An amphibious vehicle for operation in a liquid manure lagoon, the vehicle comprising: a floatable vehicle body; a ground engaging propulsion structure; a liquid manure pump for pumping liquid manure from the liquid manure lagoon; a power source for powering both the ground engaging propulsion structure and the liquid manure pump; and, a remote control structure for controlling the ground engaging propulsion structure, the liquid manure pump and the power source.

The present invention provides an apparatus, method and system for utilizing commercial cargo containers. The present invention utilizes containers made autonomous by coupling a container with a detachable propulsion system, having a motor and navigation and steering controls, permitting the rapid, controlled, efficient and safe delivery of cargo containers individually by water. Ballast units, deployment systems and control via remote units are also disclosed. The containers, utilizing their inherent buoyancy, can move autonomously according to a preplanned or remote controlled route to a specific location.

The invention is about fast installing self-propelled pontoon bridge. The pontoon bridge consists of the entrance vehicle (A-1), vehicle-floats (A-2) connecting the entrance vehicle and the exit vehicle of the bridge (A-3). The anchoring vehicle (A-4) is to moor the bridge to the river bed when installing/uninstalling the bridge. The bodies of the portions are main floats; the vehicles are designed in a way that they can both move on the ground and in the water. For parts associated with moving on the ground, the conventional axles are replaced by the wheels directly driven by hydraulic motors (1). The vehicles' structures are modified to fit new operation methods. The vehicles act as joints. The vehicles are designed for straight line connection; and, the soft connecting is carried out before entering the water. Each vehicle can cross the river by itself. Once the exit vehicle of the bridge is approaching the opposite river bank, all the vehicles are connected. Due to the novelty design, the installing/uninstalling required a person, in the cab, for each vehicle; and much less time consumed.

An amphibian (1) for use on land and water, comprising: a hull having a planing surface (2), and at least one retractable suspension apparatus (4) movable from a vehicle supporting position to a retracted position, comprising for each wheel (5), upper and lower suspension arms (8, 9) that are pivotably connected at inboard ends to a support structure within the hull; and are pivotably connected at outboard ends to a suspension upright (7). Upright (7) extends from a first, upper connection past a second, lower connection to a location (10) for a wheel hub mounting. The suspension upright when deployed in land use extends externally of the hull across a side face (2A) of the planing surface; while lower suspension arm (9) remains above the top of planing surface (2) throughout use of the amphibian on land. This suspension arrangement allows the hull to have no cutouts in its planing surface.

An apparatus for controlling an amphibious vehicle includes an engine, a land propeller generating a propulsion force on land, a water propeller generating a propulsion force on water, a power distributor distributing power to the land propeller and the water propeller, a transmission for changing a shift ratio of the power supplied to the land propeller, and a controller, wherein the controller selects and executes one of a land mode for controlling travel on land, a water mode for controlling travel on the water, and a transition mode controlling the travel in a transition region, and the controller maintains an engine output torque in the land mode to be constant and maintains an engine output speed in the water mode and the transition mode to be constant.

A method for deploying a payload at a subaquatic deployment location includes submersing a submersible aquatic vehicle in a body of water. The submersible aquatic vehicle carries a payload. The method also includes driving the submersible aquatic vehicle to a deployment location under the body of water while the submersible aquatic vehicle carries the payload in a first position. The method additionally includes at the deployment location, moving the payload from the first position to a second position. The method further includes deploying the payload from the second position to a deployment position at the deployment location.

An amphibious pumping vehicle has a floatable vehicle body, a ground engaging propulsion structure, a fluid pump, a plurality of fluid nozzles comprising a first fluid nozzle connected by a fluid conduit to the fluid pump and at least one second fluid nozzle connected to the fluid conduit, a valve structure in the fluid conduit, the plurality of fluid nozzles and the valve structure co-operating to provide directional control and motive power for the vehicle when floating, and a power source configured to provide power to both the ground engaging propulsion structure and the fluid pump.

The present invention provides an apparatus, method and system for utilizing commercial cargo containers. The present invention utilizes containers made autonomous by coupling a container with a detachable propulsion system, having a motor and navigation and steering controls, permitting the rapid, controlled, efficient and safe delivery of cargo containers individually by water. Ballast units, deployment systems and control via remote units are also disclosed. The containers, utilizing their inherent buoyancy, can move autonomously according to a preplanned or remote controlled route to a specific location.

An amphibious pumping vehicle has a floatable vehicle body, a ground engaging propulsion structure, a fluid pump, a plurality of fluid nozzles comprising a first fluid nozzle connected by a fluid conduit to the fluid pump and at least one second fluid nozzle connected to the fluid conduit, a valve structure in the fluid conduit, the plurality of fluid nozzles and the valve structure co-operating to provide directional control and motive power for the vehicle when floating, and a power source configured to provide power to both the ground engaging propulsion structure and the fluid pump.

A multi-dimensional vehicle configured for aerial and ground mobility is provided and includes a vehicle body, a plurality of vehicle wheels movably associated with the vehicle body and configurable between a ground mobility configuration and an aerial mobility configuration and a control device, wherein the control device is configured for wireless communication and is associated with the plurality of vehicle wheels to controllably operate the plurality of vehicle wheels and to controllably configure the plurality of vehicle wheels between the ground mobility configuration and the aerial mobility configuration, wherein each of the plurality of vehicle wheels include a wheel rim having an inner rim circumference and a plurality of fan blades distributed along the inner rim circumference, wherein the plurality of fan blades are configured to create a flow channel between each of the plurality of fan blades and an adjacent fan blade.