A drivetrain system for a reverse trike configured to transmit power from the motor to the rear wheel includes a first and a second drive chain being the only two drive chains utilized. A jackshaft has at one end a first universal joint connected to a first jackshaft sprocket and at an opposite end has a second universal joint connected to a second jackshaft sprocket. The first drive chain is connected between the motor output sprocket and the first jackshaft sprocket. The second drive chain is connected between the second jackshaft sprocket and the rear wheel drive sprocket. The first jackshaft sprocket is rotatably attached to the frame and configured to be movable away from and towards the motor output sprocket. The second jackshaft sprocket is rotatably attached to the frame and configured to be movable away from and towards the rear wheel drive sprocket.

A bicycle has a bicycle body, a bicycle component, and a battery. The bicycle body has a frame including a down tube, a component mounting portion, and a seat tube. The bicycle component includes a bicycle drive unit. At least a portion of the bicycle component is arranged inside the frame. The battery is mounted on the bicycle to supply the bicycle component with electrical power. The frame further includes a first open portion that is provided on the component mounting portion and opens toward an upper side of the bicycle. At least a portion of the bicycle drive unit is disposed inside the frame and is exposed through the first open portion.

A bicycle has a bicycle body, a bicycle component, and a battery. The bicycle body has a frame including a down tube, a component mounting portion, and a seat tube. The bicycle component includes a bicycle drive unit. At least a portion of the bicycle component is arranged inside the frame. The battery is mounted on the bicycle to supply the bicycle component with electrical power. The frame further includes a first open portion that is provided on the component mounting portion and opens toward an upper side of the bicycle. At least a portion of the bicycle drive unit is disposed inside the frame and is exposed through the first open portion.

Disclosed is a continuous variable transmission drive system for providing automatic continuously variable transmission for driving wheels of a vehicle. The vehicle includes wheels and either pedals or a motor. The continuous variable transmission drive system includes a drive shaft, a drive wheel, a drive disk, a sensor, a jack mechanism and a transmission unit. The drive shaft having a first end to receive a rotational force and a second end is connected to the drive wheel and moves along the drive shaft. The drive disk receives the power of the drive shaft from the drive wheel. The sensor for measuring compression force between the drive disk and the drive wheel. The jack mechanism applies variable compression force to control friction between the drive disk and the drive wheel. The transmission unit moves the drive wheel along the drive shaft, and changes ratio of angular velocity between the drive wheel and the drive disk to provide continuously variable transmission.

Disclosed is a continuous variable transmission drive system for providing automatic continuously variable transmission for driving wheels of a vehicle. The vehicle includes wheels and either pedals or a motor. The continuous variable transmission drive system includes a drive shaft, a drive wheel, a drive disk, a sensor, a jack mechanism and a transmission unit. The drive shaft having a first end to receive a rotational force and a second end is connected to the drive wheel and moves along the drive shaft. The drive disk receives the power of the drive shaft from the drive wheel. The sensor for measuring compression force between the drive disk and the drive wheel. The jack mechanism applies variable compression force to control friction between the drive disk and the drive wheel. The transmission unit moves the drive wheel along the drive shaft, and changes ratio of angular velocity between the drive wheel and the drive disk to provide continuously variable transmission.

A method and system for assembling a vehicle of a family of vehicles includes providing a group of engines. A first engine including a first number of cylinders corresponds to a first vehicle. A second engine including a second number of cylinders corresponds to a second vehicle. The second number is greater than the first number which is at least one. A cylinder plane extends vertically and longitudinally. At least one cylinder is disposed at least partly forward of a front wheel plane. The transmission assembly is rearward of the selected engine and one of the transmission assembly and the selected engine is in a same location whether the selected engine is the first or the second. The seat is at least in part longitudinally rearward of the transmission assembly. The selected engine is laterally disposed between the centers of the footrests.

A bicycle drive system includes a front face gear, a rear face gear, a drive shaft, and a front roller-toothed gear assembly coupled to the first end of the drive shaft, and a rear roller-toothed gear assembly coupled to the second end of the drive shaft. Both the front roller-toothed gear assembly and the rear roller-toothed gear assembly include one or more roller elements. The roller-toothed gear assemblies are advantageous in ensuring the bicycle drive system is highly efficient, and is only minimally or not at all affected by dirt, water, contaminants, or other foreign matter typically experienced in un-clean riding conditions.

A bicycle drive system includes a front face gear, a rear face gear, a drive shaft, and a front roller-toothed gear assembly coupled to the first end of the drive shaft, and a rear roller-toothed gear assembly coupled to the second end of the drive shaft. Both the front roller-toothed gear assembly and the rear roller-toothed gear assembly include one or more roller elements. The roller-toothed gear assemblies are advantageous in ensuring the bicycle drive system is highly efficient, and is only minimally or not at all affected by dirt, water, contaminants, or other foreign matter typically experienced in un-clean riding conditions.

A dual powered propulsion system for use with a human powered vehicle is provided. The system includes a connecting rod with a front end operatively coupled to yoke-connected forearm bars. The system also includes a splitter coupled to a rear end of the connecting rod, wherein the splitter is coupled to a first rack and a second rack that operate with a first and second pinion gear to turn a crank axle. This system supplies rotational power to the crank axle in a single rotational direction as the connecting rod is oscillated up and down and back and forth. Even though a solid connecting rod is used to transfer power from the oscillating forearm bars to the crank axle, the vehicle is steerable to the right or left as a result of the use of a carriage, on rollers, and a turning track operatively connected to the forearm bars.

A dual powered propulsion system for use with a human powered vehicle is provided. The system includes a connecting rod with a front end operatively coupled to yoke-connected forearm bars. The system also includes a splitter coupled to a rear end of the connecting rod, wherein the splitter is coupled to a first rack and a second rack that operate with a first and second pinion gear to turn a crank axle. This system supplies rotational power to the crank axle in a single rotational direction as the connecting rod is oscillated up and down and back and forth. Even though a solid connecting rod is used to transfer power from the oscillating forearm bars to the crank axle, the vehicle is steerable to the right or left as a result of the use of a carriage, on rollers, and a turning track operatively connected to the forearm bars.