An assembly for flexibly damping a power gear box for a gas turbine engine, the assembly includes a flexible mount connected to the power gear box at a first end of the flexible mount; a member connected to the flexible mount at the first end of the flexible mount and a second end of the flexible mount, wherein the first end of the flexible mount includes an outer rim connected to the member and an inner rim connected to the power gear box and a set of circumferentially segmented squeeze film damper lands configured to receive a damping fluid is provided between the inner rim and the outer rim.

An assembly for flexibly damping a power gear box for a gas turbine engine, the assembly includes a flexible mount connected to the power gear box at a first end of the flexible mount; a member connected to the flexible mount at the first end of the flexible mount and a second end of the flexible mount, wherein the first end of the flexible mount includes an outer rim connected to the member and an inner rim connected to the power gear box and a set of circumferentially segmented squeeze film damper lands configured to receive a damping fluid is provided between the inner rim and the outer rim.

A high speed ratio drive system is formed of planet rollers, each having varying diameter, an outer fixed ring in contact with one diameter of the planet rollers, and an outer drive ring in contact with another diameter of the planet rollers. An inner drive element is provided by a sun drive roller in contact with the planet rollers or by a planet carrier. Preferably the system has an axial reflective symmetry minimizing twisting forces on the planet rollers.

A high speed ratio drive system is formed of planet rollers, each having varying diameter, an outer fixed ring in contact with one diameter of the planet rollers, and an outer drive ring in contact with another diameter of the planet rollers. An inner drive element is provided by a sun drive roller in contact with the planet rollers or by a planet carrier. Preferably the system has an axial reflective symmetry minimizing twisting forces on the planet rollers.

A system for driving a reel mixing tool, including a unit structure, a bottom output shaft, an output gearbox, a reel mixer driveshaft, a reel mixer gearbox, a flexible coupling, and a reel mixing tool, is provided. The unit structure supports the bottom output shaft which is connected to the output gearbox, the output gearbox is connected to the reel mixer driveshaft, the reel mixer driveshaft is connected to the reel mixer gearbox, the reel mixer gearbox is directly coupled to the reel mixing tool by the flexible coupling, allowing the bottom output shaft to transfer power through to the reel mixing tool.

A system for driving a reel mixing tool, including a unit structure, a bottom output shaft, an output gearbox, a reel mixer driveshaft, a reel mixer gearbox, a flexible coupling, and a reel mixing tool, is provided. The unit structure supports the bottom output shaft which is connected to the output gearbox, the output gearbox is connected to the reel mixer driveshaft, the reel mixer driveshaft is connected to the reel mixer gearbox, the reel mixer gearbox is directly coupled to the reel mixing tool by the flexible coupling, allowing the bottom output shaft to transfer power through to the reel mixing tool.

An engine and transmission spacer with integrated hydraulic tank preferably includes a spacer case, an engine flange and a transmission flange. The spacer case includes an outer peripheral wall, a first outer wall and a second outer wall. The first outer wall is formed on one end of the outer peripheral wall and the second outer wall is formed on an opposing end of the outer peripheral wall. The engine flange extends from one end of the spacer case and the transmission flange extends from the opposing end thereof. A fluid cavity is formed in an inner surface of the outer peripheral wall, the first outer wall and the second outer wall. At least one pump port is preferably formed through a side of the outer peripheral wall. An oil pump is used to transfer fluid from the fluid cavity to another location.

An engine and transmission spacer with integrated hydraulic tank preferably includes a spacer case, an engine flange and a transmission flange. The spacer case includes an outer peripheral wall, a first outer wall and a second outer wall. The first outer wall is formed on one end of the outer peripheral wall and the second outer wall is formed on an opposing end of the outer peripheral wall. The engine flange extends from one end of the spacer case and the transmission flange extends from the opposing end thereof. A fluid cavity is formed in an inner surface of the outer peripheral wall, the first outer wall and the second outer wall. At least one pump port is preferably formed through a side of the outer peripheral wall. An oil pump is used to transfer fluid from the fluid cavity to another location.

A gear device includes: a housing cover having an annular shape and including a center opening configured to dispose a connection shaft for a gear, the housing cover being disposed at one end portion of a housing in an axis direction, the housing having a cylindrical shape and configured to house the gear. At an outer surface of the housing cover, an assembling mechanism configured to detachably assemble another housing cover is provided.

A gear device includes: a housing cover having an annular shape and including a center opening configured to dispose a connection shaft for a gear, the housing cover being disposed at one end portion of a housing in an axis direction, the housing having a cylindrical shape and configured to house the gear. At an outer surface of the housing cover, an assembling mechanism configured to detachably assemble another housing cover is provided.