A coaxial co-located vehicle power drive and steering system includes a motor coupled to a transmission having a drive shaft with a first portion and a second portion mechanically interlocked by a spline having corresponding meshing features extending parallel to the drive shaft longitudinal axis. A drive shaft housing enclosing at least a length of the drive shaft, the drive shaft housing including a first portion and a second portion mechanically interlocked by a spline having corresponding meshing features extending parallel to the drive shaft longitudinal axis. A distal end of the drive shaft terminating within a differential gearbox in mechanical communication with an axle. A steering system coupled to the drive shaft housing second portion, the steering system including one or more rotatable gears which cause an angular rotation of the housing in relation to the drive shaft.

The invention discloses a novel power transmission structure suitable for all-terrain karts, comprising a first sprocket support frame, the upper part of the first sprocket support frame is provided with an upper bearing chock of the support frame, and the lower part is provided with a lower bearing chock of the support frame, the engine end output shaft of the engine is connected to the upper bearing chock of the support frame through a suitable coupling and bearing, the engine end output shaft is equipped with a first sprocket and chain mechanism, and the sprocket of the first sprocket and chain mechanism is installed on the sprocket bearing chock. Compared with the prior art, the invention has the advantages that the overall structure is simple and practical, and the power output from the engine is efficiently transmitted to the rear drive axle, so that the vehicle can better adapt to off-road driving, the engine can also be installed on the frame and separated from the drive axle, which reduces the unsprung mass and improves the comfort of the driver and passengers, greatly improves the power transmission efficiency of the kart, and reduces a large amount of costs invested in the early stage and maintenance cost in the later stage, it has good applicability and is easy to promote.

A system for determining the number of revolutions of a cardan shaft, having at least a magnet and at least a hall sensor is positioned to provide magnetic interaction between them, characterized by connecting one of the magnet and hall sensor onto either the rotating elements of the cardan shaft and the other to a fixed point and including a detection element for detecting the revolution rate by correlating to the revolution and the pulse created by the hall sensor as a result of interaction between the magnet and the hall sensor, when the cardan shaft rotates.

A system for determining the number of revolutions of a cardan shaft, having at least a magnet and at least a hall sensor is positioned to provide magnetic interaction between them, characterized by connecting one of the magnet and hall sensor onto either the rotating elements of the cardan shaft and the other to a fixed point and including a detection element for detecting the revolution rate by correlating to the revolution and the pulse created by the hall sensor as a result of interaction between the magnet and the hall sensor, when the cardan shaft rotates.

A vehicle drive system is provided and generally includes a hub assembly, a drive assembly and a clutch assembly. The hub assembly having wheel hub upon which a wheel assembly is secured. The drive assembly is configured to selectively transmit a motive force to cause the hub to turn. The drive assembly includes a motor with a rotatable motor output shaft, a transmission assembly connected to the motor and receiving in the rotatable motor output shaft into an input opening therein, and a driveshaft connected to an output from the transmission assembly. The clutch assembly connected to the hub assembly and engagebale to the driveshaft.

A power divider unit including an input shaft, a drive gear disposed around the input shaft, an inter-axle differential assembly coupled to the input shaft, an output side gear coupled to the input shaft, and a locking system for the power divider unit. The locking system is configured to passively lock the inter-axle differential assembly. The locking system includes a ramped first clutch member in selective engagement with the drive gear, a mating second clutch member configured to engage the first clutch member, a clutch pinion, and a slip clutch assembly. The second clutch member and the first clutch member rotate at different speeds, the clutch pinion rotates and causes the slip clutch assembly and second clutch member to rotate at a speed of the input shaft, causing the first clutch member to mate with the first clutch member.

A power divider unit including an input shaft, a drive gear disposed around the input shaft, an inter-axle differential assembly coupled to the input shaft, an output side gear coupled to the input shaft, and a locking system for the power divider unit. The locking system is configured to passively lock the inter-axle differential assembly. The locking system includes a ramped first clutch member in selective engagement with the drive gear, a mating second clutch member configured to engage the first clutch member, a clutch pinion, and a slip clutch assembly. The second clutch member and the first clutch member rotate at different speeds, the clutch pinion rotates and causes the slip clutch assembly and second clutch member to rotate at a speed of the input shaft, causing the first clutch member to mate with the first clutch member.

An all-terrain vehicle including a frame having longitudinally-spaced ends defining a first longitudinal axis, and an engine supported by the frame. The engine includes a crankshaft defining a second longitudinal axis substantially parallel to the first longitudinal axis.

An all-terrain vehicle including a frame having longitudinally-spaced ends defining a first longitudinal axis, and an engine supported by the frame. The engine includes a crankshaft defining a second longitudinal axis substantially parallel to the first longitudinal axis.

An electromechanical drive arrangement for a motor vehicle includes an electromechanical main drive motor, a reduction transmission device which comprises a transmission input, a transmission output, at least one reduction stage and a transmission housing which accommodates the reduction stage, an axial differential transmission for splitting the drive power, which is guided by means of the reduction stage, between a first and a second wheel drive train section, and an auxiliary assembly which can be driven by the main drive motor by means of the reduction stage. The auxiliary assembly is arranged outside the transmission housing. A switching element is provided in the transmission housing such that the drive connection from the reduction stage to the axial differential transmission can be closed in a switchable manner and can be disconnected in a switchable manner.