An apparatus for installing a land anchor of a foundation in an earthen surface includes an articulated arm assembly including a first linear actuator and a drill configured to releasably couple to a helical member, and a control system coupled to the articulated arm assembly and configured to operate the first linear actuator in a free-floating mode configured to maintain an installation angle between the drill and the earthen surface as the helical member is drilled into the earthen surface.

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.

A foot for a drilling device includes a foot frame and a plurality of louver assemblies attached to the foot frame. Each louver assembly includes a louver that is at a first position when the foot is on a surface and that is movable toward a second position to facilitate release of the foot from the surface.

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.

The present invention provides, with reference to FIG. 1, a power train for an amphibian operable in land and marine modes. The power train comprises a prime mover, a first land propulsion device, a first marine propulsion device and a speed change transmission. The prime mover is arranged to drive the first land propulsion device through/via the speed change transmission in land mode. The prime mover, or at least a portion thereof, is located between the speed change transmission and a rearward most part of the amphibian, with the speed change transmission located spaced ahead of, in front of, the prime mover.

A large-scale, high-mobility all-terrain vehicle is equipped with at least two articulated front legs and at least two articulated rear legs. Each articulated leg is connected to the vehicle structure about two mutually orthogonal axes to allow a variation of the track width distance between each pair of track assemblies and a variation of the height of the vehicle structure with respect to each track assembly. Each track assembly is connected to the respective leg about a horizontal transverse axis and about a vertical axis, and about a longitudinal axis. The vehicle structure has a front module and a rear module articulated about a longitudinal axis and a driving cabin that can be rotated downwards to allow ample visibility of the ground in front. The track assemblies are connected to the respective articulated legs by quick coupling devices.

An amphibious platform vehicle-vessel to support and to move hydraulically operated and controlled earth-moving and lifting equipment, such as excavators and cranes, on solid ground, semi-solid or marshy ground, shallow water, and deeper water. The modular units can be transported to a worksite on separate trailers and assembled and reconfigured on site. Two compartmented pontoon units are mounted to an adaptive cross member that can accommodate different types of moving-lifting equipment through different mounting flanges, and to auxiliary cross members. Propulsion is provided through amphibious cleats on drive chains in chain tracks driven by dual-motor driving drums and over a tension-adjusting passive chain roller, surrounding a sealed pontoon shell internally reinforced with bulkhead partitions, beam shell-bottom stiffeners, and pressed-angle shell-bottom stiffeners. An extendable auxiliary float can be extended outward from each compartmented pontoon for increased stability in floating operations. Spud units having a chain-drive spud and a spud-driving mount unit with spud-mount wear strips are hydraulically raised and lowered by a spud-driver motor at the command of the equipment operator using a spud-control switch.

An apparatus for installing a land anchor of a foundation in an earthen surface includes an articulated arm assembly including a first linear actuator and a drill configured to releasably couple to a helical member, and a control system coupled to the articulated arm assembly and configured to operate the first linear actuator in a free-floating mode configured to maintain an installation angle between the drill and the earthen surface as the helical member is drilled into the earthen surface.

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).

The present invention relates to an amphibious vehicle comprising a vehicle frame and a cab supported by said vehicle frame, said cab being connected to said vehicle frame via hinge means so as to allow tilting of said cab about said hinge means between a closed position and an open position, wherein said vehicle comprises a sealing arrangement comprising sealing means arranged to provide liquid tight sealing between the cab and the vehicle frame in said closed position, wherein in the closed position, the sealing arrangement is arranged to provide a confined space for protecting components of said vehicle enclosed inside said space.