A torque converter includes a front cover to which a power is inputted, an impeller coupled to the front cover, a turbine from which the power is outputted, a stator and a centrifugal clutch. The impeller forms a hydraulic oil chamber together with the front cover. The impeller includes an impeller core. The turbine is opposed to the impeller. The turbine includes a turbine core. The stator is disposed between an inner peripheral part of the impeller and an inner peripheral part of the turbine. The stator is configured to regulate a hydraulic oil flowing from the turbine to the impeller. The centrifugal clutch is disposed in a space between the impeller core and the turbine core. The centrifugal clutch is configured to directly transmit the power from the impeller to the turbine when a rotational speed of the turbine is greater than or equal to a predetermined value.

A torque converter includes an impeller and a cover rotationally fixed to the impeller. The cover has opposing inner and outer surfaces and a through hole extending from the inner surface to the outer surface. A stud is attached to the cover. The stud has a head and a shank extending from the head. The head defines an annular projection circumscribing the shank and raised from the head. The stud is disposed on the cover with the shank extending through the hole to project from the outer surface and with the head being connected to the cover by coalescence between the annular projection and the inner surface creating a hermetic seal around the hole.

A torque converter includes an impeller and a cover rotationally fixed to the impeller. The cover has opposing inner and outer surfaces and a through hole extending from the inner surface to the outer surface. A stud is attached to the cover. The stud has a head and a shank extending from the head. The head defines an annular projection circumscribing the shank and raised from the head. The stud is disposed on the cover with the shank extending through the hole to project from the outer surface and with the head being connected to the cover by coalescence between the annular projection and the inner surface creating a hermetic seal around the hole.

A rotor for a hybrid drivetrain includes a rotor carrier, at least one rotor segment, and a torque converter. The rotor carrier has a first tubular portion with an outer surface, and an annular portion with a first through hole. The at least one rotor segment is installed on the outer surface. The torque converter has an impeller with a first shell and a plurality of first blades fixed to the first shell, a cover with a second shell fixed to the first shell to form a hydraulic chamber and a fastener fixed to the second shell and extending through the first through hole, and a turbine disposed in the hydraulic chamber and including a third shell and a plurality of second blades fixed to the second shell.

A process fluid lubricated pump for conveying a process fluid, includes a common housing, a pump unit arranged in the common housing, a drive unit arranged in the common housing, and a hydrodynamic coupling. The common housing includes a pump inlet and a pump outlet for the process fluid. The pump unit includes at least one impeller configured to convey the process fluid from the pump inlet to the pump outlet, and a pump shaft, on which the impeller is mounted. The drive unit includes a drive shaft configured to drive the pump shaft, and an electric motor configured to rotate the drive shaft about an axial direction. The hydrodynamic coupling is configured to hydrodynamically couple the drive shaft to the pump shaft by a transmission fluid, and is configured to receive the process fluid as the transmission fluid.

Embodiments are directed to solid lubricant assemblies for providing over temperature protection for bearings and gears in rotorcraft systems. A solid lubricant enters a fluid state above a certain temperature and is positioned so that fluid lubricant is applied to the bearings or gears.

Embodiments are directed to solid lubricant assemblies for providing over temperature protection for bearings and gears in rotorcraft systems. A solid lubricant enters a fluid state above a certain temperature and is positioned so that fluid lubricant is applied to the bearings or gears.

A torque converter includes a front cover to which a power is inputted, an impeller coupled to the front cover, a turbine from which the power is outputted, a stator and a centrifugal clutch. The impeller forms a hydraulic oil chamber together with the front cover. The impeller includes an impeller core. The turbine is opposed to the impeller. The turbine includes a turbine core. The stator is disposed between an inner peripheral part of the impeller and an inner peripheral part of the turbine. The stator is configured to regulate a hydraulic oil flowing from the turbine to the impeller. The centrifugal clutch is disposed in a space between the impeller core and the turbine core. The centrifugal clutch is configured to directly transmit the power from the impeller to the turbine when a rotational speed of the turbine is greater than or equal to a predetermined value.

A shaft (W) for a motor vehicle transmission (G) may have axial bore holes positioned within the shaft and configured to guide fluid within the shaft. The shaft may have first, second, and third axial sections (W1, W2, W3), the second axial section being axially between the first and third axial sections. Fluid enters the axial bore holes in the second axial section and exits the axial bore holes in the first and third axial sections. One of the axial bore holes (B2; B1, B1a) is arranged, at least partially, in the first axial section and is radially spaced from an axis of rotation (WA) of the shaft. Another of the axial bore holes (B1RS; B_SE5, B3a) is arranged, at least partially, in the third axial section. The one of the axial bore holes (B2; B1, B1a) is coaxial with the other of the axial bore holes (B1RS; B_SE5, B3a).

A shaft (W) for a motor vehicle transmission (G) may have axial bore holes positioned within the shaft and configured to guide fluid within the shaft. The shaft may have first, second, and third axial sections (W1, W2, W3), the second axial section being axially between the first and third axial sections. Fluid enters the axial bore holes in the second axial section and exits the axial bore holes in the first and third axial sections. One of the axial bore holes (B2; B1, B1a) is arranged, at least partially, in the first axial section and is radially spaced from an axis of rotation (WA) of the shaft. Another of the axial bore holes (B1RS; B_SE5, B3a) is arranged, at least partially, in the third axial section. The one of the axial bore holes (B2; B1, B1a) is coaxial with the other of the axial bore holes (B1RS; B_SE5, B3a).