This non-tilting steering system for reverse trikes uses three cross axis helical gear set. Steerer rod at the center, and steerer rod controlling the wheels are connected to cross axis helical gear set. Central gear set as well as gear set on the wheel consist of one vertical helical gear meshingly engaged, on its front and rear side, with two transversely oriented horizontal helical gears. Steerer rod at the center upon rotation via handle rotates coaxial worm gear which in turn rotates pinion helical gears engaged with it. Pinion helical gears at the center then rotates transverse helical gears of the gear set of the steering system at each of the wheels via a transmission shaft which in turn rotates the vertical helical gears attached to steerer rods of the wheels, thus rotating the wheels. This steering system can also be used in a four wheeler.

A method of modifying the rake angle on a motorcycle having a double wishbone front suspension. The motorcycle has a tubular steering housing connected to a non-telescoping fork assembly by a straight body steering stem. The method includes the step of replacing the straight body steering stem with a canted body steering stem. The canted body steering stem includes (i) a primary section having a steering axis corresponding to a steering axis of the motorcycle; and (ii) a secondary section having a cant axis which varies from the steering axis by between 1 and 16.

A method of modifying the rake angle on a motorcycle having a double wishbone front suspension. The motorcycle has a tubular steering housing connected to a non-telescoping fork assembly by a straight body steering stem. The method includes the step of replacing the straight body steering stem with a canted body steering stem. The canted body steering stem includes (i) a primary section having a steering axis corresponding to a steering axis of the motorcycle; and (ii) a secondary section having a cant axis which varies from the steering axis by between 1 and 16.

A saddled vehicle includes a steering stem inserted into a center part of a top bridge and having an upper end to be fixed to the top bridge with a fastening member. The saddled vehicle includes a handle locking device placed behind the top bridge in the vehicle front-rear direction. The handle locking device has a locking member and the top bridge includes a retaining recess on the rear face for detachable engagement with the locking member. The center part of the top bridge has a through hole for penetration of the steering stem and a storage recess that stores the upper end of the steering stem and the fastening member and is open toward the upper face of the top bridge. The storage recess continues to the upper part of the through hole while having a bottom that faces upward and is located between the through hole and the wall of the storage recess. The top bridge has a drainage hole connecting the storage recess and the retaining recess.

A mounting specification adjustable front fork mount for mounting on a bike rack on a car roof to cooperate with a quick release for securing a bicycle front fork is disclosed to include a holder having a shaft tube with a protruding portion at each of two opposite ends of the shaft tube, and two mounting tubes each having a first coupling recess and a second coupling recess so designed that the bottom of the first coupling recess and the bottom of the second coupling recess are respectively spaced from the distal end of the mounting tube by a different distance. The protruding portion at each end of the shaft tube can be selectively engaged into the first coupling recess or the second coupling recess according to the specification of the bicycle front fork.

A mounting specification adjustable front fork mount for mounting on a bike rack on a car roof to cooperate with a quick release for securing a bicycle front fork is disclosed to include a holder having a shaft tube with a protruding portion at each of two opposite ends of the shaft tube, and two mounting tubes each having a first coupling recess and a second coupling recess so designed that the bottom of the first coupling recess and the bottom of the second coupling recess are respectively spaced from the distal end of the mounting tube by a different distance. The protruding portion at each end of the shaft tube can be selectively engaged into the first coupling recess or the second coupling recess according to the specification of the bicycle front fork.

A shock absorber includes a stationary part; a steering part extending in a longitudinal direction and rotatably coupled to the stationary part by a rotation axis in the longitudinal direction; a sliding part which forms an internal space containing fluid between the steering part and slidably coupled to the steering part in a direction in which the steering part extends; an elastic body having both ends respectively coupled to the steering part and the sliding part to support the steering part and the sliding part and maintain the internal space between the steering part and the sliding part; a flow path formed in the sliding part and configured to communicate the internal space between the steering part and the sliding part to outside so that the fluid can flow; and a steered driving wheel slidably connected to the sliding part.

A system for manipulating the steering axis angle of an object is provided. The system is beneficial for improving performance and enjoyability of use for objects employing a steering axis, including bicycles, toys, tools, sporting goods, and other modes of transportation. The system includes a reversible bearing plate with a bearing plate bore that permits passage of a steerer tube through a head tube when reversible bearing plates are installed at the head tube ends. The bearing plate bore may be at the center of the reversible bearing plate to maintain a steering axis coaxial with the head tube central axis. The bearing plate bore may be offset from the center of the reversible bearing plate and may employ an angled annular space such that when reversible bearing plates are installed oppositely at the head tube ends, the steering axis is offset from the center of each reversible bearing plate generating an angle between the steerer tube central axis and the head tube central axis, resulting in a correspondingly steeper or slacker head angle. Methods of employing reversible bearing plates for maintaining, steepening, or slackening the head angle of a bicycle are provided.

A system for manipulating the steering axis angle of an object is provided. The system is beneficial for improving performance and enjoyability of use for objects employing a steering axis, including bicycles, toys, tools, sporting goods, and other modes of transportation. The system includes a reversible bearing plate with a bearing plate bore that permits passage of a steerer tube through a head tube when reversible bearing plates are installed at the head tube ends. The bearing plate bore may be at the center of the reversible bearing plate to maintain a steering axis coaxial with the head tube central axis. The bearing plate bore may be offset from the center of the reversible bearing plate and may employ an angled annular space such that when reversible bearing plates are installed oppositely at the head tube ends, the steering axis is offset from the center of each reversible bearing plate generating an angle between the steerer tube central axis and the head tube central axis, resulting in a correspondingly steeper or slacker head angle. Methods of employing reversible bearing plates for maintaining, steepening, or slackening the head angle of a bicycle are provided.

A steering assembly for a bicycle includes a front fork that includes an upper crown, a lower crown, and a rigid crown connector that connects the upper crown to the lower crown. The steering assembly also includes an upper cone configured to mount to the upper crown of the front fork. The upper cone includes an upper cone bearing interface configured to interact with an upper bearing assembly seated in an upper portion of a head tube of a bicycle frame. The steering assembly also includes a lower cone configured to mount to the lower crown of the front fork. The lower cone includes a lower cone bearing interface configured to interact with a lower bearing assembly seated in a lower portion of the head tube of the bicycle frame.