Abstract: A method of operating a hybrid vehicle includes disengaging, i.e., turning off, an internal combustion engine when a brake pedal is disposed in a released position, i.e., non-depressed position, an accelerator pedal is disposed in a released position, i.e., non-depressed position, and a forward path of the hybrid vehicle is blocked, thereby conserving fuel. The method includes engaging, i.e., starting, the internal combustion engine when the brake pedal is disposed in the released position, the accelerator pedal is disposed in the released position, and the forward path of the hybrid vehicle is clear, thereby allowing for a quick launch of the vehicle.

Abstract: An integrated electrical connector comprises one or more terminals housed within a connector body. The connector body is configured and arranged to structurally join an auxiliary component to a host vehicle to which the integrated electrical connector is mechanically fixed and electrically coupled. The connector body is configured to facilitate electrically coupling electrical circuitry of the auxiliary component to the host vehicle. The connector body is configured to facilitate transmission of information among the auxiliary component and the host vehicle.

Abstract: Methods, systems, and automotive vehicles are provided for providing routing for an automotive vehicle from a first location to a second location. The automotive vehicle is configured to operate using a primary energy source and a secondary energy source. An energy indicator is configured to provide a measure of available energy from the primary energy source onboard the automotive vehicle. A processor is coupled to the energy indicator, and is configured to ascertain characteristics of a plurality of segments connecting the first location and the second location, and to select an optimized route between the first location and the second location using the measure of available energy and the characteristics of the plurality of segments.

Abstract: An integrated electrical connector comprises one or more terminals housed within a connector body. The connector body is configured and arranged to structurally join an auxiliary component to a host vehicle to which the integrated electrical connector is mechanically fixed and electrically coupled. The connector body is configured to facilitate electrically coupling electrical circuitry of the auxiliary component to the host vehicle. The connector body is configured to facilitate transmission of information among the auxiliary component and the host vehicle.

Abstract: A cogeneration system includes an engine, a motor/generator unit (MGU) powered by the engine, a compressor powered by the MGU, and a heat storage tank. The system further includes an engine coolant loop which places the engine in thermal communication with the tank, and a vapor loop which circulates refrigerant from the compressor. An air handler unit exchanges heat between the engine coolant loop and the vapor loop. A controller is configured to control the engine, MGU, compressor, and air handler unit, alone or in combination, to heat or cool air supplied to a building and water in the tank, and to selectively charge at least one auxiliary device such as a battery of an electric vehicle (EV) via the MGU. The system may include two power plants, with one, e.g., an EV or a portable module, having the engine and a first engine coolant loop.

Abstract: A system and method of determining a geographically reachable area is provided. A vehicle is in communication with a network. The network is in communication with at least one other vehicle. The method includes establishing communication between the vehicle and at least one other vehicle through the network. The method includes determining a travel range for the vehicle and a travel range for the at least one other vehicle. The method includes comparing the travel range for the at least one other vehicle with the travel range for the vehicle. The method includes determining where the travel range for the at least one other vehicle and the travel range for the vehicle overlap. The method further includes identifying the geographically reachable area by both the vehicle and the at least one other vehicle.

Abstract: A vehicle includes a seat moveable between a horizontal seating position and a vertical raised position. An under-seat space is defined between a floor surface of the vehicle and a bottom surface of the seat. A collapsible storage system is stowable under the seat, flat against the bottom surface of the seat when not needed for storage, and is positionable on the floor to define a lateral boundary wall to convert the under-seat space into an enclosed storage space.

Abstract: A navigation system for a vehicle includes a display device and host machine. The host machine communicates with a map database containing information describing a geocoded road network. The network includes nodes each describing a point within the network, with some nodes describing charging waypoints. The host machine executes a method, including recording a destination, determining a remaining state of charge (SOC) of a battery, and calculating a remaining electric vehicle (EV) range of the vehicle using the remaining SOC for every node. The host machine generates a first recommended EV travel route to the destination using a shortest distance or travel time approach when the destination lies within the remaining EV range. The host machine generates a second recommended EV travel route to the destination through a charging waypoint(s) when the destination lies outside of the remaining EV range. The EV route is displayed via the display device.

Abstract: A method for operating a charging stall having a known geographic location configured to electrically charge an electrically-powered vehicle includes communicating a first message to a remote access server from a subject vehicle, the first message including geographic location information corresponding to the subject vehicle, detecting a presence of a parked vehicle at the charging stall with a monitoring system signally connected to a monitoring controller, communicating a second message to the remote access server from the monitoring controller, the second message comprising the detected presence of the parked vehicle at the charging stall, resolving that the parked vehicle at the charging stall comprises the subject vehicle based upon the first and second messages, and activating a power access control device at the charging stall to permit electric power flow through a corresponding electric power outlet.

Abstract: A method is provided for generating projected vehicle energy consumption information for a second vehicle using statistical information describing a driving history of a driver of a first vehicle. Statistical information is determined from collected vehicle performance values while the driver operates the first vehicle, and is archived in at least one memory location. The archived statistical information is correlated with a vehicle specification describing a performance capability of the second vehicle. A message is processed that includes the projected vehicle energy consumption information for the second vehicle. A vehicle is provided for generating the projected vehicle energy consumption information, and includes at least one memory location, sensors for measuring vehicle performance values of the vehicle describing a driver history of the first vehicle, and a controller adapted for automatically determining the statistical information. A controller is also provided adapted for executing the method.

Abstract: An energy conversion system includes a first core section, a tank, a flexible structure, and an output coil. The tank contains a volume of fluid having a high magnetic permeability. The flexible structure is fluidly coupled to the tank and movable from a retracted to an extended position in response to the injection of the fluid from the tank. The output coil is in electrical communication with the first core section. A charging station includes a second core section and an input coil. The first and second core sections are in alignment to define an air gap therebetween. The air gap is reduced when the flexible structure is in the extended position within the air gap such that the flexible structure transmits magnetic flux between the second core section and the first core section. The magnetic flux in the first core section induces electrical current in the output coil.

Abstract: An electric vehicle includes a charging receiver unit. The charging receiver unit includes a plurality of core members, a plurality of biasing devices, and a receiver wire. The plurality of core members are disposed in spaced relationship to one another. Each of the plurality of core members is configured for alignment with a plurality of magnetic elements. The plurality of biasing devices longitudinally bias a respective one of the plurality of core members toward a respective one of the plurality of magnetic elements such that magnetic flux is transmitted between each of the plurality of magnetic elements and the respective one of the plurality of core members. The receiver wire is disposed in electrical communication with each of the plurality of core members. Magnetic flux in the plurality of core members induces electrical current in the receiver wire.

Abstract: A vehicle includes a vehicle body, a first motor disposed within the vehicle body, a second motor disposed within the vehicle body, and an engine removably disposed on the vehicle body and configured to selectively provide torque to the first motor when disposed on the vehicle body. A climate control compressor is disposed within the vehicle body and is selectively coupled to the first motor. A controller is configured to control the coupling of the climate control compressor to the first motor and to control the coupling of the engine to the first motor. The first motor is configured to generate electrical energy to operate the second motor when coupled to the engine. The controller is further configured to control operation of the engine.

Abstract: An electromagnetic (EM) clutch assembly includes input and output discs, a plunger, a control solenoid, and a controller. The input disc is connected to a rotatable input member, and defines an input face having a mechanical feature. The output disc is connected to a rotatable output member, and includes a bore wall defining a bore. The plunger is positioned at least partially within the bore. The controller transmits a time-varying electrical control signal to the solenoid to thereby resonate the plunger toward the input disc, and transmits a steady-state electrical control signal to capture the plunger in an engaged position. Rotation of the discs is controlled until the plunger encounters the mechanical feature, thereby placing the assembly in an engaged state. A vehicle having a transmission and the EM clutch assembly is also disclosed, as is a method for controlling the clutch assembly via the electrical control signals.

Abstract: A method for reserving a vehicle charging station includes receiving a desired destination, and automatically verifying the availability of a designated station at an expected arrival time. The method further includes reserving the designated station when the designated station is available at the expected arrival time, and transmitting an electronic token to the client device. The token confirms the reservation and uniquely identifies the vehicle. A system for reserving the station includes a server in communication with the station, and with a client device configured for communicating a desired destination to the server. The server automatically verifies the availability of the designated charging station at an expected arrival time at the desired destination, reserves the designated station when it is available at the expected arrival time, and then generates and transmits the token to the client device.

Abstract: A HVAC-APU system is provided for a battery electric vehicle. The system includes, but is not limited to a refrigerant fluid. A power cycle loop section, a cabin heating cycle loop section, and a cabin refrigeration cycle loop section are in selective fluid communication with each other to advance the refrigerant fluid through the system. A compressor-expander train includes, but is not limited to a reversing compressor-expander and a high-pressure pump that are operably connected by a shaft. The high-pressure pump pressurizes the refrigerant fluid to form a high-pressure refrigerant fluid. An auxiliary fuel cell and combustion unit heats a heat transfer fluid. A heat exchanger transfers heat from the heated transfer fluid to the high-pressure refrigerant fluid to form a heated high-pressure refrigerant fluid. The reversing compressor-expander expands the heated high-pressure refrigerant fluid to rotate the shaft in a first direction to drive the high-pressure pump.

Abstract: A control system for a hybrid powertrain determines operator demands, a powertrain operating state, and operating conditions based upon the inputs; selects an operating strategy based upon the operator demands, the powertrain operating state, and the operating conditions; determines a preferred powertrain operating state; and controls the powertrain to the preferred powertrain operating state based upon the selected operating strategy, the operator demands and the operating conditions.

Abstract: A vehicle includes a power source, an energy storage device, a navigation system, and a controller. The power source is configured to drive the vehicle. The energy storage device is configured to supply energy to the power source. The navigation system includes a memory location. The controller is configured for determining an optimized route for the vehicle driving on a plurality of roads and road segments, as a function of powertrain limitations of the vehicle. The optimized rout for the vehicle may be presented to the driver of the vehicle on a visual display screen.

Abstract: A vehicle includes a powertrain controller, an energy storage system (ESS), a traction motor, an electrical device such as an HVAC system and/or auxiliary system, and a navigation system. The navigation system generates a recommended eco-route or other travel route. The navigation system receives vehicle state information including a current powertrain state from the controller and a power load value from the device(s), including a state of charge of the ESS. The vehicle state information is used to select between a charge-depleting and a charge-sustaining costing model. The route is generated using the selected model, and then displayed. The navigation system includes a host machine which selects the model and generates the route, and a display screen for displaying the route. A method for generating the route includes receiving the current powertrain state and power load values, and using the state information to select between the charge-depleting and charge-sustaining models.

Abstract: An electric vehicle maximizes an electric-only driving range. The vehicle includes a power source, an energy storage device, an auxiliary power unit (APU), and a controller. The power source propels the vehicle. The energy storage device supplies electricity to the power source. The APU supplies supplemental energy to the power source. The controller operates the vehicle in an electric-only driving mode to propel the vehicle and obtains a state of charge (SOC) of the energy storage device. The vehicle and at least one charging station are located. The controller determines a minimum required SOC of the energy storage device for the vehicle to reach at least one charging station. The controller activates the APU to operate the vehicle when the SOC of the energy storage device is below the minimum required SOC of the energy storage device for the vehicle to reach the location of at least one charging station.