An exterior shell for an armored cab having a longitudinal axis and a transverse axis is provided. The exterior shell has a right side panel extending parallel to the longitudinal axis, a left side panel extending parallel to the longitudinal axis, and a rear panel extending parallel to the transverse axis. A cab lower surface extends between the right side panel and the left side panel. The cab lower surface has a center tunnel extending along the longitudinal axis with an exterior curvature having a variable radius as the center tunnel extends along the transverse axis of the exterior shell. The center tunnel is configured to act as a pressure vessel in the event of an explosion beneath the armored cab.

A technique for a modular tracked vehicle that can be reconfigured as needed to address different requirements and use cases. The modular tracked vehicle includes a chassis hull that allows interchangeable components to be connected thereto. The interchangeable components include interchangeable final drives which drive the vehicle's tracks. The chassis hull stores an energy reservoir, such as a battery or fuel tank, and the final drives include at least a gear box and drive axle. Different final drives may be provided for different torque levels, speed levels, energy sources, and or other specifications, and the final drives may be swapped based on mission requirements. Other components of the modular tracked vehicle may be interchangeable, as well. The technique may be provided, for example, as a modular tracked vehicle, a platform for a modular tracked vehicle, and/or as a method for use with a modular tracked vehicle.

A torsion bar restraint system for tracked combat vehicles that aids in the improvement of occupant survival rates when associated with asymmetric threats. The blast mitigating restraint system can reduce the dynamic deflection of torsion bars based on the severity of the blast impulse as needed. Systems comprise one or more components that secure the torsion bar to the hull for protecting against dynamic deflection and lateral displacement. The two disclosed components, an end restraint device and an M-Ring restraining device, can be used in conjunction or independently from each other based on the type of threat likely to be encountered.

Architected materials with superior energy absorption properties when loaded in compression. In several embodiments such materials are formed from micro-truss structures composed of interpenetrating tubes in a volume between a first surface and a second surface. The stress-strain response of these structures, for compressive loads applied to the two surfaces, is tailored by arranging for some but not all of the tubes to extend to both surfaces, adjusting the number of layers of repeated unit cells in the structure, arranging for the nodes to be offset from alignment along lines normal to the surfaces, or including multiple interlocking micro-truss structures.

A vehicle includes a frame extending longitudinally, a front cabin coupled to the frame and configured to accept at least one occupant, and a support coupled to the frame. The vehicle is reconfigurable between an A-kit configuration and a B-kit configuration. In the A-kit configuration, a spacer extends between the frame and the support and couples the support to the frame, and an armor component is removed from between the frame and the support. In the B-kit configuration, the armor component extends between the frame and the support and couples the support to the frame, and the spacer is removed from between the frame and the support.

A vehicle includes a frame, a series of tractive assemblies coupled to the frame, a cabin, and a mount. The mount includes a boss coupled to the cabin, a first bracket pivotably coupled to the boss, a second bracket coupled to the frame, and a first isolator and a second isolator extending between the first bracket and the second bracket and coupling the first bracket to the second bracket.

An armoured vehicle undershield for a land-based armoured vehicle, comprising: an underside guard; one or more casings coupled to the underside guard; and a fibre reinforced composite material encased by the one or more casings.

A vehicle includes a frame, a cabin coupled to the frame, and a blast mat. The cabin includes a seat configured to support an occupant and a series of walls at least partially defining a footwell configured to receive a foot of the occupant when the occupant is seated in the seat. The blast mat is positioned within the footwell and configured to absorb energy from an explosion. The blast mat has a top surface and a bottom surface. The cabin defines a longitudinal axis extending parallel to a forward direction of travel of the vehicle and a lateral axis extending perpendicular to the longitudinal axis. At least a portion of the bottom surface of the blast mat engages at least one of the walls. A thickness of the blast mat varies throughout the blast mat.

The present technology regards a de-coupled V-hull structure for use with an armored vehicle, and energy absorbing crush elements suitable for mounting the V-hull structure in a de-coupled manner to the vehicle. The energy absorbing V-hull structure includes a sloped armor structure forming a cavity having a v-shaped cross-section and a plurality of reinforcing elements, including a backbone, hull stiffeners and lateral supports. The elements are coupled together and supported by energy absorber mounts, extending along each side of the structure. Crush elements suitable for decoupling the V-hull structure are also disclosed, having a uniquely designed housing, a plurality of plates positioned within the housing, and affixation means for securing the crush element to the underside of the vehicle and to the top of the V-hull structure.

A vehicle includes a frame, tractive assemblies engaging the frame, a cabin configured to contain at least one operator during operation of the vehicle, and a mount configured to pivotably couple the cabin to the frame. The mount includes a boss coupled to the cabin and defining a first aperture, a first bracket defining a second aperture, a pin extending through the first and second apertures, a second bracket coupled to the frame, and a pair of isolators extending between the first bracket and the second bracket. The isolators are configured to couple the first bracket to the second bracket and to reduce the transfer of vibrations between the frame and the cabin. The cabin is configured to rotate between use position and maintenance positions. The cabin is positioned near the frame in the use position and rotated away from the frame in the maintenance position.