A human powered watercraft or land vehicle is described herein. A watercraft or land vehicle may have two pedals that reciprocated are in a linear or slightly curved trajectory but not a circular motion. As the two pedals are reciprocated, an output shaft is rotated in either a clockwise or counterclockwise direction when the left pedal is pushed forward or when the right pedal is pushed forward. The output shaft may be connected to a propeller of a watercraft or a land vehicle so as to propel the watercraft or land vehicle forward. The output shaft may receive rotational input through two gears mounted to the output shaft with one-way bearings that enable the output shaft to rotate in the same direction regardless of whether the left pedal or the right pedal is being pushed forward.

A vehicle includes: a power source; a first drive device configured to be driven by an output of the power source; a second drive device configured to be driven by the output of the power source; a non-stage transmission device capable of continuously changing a rotation speed which is transmitted to an input shaft of the second drive device; a power distribution device coupled to an output shaft of the power source, coupled to an input shaft of the first drive device and an input shaft of the non-stage transmission device, and configured to be capable of distributing the output of the power source to the first drive device and the second drive device in a state where the output shaft of the power source is coupled to the input shaft of the first drive device and the input shaft of the non-stage transmission device at respective predetermined fixed reduction ratios; a first instruction device configured to output a first instruction value related to a rotation speed of the input shaft of the first drive device; a second instruction device configured to output a second instruction value related to a torque of the input shaft of the second drive device; and a control device configured to be capable of controlling the output of the power source and a transmission ratio of the non-stage transmission device. The control device includes: an output control part configured to control an output of the power source in accordance with the first instruction value outputted from the first instruction device; and a transmission control part configured to control the transmission ratio of the non-stage transmission device in accordance with the second instruction value outputted from the second instruction device.

A crayfish or crawfish harvesting apparatus employs an improved drive that uses hydraulic wheels (e.g., rubber tired wheels) encircled by one or more endless belts. One or more hydraulic motor drives can be used to drive the wheels. Lugs or guide lugs are placed on opposing sides of each wheel and are preferably connected to the belt. Fasteners (e.g., bolts or rivets) attach cleats (e.g., steel u-shaped channel cleats) to the belts and lugs.

A shock absorbing system of an amphibious and remotely controlled vehicle is provided, including a chassis, a controller, a transmission shaft, six transmission members, a front wheel driving mechanism, a rear wheel driving mechanism and a smart electronic device. When the smart electronic device transmits a first control message, the controller drives the transmission shaft to pivot toward a first direction, the transmission shaft leads the six transmission members to pivot and the controller and the chassis move away from the casing of the remotely controlled vehicle. When the smart electronic device transmits a second control message, the controller drives the transmission shaft to pivot toward a second direction, the transmission shaft leads the six transmission members to pivot and the controller and the chassis move toward the casing of the remotely controlled vehicle.

An amphibious vehicle power train having an engine (2) with an output shaft (4), driving an input member (6) of a variable speed change transmission (11). The speed change transmission, which may be a continuously variable transmission is arranged to drive road wheels through an output member (8). The engine also drives a marine propulsion unit (24). The axis of the output member (8) is above the axis of the input member (6). Four wheel drive may be provided (FIG. 2).

An amphibious vehicle power train having an engine (2) with an output shaft (4), driving an input member (6) of a variable speed change transmission (11). The speed change transmission, which may be a continuously variable transmission is arranged to drive road wheels through an output member (8). The engine also drives a marine propulsion unit (24). The axis of the output member (8) is above the axis of the input member (6). Four wheel drive may be provided (FIG. 2).

Disclosed is a vehicle with only two parallel independent drive wheels, capable of moving on a solid or semi-solid ground, as well as on water if provided with blades on the wheels. The vehicle is stable in that it has a unit for lowering the center of gravity, which are housed in the wheels, which are in turn internally hollow for this purpose.

An amphibious vehicle comprises a buoyant hull, a boat motor affixed to the hull to propel the amphibious vehicle in water, two or more powered wheel assemblies affixed to the hull to propel the amphibious vehicle on land, and two or more selectively rotatable arms affixing each wheel assembly to the hull. One or more of the wheel assemblies are affixed to opposing sides of the hull. Two or more selectively rotatable arms affix each wheel assembly to the hull. The arms affixing each respective wheel assembly are selectively rotatable in unison to move the respective wheel assembly between a lowered position and a raised position.

A fast installing self-propelled pontoon bridge consisting of the entrance vehicle (A-1), a vehicle-float which is connected with the entrance vehicle and an exit vehicle, an exit vehicle, and an anchoring vehicle to keep the bridge in one place, being equipped with an anchor to keep the pontoon bridge to resist the water flow.

A propeller switching system of an amphibious and remotely controlled car is provided, including a controller, a transmission mechanism, a propeller mechanism, and a wheel driving mechanism. When an intelligent electronic device transmits an operation message and a first control message to the controller, a propeller rotates. When the intelligent electronic device transmits the operation message and a second control message to the controller, the wheels of the amphibious and remotely controlled car rotate.