PWM power isolating driver module, and a control module. In the present utility model, when detecting a decrease in the input power through the input power detecting module, the control module of the charging circuit will control the boost module to increase the electric energy stored in the electric energy storage, thus the charging voltage for the battery is increased and the charging efficiency of the charging circuit is improved. | 06-02-2011 |
20110133700 | METHOD AND SYSTEM FOR MINIMUM OUTPUT-VOLTAGE BATTERY CHARGER - An apparatus and method for a portable device incorporating a battery and a battery charger. In the portable device, there are a plurality of system components configured to facilitate a plurality of functions that the portable device is designed to perform. The battery in the portable device is configured for providing an internal power supply to the plurality of system components in the absence of an external input power supply. The battery charger is configured for charging the battery when the external input power supply is available. The battery charger disclosed herein is capable of supplying system power to the system components when voltage of the battery that is being charged is below a limit, thereby allowing the portable device to operate when voltage of the battery drops below the limit. | 06-09-2011 |
20110140673 | Pulse width modulated battery charging - A battery management system for charging a battery by a charger includes a transistor and either a charge pump or a push-pull output driver. The transistor increases and decreases an electrical connection between the battery and a voltage from the charger and transmits a charge current from the charger to the battery by turning on and off in response to a pulse width modulated drive signal generated by the charge pump or the push-pull output driver. The charge pump or the push-pull output driver increases the drive signal when the voltage from the charger is above a pre-charge threshold voltage and decreases the drive signal when the voltage from the charger is below the pre-charge threshold voltage. | 06-16-2011 |
20110215769 | BATTERY CHARGING SYSTEM AND METHOD - An exemplary battery charging system includes a temperature sensor, a voltage measuring device, a processor and a charger. The temperature sensor is used for continuously sensing the current temperature of a rechargeable battery. The voltage measuring device is used for continuously measuring the current voltage U of the rechargeable battery. The processor is used for comparing the current temperature T with two temperature thresholds and comparing the current voltage U with two cut-off voltages, and generating a PWM control signal to the charger based on the results of the comparisons. The charger is used for charging the battery. When T reads as normal, the charger charges the battery using a first average current I | 09-08-2011 |
20110227542 | CHARGE CONTROL DEVICE AND LOAD DRIVING DEVICE - A charge control device includes a charge control circuit to control a charge of a secondary battery by controlling an output stage connected between a power supply and the secondary battery. The charge control circuit includes a first error amplifier to generate a first error voltage in response to a difference between a predetermined first reference voltage and a first feedback voltage. The value of the first feedback voltage is determined in accordance with a primary current supplied from the power supply to the output stage. The charge control circuit also includes a second error amplifier to generate a second error voltage in response to a difference between either one of a predetermined second reference voltage and the first error voltage, and a second feedback voltage. The value of the second feedback voltage is determined in accordance with a charge current supplied from the output stage to the secondary battery. The charge control circuit also includes a control signal generator to generate the control signal of the output stage in response to the second error voltage. | 09-22-2011 |
20110260693 | RECHARGING DEVICE WITH VOLTAGE DETECTION FOR AN ALKALINE PRIMARY CELL - A recharging device with voltage detection for an alkaline primary cell includes an oscillating unit that generates a pulse signal from an input power to charge the alkaline primary cell. The recharging device also includes a detecting unit configured to be electrically coupled to the alkaline primary cell. The detecting unit is also configured to detect a voltage of the alkaline primary cell and output a corresponding detection signal. The recharging device further includes a control unit electrically coupled to the oscillating unit and the detecting unit. The control unit controls the oscillating unit to operate in one of a first charge mode and a waiting mode based on the detection signal output by the detecting unit. The oscillating unit outputs the pulse signal when operated in the first charge mode and discontinues output of the pulse signal when operated in the waiting mode. | 10-27-2011 |
20110291621 | Smart Battery Charging System For Electrical Generator - An electrical generator has an engine that provides a mechanical output that is converted to electrical current by an alternator. The engine is started by a battery-powered motor starter. The battery is charged during running of the electrical generator by a portion of the electrical current output by the alternator. The battery is charged according to a charging profile based on the temperature of the battery at start up of the electrical generator. | 12-01-2011 |
20120112703 | System and Method for Managing a Battery - A method for managing a battery with multiple battery cells is disclosed. The method includes monitoring parameters of the battery cells by an information acquisition unit. Parameters of the battery cells include individual cell voltages. The method further includes selecting, by a controller one of multiple charging modes in which the battery cells are charged according to the cell voltages. The charging modes include a constant current charging mode, a constant voltage charging mode, and a pulse charging mode. | 05-10-2012 |
20120126755 | SYSTEMS AND METHODS FOR PROVIDING POWER TO A LOAD BASED UPON A CONTROL STRATEGY - Systems and methods are provided for an electrical system. The electrical system includes a load, an interface configured to receive a voltage from a voltage source, and a controller configured to receive the voltage from the voltage source through the interface and to provide a voltage and current to the load. Wherein, when the controller is in a constant voltage mode, the controller provides a constant voltage to the load, when the controller is in a constant current mode, the controller provides a constant current to the load, and when the controller is in a constant power mode, the controller provides a constant power to the load | 05-24-2012 |
20120133336 | RECHARGEABLE BATTERY CHECKER - A rechargeable battery checker for measuring the voltage of a rechargeable battery includes a PMIC, a charging switch, a voltage measuring switch, and a control circuit. The charging switch is connected to a charging terminal of the PMIC and the rechargeable battery, to control the PMIC to charge or pause charging the rechargeable battery. The voltage measuring switch is connected to a voltage measuring terminal of the PMIC and the rechargeable battery, to control the PMIC to measure or pause measuring the voltage of the rechargeable battery. The control circuit connects to the charging switch and the voltage measuring switch, and to output a modulated signal, and periodically change the signal to switch on/off the charging switch and the voltage measuring switch. The PMIC determines whether the rechargeable battery is fully charged according to the measured voltage of the rechargeable battery. | 05-31-2012 |
20120161717 | CIRCUITS AND METHOS FOR BATTERY CHARGING - A circuit for charging a battery pack includes a transformer and a charger controller. The transformer is operable for receiving an input power and for providing a charging power according to a driving signal to charge the battery pack. The charger controller is operable for monitoring a status of the battery pack, for selecting a charging mode from multiple charging modes according to the status, and for generating the driving signal according to the charging mode to adjust the charging power. The charger controller further executes a state machine that stores data indicating predetermined battery statuses that cause saturation of the transformer, and that selects a protection mode in which said charging power is restricted if the status of the battery pack matches to one of the predetermined battery statuses. | 06-28-2012 |
20120169295 | BATTERY PULSE CHARGING METHOD AND APPARATUS - Disclosed herein are some embodiments for safely charging a mobile system battery pack, even when the power source (e.g., adapter) voltage is at a relatively high level that would otherwise result in excessive charge current. | 07-05-2012 |
20120306454 | SYSTEMS AND METHODS FOR INITIALIZING A CHARGING SYSTEM - Systems and methods are provided for initiating a charging system. The method, for example, may include, but is not limited to, providing, by the charging system, an incrementally increasing voltage to a battery up to a first predetermined threshold while the energy conversion module has a zero-percent duty cycle, providing, by the charging system, an incrementally increasing voltage to the battery from an initial voltage level of the battery up to a peak voltage of a voltage source while the energy conversion module has a zero-percent duty cycle, and providing, by the charging system, an incrementally increasing voltage to the battery by incrementally increasing the duty cycle of the energy conversion module. | 12-06-2012 |
20130015822 | Multi-Purpose Power Management Apparatus, Power Path Control Circuit and Control Method ThereforAANM Kung; Nien-HuiAACI Hsinchu CityAACO TWAAGP Kung; Nien-Hui Hsinchu City TW - The present invention discloses a multi-purpose power management apparatus, a power path control circuit, and a control method therefor. The multi-purpose power management apparatus controls power conversion between an input power and an output power and charging operation from the output power to a battery. The multi-purpose power management apparatus includes: a switch circuit including at least one power transistor; a switch control circuit generating a PWM signal to control the power transistor, for controlling the power conversion between the input power and the output power; a charging management circuit for controlling the charging operation from the output power to the battery; and a path selection circuit for determining whether the charging operation is controlled by the charging management circuit. | 01-17-2013 |
20130021003 | COMMUNICATION TERMINAL, CHARGE CONTROL PROGRAM AND CHARGE CONTROL METHOD - A communication terminal having a secondary battery and configured to control charge of the secondary battery, a charge control program, and a charge control method of the communication terminal are provided. The communication terminal includes a first detection unit configured to detect a temperature, a second detection unit configured to detect a transmission power of an electric wave, a charge unit configured to perform intermittent charge to the secondary battery, and a change unit configured to change a duty ratio of the intermittent charge by the charge unit based on the temperature detected by the first detection unit and the transmission power detected by the second detection unit. | 01-24-2013 |
20130038297 | BATTERY CHARGING CONTROL DEVICE AND METHOD OF IMPLEMENTING THE SAME - The invention discloses a charging control method for adjusting a charging current of a charging device, including monitoring a working voltage of the charging device, wherein the working voltage includes a voltage difference between a charging voltage and a battery voltage; adjusting the charging current of the charging device dynamically according to the working voltage of the charging device to maintain a working power of the charging device within a predetermined power range. | 02-14-2013 |
20130076312 | CHARGING CURRENT CONTROL METHOD AND CHARGING SYSTEM - A charging method and a charging system are introduced for controlling a charging current by a PWM method. A charging IC is controlled to supply the charging current to a battery, and a control unit is used to generate a PWM signal with a duty cycle, and a filter unit is used to convert the PWM signal into a voltage signal to be supplied to the charging IC, and the control unit determines whether a current of a battery detected by the battery status detection unit reaches a regular current, so that a PWM signal with a duty cycle greater than the previous duty cycle by a default increased cycle is provided if the detected current has not reached the regular current. Thus, the feature of the PWM signal is used to set the charging current according to the capacity of the battery automatically. | 03-28-2013 |
20140055099 | SYSTEM, METHOD, AND COMPUTER PROGRAM PRODUCT FOR REMEDYING A CHARGING ERROR - A system, method, and computer program product are provided for remedying a charging error. In use, a battery and a battery charger are identified. Additionally, an error associated with the charging of the battery by the battery charger is detected. Further, the error is remedied. | 02-27-2014 |
20140191730 | CONVERTER AND METHOD FOR EXTRACTING MAXIMUM POWER FROM PIEZO VIBRATION HARVESTER | 07-10-2014 |
20140312853 | METHOD FOR MONITORING AND OPTIMISING THE OPERATION OF A CHARGING TERMINAL FOR AN ELECTRIC VEHICLE AND CHARGING TERMINAL FOR IMPLEMENTING SAID METHOD - A method for monitoring and optimizing operation of a terminal, including: generating an output voltage equal to a first DC value; connecting a vehicle, the output voltage switching to a second value; authorizing charging of the vehicle by modulating the output voltage between two values, with a maximum authorized charge current being set; checking an ability of the vehicle to be recharged by monitoring a value of the output voltage; supplying an output voltage modulated between a third voltage value and a negative value; initializing a first timer; reading a diagnosis time between initialization and the switching of the voltage from the second to the third value; comparing the time with standard values to determine a type of charger; taking characteristics of the charger into account to optimize energy management. | 10-23-2014 |
20140340049 | BATTERY EQUALIZING CIRCUIT - The present disclosure discloses a battery equalizing circuit, which comprises a first battery unit, a second battery unit, a current detecting resistor, an equalizing inductor, a first control switch, a second control switch and a feedback control circuit. The first battery unit is connected in series with the second battery unit. The first battery unit, the current detecting resistor, the equalizing inductor and the first control switch are electrically connected with each other to form a first circuit loop. The second battery unit, the current detecting resistor, the equalizing inductor and the second control switch are electrically connected with each other to form a second circuit loop. The feedback control circuit is connected in parallel with the current detecting resistor to detect a voltage drop across the current detecting resistor, and switch between the first and the second circuit loop so as to make an equalizing current substantially constant. | 11-20-2014 |
20140375276 | UNIVERSAL INDUSTRIAL BATTERY OPTIMIZATION DEVICE - Improvements in a battery de-sulfating device are disclosed. The improvements including a plurality of capacitive discharge channels selectively activatable by a control board to provide a pulse wave modulated de-sulfating current to a lead-acid battery. The de-sulfating current can be a variable, or harmonic, repeating pattern of about 0.1-1.5 ms ON pulse followed by an about 2-9 ms OFF period which may be applied to the battery at an operator-adjustable peak amperage of about 0-350 amps. The de-sulfation process before, during or after the normal battery charging cycle, or any combination thereof. The temperature of the battery and the specific gravity of the fluid within the battery is measure during the de-sulfating process. The extent of sulfation of the battery may be ascertained by measuring the impedance of the battery. | 12-25-2014 |
20150061604 | WIRELESS CHARGING CIRCUIT AND ABNORMAL STATE PROTECTION CIRCUIT THEREOF - A wireless charging circuit and an abnormal state protection circuit thereof is provided in the present invention. The wireless charging circuit includes a power converter, a resonant circuit and an abnormal state protection circuit. The power converter receives an input voltage for outputting a PWM (pulse width modulation) signal. The input terminal of the resonant circuit receives the PWM signal. The common voltage terminal of the resonant circuit is coupled to a common voltage. The abnormal state protection circuit includes a DC sampling circuit and a control circuit. The DC sampling circuit is coupled to the resonant terminal of the resonant circuit for sampling the DC component of the voltage of the resonant terminal to obtain a DC voltage. The control circuit is coupled to the power converter and the DC sampling circuit for receiving the DC voltage. When the DC voltage is greater than a threshold voltage, the control circuit controls the power converter to reduce the current flowing through the resonant circuit. | 03-05-2015 |
20160172877 | Optimal Battery Current Waveform for Bidirectional PHEV Battery Charger | 06-16-2016 |
20180026472 | Charging System, Charging Method, and Power Adapter | 01-25-2018 |