The present teachings provide for a system comprising a gearbox including a gear assembly, the gearbox having an outer surface, the outer surface with a pair of apertures; and an actuator. The actuator including a support with a pair of lugs, with each lug having an opening; an drive system connected to the support; a shift fork including a pair of arms, the shift fork in communication with the drive system and configured to move a distance defining a stroke length between a disengaged position and an engaged position; and an actuation assembly operatively connected with the drive system to move the shift fork between a neutral position, and a shifted position, with a plurality of intermediate positions between the neutral and shifted positions. The actuator is mounted onto the outer surface of the gearbox, with the pair of lugs extending into the pair of apertures of the gearbox, and at least a portion of the shift fork extends extending through the lugs into and below the outer surface of the gearbox. The portion of the shift fork within the gearbox engages a gear assembly within the gearbox.

The transmission includes a plurality of shift forks which includes a U-shaped main body, an engaging portion and a pair of supporting portions provided at both sides of the main body. When the engaging portion engages with the inner lever and the shift select shaft moves along in the axis line, the plurality of shift forks is rotated relative to the housing about the pair of supporting portions as a rotation center thereof and the sleeve connected to the pair of connecting portions is configured to be movable between the low speed side gear and the high speed side gear and the pair of supporting portions is provided at a point between a pair of reference fulcrums and the pair of connecting portions where a rotational moment of a connecting body formed by connecting the sleeve with the plurality of shift forks becomes zero at the pair of reference fulcrums.

A drive system is provided for an engine arrangement, which includes a gear reduction mechanism such as an epicyclic gearing including first junction element connected to an engine crankshaft, second junction element connected to an accessory pulley which is drivingly connected to an electric machine and at least one accessory, and third junction element. A free wheel is connected to a non-rotating part of the engine arrangement. In a first operating phase of the drive system, the free wheel is coupled to the third junction element and is configured such that when the third junction element exerts torque on the free wheel in one direction, the free wheel is in an engaged state and stops the rotation of the third junction element, and, when the third junction element exerts torque on the free wheel in the opposite direction, the free wheel is in a free state and allows rotation of the third junction element.

A shifting apparatus including a shaft extending along an axis, and at least one shifting feature, each of the at least one shifting feature including: a multi-part pin having first and second parts arranged to rotate relative to each other that extend through respective slots extending along the shaft; a drum arranged around the shaft and having channels extending along the length thereof wherein the first and second parts of the multi-part pin are respectively received for enabling torque transfer to the drum when the shaft is rotated, the drum also defining a track at least partially around its outer surface; a biasing mechanism for urging the drum towards a rest position along the length of the shaft; and a drive member selector member provided in operative relation to the track. The drive member selector member can be controlled to selectively engage a drive member.

A transmission according to an embodiment includes a shift fork swingably supported by a case to move a movable element in an axial direction in accordance with the motion of a second shaft to two shift positions; two first protrusions provided on the second shaft and spaced apart from each other in the axial direction; and a second protrusion provided on the shift fork, and when the second shaft is in one of select positions, is positioned between the two first protrusions and overlaps with the first protrusions viewed from the axial direction. A protruding direction of the first protrusions and a protruding direction of the second protrusion are orthogonal to a swinging center of the shift fork when viewed in the axial direction. The second protrusion protrudes from the shift fork toward the swinging center. The second shaft is positioned between the second protrusion and the swinging center.

A shifting apparatus for a manual transmission able to shift two shift stages, of which selection positions are different but shift positions are the same, using a single fork and a single sleeve. Compared to the related art in which a fork and a synchronization sleeve are provided to each of two independent shift stages, the full length of the transmission is reduced, thereby reducing the weight and manufacturing costs.

The present teachings provide for a system comprising a gearbox including a gear assembly, the gearbox having an outer surface, the outer surface with a pair of apertures; and an actuator. The actuator including a support with a pair of lugs, with each lug having an opening; an drive system connected to the support; a shift fork including a pair of arms, the shift fork in communication with the drive system and configured to move a distance defining a stroke length between a disengaged position and an engaged position; and an actuation assembly operatively connected with the drive system to move the shift fork between a neutral position, and a shifted position, with a plurality of intermediate positions between the neutral and shifted positions. The actuator is mounted onto the outer surface of the gearbox, with the pair of lugs extending into the pair of apertures of the gearbox, and at least a portion of the shift fork extends extending through the lugs into and below the outer surface of the gearbox. The portion of the shift fork within the gearbox engages a gear assembly within the gearbox.

An improved gear shift mechanism for an auger gear drive which uses a hydraulic cylinder or other linear force means to push on one end of a rocker arm. This moves the rocker arm and the gear train between a first gear set and a second gear set. A biasing means is applied directly to the rocker arm by a spring or other device. The design eliminates adjustable linkages and the need adjustments in the field and allows for use of a simpler hydraulic cylinder than found in the prior art.

An interlock mechanism includes a shift-and-select shaft a first fork, a second fork, a first inner lever, a second inner lever, an interlock member coaxially arranged around an outer circumference of the shift-and-select shaft while being allowed to rotate together with the shift-and-select shaft in the rotation direction as a unit and not allowed to be displaced in the axial direction, a first engagement portion formed on the first fork, a second engagement portion formed to project from the second fork, a first engaged portion formed to project from the inter lock member and engaged with the first engagement portion while the interlock member is positioned at a second rotation position and a second engaged portion formed on the interlock member and engaged with the second engagement portion while the interlock member is positioned at a first rotation position.

The present teachings provide for an actuator system including a support; a drive system connected to the support; a shift fork operatively connected to the drive system and configured to move a distance defining a stroke length between a disengaged position and an engaged position, the shift fork having a cam follower; a cam assembly operatively connected with the drive system to move between a neutral position, and a shifted position, with a plurality of intermediate positions between the neutral and shifted positions, the shift fork being in the disengaged position when the cam assembly is in the neutral position, the cam assembly including: a cam having an aperture defining an interior surface; a hub housing disposed within the aperture of the cam and connected to the drive system; and a biasing member disposed within the aperture and preloaded between an interior surface of the aperture and the hub housing.