A boat comprising a hull, a steering wheel, an engine power system comprising a first foot pedal that is operated by a user's foot to control the boat's speed through water, and a braking system comprising a second foot pedal that is depressed by the user's foot to slow or stop the boat.

A towable boat comprising a hull, a front wheel movable between an extended position and a retracted boating position, two rear wheels, each of which is movable between an extended towing position and a retracted boating position, and a trailer tongue movable between an extended towing position and a retracted boating position.

The present invention is an amphibious all-terrain vehicle. This amphibious all-terrain vehicle includes a boat-shaped hull and a continuous track system that is configured to provide propulsion at multiple speeds while in water. The amphibious all-terrain vehicle includes a drive train, a suspension system having one or more tracks, an operator's station, and one or more handle bars as a steering system.

An amphibious vehicle such as a tug boat, comprising a running gear configured to be at least positioned in a deployed position suited to the rolling of the vehicle, and at least one retracted position suited to the navigation of the vehicle. The running gear comprises a fairing element rigidly connected to the running gear, so that the fairing element advantageously serves as an anti-projection device in the deployed position of the running gear. According to one option, the vehicle comprises a semi-rigid shell.

Provided herein are a suspension apparatus and a specialized vehicle including the same. The suspension apparatus includes a crankshaft fixed to a vehicle body, a housing rotatably connected to the crankshaft, a first damping portion arranged in the housing and having a damping fluid accommodated in the first damping portion, an amount of the damping fluid in the first damping portion being adjusted according to an external force applied to the vehicle body, a second damping portion arranged in the housing, connected to the first damping portion such that the damping fluid moves between the first damping portion and the second damping portion, and including: a first space accommodating a compressed gas; and a second space accommodating the damping fluid, the first space facing the second space; and a rotational force applier arranged in the housing and configured to apply a rotational force to the housing by adjusting an amount of a working fluid in the rotational force applier.

Provided herein are a suspension apparatus and a specialized vehicle including the same. The suspension apparatus includes a crankshaft fixed to a vehicle body, a housing rotatably connected to the crankshaft, a first damping portion arranged in the housing and having a damping fluid accommodated in the first damping portion, an amount of the damping fluid in the first damping portion being adjusted according to an external force applied to the vehicle body, a second damping portion arranged in the housing, connected to the first damping portion such that the damping fluid moves between the first damping portion and the second damping portion, and including: a first space accommodating a compressed gas; and a second space accommodating the damping fluid, the first space facing the second space; and a rotational force applier arranged in the housing and configured to apply a rotational force to the housing by adjusting an amount of a working fluid in the rotational force applier.

A power train for an amphibian operable in land and marine modes includes a prime mover, at least a first land propulsion unit, a first marine propulsion unit, a second marine propulsion unit, and at least one speed change transmission. The prime mover is arranged to drive the at least first land propulsion unit through/via the at least one speed change transmission in land mode, and the prime mover is arranged to drive the first marine propulsion unit and the second marine propulsion unit through/via the at least one, or another, or combinations of, speed change transmission in marine mode. In addition, the present invention provides an amphibian comprising the power train.

An amphibious motorcycle with a hull that provides desirable buoyancy for the vehicle to float while in the water and yet allows the vehicle to lean/turn during use on land is provided. The amphibious motorcycle has a front wheel with a front suspension system and a rear wheel with a rear suspension system. Also included can be at least one wheel retraction system that is operable to move the front wheel and/or the rear wheel between a deployed position for use of the amphibious motorcycle on land and a retracted position for use of the amphibious motorcycle on or in the water. The amphibious motorcycle also has a hull that can have a center portion with a center bow and two oppositely disposed and spaced apart side portions each with a side bow.

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.

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).