A cam follower includes a shaft and a hub rotatable with respect to the shaft via at least one bearing. A flanged tire is affixed to the outer peripheral surface of the hub, the flanged tire having a main body portion and a flange portion extending radially outwardly therefrom. The main body portion and the flange portion are integrally formed from a polymeric material, and the hub, the main body portion and the flange portion are disposed so as to define a generally planar outer surface. A flange support plate, having a support plate outer diameter that is generally equal to or greater than the flange diameter, is positioned abutting the generally planar outer surface and is rigidly affixed to the hub, the flange support plate being formed from a metal material, thereby providing structural support to the flange portion for axial forces applied to the flange portion.

A cam follower includes a shaft and a hub rotatable with respect to the shaft via at least one bearing. A flanged tire is affixed to the outer peripheral surface of the hub, the flanged tire having a main body portion and a flange portion extending radially outwardly therefrom. The main body portion and the flange portion are integrally formed from a polymeric material, and the hub, the main body portion and the flange portion are disposed so as to define a generally planar outer surface. A flange support plate, having a support plate outer diameter that is generally equal to or greater than the flange diameter, is positioned abutting the generally planar outer surface and is rigidly affixed to the hub, the flange support plate being formed from a metal material, thereby providing structural support to the flange portion for axial forces applied to the flange portion.

The present invention relates to a cam-operated device (5) for controlling at least one component, said device comprising a cam (6) comprising at least one first camway (7, 8) on a first face and a second camway (9) on an opposite face, said first camway (7, 8) having a depth, measured starting from an opening, at the level of said first face, of said first camway, and said second camway (9) having a depth, measured starting from an opening, at the level of said opposite face, of said second camway, a height of the cam (6), measured between the opening of the first and second camways, being less than the sum of the depths of the camways (7, 8, 9).

The present invention relates to a cam-operated device (5) for controlling at least one component, said device comprising a cam (6) comprising at least one first camway (7, 8) on a first face and a second camway (9) on an opposite face, said first camway (7, 8) having a depth, measured starting from an opening, at the level of said first face, of said first camway, and said second camway (9) having a depth, measured starting from an opening, at the level of said opposite face, of said second camway, a height of the cam (6), measured between the opening of the first and second camways, being less than the sum of the depths of the camways (7, 8, 9).

A level wind mechanism for a dual-bearing reel including a first reel body and a second reel body includes a worm shaft, a guide member, and a first seal member. The worm shaft including a first end, a second end, a shaft body and a helical groove. The first end is on the same side as the first reel body. The second end is on the same side as the second reel body. The shaft body extends between the first end and the second end. The helical groove is on the shaft body. The guide member includes a tubular shape, is outside the worm shaft in a radial direction from a rotational axis of the worm shaft, and extends between the first reel body and the second reel body. The first seal member seals between the first end of the worm shaft and the guide member.

A level wind mechanism for a dual-bearing reel including a first reel body and a second reel body includes a worm shaft, a guide member, and a first seal member. The worm shaft including a first end, a second end, a shaft body and a helical groove. The first end is on the same side as the first reel body. The second end is on the same side as the second reel body. The shaft body extends between the first end and the second end. The helical groove is on the shaft body. The guide member includes a tubular shape, is outside the worm shaft in a radial direction from a rotational axis of the worm shaft, and extends between the first reel body and the second reel body. The first seal member seals between the first end of the worm shaft and the guide member.

A speed reducer including: an input shaft; a first barrel cam; a first output table; an intermediate shaft; a second cam; and a second output table, in the first output table, the plurality of first cam followers being provided concentrically around a rotation center position of the intermediate shaft, concerning a certain first cam follower among the plurality of first cam followers, when a center position of the certain first cam follower when the certain first cam follower has been moved to a farthest end on one side in the up-down direction is defined as a reference position, a center position of the first barrel cam being shifted to another side in the up-down direction with respect to the reference position, an engagement center position in the front-rear direction between an engagement start position and an engagement end position being shifted either of forward and rearward with respect to the reference position.

A backlash-free double row roller cam transmission mechanism includes two passive wheels, two sets of rollers respectively pivotally arranged on the circular peripheral edges of the passive wheels, and a transmission camshaft with two opposite sides of a spiral protrusion respectively abutted against the two sets of rollers. Use the principle of oblique wedge adjustment to generate the reverse thrust of the rollers, thereby eliminating the backlash between the rollers and the spiral protrusion. All rollers can abut against the entire spiral protrusion to increase the structural rigidity and transmission load and prolong the service life. The design is conducive to achieving the cam self-locking function.

A speed reducer including: an input shaft; a first barrel cam; a first output table; an intermediate shaft; a second cam; and a second output table, in the first output table, the plurality of first cam followers being provided concentrically around a rotation center position of the intermediate shaft, concerning a certain first cam follower among the plurality of first cam followers, when a center position of the certain first cam follower when the certain first cam follower has been moved to a farthest end on one side in the up-down direction is defined as a reference position, a center position of the first barrel cam being shifted to another side in the up-down direction with respect to the reference position, an engagement center position in the front-rear direction between an engagement start position and an engagement end position being shifted either of forward and rearward with respect to the reference position.

A solar tracking system is provided and includes a solar array, a plurality of support beams configured to support the solar array, a torque tube coupled to the plurality of support beams, a base configured to rotatably support the torque tube, and an articulation system configured to rotate the torque tube relative to the base. The articulation system includes a first helical tube coupled to the torque tube, a first helical tube support disposed on the base and configured to slidably support the first helical tube, and a gearbox in mechanical communication with the first helical tube. Actuation of the gearbox causes the first helical tube to translate within the first helical tube support and the first helical tube support is configured to rotate the first helical tube as the first helical tube is translated therein to cause a corresponding rotation of the solar array.