Abstract: An system includes a first battery having a first desired operating temperature range between a first lower threshold temperature and a first upper threshold temperature and a second battery having a second desired operating temperature range between a second lower threshold temperature and a second upper threshold temperature. The system further includes a temperature control system coupled to the first and second batteries and configured to convey heat energy from the first battery to the second battery when the temperature of the second battery is less than the second lower threshold temperature to increase the temperature of the second battery toward the second desired operating temperature range and to convey heat energy away from the second battery when the temperature of the second battery is greater than the second upper threshold temperature to decrease the temperature of the second battery toward the second desired operating temperature range.

Abstract: A busbar assembly for an inverter module has a power module, a capacitor module with at least one capacitor, and a battery all interconnected by a busbar. The busbar includes a base busbar portion that is electrically coupled to the battery and a branch busbar portion that extends from the base busbar to the power module and that electrically connects to the capacitor module at points located between the base node and the power module.

Abstract: A propulsion system is provided that includes an electric drive, a first energy storage system electrically coupled to the electric drive through a direct current (DC) link, and a second energy storage system electrically coupled to the electric drive. The propulsion system further includes a multi-channel bi-directional boost converter coupled to the first energy storage system and to the second energy storage system such that the second energy storage system is decouplable from the DC link, wherein the second energy storage system comprises at least one battery coupled in series with at least one ultracapacitor.

Abstract: An AC/DC power converter which charges a secondary battery from an AC power supply and also converts power from the secondary battery to the AC voltage is provided. A capacitor C is connected to DC terminals of the four reverse-conductive type semiconductor switches in a single-phase bridge structure, and a secondary battery is connected via a DC inductance to the semiconductor switches. The semiconductor switches are connected via an AC inductance L with an AC power supply and opposing pairs of the semiconductor switches are alternately turned ON/OFF in synchronization with the phase of the supply voltage. When an AC power supply with a frequency which is lower than the resonance frequency of the LC is connected, the switching will be carried out in a zero-voltage-zero-current condition and AC/DC reversible power conversion is possible just through the control of the gate phase of the switches.

Abstract: A system and method for recharging a plug-in hybrid vehicle. The system includes a controller that schedules the recharging of the vehicles on local electrical distribution networks. The system arranges the schedule to minimize the demand loading on the local distribution network to more efficiently operate power plants providing electrical power to the distribution networks. A system for collecting charges associated with the recharging of plug-in hybrid vehicles is also disclosed providing for prepaid utility accounts.

Abstract: A method for recharging an electric storage battery in the charging system of an electric vehicle from an electric utility power grid includes determining the length of time required to recharge the battery, determining the desired time when the recharge is to be completed, transmitting to the electric power utility the length of time required to recharge the battery and the desired time, and recharging the battery from the utility grid during a period when projected load demand is lower than peak demand and ending no later than the desired time.

Abstract: A limit value of an output current of power converter is defined as a first current value when a voltage at both ends of capacitor is higher than a voltage at both ends of battery, and a limit value of the output current thereof is defined as a second current value when the voltages are substantially equal to each other, the first current value is set to be smaller than the second current value. Thus, when a voltage at both ends of capacitor and a voltage at both ends of battery are substantially equal, heat is hardly generated. The limit value of the output current is set to a maximum current consumed by load. When a voltage at both ends of capacitor is higher than a voltage at both ends of battery, the limit value of the output current is set to be smaller than the second current value, and thereby heat generation is suppressed. Thus, the size of the heat dissipating components can be reduced, and a power supply system whose entire size can be minimized can be provided.

Abstract: An electromechanical power transfer system for a vehicle, comprises: an electrical power source; a system controller; at least two dynamoelectric machines; an electrically engageable clutch for each machine; an input shaft coupled to the jack shaft; an output shaft coupled to a load presented by the vehicle; and at least two electrically engageable transmission gear sets for coupling the input shaft to the output shaft; wherein the system controller selectively engages each machine clutch and each transmission gear set.

Abstract: A battery arrangement (1) has at least two battery cell packs (2, 3) arranged in a common battery housing (4). The battery housing (4) has at least one first opening (5) for supplying cooling air and at least one second opening (6) for discharging heated air. The battery cell packs (2, 3) are arranged one above the other and delimit a tunnel (7) therebetween in a height direction. At least one of the first and second openings (5, 6) is arranged substantially at the same level as the tunnel (7). The tunnel (7) is closed at a side facing one of the first and second openings (5, 6) so that air flowing between the first and second openings (5, 6) is channeled through or around the battery cell packs (2, 3).

Abstract: If a voltage of each of a plurality of capacitor cells forming a capacitor is lower than a system malfunction voltage V(1), and if the voltage of any one of the capacitor cells is higher than a cell charge inhibition voltage V(2) lower than the system malfunction voltage V(1), an ECU executes a program including a step of setting a limit value WIN(C) of electric power to be stored in the capacitor to be “0”.

Abstract: In a hybrid vehicle 20, when the ECO switch 88 is turned on, a maximum allowable charging power Pcmax is set based on a vehicle speed and an ECO mode maximum allowable charging power setting map that is a second relationship having a tendency to allow charging of a battery 50 in comparison with a normal maximum allowable charging power setting map (Step S130), and an engine 22, motors MG1 and MG2 are controlled so that the battery 50 is charged with an effective charge-discharge power demand Pb* as a charging power demand set at Step S140 in accordance with state of the battery 50 within a range of the maximum allowable charging power Pcmax and a torque demand Tr* for driving is ensured (Steps S150-S280).

Abstract: A method for controlling a vehicular electric system having multiple power sources including an engine-driven generator. The power sources for supplying power to charge an onboard battery are determined based on difference between the power generation cost of each power source and that for generating an amount of power charged in the battery. Furthermore, amounts power to be supplied to the battery 103 for charge is determined based on the amount of power currently charged in the battery.

Abstract: The present application relates to a charging station operable in a charging cycle for charging an electric vehicle. The charging station has a key-activated controller for controlling the charging cycle. The application also relates to a key for operating the charging station. Furthermore, the application relates to a charging station having an interface for connecting the charging station to a data network. The application also relates to a charging station having a socket for receiving a plug and a key-operated locking mechanism for locking a plug in said socket. A frangible panel movable between an open position and a closed position may be provided. A processor may be provided for generating data to impose a financial charge on an individual for using the charging station.

Abstract: A device for cooling batteries, particularly of an electric and/or hybrid vehicle comprises a pair of compartments (1, 12) in communication with one another, including a first compartment (1) housing the batteries distributed among adjacent columns and a second compartment (12) housing at least a blower (14). One of these compartments (1, 12) has an air intake aperture (5) while the other compartment (1, 2) has a discharge aperture (5) for discharging the admitted air to the outside. The first compartment (1) is equipped with means for modifying the dynamics of the air passing through it, starting from an axial circulation of air along the columns of batteries.

Abstract: A hybrid powertrain system for a vehicle includes an electric machine, a gear set mechanically connected with the electric machine, and a clutch mechanically coupled with at least one of a primary and secondary driveline assembly. The electric machine is configured to selectively provide motive power to at least one of the primary and secondary driveline assemblies. The gear set is configured to permit differential rotation between the primary and secondary driveline assemblies. The clutch is configured to selectively transfer torque between the primary and secondary driveline assemblies.

Abstract: A vehicle includes a charging inlet for connection with a ground line and a pair of power lines used to charge an electrical storage device from outside the vehicle; a terminal of the charging inlet for connection with the ground line; and a GND relay that connects the terminal to a body earth of the vehicle. Desirably, the vehicle further includes an ECU that controls charging of the electrical storage device. Before charging of the electrical storage device is started after the pair of power lines and the ground line are connected to the charging inlet, the ECU opens the GND relay and then determines whether there is a disconnection in the ground line.

Abstract: To protect the inverters and motor generators from damage caused by abnormal currents resulting from the sudden changes in voltage that occur when changing the battery voltage. A vehicle equipped with an engine 10* and first and second motor-generators 11 and 12 that can generate electricity by being driven by engine 10* or from regeneration of kinetic energy of the vehicle, power supply line 25 that connects first motor-generator 11 with second motor-generator 12, and battery 23 connected via switch 24 in the middle of electric power supply line 25. When changing the voltage of battery 23, switch 24 is opened before the voltage of battery 23 is changed, and switch 24 is closed only after one of the motor generators 11 and 12 is caused to generate electric power or propel the vehicle in order to reduce the difference in voltage between power supply line 25 and battery 23.

Abstract: A method for controlling charging of a power source of a hybrid vehicle. The method includes determining a maximum output level of a primary power source, determining a state of charge of a secondary power source, determining a charge torque modifier value based on the maximum output torque level and the state of charge, determining a target torque level for an electrical machine based on the charge torque modifier value, and driving the electrical machine at the target torque level with the primary power source to charge the secondary power source.

Abstract: A hybrid electric vehicle (HEV) power system is provided that includes a vehicle electrical system (VES), an inverter-controller unit (ICU) and an AC electric motor/generator unit (MGU). The VES includes a first DC voltage source and a second DC voltage source coupled in series with the first DC voltage source. The VES also includes a first electrical load coupled across the first DC voltage source, and a second electrical load coupled across the second DC voltage source. The ICU is coupled across the first DC voltage source and the second DC voltage source and is designed to convert DC power from the first DC voltage source and the second DC voltage source to generate AC power for the AC electric MGU. Together the DC voltage sources can replace a conventional high-voltage DC voltage source. In some implementations, techniques are provided for “charge balancing” the first DC voltage source and the second DC voltage source without expensive devices.

Abstract: Catalytically activated carbon materials and methods for their preparation are described. The activated carbon materials are engineered to have a controlled porosity distribution that is readily optimized for specific applications using metal-containing nanoparticles as activation catalysts for the mesopores. The activated carbon materials may be used in all manner of devices that contain carbon materials, including but not limited to various electrochemical devices (e.g., capacitors, batteries, fuel cells, and the like), hydrogen storage devices, filtration devices, catalytic substrates, and the like.

Abstract: A method includes detecting high-voltage faults, such as welded contactors or disconnected components, in a vehicle by measuring the total electrical impedance between positive and negative rails of a high-voltage bus and a ground or chassis, comparing the impedance before and after opening the contactors, and executing a maintenance response. The response includes setting an error code when the open impedance level is less than a threshold multiple of the closed impedance level. A vehicle includes a chassis, energy storage system (ESS), motor/generator, and a high-voltage bus conducting electrical current from the ESS to the motor/generator. Contactors are positioned along each of the rails of the bus, a device for measuring a total electrical impedance level between the chassis and each of the rails, and a controller for determining a welded contactor condition of at least one of the contactors based on the measured total electrical impedance level.

Abstract: A vehicle propulsion includes an alternating current (AC) traction drive, a first energy storage system electrically coupled to the traction drive through a direct current (DC) link, a second energy storage system electrically coupled to the traction drive such that the voltage output from the second energy storage system is decoupled from the DC link using a bi-directional boost converter, and a uni-directional current device that is poled to conduct current from the low voltage side of the boost converter to the high voltage side of the boost converter.

Abstract: A system and method for protecting a hybrid electric vehicle propulsion energy storage pack from an overvoltage condition is described. The energy storage pack includes a plurality of energy storage cells electrically connected in series and electrically coupled with a vehicle direct current (DC) bus. The system includes one or more overvoltage detection circuits, a disconnect circuit and one or more connection verification circuits. The one or more voltage detection circuits detect an overvoltage condition across a subset of the plurality of energy storage cells. The disconnect circuit electrically decouples the energy storage pack from the DC power bus upon detection of an overvoltage condition across the subset of the plurality of energy storage cells. The one or more connection verification circuits verify that the overvoltage detection circuit is electrically coupled to the subset of the plurality of energy storage cells.

Abstract: An underground source of electrical energy is inductively coupled to a receiver on a hybrid automotive vehicle to provide charging power for the vehicle's battery.

Abstract: In a hybrid electric motor vehicle, a power supply system for storing and supplying electrical power includes a motor-generator located onboard the vehicle, driveably connected to the vehicle wheels and producing AC electric power, an energy storage device for alternately storing and discharging electric power, an inverter coupled to the motor-generator and the energy storage device for converting alternating current produced by the motor-generator to direct current transmitted to the energy storage device, and for converting direct current stored in the energy storage device to alternating current transmitted to the motor-generator, a source of AC electric power located external to the vehicle, and a charger coupled to said electric power source and the energy storage device for supplying DC electric power to the energy storage device from said AC electric power source.

Abstract: A power train is provided having a power source for generating a power output. The power train also has a power storage device for storing and distributing power. The power train further has a controller configured to cause the distribution of power from the power storage device for assisting the power source when the rate of fuel entering the power source is above a threshold fuel rate. The threshold fuel rate is a fuel rate at which, assisting the power source increases the efficiency of the power train.

Abstract: A structure for mounting a power supply apparatus on a vehicle includes a driver's seat and a passenger's seat installed within a vehicle compartment and aligned in the vehicle width direction, an instrument panel provided at the vehicle front inside the vehicle compartment and equipped with electronics, a battery pack assembly located between the driver's seat and the passenger's seat, and wire harnesses electrically connected to the battery pack assembly. The vehicle front side and the vehicle upper side of the wire harnesses face the battery pack assembly. With the above-described configuration, there is provided a structure for mounting a power supply apparatus on a vehicle where the electronics provided at the instrument panel are appropriately protected from an electromagnetic wave.

Abstract: A method for actuating the transmission of a motor vehicle having a hybrid drive mechanism, especially for the case when an electric accumulator is loaded via the internal combustion engine and the selector lever (1) is locked electronically or via a mechanical selector lever locking device during the loading operation. Regarding the selector lever actuation, the driver's wish is detected by way of a sensor device (3) and when it is determined that the drive is going to activate a running step by the sensor device (3), the loading operation of the electric accumulator is immediately discontinued, via the internal combustion engine, and an operating state is adjusted which allows a safe activation of a transmission running step and subsequently the lock of the selector lever (1) is released or the selector lever locking device (2) is unlocked.

Abstract: A power storage device is mounted on a rear portion of a vehicle. The power storage device includes a high-voltage terminal and a low-voltage connector having a lower voltage than the high-voltage terminal. The high-voltage terminal is arranged on a front side in the vehicle. The low-voltage connector is arranged on a rear side in the vehicle.

Abstract: A split serial-parallel hybrid dual-power drive system, comprised of two or more than two separation drive systems allowing independent operation to respectively drive the load, or all loads driven individually are incorporated in a common frame to drive land, surface, underwater transportation means or aircraft, industrial machines and equipment or any other load drive by rotational kinetic energy.

Abstract: A protection device for an assembled battery includes a sampling capacitor, first switches and second switches to sample the voltages of the battery cells and hold the voltages in the capacitor, a detection unit which detects the voltages of the battery cells based on the voltage sampled by any one of the first switches and the second switches and held on the capacitor and output the detected value, a computing unit which computes an average value of the detected values, a comparator which compares the detected value with the average value so as to obtain a result of comparison indicating a relation in size between the both, and a controller which controls the first switches and the second switches, for the second switches to sample if the detected value obtained by sampling by the first switches is higher than the average value according to the comparison result.

Abstract: A battery system for storing electrical power and supplying electrical power to a vehicle is disclosed. The system includes multiple battery packs, each with a plurality of cells. The cells in each battery pack are electrically connected with one another and the multiple battery packs are also electrically connected with one another to combine the total energy output of the cells of the system. The electrical connections between at least some of the cells include a severable feature, whereby the electrical connection is severed locally at the severable feature in response to an impact force that is in excess of a predetermined magnitude and/or an overcurrent/overtemperature condition.

Abstract: A split serial-parallel hybrid dual-power drive system, comprised of two or more than two separation drive systems allowing independent operation to respectively drive the load, or all loads driven individually are incorporated in a common frame to drive land, surface, underwater transportation means or aircraft, industrial machines and equipment or any other load drive by rotational kinetic energy.

Abstract: This invention is a system and a method that uses the braking resistor, commonly used and available in electrically or hybrid-electrically propelled vehicles, to limit the precharge current during the startup of a high power ultracapacitor pack energy storage device and/or safely and rapidly discharge an ultracapacitor pack for maintenance work or storage to lengthen the life of the individual ultracapacitor cells and, correspondingly, the whole pack. The use of the braking resistor for precharging an ultracapacitor energy storage pack is an effective and less expensive method compared to other methods such as a separate DC-to-DC converter. This method includes the control logic sequence to activate and deactivate switching devices that perform the connections for the charging and discharging current paths.

Abstract: An energy storage type of differential hybrid power distribution system to drive an all wheel driving carrier; a revolution output end of an internal combustion engine (or any other revolution power source) to drive the front wheel through an intermediate transmission and control interface device, and to also drive an input end of the energy storage type of differential hybrid power device to output kinetics to further drive the rear wheel; and an electromechanical unit functioning as a generator and a motor being disposed in the energy storage type of differential hybrid power device to regulate the power distribution between the front wheel and the rear wheel by controlling the electromechanical unit to operate as a motor or as a generator.

Abstract: A method and apparatus that allows the end user to optimize the performance of an all-electric or hybrid vehicle and its charging system for a desired mode of operation is provided. The system of the invention includes multiple charging/operational modes from which the user may select. Each charging/operational mode controls the cut-off voltage used during charging and the maintenance temperature of the battery pack.

Abstract: In a vehicle drive system including a motor and a secondary battery, the motor and secondary battery are integrated to provide a drive system having good mountability. In a gap between a cylindrical outer housing (116) and a rotor (112), a layered cylindrical secondary battery is provided within the outer housing. A cylindrical cooling member (180) is further arranged between the rotor and secondary battery.

Abstract: In a powertrain that includes wheels for driving a vehicle, an engine including a crankshaft, a machine driveably connected to the crankshaft and able to operate alternately as an electric motor and electric generator, a transmission including an input clutch driveably connected to the crankshaft and an output driveably connected to at least two of the wheels, and an electric storage battery having a variable state of charge and electrically connected to the machine, a method for controlling vehicle creep including adjusting a torque capacity of the input clutch to a desired magnitude of input clutch torque transmitted to the wheels, determining a desired change in torque produced by the machine such that a speed of the crankshaft is controlled to a desired idle speed, using the magnitude of input clutch torque capacity and the desired change in torque produced by the machine to determine a desired magnitude machine torque, and using the machine to produce said desired magnitude of machine torque.

Abstract: The automobile of the present invention is provided with a capacitor for backup use in case of disconnection or breakdown of a battery. When a start switch is turned off, the collected charge in the capacitor is supplied to a device in which a large current is flowing, such as discharging resistor, motor or lamp, or a device in which a small current is flowing, such as dark current consuming device, and therefore, after the start switch is turned off, power consumption of the battery can be suppressed.

Abstract: A method for determining driver efficiency in a hybrid vehicle includes the steps of measuring a hybrid vehicle parameter, and calculating driver efficiency based, at least in part, on the hybrid vehicle parameter. The hybrid vehicle parameter is influenced, at least in part, by an action taken by a driver.

Abstract: A system is provided for the coordination of at least one switchable vehicle function of a motor vehicle, at least one battery charge condition threshold value of the energy accumulator unit being assigned to the at least one vehicle function such that, when there is an exceeding of or falling below the battery charge condition threshold value, the assigned vehicle function can be activated. Different battery charge condition threshold values can be assigned to the at least one vehicle function as a function of the operating condition of the drive unit, the temperature of the energy accumulator, the temperature outside the vehicle, and/or the age condition of the energy accumulator unit.

Abstract: An energy storage system (10) with an energy storage unit (8) to which a short-circuit fuse element is assigned, is designed to enable an increase in operational safety in a hybrid motor vehicle. For this purpose, it is provided according to the invention that the short-circuit fuse element is electrically connected in series with a current restricting component.

Abstract: A power unit including a plurality of series-connected battery modules and a safety circuit. A service plug is inserted from the side of a terminal board of a battery pack, thereby establishing an electrical connection among battery modules. A connector is provided on a back of a terminal cover by way of a projecting section, and a second safety switch is activated by attachment of a terminal cover and insertion of the connector to the terminal board, thereby establishing an electrical connection among the battery modules. Even when the service plug is attached at the time of completion of maintenance without attachment of the terminal cover, the battery modules are still kept in an unconnected state by means of a second switch, and energization, which would otherwise arise with exposed terminals, is prevented.

Abstract: An inflatable electric and hybrid vehicle system, that has the features and accoutrements of traditional automotive vehicles, that is extremely safe, lightweight, inexpensive, compact and energy efficient. The system designed to be shipped by common carrier and then assembled in a few hours with a minimal amount of tools or effort. The vehicle has either an inflatable body or membrane skin with a hybrid-type or electric motor drive train as well as heating and cooling system and inflatable seats. The battery power supply utilizes banks of commonly available batteries charged by a mobile onboard charger, configured to be easily removed with agnostic software and hardware to manage the power source They are also networked via wireless communication to various base stations to allow for monitoring and exchange of battery banks quickly and efficiently.

Abstract: A vehicle source device capable of performing a more accurate temperature-rise corresponding to the ability of the capacitor is provided. The correlation of the temperature and the internal resistance corresponding to the ability of the current capacitor in time of activation is obtained in advance, the internal resistance is obtained for every repetition of charge/discharge, and the temperature of the inside of the capacitor is obtained from the correlation. Since the accurate temperature of the inside of the capacitor is obtained, the capacitor is accurately temperature-raised to the target temperature.

Abstract: The present invention discloses a system for transferring electrical power between a grid and at least one vehicle. The vehicle can be Battery Electric Vehicle (BEV), Plug-in Hybrid Electric Vehicle (PHEV) or Fuel Cell Vehicle (FCV). The type of vehicle will be recognized and controlled by the system to support demand response and supply side energy management. Vehicle recognition can be carried out by load signature analysis, power factor measurement or RFID techniques. In an embodiment of the invention, the grid is a Smart Grid. The present invention also discloses a method for facilitating electrical power transfer between the grid and the vehicle.

Abstract: A power frequency distribution predicting unit predicts the power frequency distribution of a vehicle in a case where the vehicle travels a route with reference to the history of the vehicle power Pv when the vehicle traveled the route in the past. An operation condition setting unit sets the range of the required vehicle power Pv0 to operate the engine as an engine operation condition for controlling the energy balance between generated power and generated electric power of an electric rotating machine in a case where the vehicle travels the route to be at a preset value according to the power frequency distribution predicted by the power frequency distribution predicting unit. An operation control unit controls the operation of the engine according to the range of the required vehicle power Pv0 to operate the engine set by the operation condition setting unit.

Abstract: An energy storage pack specially adapted for a hybrid electric vehicle, the energy storage pack having overvoltage protection and a method of protecting the same. In particular, the energy storage pack includes a robust, low-cost, parasitic circuit configured to detect overvoltage conditions within the vehicle energy storage and report it to the vehicle.

Abstract: A parallel hybrid vehicle system utilizing the Power Take Off connection on an automatic transmission as a transfer port for a secondary device is described for both driving modes and stationary operation. The secondary device is a battery powered electric motor providing motive power or regenerative braking in driving mode or providing power to accessories typically mounted to a conventional PTO while stationary.

Abstract: State of charge control for electric and hybrid vehicles. In one embodiment, a battery may be electrically connected to an electric motor to propel a vehicle. In such an embodiment, during vehicle operation a state of charge of the battery may fluctuate within a given state of charge range and may be regulated to a target state of charge. Such target state of charge may be set below the midpoint of the state of charge range. As the vehicle operates various devices may be controlled to regulate the state of charge to the target. In particular, an electric motor may be employed to lower the state of charge and an internal combustion engine may be employed to raise the state of charge. In other embodiments, regenerative braking, solar power or the like may be employed to raise the state of charge from at or below the target state of charge to the upper state of charge limit.