Gearbox and support apparatus for gearbox carrier

What is claimed is: 1 . A planet gearbox for an epicyclic gearing arrangement that has only a single input and a single output and that includes a sun gear and a ring gear disposed circumferentially around the planet gearbox and the sun gear, the planet gearbox comprising: a gearbox carrier having a central axis, the carrier configured to mount one or more rotating gears therein, the carrier including spaced-apart forward and aft walls, each of the forward wall and the aft wall defining a respective coaxial bore; a pin received in the bores defined in the forward wall and the aft wall of the gearbox carrier; and an inner race incorporating a first pair of raised guides and a second pair of raised guides, the first pair of guides defining a forward raceway and the second pair of raised guides defining an aft raceway, the inner race connected to the pin and sized so that the inner race cannot move axially relative to the gearbox carrier, wherein the inner race is a single integral component incorporating both pairs of raised guides. 2 . The planet gearbox of claim 1 , further comprising: a planet gear having a cylindrical interior surface that defines an outer race disposed to face the raised guides. 3 . The planet gearbox of claim 1 , further comprising: a plurality of rollers received by the forward raceway and the aft raceway. 4 . The planet gearbox of claim 3 , further comprising: a planet gear having a cylindrical interior surface that defines an outer race wherein the rollers are disposed between the raceways and the outer race. 5 . The planet gearbox of claim 4 , wherein axial sliding of the rollers can occur relative to the outer race during operation of the apparatus so as to permit limited axial movement of the carrier gearbox sufficient to allow for tolerance and thermal stackup in the carrier gearbox. 6 . The planet gearbox of claim 3 , wherein each of the rollers is configured as a cylindrical roller. 7 . The planet gearbox of claim 3 , wherein each of the rollers has a profile defining a barrel-like shape with a central crown of maximal diameter and with end portions that taper off in a convex curve to a smaller diameter. 8 . The planet gearbox of claim 3 , wherein each of the cylindrical rollers is made of a ceramic material. 9 . The planet gearbox of claim 8 , wherein the ceramic material is silicon nitride. 10 . A gearbox carrier having a central axis, the carrier configured to mount one or more rotating gears therein, the carrier including: spaced-apart forward and aft walls with respective forward and aft coaxial bores; a pin with forward and aft ends received in the forward and aft bores, respectively, the pin secured against axial movement relative to the carrier, an inner race mounted on the pin between the forward and aft ends in a manner secured against axial movement relative to the carrier, the inner race including two pairs of raised guides, each pair of raised guides defining a respective annular raceway, wherein the inner race is a single integral component incorporating both pairs of raised guides; a plurality of generally cylindrical rollers made of a ceramic material disposed rotatably in each of the raceways; and a planet gear mounted for rotation about the pin such that a cylindrical interior surface of the planet gear defines an outer race surrounding the rollers. 11 . The gearbox carrier of claim 10 , wherein: the aft end of the pin includes an annular, radially-outwardly-extending flange that bears against the inner race, so as to prevent forward axial motion of the pin relative to the carrier; and the forward end of the pin is connected to a retainer that bears against the forward wall of the carrier, so as to prevent rearward axial motion of the pin relative to the carrier. 12 . The gearbox carrier of claim 10 , wherein the rollers have a barrel-like shape with a central crown of maximum diameter and end portions tapering off from the central crown to a smaller diameter. 13 . The gearbox carrier of claim 10 , wherein each of the cylindrical rollers is made of a ceramic material. 14 . The gearbox carrier of claim 13 , wherein the ceramic material is silicon nitride. 15 . A planet gearbox for an epicyclic gearing arrangement that has only a single input and a single output and that includes a sun gear and a ring gear disposed circumferentially around the planet gearbox and the sun gear, the planet gearbox comprising: a gearbox carrier having a central axis, the carrier configured to mount one or more rotating gears therein, the carrier including spaced-apart forward and aft walls, each of the forward wall and the aft wall defining a respective coaxial bore; a pin received in the bores defined in the forward wall and the aft wall of the gearbox carrier; and an inner race incorporating a first pair of raised guides and a second pair of raised guides, the first pair of guides defining a forward raceway and the second pair of raised guides defining an aft raceway, the inner race connected to the pin and sized so that the inner race cannot move axially relative to the gearbox carrier, wherein the inner race is two separate inner races, each having raised guides. 16 . The planet gearbox of claim 15 , further comprising: a planet gear having a cylindrical interior surface that defines an outer race disposed to face the raised guides. 17 . The planet gearbox of claim 15 , further comprising: a plurality of rollers received by the forward raceway and the aft raceway. 18 . The planet gearbox of claim 17 , further comprising: a planet gear having a cylindrical interior surface that defines an outer race wherein the rollers are disposed between the raceways and the outer race. 19 . The planet gearbox of claim 18 , wherein axial sliding of the rollers can occur relative to the outer race during operation of the apparatus so as to permit limited axial movement of the carrier gearbox sufficient to allow for tolerance and thermal stackup in the carrier gearbox. 20 . The planet gearbox of claim 18 , wherein each of the rollers is configured as a cylindrical roller.