Abstract: A system for collecting debris includes a collector configured to accumulate debris and retain an electrostatic charge; a deployment mechanism configured to move the collector into a path of the debris; an electrostatic charging array comprising one or more wires or plates operatively connected to the collector; and one or more processors operatively coupled to the collector, the deployment mechanism, and the electrostatic charging array. The one or more processors are configured to track debris in relation to the collector; control movement of the collector and the deployment mechanism; and regulate power to the electrostatic charging array.

Abstract: A robotic system with an arm assembly that includes: a pedestal, a first member operatively coupled to an opposing end of the pedestal, and a second member operatively coupled to an opposing end of the first member. The robotic system further includes a joint operatively coupled to an opposing end of the second member and at least one phalange assembly operatively coupled to the joint. The at least one phalange assembly includes: a third member operatively coupled to the joint, a fourth member operatively coupled to an opposing end of the third member, and a fifth member operatively coupled to an opposing end of the fourth member. The robotic system further includes an interchangeable manipulator is operatively coupled to the opposing end of the fifth member.

Abstract: A device for applying a layer of material within a thin-walled pressure vessel may include one or more maneuvering actuators configured to direct the device within the thin-walled pressure vessel, an applicator operatively coupled to the one or more maneuvering actuators, and a controller operatively coupled to the one or more maneuvering actuators and the applicator, the controller is configured to control the one or more maneuvering actuators and the applicator. The applicator may include an expander configured to apply pressure along a portion of an inner wall of the thin-walled pressure vessel, a receptacle configured to secure the material to the device and position the material along the inner wall of the thin-walled pressure vessel, and a bonder configured to bond the material along the inner wall of the thin-walled pressure vessel.

Abstract: A device for applying a layer of material within a thin-walled pressure vessel may include one or more maneuvering actuators configured to direct the device within the thin-walled pressure vessel, an applicator operatively coupled to the one or more maneuvering actuators, and a controller operatively coupled to the one or more maneuvering actuators and the applicator, the controller is configured to control the one or more maneuvering actuators and the applicator. The applicator may include an expander configured to apply pressure along a portion of an inner wall of the thin-walled pressure vessel, a receptacle configured to secure the material to the device and position the material along the inner wall of the thin-walled pressure vessel, and a bonder configured to bond the material along the inner wall of the thin-walled pressure vessel.

Abstract: A support structure of a 3D printer may include a printable surface that receives a heated bead of material and can support one or more extruded layers of material from the 3D printer. The support structure may include at least one inlet adjacent to the printable surface and one or more outlets that exit onto the printable surface. The one or more outlets are hermetically sealed to the inlet. The support structure may also include an injection mechanism operatively coupled to the at least one input.

Abstract: A printer system may include a coaxial extruder head that extrudes a core, a bulk, and/or a core and bulk cladding to form complex structures without retooling. The coaxial extruder head may include a distribution channel with an entrance and an exit, a priming chamber that surrounds the distribution channel. The priming chamber may include an outlet and a first inlet, a heating element thermally connected to the priming chamber, and a nozzle connected to the outlet of the priming chamber. Further, the nozzle may converge from the outlet of the priming chamber to an orifice of the nozzle. In addition, the exit of the distribution channel may be disposed at the orifice of the nozzle. This structure facilitates extruding a core and cladding type composite from the extruder head.

Abstract: A technique for a dielectric lens and an antenna assembly. The dielectric lens that includes a for a reference surface and a pattern of varying thicknesses made from a first dielectric. The pattern of varying thicknesses is situated on the reference surface. The thickness differences between adjacent formations of the pattern of varying thicknesses is less than an incident wavelength of electromagnetic energy. The antenna includes mounting fixture, the dielectric lens connected to the mounting fixture, and a transceiver operatively coupled to the mounting fixture. The transceiver is configured to transmit an electromagnetic signal directed to the dielectric lens.

Abstract: A lens and antenna assembly technique that includes a first bladder that is configured to be filled with a first fluid and the first fluid having a first index of refraction. The technique further includes a second bladder nested within the first bladder. The second bladder is configured to be filled with a second fluid and the second fluid has a second index of refraction. This technique is for deploying an inflatable lens that includes inflating a first bladder with a first fluid and inflating a second bladder with a second fluid. The second bladder is nested within the first bladder. The technique for deploying an inflatable lens further includes replacing the first fluid with a third fluid and replacing the second fluid with a fourth fluid.

Abstract: A printer system may include a coaxial extruder head that extrudes a core, a bulk, and/or a core and bulk cladding to form complex structures without retooling. The coaxial extruder head may include a distribution channel with an entrance and an exit, a priming chamber that surrounds the distribution channel. The priming chamber may include an outlet and a first inlet, a heating element thermally connected to the priming chamber, and a nozzle connected to the outlet of the priming chamber. Further, the nozzle may converge from the outlet of the priming chamber to an orifice of the nozzle. In addition, the exit of the distribution channel may be disposed at the orifice of the nozzle. This structure facilitates extruding a core and cladding type composite from the extruder head.

Abstract: A robotic system with an arm assembly that includes: a pedestal, a first member operatively coupled to an opposing end of the pedestal, and a second member operatively coupled to an opposing end of the first member. The robotic system further includes a joint operatively coupled to an opposing end of the second member and at least one phalange assembly operatively coupled to the joint. The at least one phalange assembly includes: a third member operatively coupled to the joint, a fourth member operatively coupled to an opposing end of the third member, and a fifth member operatively coupled to an opposing end of the fourth member. The robotic system further includes an interchangeable manipulator is operatively coupled to the opposing end of the fifth member.

Abstract: A printer system may include a coaxial extruder head that extrudes a core, a bulk, and/or a core and bulk cladding to form complex structures without retooling. The coaxial extruder head may include a distribution channel with an entrance and an exit, a priming chamber that surrounds the distribution channel. The priming chamber may include an outlet and a first inlet, a heating element thermally connected to the priming chamber, and a nozzle connected to the outlet of the priming chamber. Further, the nozzle may converge from the outlet of the priming chamber to an orifice of the nozzle. In addition, the exit of the distribution channel may be disposed at the orifice of the nozzle. This structure facilitates extruding a core and cladding type composite from the extruder head.

Abstract: A printer system may include a coaxial extruder head that extrudes a core, a bulk, and/or a core and bulk cladding to form complex structures without retooling. The coaxial extruder head may include a distribution channel with an entrance and an exit, a priming chamber that surrounds the distribution channel. The priming chamber may include an outlet and a first inlet, a heating element thermally connected to the priming chamber, and a nozzle connected to the outlet of the priming chamber. Further, the nozzle may converge from the outlet of the priming chamber to an orifice of the nozzle. In addition, the exit of the distribution channel may be disposed at the orifice of the nozzle. This structure facilitates extruding a core and cladding type composite from the extruder head.

Abstract: A lens and antenna assembly technique that includes a first bladder that is configured to be filled with a first fluid and the first fluid having a first index of refraction. The technique further includes a second bladder nested within the first bladder. The second bladder is configured to be filled with a second fluid and the second fluid has a second index of refraction. This technique is for deploying an inflatable lens that includes inflating a first bladder with a first fluid and inflating a second bladder with a second fluid. The second bladder is nested within the first bladder. The technique for deploying an inflatable lens further includes replacing the first fluid with a third fluid and replacing the second fluid with a fourth fluid.

Abstract: A technique for a dielectric lens and an antenna assembly. The dielectric lens that includes a for a reference surface and a pattern of varying thicknesses made from a first dielectric. The pattern of varying thicknesses is situated on the reference surface. The thickness differences between adjacent formations of the pattern of varying thicknesses is less than an incident wavelength of electromagnetic energy. The antenna includes mounting fixture, the dielectric lens connected to the mounting fixture, and a transceiver operatively coupled to the mounting fixture. The transceiver is configured to transmit an electromagnetic signal directed to the dielectric lens.

Abstract: A printer system may include a coaxial extruder head that extrudes a core, a bulk, and/or a core and bulk cladding to form complex structures without retooling. The coaxial extruder head may include a distribution channel with an entrance and an exit, a priming chamber that surrounds the distribution channel. The priming chamber may include an outlet and a first inlet, a heating element thermally connected to the priming chamber, and a nozzle connected to the outlet of the priming chamber. Further, the nozzle may converge from the outlet of the priming chamber to an orifice of the nozzle. In addition, the exit of the distribution channel may be disposed at the orifice of the nozzle. This structure facilitates extruding a core and cladding type composite from the extruder head.

Abstract: A printer system may include a coaxial extruder head that extrudes a core, a bulk, and/or a core and bulk cladding to form complex structures without retooling. The coaxial extruder head may include a distribution channel with an entrance and an exit, a priming chamber that surrounds the distribution channel. The priming chamber may include an outlet and a first inlet, a heating element thermally connected to the priming chamber, and a nozzle connected to the outlet of the priming chamber. Further, the nozzle may converge from the outlet of the priming chamber to an orifice of the nozzle. In addition, the exit of the distribution channel may be disposed at the orifice of the nozzle. This structure facilitates extruding a core and cladding type composite from the extruder head.

Abstract: A printer system may include a coaxial extruder head that extrudes a core, a bulk, and/or a core and bulk cladding to form complex structures without retooling. The coaxial extruder head may include a distribution channel with an entrance and an exit, a priming chamber that surrounds the distribution channel. The priming chamber may include an outlet and a first inlet, a heating element thermally connected to the priming chamber, and a nozzle connected to the outlet of the priming chamber. Further, the nozzle may converge from the outlet of the priming chamber to an orifice of the nozzle. In addition, the exit of the distribution channel may be disposed at the orifice of the nozzle. This structure facilitates extruding a core and cladding type composite from the extruder head.

Abstract: A carrier for releasably securing an object, such as an ammunition magazine, a PDA, a mobile phone, an MP3 player, and the like, having a latching pin and an opposed biasing member. The latching pin is positioned on an interior wall of the housing of the carrier to mate with a corresponding aperture or the like formed on the interior surface of an object when the object is inserted in the carrier, to enable rapid insertion of the object into the carrier, to provide secure retention of the object in the carrier, and to enable the rapid and easy retrieval of the object from the carrier.