Embodiments of the present systems and apparatus may provide vehicle armor materials and systems that generate electricity from impact and blast energy. For example, in an embodiment, a protective apparatus may comprise a layer of armor and a layer comprising a plurality of electrical generating devices abutting the layer of armor and configured so that energy applied to the layer of armor is transferred to the plurality of electrical generating devices causing the plurality of electrical generating device to generate electrical energy.

Embodiments of the present systems and apparatus may provide vehicle armor materials and systems that generate electricity from impact and blast energy. For example, in an embodiment, a protective apparatus may comprise a layer of armor and a layer comprising a plurality of electrical generating devices abutting the layer of armor and configured so that energy applied to the layer of armor is transferred to the plurality of electrical generating devices causing the plurality of electrical generating device to generate electrical energy.

An kinetic object protection system for protecting a space in a building or vehicle from a threat, the system including a plurality of smart devices at least one of which is connected to a remote server, the system for protecting the space by deploying a protective barrier including one or more sheets having a lightweight, flexible, ballistic resistant material, such as woven sheets, nets, or mesh. A plurality of sheets may be laminated together by using a glue, heat weld, or stitching or some other laminating process. The system includes an automated control system operably configured to, upon detection of the threat, cause a change in state of the barrier from a retracted state to a protective deployed state. The barriers are adapted to be resistant to penetration by the kinetic objects such as vehicles, moving persons, bullets, or shrapnel, for example.

An kinetic object protection system for protecting a space in a building or vehicle from a threat, the system including a plurality of smart devices at least one of which is connected to a remote server, the system for protecting the space by deploying a protective barrier including one or more sheets having a lightweight, flexible, ballistic resistant material, such as woven sheets, nets, or mesh. A plurality of sheets may be laminated together by using a glue, heat weld, or stitching or some other laminating process. The system includes an automated control system operably configured to, upon detection of the threat, cause a change in state of the barrier from a retracted state to a protective deployed state. The barriers are adapted to be resistant to penetration by the kinetic objects such as vehicles, moving persons, bullets, or shrapnel, for example.

An kinetic object protection system for protecting a space in a building or vehicle comprising a protective barrier including one or more sheets of a laminated material having a plurality of layers of lightweight, flexible, ballistic resistant material such as woven sheets, nets, or mesh which are secured together using a glue, heat weld, or stitching. The system may include an automated control system operably configured to cause a change in state of the barrier from a retracted state to a protective deployed state, which may include a sensing system operably configured to detect a threatening event, wherein the sensing system upon sensing the threatening event triggers the barrier to transition from the retracted state to the deployed protective state such that in the protective state, the barriers are adapted to be resistant to penetration by the kinetic objects such as vehicles.

An kinetic object protection system for protecting a space in a building or vehicle comprising a protective barrier including one or more sheets of a laminated material having a plurality of layers of lightweight, flexible, ballistic resistant material such as woven sheets, nets, or mesh which are secured together using a glue, heat weld, or stitching. The system may include an automated control system operably configured to cause a change in state of the barrier from a retracted state to a protective deployed state, which may include a sensing system operably configured to detect a threatening event, wherein the sensing system upon sensing the threatening event triggers the barrier to transition from the retracted state to the deployed protective state such that in the protective state, the barriers are adapted to be resistant to penetration by the kinetic objects such as vehicles.

A supercapacitor-like device is described that uses a porous, conductive foam as the electrodes. After the device is charged, an explosive wave front can be used to remove electrolyte from the metal foam. This creates a large net charge on each electrode, which will readily flow through a load placed across the electrodes. The removal of charge can potentially occur on a time scale of microseconds, allowing a supercapacitor to be used in pulsed power applications. The creation of this net charge requires significant energy, meaning this concept may also be suitable for removing kinetic energy from objects.

A supercapacitor-like device is described that uses a porous, conductive foam as the electrodes. After the device is charged, an explosive wave front can be used to remove electrolyte from the metal foam. This creates a large net charge on each electrode, which will readily flow through a load placed across the electrodes. The removal of charge can potentially occur on a time scale of microseconds, allowing a supercapacitor to be used in pulsed power applications. The creation of this net charge requires significant energy, meaning this concept may also be suitable for removing kinetic energy from objects.

Armor for protection against projectiles, shrapnel, blades, and other penetrants has an inner container subdivided into cells, with the cells being filled with a slurry made of dilatant (shear-thickening fluid) and hard particles. The opposing outer surfaces of the container are shielded by ballistic fabric layers and hard outer plates, with the container, fabric layers, and plates then preferably being bound together by an outer envelope. The various layers of the armor cooperate to provide high protection against penetrants, while at the same time providing lightweight and easily repairable armor suitable for cladding of personnel, vehicles, buildings, and other structures.

Armor for protection against projectiles, shrapnel, blades, and other penetrants has an inner container subdivided into cells, with the cells being filled with a slurry made of dilatant (shear-thickening fluid) and hard particles. The opposing outer surfaces of the container are shielded by ballistic fabric layers and hard outer plates, with the container, fabric layers, and plates then preferably being bound together by an outer envelope. The various layers of the armor cooperate to provide high protection against penetrants, while at the same time providing lightweight and easily repairable armor suitable for cladding of personnel, vehicles, buildings, and other structures.