This cooling device for an amphibious vehicle includes: a heat exchanger mounted in the amphibious vehicle; a coolant introduction passage through which cooling air or cooling water can be introduced from the outside to the heat exchanger as a coolant; a cooling air discharge passage through which the cooling air having passed through the heat exchanger can be discharged to a cooling air discharge portion communicating with the outside; and a cooling water discharge passage through which the cooling water having passed through the heat exchanger can be discharged to a cooling water discharge portion communicating with the outside. The cooling air discharge passage and the cooling water discharge passage are formed such that at least the cooling air discharge portion and the cooling water discharge portion are independent of each other.

A chassis system of an amphibious remote control vehicle is provided, including a vehicle chassis and a hull form chassis, the vehicle chassis comprises a first joint portion and a second joint portion. The width of one end of the hull form chassis is smaller than that of one other end of the hull form chassis, the hull form chassis comprises a third joint portion being corresponding to the first joint portion and two fourth joint portions being corresponding to the second joint portion. The hull form chassis comprises a hull form chassis centerline, the hull form chassis centerline extends obliquely to two sides to form two inclined surfaces, the first joint portion is engaged with the third joint portion, and the second joint portion and the two fourth joint portion are combined by a fixing member.

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 electronic device transmits an operation message and a first control message to the controller, a propeller rotates. When the electronic device transmits the operation message and a second control message to the controller, the wheels of the amphibious and remotely controlled car rotate.

An amphibian includes a planing hull, first and second sides, at least one retractable wheel, at least one prime mover, at least one steerable wheel which is connected to a steering control device operable by a driver to steer the amphibian, wherein the steering control device includes at least one of handlebars, a steering wheel, and steering levers, and is positioned to be grasped by an operator while operating the amphibian and wherein the steering control device is moveable between at least two distinct laterally spaced positions across a width of the amphibian between a center line and the respective sides of the planing hull.

The present invention provides a power train for an amphibian operable in land and marine modes. The power train including a prime mover, a first land propulsion device, a first marine propulsion device, and a speed change transmission, wherein the prime mover is arranged to drive the first land propulsion device via the speed change transmission in land mode, and at least a portion of the prime mover is located between the speed change transmission and a rearward most part of the amphibian, with the speed change transmission located spaced ahead of the prime mover by a selected distance using one or more drive shaft(s).

An amphibious vehicle includes a vehicle body, a prime mover, a drive wheel, a water propulsion device, a drive wheel transmission, and a propulsion transmission. The drive wheel is disposed on a front side of the prime mover. The water propulsion device is disposed on a rear side of the prime mover. The drive wheel transmission is disposed on the front side of the prime mover and transmits power from the prime mover to the drive wheel. The propulsion transmission is disposed on the rear side of the prime mover and transmits the power from the prime mover to the water propulsion device.

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.

A chassis system of an amphibious remote control vehicle is provided, including a vehicle chassis and a hull form chassis, the vehicle chassis comprises a first joint portion and a second joint portion. The width of one end of the hull form chassis is smaller than that of one other end of the hull form chassis, the hull form chassis comprises a third joint portion being corresponding to the first joint portion and two fourth joint portions being corresponding to the second joint portion. The hull form chassis comprises a hull form chassis centerline, the hull form chassis centerline extends obliquely to two sides to form two inclined surfaces, the first joint portion is engaged with the third joint portion, and the second joint portion and the two fourth joint portion are combined by a fixing member.

A power train for an amphibian operable in land and marine modes includes a prime mover having an integral speed change transmission, at least a first land propulsion unit, at least a first marine propulsion unit, and a power transmission unit including a drive member configured to couple the prime mover to the at least first marine propulsion unit, wherein the prime mover is arranged to drive the at least first land propulsion unit through/via the integral speed change transmission in the land mode, and the prime mover is arranged to drive the at least first marine propulsion unit through/via the power transmission unit in both the marine mode and the land mode.

A two wheeled planing amphibian (10) has a hull (20), bow (24), front wheel (30) and rear wheel (40). Front suspension (32) and rear suspension (42) are retractable, separately or simultaneously. Front wheel (30) may retract vertically or rotationally. Steering is by handlebars (50), link (54), and forks (36). Front wheel (20) may be located outside the hull in both protracted and retracted positions. The underside of hull (20) may be continuous in both land mode and marine mode along and across its centreline from the bow to the rearmost underside point on the hull along the centreline; or from the forwardmost underside point on the hull when it is planing at its lowest speed to the rear. There may be no wheel closures attached to the hull. A wheel bay (22), which is open at its top side, may be provided to allow rear wheel retraction.