Abstract: A method and system for braking a hybrid electric vehicle having an internal combustion engine and a traction motor coupled to a common output shaft, with the vehicle also having an energy storage battery. The method includes monitoring of the vehicle to determine if the vehicle's driver is operating the vehicle in a braking mode and if so, controlling the engine and traction motor so as to provide dynamic braking such that when the traction motor is operated regeneratively, the brake torque produce by the engine is reduced from a maximum contemporaneous brake torque value.
Abstract: An intake valve phase shift in multi-valve engines to enhance air-fuel mixing and optimum combustion at all operating conditions. The intake valve members are independently operated by electro-mechanical actuators or the like, and activated and deactivated by the electronic controller of the engine. A channel or passageway in a diverter member positioned between the two intake ports in the cylinder head allows air and fuel from a closed intake port to be diverted to an open intake port and thus into the combustion chamber. The passageway preferably has a configuration with a certain curvature, orientation and position relative to the diameter of the inlet ports. The curvature is about one-half the diameter D of the inlet port, the passageway is symmetrical from port to port and directs the fuel toward the opposite sides of the ports, and the passageway is positioned about D/4 from the valve seats.
Type:
Grant
Filed:
August 7, 2002
Date of Patent:
March 16, 2004
Assignee:
Ford Global Technologies, LLC
Inventors:
Mohammad Haghgooie, William Francis Stockhausen
Abstract: The invention relates to a method and arrangement for load testing electrical systems of a motor vehicle. The operator control elements of the electrical systems are activated via an externally controlled robot during a test period of typically 7 to 14 days. The motor vehicle containing the electrical systems is located during the test in a simulation chamber in which the temperature and/or atmospheric humidity can be set by an air-conditioning system, and simulated solar radiation are set by one or more radiators. In addition, acceleration forces occurring during driving are simulated via a road simulator. The forces and moments occurring when the operator control elements are activated are preferably sensed and recorded for analysis and evaluation.
Type:
Grant
Filed:
October 31, 2001
Date of Patent:
February 10, 2004
Assignee:
Ford Motor Company
Inventors:
Andreas Sigwart, Holm Freese, Karl-Heinz Richarz, Peter Bockemuehl
Abstract: The invention relates to a device for improving the vacuum in an auxiliary device. The auxiliary device uses vacuum for one or more applications in a vehicle. The auxiliary device is connected to the inlet manifold of a vehicle via a duct having a one-way valve directing the flow from the auxiliary device to the inlet manifold. The device comprises a chamber having an inlet duct connected to said auxiliary device and an outlet duct. Each of said inlet and outlet ducts have a one-way valve. The chamber is separated from the inlet manifold via a flexible member.
Abstract: A combined regenerative and friction braking system for the road wheels of a vehicle includes a friction braking subsystem, a regenerative braking subsystem coupled to the road wheels equipped with the friction braking subsystem, and a brake system controller for controlling both the friction and regenerative braking subsystems such that regenerative braking is restored to a maximum practicable value following conclusion of an antilock braking event.
Abstract: An internal combustion engine includes a variable compression ratio apparatus, a field-sensitive fluid coupled to the variable compression ratio apparatus, and a circuit for applying a field to the field-sensitive fluid to configure the variable compression ratio apparatus in accordance with a selected compression ratio of the internal combustion engine.
Abstract: In an electric or hybrid electric vehicle, a voltage monitor (102) is directly coupled to a traction motor (38) and/or generator motor (30) to detect a permanent magnet induced voltage within the motor at a predetermined speed and no load condition (300). A controller (100) compares the detected permanent magnet induced voltage with an expected reference voltage that represents an expected permanent magnet induced voltage at full magnetization and the predetermined speed (302). The controller produces an indication of magnetization based on the reference voltage, the detected permanent magnet induced voltage, and the predetermined speed. If the indication of magnetism reaches a predetermined threshold, the motor is made inoperable and/or a current to the motor is limited to prevent damage to components (306, 308, 310, 312, 314). Preferably, a user of the vehicle is made aware of these actions by an audible and/or visual indicator (308, 314).
Type:
Grant
Filed:
March 27, 2002
Date of Patent:
January 20, 2004
Assignee:
Ford Global Technologies, LLC
Inventors:
Abbas Raftari, Patrick J. Curran, Vijay K Garg
Abstract: An electrical system (12) is provided for an automotive vehicle (10) having a first power source (14) with a first positive terminal (16) and first negative terminal (18). A second power source (20) having a second positive terminal (22) and a second negative terminal (24) is also provided. A common electrical node N2 is coupled to the first negative terminal and the second positive terminal. A first load (26) is coupled between the first positive terminal and the second node N2. A second load (28) is coupled between the common node N2 and the second negative terminal (24).
Type:
Grant
Filed:
October 12, 2001
Date of Patent:
January 6, 2004
Assignee:
Ford Global Technologies, LLC
Inventors:
Allan Roy Gale, Michael W. Degner, Paul Raymund Nicastri
Abstract: A method of operating a variable compression internal combustion engine in a motor vehicle includes the steps of determining a driveline surge based at least in part on operating parameters of the motor vehicle, determining a driveline surge tolerance based at least in part on one or more of the vehicle operating parameters, and selecting one of the compression ratio operating modes based at least in part on a comparison of the driveline surge to the driveline surge tolerance. With a variable compression engine operating in a high compression ratio mode or a low compression ratio mode, the low compression ratio mode is selected if the driveline surge exceeds the driveline surge tolerance. Otherwise, if the driveline surge is less than or equal to the driveline surge, then the high compression ratio mode is selected.
Abstract: A method of recording a plurality of audio signals associated with an entertainment sound system (42) of an automotive vehicle (12) includes an audio input (20). A plurality of audio signals (18) is transmitted from the audio input (20) to a controller (24) within the automotive vehicle (12). A preferred plurality of audio signals (36) is acoustically played on the entertainment sound system (42). A recorder (28) is actuated to record the preferred plurality of audio signals (34) onto an electronic medium (30) within the vehicle (42). Consequently, the preferred plurality of audio signals (34) is recorded onto the electronic medium (30). An acoustical transmission of the preferred plurality of audio signals (34) received from said audio input (20) is halted at a halting point. Finally, the acoustical transmission is resumed from the electronic medium (30), from the halting point simultaneously as the plurality of audio signals (18) continues being recorded.
Type:
Grant
Filed:
March 26, 2002
Date of Patent:
December 16, 2003
Inventors:
Bryan Roger Goodman, Kenneth James Varnum
Abstract: This invention is a method and system for determining whether the engine should be running in a Hybrid Electric Vehicle during vehicle idle conditions. Specifically, a controller determines if the vehicle is in idle and if engine operation is necessary. To determine whether engine operation is necessary, the controller determines whether the battery needs charging, whether vacuum needs to be replaced in the climate control system or brake system reservoir, whether the vapor canister requires purging, whether the adaptive fuel tables require fast adapting, whether the engine or catalyst temperatures are unacceptable, or whether the air conditioning has been requested. Once the controller determines that the engine must be running, the controller determines in which control mode to run the engine, either speed control mode (using powertrain controllers) or torque control mode (using a generator and generator controller).
Type:
Grant
Filed:
November 14, 2000
Date of Patent:
December 16, 2003
Assignee:
Ford Motor Company
Inventors:
Stephen John Kotre, Deepa Ramaswamy, Joanne Theresa Woestman, Mary Theresa Breida
Abstract: A method and strategy for providing real-time estimates of the machine parameters of an induction machine, including rotor resistance, rotor inductance, stator resistance, stator inductance and mutual inductance. The induction machine is a part of a torque delivery driveline. The method comprises expressing stator voltage as a function of machine parameters, stator current, stator excitation frequency and slip frequency. A functional relationship of rotor current, rotor resistance, rotor flux, electrical speed of applied stator voltage and rotor electrical speed is defined. Rotor current and characteristic parameters are calculated, the machine parameters being calculated using the characteristic parameters.
Abstract: A method and system for controlling an automotive internal combustion engine having NVH feedback uses NVH signals which are processed and compared with human threshold values to determine whether an engine control parameter such as idle speed needs to be adjusted so as to mitigate unwanted noise, vibration, and harshness.
Type:
Grant
Filed:
April 18, 2002
Date of Patent:
December 9, 2003
Assignee:
Ford Global Technologies, LLC
Inventors:
Milton Scott Bergeon, William Woebkenberg
Abstract: A method of operating a hybrid electric vehicle 10 to reduce emissions. The method utilizes the vehicle's electric motor/generator 12 to generate a negative torque during cold-start conditions, effective to increase the load on the internal combustion engine 16, thereby reducing the light-off time of the catalytic converter 28. The method also reduces emissions by utilizing the vehicle's motor/generator 12 to provide a supplemental torque to engine 16 during transient events, thereby reducing the generated mass flow and amount of untreated emissions.
Abstract: An electrical connection system adapted to be environmentally sealed by mounting a conductor block having at least one electrical conductor within a port extending through an electrical component. A first cover portion is telescopically engaged with the conductor block and has at least one wire channel formed therein. A seal is disposed against and extends about the periphery of the front portion of the non-conductive block. A second cover portion is configured to sealingly mate with the first cover portion and configured to engage the non-conductive block whereby electrical leads are retained.
Type:
Grant
Filed:
July 10, 2002
Date of Patent:
December 2, 2003
Assignee:
Ford Motor Company
Inventors:
Allan Roy Gale, Jeffrey William Nieman, Philip Thomas Koneda, Stephen John Agdorny
Abstract: A system and method to control the coolant temperature of two independent cooling loops of a fuel cell vehicle by adjusting system pump speed, fan speed and radiator bypass valve position. Multiple feedback controllers coordinated by robust flip-flop logic are used, to minimize energy consumption and provide optimal control system performance even in the case of substantially different plant responses with respect to fan speed and valve position plant inputs. The system also includes a feed forward disturbance compensator, which reacts immediately to change in net power and vehicle speed disturbance variables, thereby reducing the variance of the temperature control error. Additionally, a feedback controller preset strategy is used to compensate for distinctive plant nonlinear effects such as bypass valve dead-zone and air-conditioning system's request for abrupt change of fan speed.
Type:
Grant
Filed:
April 18, 2002
Date of Patent:
November 25, 2003
Assignee:
Ford Global Technologies, LLC
Inventors:
Davorin David Hrovat, Jahanbakhsh Asgari, Josko Deur, William Samuel Schwartz
Abstract: An online communication schema for inquiring and tracking status of an online order for a product is provided. The communication schema comprises a consumer status request message, which includes a source identifier identifying a web site from which the consumer status request message originated, and a customer identifier identifying a customer who originated the status request message. The communication schema also comprises a consumer status reply message, which includes an order number, and order status information.
Abstract: A strategy and control system for a variable displacement engine in which cylinder deactivation is obtained by intake cam phasing and exhaust valve deactivation. Fuel control for the engine and spark deactivation are sequenced with valve deactivation to avoid transferring engine exhaust gases to the intake manifold of the engine during a transition between full cylinder operation and partial cylinder operation. Excess air flow through the exhaust system for the engine is avoided during a transition from partial cylinder operation to full cylinder operation. These features achieve stable engine performance during the transition.
Type:
Grant
Filed:
March 12, 2002
Date of Patent:
November 18, 2003
Assignee:
Ford Global Technologies, LLC
Inventors:
Bradley Alan Boyer, Thomas William Megli, William F. Stockhausen
Abstract: A method and system for estimating slip gain for use in the control of torque in a multi-phase induction machine. The slip gain estimate is based on a transient response of the induction machine to torque command changes. The invention is independent of machine parameters other than the slip gain. The method uses a slip gain estimation algorithm that is suited for use either as a self-calibration procedure or a background procedure that continually updates the slip gain during normal operation of the induction machine. The estimation method of the invention is suited for automotive driveline applications, which typically have limited sensor capability and which may present tuning problems associated with high volume production and with slip gain estimates when temperature changes during normal operation.
Abstract: A post-transmission, parallel hybrid electric vehicle and method of control thereof is provided having an engine 200 joined to a differential 206 by an automated layshaft transmission 212. A motor 202 is provided which additionally provides torque to the differential 206 during gear changes of the transmission 212 to minimize the affects of clutch shudder from an engine clutch 210.
Type:
Grant
Filed:
April 12, 2002
Date of Patent:
September 30, 2003
Assignee:
Ford Motor Company
Inventors:
Robert Charles Baraszu, Susan Rebecca Cikanek