Abstract: A method and sensor or sensor subsystem permit improved evaporative leak detection in an automotive fuel system. The sensor or sensor subsystem computes temperature-compensated pressure values, thereby eliminating or reducing false positive or other adverse results triggered by temperature changes in the fuel tank. The temperature-compensated pressure measurement is then available for drawing an inference regarding the existence of a leak with reduced or eliminated false detection arising as a result of temperature fluctuations.

Abstract: A flow reversal control valve for use in a fuel cell. The valve includes a housing having a first end and a second end disposed along a longitudinal axis. The valve also includes a wall that defines a first passage in fluid communication with a second passage. The first passage is disposed proximate to the first end and the second passage is disposed proximate to the second end. The valve further includes a chamber in fluid communication with the first and second passages. There are flow flutes formed in the chamber. A seal is disposed in the chamber and coupled to at least one of the first and second passages. The seal has an elastomeric member disposed on a planar surface transverse to the longitudinal axis. There is a closure member disposed in at least one of the first passage, second passage and the chamber.

Abstract: The subject invention is an intake manifold with a swirl control valve assembly mounted to an internal combustion engine. The intake manifold assembly includes a plurality of air intake passages through which air flows to the combustion chambers of the engine. The air flow control valve assembly is mounted within the intake manifold between the intake manifold and the engine. The air flow control valve assembly includes a plurality of valve plates to direct air flowing through the air intake passages. The valve plates are disposed within the air intake passages and are mounted to a common shaft for rotation about an axis. The valve plates rotate between an open position and a closed position. Each of the valve plates has an opening that allows the flow of air through the air intake valve when the valve plate is in the closed position. The opening is configured in such a manner to direct the flow of are through the air intake passage.

Abstract: An on-board evaporative emission leak detection system and method that detects leakage from an evaporative emission space of a fuel system of an automotive vehicle. A test includes an initialization, or stabilization, phase during which a differential between pressure in the evaporative emission space and atmospheric pressure is created, and then varied, over time, within a range of differential pressures suitable for performing a leak detection test. This varying of pressure differential alternately increases the created pressure differential above a nominal pressure differential and decreases the created pressure differential below the nominal pressure differential. The leak detection test is then performed.

Abstract: A network with wireless connectivity, a vehicle connected to and including the network and a method of managing network data flow. The network includes multiple wireless access points, each connected to an Ethernet aggregation switch. Each Ethernet aggregation switch is virtual local area network (VLAN) aware and matches client traffic from connected access points with access VLANs. A virtual network switch maintains an association table between access VLANs and core VLANs. The virtual network switch uses the association table to manage free-form client traffic between mobile stations at access VLANs at connected Ethernet aggregation switches and appropriate core VLANs. The vehicle, including the network, may be a train with access points located trackside connecting train passengers to a public network, e.g., the Internet. Wireless devices on the train may also connect to an on-board such network.

Abstract: A leak detection monitor (22; 222) for an on-board evaporative emission leak detection system that detects leakage from an evaporative emission space of a fuel system of an automotive vehicle. One embodiment (22) utilizes engine intake system vacuum to vent the evaporative emission space to atmosphere when the engine is running; another (222), an electromagnet actuator (270, 280). Venting ceases when the engine is shut off. Changes in vapor pressure in the evaporative emission space are monitored over time by electric devices (74; 282) after the engine has been shut off to distinguish between a gross leak, a small leak smaller than a gross leak, and a leak that is at most smaller than a small leak.

Abstract: An on-board evaporative emission leak detection system and method that detects leakage from an evaporative emission space of a fuel system of an automotive vehicle. A test includes an initialization, or stabilization, phase during which a differential between pressure in the evaporative emission space and atmospheric pressure is created, and then varied, over time, within a range of differential pressures suitable for performing a leak detection test. This varying of pressure differential alternately increases the created pressure differential above a nominal pressure differential and decreases the created pressure differential below the nominal pressure differential. The leak detection test is then performed.

Abstract: A fuel delivery system of an automobile that eliminates the vapor canister and includes leak detection of the fuel tank while also permitting failsafe operation when there is a leak in the fuel tank. The fuel tank includes a flexible member defining a first chamber that stores fuel in a chamber devoid of air while a second chamber is at ambient pressure. The fuel system can be formed as a module for installation or retrofitting to various applications using an internal combustion engine, including automobiles. A method of operating the fuel system to purge fuel vapor is also disclosed. A method of preventing fuel leaks is additionally disclosed.

Abstract: An engine cooling module includes a shroud structure 12. A housing 20 of a d.c. electric motor is formed integrally with the shroud structure 12. The housing has an open end 21. The motor has a drive shaft 26. A heat sink 22 is disposed opposite the open end and is insert molded with respect to the housing 20. The heat sink 22 defines a seat for a bearing 24 supporting the shaft 26. A flux ring assembly 48 is insert molded with respect to the housing. The flux ring assembly includes permanent magnets 33. An armature assembly 28 is disposed in the housing and fixed to the shaft for rotation in response to a magnetic field generated by the magnets 33. A commutator 32 is disposed in the housing and electrically connected with the armature assembly 28 and mounted for movement with the armature assembly. A brush card assembly 36 is coupled to the open end 21 of the housing to define an end cap covering the open end. The brush card assembly 36 has brushes 42 associated with the commutator 32.

Abstract: A seal for a poppet valve of an integrated pressure management apparatus, a valve system using the poppet valve seal, and a method of cleaning debris off of a poppet valve. The poppet valve is movable between an open position permitting fluid flow through an aperture in a housing and a closed position preventing fluid flow through the aperture. The seal includes an annular body having a first sealing surface fixed to the housing and a second sealing surface confronting the poppet valve. An annular lip projects obliquely from the seal is resiliently deformed by the poppet valve at the closed position, thereby cleaning debris off the sealing surface of the poppet valve.

Abstract: An apparatus and method for reducing heat transfer between a motive force device and a valve. The apparatus consists of a regulator valve. The valve comprises a wall defining a flow passage disposed along a longitudinal axis. A closure member is disposed in the flow passage for rotation about an axis oblique to the longitudinal axis. The closure member is movable to a first position to prevent flow in the flow passage and the closure member is also movable to a second position to permit flow in the flow passage. A motive force device is disposed along the axis and coupled to the closure member by an insulator member. The motive force device is disposed such that it can rotate the closure member between the first position and the second position about the axis. The valve also comprises a spacing chamber having an inner wall and an outer wall. The inner wall forms a volume that houses the insulator member, the outer wall of the spacing chamber is coupled to the motive force device and the flow passage.

Abstract: A invention provides an integrated splash shield and air intake tube are provided. A splash shield defining a wheel well is at least partially arranged about a wheel. The splash shield has first and second portions secured to one another defining an air passageway with the air passageway in fluid communication with the engine. A wheel well portion has a second surface opposite a first surface. An air intake portion is supported on the wheel well portion and preferably secured thereto by a weld bead. The air intake portion and the first surface of the wheel well portion together define an air passageway having an inlet for receiving ambient air and an outlet for connection to an engine throttle of the engine. Other air passages may be defined in a similar manner in the integrated splash shield and air intake tube described above. For example, a passive noise cancellation system such as a Herschel-Quincke tube arrangement may be formed by the wheel well and air intake portions.

Abstract: An integrated pressure management system manages pressure and detects leaks in a fuel system. The integrated pressure management system also performs a leak diagnostic for the headspace in a fuel tank, a canister that collects volatile fuel vapors from the headspace, a purge valve, and all associated hoses and connections.

Abstract: An integrated pressure management system manages pressure and detects leaks in a fuel system. The integrated pressure management system also performs a leak diagnostic for the headspace in a fuel tank, a canister that collects volatile fuel vapors from the headspace, a purge valve, and all associated hoses and connections.

Abstract: A vehicle air intake system includes a noise cancellation assembly. A cooling member is provided at least partially within an air passageway for dissipating heat within an electronics module portion of the noise cancellation assembly. The cooling member preferably is a brass material insert that is supported at least partially within an air passageway by a housing that supports components of the noise cancellation assembly. A connecting member that thermally couples the electronics module to the cooling member also operates to secure the electronics module to the housing in one example embodiment.

Abstract: An air induction system comprises an air induction body, a speaker with a first diaphragm disposed about the air induction body, and a second diaphragm spaced from the first diaphragm. A signal is generated from the first diaphragm and transmitted to the second diaphragm. The second diaphragm generates a noise attenuating sound.

Abstract: An on-board evaporative emission leak detection system and method that detects leakage from an evaporative emission space of a fuel system of an automotive vehicle. A test includes an initialization, or stabilization, phase during which a differential between pressure in the evaporative emission space and atmospheric pressure is created, and then varied, over time, within a range of differential pressures suitable for performing a leak detection test. This varying of pressure differential alternately increases the created pressure differential above a nominal pressure differential and decreases the created pressure differential below the nominal pressure differential. The leak detection test is then performed.

Abstract: A manifold for a fuel injected engine has several fuel injectors that are connected to a common air assist passageway for each bank of cylinders. This passageway is preferably supplied with assist air from a central location, between two of the fuel injector pockets that intersect the air assist passageway in each bank of cylinders. This air assist passageway may be formed integral with a manifold, or may be separately formed together with the injector pockets as an air assist rail. The air assist passageway preferably intersects the center line of the fuel injector pockets and is formed by inserting pins that define the interior surface of the passageway into a mold cavity to intersect and pass through bosses that define the fuel injector pockets.

Abstract: An engine cooling module includes a shroud structure 12. A housing 20 of a d.c. electric motor is formed integrally with the shroud structure 12. The housing has an open end 21. The motor has a drive shaft 26. A heat sink 22 is disposed opposite the open end and is insert molded with respect to the housing 20. The heat sink 22 defines a seat for a bearing 24 supporting the shaft 26. A flux ring assembly 48 is insert molded with respect to the housing. The flux ring assembly includes permanent magnets 33. An armature assembly 28 is disposed in the housing and fixed to the shaft for rotation in response to a magnetic field generated by the magnets 33. A commutator 32 is disposed in the housing and electrically connected with the armature assembly 28 and mounted for movement with the armature assembly. A brush card assembly 36 is coupled to the open end 21 of the housing to define an end cap covering the open end. The brush card assembly 36 has brushes 42 associated with the commutator 32.

Abstract: An engine cooling module includes a shroud structure 12. A housing 20 of a d.c. electric motor is formed integrally with the shroud structure 12. The housing has an open end 21. The motor has a drive shaft 26. A heat sink 22 is disposed opposite the open end and is insert molded with respect to the housing 20. The heat sink. 22 defines a seat for a bearing 24 supporting the shaft 26. A flux ring assembly 48 is insert molded with respect to the housing. The flux ring assembly includes permanent magnets 33. An armature assembly 28 is disposed in the housing and fixed to the shaft for rotation in response to a magnetic field generated by the magnets 33. A commutator 32 is disposed in the housing and electrically connected with the armature assembly 28 and mounted for movement with the armature assembly. A brush card assembly 36 is coupled to the open end 21 of the housing to define an end cap covering the open end. The brush card assembly 36 has brushes 42 associated with the commutator 32.