Abstract: A damper system includes a turbine shaft rotatably connected to a torque converter having a clutch. A hydraulically actuated clutch is coupled to the turbine shaft. A first spring cage has a first cage portion connected to the hydraulically actuated clutch and a second cage portion connected to a friction plate. A first spring set is connected to the first and second cage portions. Springs of the first spring set are deflected by axial rotation between the first and second cage portions when the torque converter clutch is engaged. A second spring cage has a first cage section connected to the hydraulically actuated clutch and a second cage section connected to a torque converter turbine. A second spring set has second springs having a spring constant different than the first spring set. The second spring set springs are deflected by axial rotation between the first and second cage sections.

Abstract: A torsional vibration damper includes a planetary gear set having a ring gear connected to a transmission input shaft, a carrier rotatably supporting multiple planet gears individually meshed with a sun gear, and with the ring gear meshed with the planet gears. A spring cage includes a first spring support member having: a member first leg fixed to the ring gear; a member second leg rotatably connected to the transmission input shaft; and multiple first spring support member elements. A second spring support member connected to the carrier, the second spring support member having multiple second spring support member elements. Multiple springs each spring have at least one of the first spring support member elements and one of the second spring support member elements in contact with opposed ends of the spring. An inertial mass member is connected to the sun gear at a first end and has an inertial mass connected at a second end.

Abstract: A torsional vibration damper includes a planetary gear set having a ring gear connected to a transmission input shaft, a carrier rotatably supporting multiple planet gears individually meshed with a sun gear, and with the ring gear meshed with the planet gears. A spring cage includes a first spring support member having: a member first leg fixed to the ring gear; a member second leg rotatably connected to the transmission input shaft; and multiple first spring support member elements. A second spring support member connected to the carrier, the second spring support member having multiple second spring support member elements. Multiple springs each spring have at least one of the first spring support member elements and one of the second spring support member elements in contact with opposed ends of the spring. An inertial mass member is connected to the sun gear at a first end and has an inertial mass connected at a second end.

Abstract: A damper system includes a turbine shaft rotatably connected to a torque converter having a clutch. A hydraulically actuated clutch is coupled to the turbine shaft. A first spring cage has a first cage portion connected to the hydraulically actuated clutch and a second cage portion connected to a friction plate. A first spring set is connected to the first and second cage portions. Springs of the first spring set are deflected by axial rotation between the first and second cage portions when the torque converter clutch is engaged. A second spring cage has a first cage section connected to the hydraulically actuated clutch and a second cage section connected to a torque converter turbine. A second spring set has second springs having a spring constant different than the first spring set. The second spring set springs are deflected by axial rotation between the first and second cage sections.

Abstract: A system for absorbing vibration and transmitting torque from a rotating power source to a rotatable load includes a rotatable driving member configured as an input to be driven by the power source. The system also includes a rotatable driven member configured to be driven by the driving member via a fluid coupling of the driven member to the driving member. The system also has a rotatable component configured as an output to drive the load, and a centrifugal pendulum absorber attached to the rotatable component. A first resilient member connects the driven member to the rotatable component.

Abstract: A torque transmission device for a powertrain system includes a continuously variable unit (CVU) of a continuously variable transmission (CVT) arranged in parallel with a fixed-gear-ratio transmission. The fixed-gear-ratio transmission includes first and second planetary gear sets and a plurality of transmission clutches, wherein the first and second planetary gear sets are arranged to transfer torque between an input member and an output member in one of first and second fixed-gear-ratio modes by selectively activating the transmission clutches. The torque transmission device operates in a first fixed overdrive input/output speed ratio when the CVU input clutch is deactivated and a first set of two of the transmission clutches is activated. The torque transmission device operates in a second fixed overdrive input/output speed ratio when the CVU input clutch is deactivated and a second set of two of the transmission clutches is activated.

Abstract: A torque transmission device for a powertrain system is described, and includes a continuously variable unit (CVU) of a continuously variable transmission (CVT) arranged in parallel with a fixed-gear-ratio transmission to transfer torque between a transmission input member and a transmission output member. The fixed-gear-ratio transmission includes first and second planetary gear sets arranged to transfer torque between the transmission input member and the transmission output member in one of a plurality of fixed-gear-ratio modes by selectively activating a plurality of transmission clutches. The transmission input member rotatably couples to one of the nodes of the first planetary gear set and one of the nodes of the second planetary gear set. The torque transmission device transfers torque in one of a continuously variable mode, a fixed underdrive input/output speed ratio, or a fixed overdrive input/output speed ratio.

Abstract: A torque transmission device for a powertrain system is described, and includes a continuously variable unit (CVU) of a continuously variable transmission (CVT) arranged in parallel with a fixed-gear-ratio transmission to transfer torque between a transmission input member and a transmission output member. The fixed-gear-ratio transmission includes first and second planetary gear sets arranged to transfer torque between the transmission input member and the transmission output member in one of a plurality of fixed-gear-ratio modes by selectively activating a plurality of transmission clutches. The transmission input member rotatably couples to one of the nodes of the first planetary gear set and one of the nodes of the second planetary gear set. The torque transmission device transfers torque in one of a continuously variable mode, a fixed underdrive input/output speed ratio, or a fixed overdrive input/output speed ratio.

Abstract: A torque transmission device for a powertrain system includes a continuously variable unit (CVU) of a continuously variable transmission (CVT) arranged in parallel with a fixed-gear-ratio transmission. The fixed-gear-ratio transmission includes first and second planetary gear sets and a plurality of transmission clutches, wherein the first and second planetary gear sets are arranged to transfer torque between an input member and an output member in one of first and second fixed-gear-ratio modes by selectively activating the transmission clutches. The torque transmission device operates in a first fixed overdrive input/output speed ratio when the CVU input clutch is deactivated and a first set of two of the transmission clutches is activated. The torque transmission device operates in a second fixed overdrive input/output speed ratio when the CVU input clutch is deactivated and a second set of two of the transmission clutches is activated.

Abstract: A powertrain system in a hybrid vehicle includes a hydraulic device, a pilot valve, and a regulator valve. The pilot valve is operably connected to the hydraulic device and configured to actuate. The pilot valve includes at least one micro-electro-mechanical systems (MEMS) based device. The regulator valve is operably connected to the pilot valve and the hydraulic device. The regulator valve is configured to direct fluid to the hydraulic device based on the actuation of the pilot valve.

Abstract: A wet dual clutch transmission includes at least one hydraulic component and a pilot valve operably connected to the hydraulic component to actuate the hydraulic component. The pilot valve includes a Micro-Electro-Mechanical Systems (MEMS) based pressure differential actuator valve. The hydraulic component may include but is not limited to a first clutch and a second clutch of the wet dual clutch transmission, a lube regulator valve, an on/off solenoid, a synchronizing shift fork or a line pressure control valve.

Abstract: A method of modeling initial temperatures of a dry DCT includes reactivating a controller after a time lapse between first and second clock times representing an offline period. The last known temperatures of a first component and a second component are read and a first temperature difference therebetween is calculated. The method calculates a stop time and a start time on a predefined exponential function from the calculated temperature difference. A first conductive heat transfer between the first and second components is calculated by integrating the predefined exponential function between the stop time and the start time. Based upon the calculated first conductive heat transfer, a first conductive temperature change between the first and second components is calculated. A starting temperature of the first component is calculated from first conductive temperature change, and a control action on the dry DCT is executed based upon the calculated starting temperature.

Abstract: A transmission includes a first gear set with a first sun gear member rotatable about a first axis of rotation, a first carrier member, and a first ring gear member radially outward of and concentric with the first sun gear member. The first ring gear member has a radially inward-facing surface with inner teeth and a radially outward-facing surface with outer teeth. A second gear set has a second carrier member, and a second ring gear member radially outward of and concentric with the first ring gear member. The second ring gear member has a radially inward-facing surface with inner teeth. A first annular gear has a radially inward-facing surface with inner teeth and a radially outward-facing surface with outer teeth. The first annular gear is rotatable about a second axis of rotation and meshes with the first ring gear member.

Abstract: An automatic transmission for a vehicle includes a hydraulically-controlled component and a pilot valve. The pilot valve includes at least one micro-electrical-mechanical systems (MEMS) based device. The pilot valve is operably connected to and is configured for actuating the hydraulically-controlled component. The pilot valve additionally includes a regulating valve operably connected to the pilot valve and to the hydraulically-controlled component. The regulating valve is configured to direct fluid to the hydraulically-controlled component when actuated by the pilot valve.

Abstract: A continuously variable transmission (CVT) for a vehicle includes a hydraulically-controlled component and a pilot valve. The pilot valve includes at least one micro-electrical-mechanical-systems (MEMS) based device. The pilot valve is operably connected to and is configured for actuating the hydraulically-controlled component. The pilot valve additionally includes a regulating valve operably connected to the pilot valve and to the hydraulically-controlled component. The regulating valve is configured to direct fluid to the hydraulically-controlled component when actuated by the pilot valve.

Abstract: A pressure and flow control system includes a hydraulically-controlled component, a pilot valve, and a regulating valve. The pilot valve is configured to produce a pilot signal and includes a first valve, which is a MEMS microvalve. The regulating valve is in fluid communication with the pilot valve, and is configured to receive the pilot signal. The regulating valve is further configured to output a control signal, which controls the hydraulically-controlled component.

Abstract: A method of determining temperatures for a dry dual clutch mechanism includes one or more steps, such as determining a first heat input from a first clutch and determining a second heat input from a second clutch. The second clutch is separated from the first clutch by a center plate. The method also includes determining a housing air temperature of housing air within a bell housing case of the dry dual clutch mechanism. A thermal model is applied with the determined first heat input and second heat input. The thermal model includes temperature states for at least the first clutch, the second clutch, and the center plate. From the thermal model, the method determines at least a first clutch temperature and a second clutch temperature. The method includes executing a control action with the determined first clutch temperature and second clutch temperature.

Abstract: A pressure and flow control system for a dog clutch includes a pilot valve, a regulating valve, and a selector. The pilot valve is configured to produce a pilot signal and includes a first valve, which is a MEMS microvalve. The regulating valve is in fluid communication with the pilot valve, and is configured to receive the pilot signal. The regulating valve is further configured to output a control signal. The selector is configured to engage and disengage the dog clutch in response to the control signal.

Abstract: A method for determining initial or starting temperatures for a dry dual clutch mechanism at vehicle start-up includes as determining a time lapse from shut-down to start-up. The method determines a housing air start temperature of the housing air within a bell housing case of the dry dual clutch mechanism at vehicle start-up, reads a first clutch stop temperature of a first clutch at vehicle shut-down, reads a housing air stop temperature of the housing air at vehicle shut-down, and determines a heat transfer coefficient between the first clutch and the housing air. The method includes determining a first clutch start temperature from, at least: the heat transfer coefficient between the first clutch and the housing air; a temperature differential between the first clutch stop temperature and the housing air stop temperature; and the housing air start temperature.

Abstract: An automated manual transmission includes a hydraulic device, a pilot valve, and a regulating valve. The pilot valve is operably connected to the hydraulic device and configured to actuate. The pilot valve includes at least one micro-electro-mechanical systems (MEMS) based device. The regulating valve is operably connected to the pilot valve and the hydraulic device. The regulating valve is configured to direct fluid to the hydraulic device based on the actuation of the pilot valve.