Abstract: The embodiments of the printed wire board stand-off are comprised of a Printed Wire Board (“PWB”) stand-off; a PWB stand-off rail fixture; a PWB a stand-off holder; or a PWB male stand-off, or any combination thereof. The PWB stand-off is comprised of a large stand-off cylinder and an elongated stand-off cylinder. The PWB a stand-off rail fixture is comprised of two sides, a top, a set screw aperture, and a set screw. The PWB stand-off carrier is comprised of a base, a vertical post, and a handle. The PWB male stand-off is comprised of a male stand-off base, a male stand-off post, and a male thread.

Abstract: The embodiments of the Remote Video Inspection System comprise a remote video inspection hardware assembly and a video inspection software system. The remote video inspection hardware assembly is comprised of a camera and a stage assembly. The stage assembly is comprised of a horizontal gimbal, an outer gimbal, and an inner gimbal, a base plate, and a component table. The video inspection software system is comprised of both a local and remote component. The local component is operated by a technician who oversees the remote inspection, and allows for setup, manual positioning, and manual camera adjustment. The remote component is operated by an inspector, and provides video feed to them, as well as a system to control the viewing angle and position of the component/camera.

Abstract: The embodiments of the embodiments of the Nanostructure Lithium Ion Battery are comprised of a multi-layer coaxial assembly formed over a cylindrical core. The multilayers are each comprised of sublayers in order as follows: a copper sublayer with nano “chicken wire” embedded in the copper sublayer for current collection, a nanostructured aluminum substrate sublayer, a nanostructured cathode sublayer, an electrolyte sublayer, a nanostructured anode sublayer, and a copper interlayer sublayer. The nanobatteries are arranged in layered stacks of nanocells. The nanocells stacks are comprised of a plurality of individual octagonal shaped multilayer nanocells. Each nanocell stack is electrically connected to an array of other nanocells stacks via electrode contacts. A lower copper bus serves as the anode current collector and an upper copper bus serves as the cathode current collector. Pass-throughs connect to the appropriate cathode layers in the multilayer nanocell stacks.

Abstract: The embodiments of the embodiments of the Nanostructure Lithium Ion Battery are comprised of a multi-layer coaxial assembly formed over a cylindrical core. The multilayers are each comprised of sublayers in order as follows: a copper sublayer with nano “chicken wire” embedded in the copper sublayer for current collection, a nanostructured aluminum substrate sublayer, a nanostructured cathode sublayer, an electrolyte sublayer, a nanostructured anode sublayer, and a copper interlayer sublayer. The nanobatteries are arranged in layered stacks of nanocells. The nanocells stacks are comprised of a plurality of individual octagonal shaped multilayer nanocells. Each nanocell stack is electrically connected to an array of other nanocells stacks via electrode contacts. A lower copper bus serves as the anode current collector and an upper copper bus serves as the cathode current collector. Pass-throughs connect to the appropriate cathode layers in the multilayer nanocell stacks.

Abstract: The embodiments of the Remote Video Inspection System comprise a remote video inspection hardware assembly and a video inspection software system. The remote video inspection hardware assembly is comprised of a camera and a stage assembly. The stage assembly is comprised of a horizontal gimbal, an outer gimbal, and an inner gimbal, a base plate, and a component table. The video inspection software system is comprised of both a local and remote component. The local component is operated by a technician who oversees the remote inspection, and allows for setup, manual positioning, and manual camera adjustment. The remote component is operated by an inspector, and provides video feed to them, as well as a system to control the viewing angle and position of the component/camera.

Abstract: The embodiments of the embodiments of the Nanostructure Lithium Ion Battery are comprised of a multi-layer coaxial assembly formed over a cylindrical core. The multilayers are each comprised of sublayers in order as follows: a copper sublayer with nano “chicken wire” embedded in the copper sublayer for current collection, a nanostructured aluminum substrate sublayer, a nanostructured cathode sublayer, an electrolyte sublayer, a nanostructured anode sublayer, and a copper interlayer sublayer. The nanobatteries are arranged in layered stacks of nanocells. The nanocells stacks are comprised of a plurality of individual octagonal shaped multilayer nanocells. Each nanocell stack is electrically connected to an array of other nanocells stacks via electrode contacts. A lower copper bus serves as the anode current collector and an upper copper bus serves as the cathode current collector. Pass-throughs connect to the appropriate cathode layers in the multilayer nanocell stacks.

Abstract: The embodiments of the instant invention comprise a lightweight, robust electronic rack enclosure. The embodiments are comprised of an outer chassis, an inner chassis, bottom vibration isolators, and top vibration isolators. The outer chassis is comprised of an outer chassis door, two outer chassis side assemblies, an outer chassis top panel, an outer chassis bottom panel, and an outer chassis back panel. The inner chassis is comprised of two inner chassis side assemblies, an inner chassis top panel, and an inner chassis bottom panel. Each outer chassis side assembly is comprised of a flat outer chassis side panel, one or more diagonal reinforcing members, one or more horizontal reinforcing members, and one or more vertical reinforcing members. Each inner chassis side assembly is comprised of an inner chassis flat side panel, and one or more inner chassis side panel horizontal supports.

Abstract: The embodiments of the invention, a low-cost display system (MDP), consists of an operating system software, electronic circuit cards, a display module, a ruggedized housing, a control bezel, and interface connectors that can be utilized as a platform for hosting application-specific software. The application-specific software would be developed to cause the MDP to fulfill display requirements that are specific to the weapons system, vehicle or other platform into which it is to be installed. This technical approach is analogous to the iPhone (representing the MDP) and its apps (representing the application-specific software). The electronic hardware and software designs contain “hooks” that allow for the expansion of current functionality and the addition of new functionality without significant design/engineering effort. This allows customization of the MDP to meet the needs of multiple applications while maintaining a low cost.