Abstract: Recycling devices for producing additive manufacturing filament from received materials including objects to be recycled, discarded objects, obsolete objects, and the like. A recycling device may include a material processing system an extrusion mechanism and a spooling assembly. The material processing system receives material, reduces the size of the received material via a material size reducer and actively pushes the material through at least a portion of the device. The extrusion mechanism produces filament from the material and the spooling assembly loads the filament onto a spool for later use. The spooling assembly may include detachable elements configured to interface with and supply filament to an additive manufacturing device. Depending on configuration, recycling devices may create filament from plastic, metal, in-situ material, or a combination thereof.

Abstract: Additive manufacturing devices operable in various external force environments are disclosed. In an aspect, an additive manufacturing device operable in microgravity is disclosed. In other aspects, devices which are operable in high-vibration environments or varying external force environments are disclosed. Additive manufacturing devices herein may produce parts from metal, polymer, or other feedstocks.

Abstract: A system including an additive manufacturing device to perform at least one additive manufacturing process and to include a prefabricated component during the at least one additive manufacturing process to accelerate build completion of a produced object. Another system and a method are also disclosed.

Abstract: Additive manufacturing devices operable in various external force environments are disclosed. In an aspect, an additive manufacturing device operable in microgravity is disclosed. In other aspects, devices which are operable in high-vibration environments or varying external force environments are disclosed. Additive manufacturing devices herein may produce parts from metal, polymer, or other feedstocks.

Abstract: Additive manufacturing devices operable in various external force environments are disclosed. In an aspect, an additive manufacturing device operable in microgravity is disclosed. In other aspects, devices which are operable in high-vibration environments or varying external force environments are disclosed. Additive manufacturing devices herein may produce parts from metal, polymer, or other feedstocks.

Abstract: A system including an additive manufacturing device to perform at least one additive manufacturing process and to include a prefabricated component during the at least one additive manufacturing process to accelerate build completion of a produced object. Another system and a method are also disclosed.

Abstract: A manufacturing system including catalog database for retaining a plurality of three-dimensional content for use to at least one of create a produced object and repair an existing object with at least one additive manufacturing process, one or more user interfaces to access the catalog database at least one of simultaneously and at different times, a communication infrastructure to provide for real-time communication between the catalog database and the one or more user interfaces, and a manufacturing system comprising at least one user interface to apply the at least one additive manufacturing process to at least one of create the produced object and to repair the existing object. Methods are also disclosed.

Abstract: A system comprising a manufacturing device to evaluate an object to determine whether to at least one of repair and replicate the object wherein to repair further comprises at least one of a subtractive process and an additive manufacturing process applied to the object and to replicate further comprises an additive manufacturing process applied to create a second object. Another system and a method are also disclosed.

Abstract: What is disclosed is a lifting bale that has at least two side supports, at least two cross support, and at least one center support and ideally configured to fit over the motor of a concrete saw, to provide handles for lifting the saw, and to provide an attachment point for a lifting mechanism to attach to the lifting bale and to lift the concrete saw, or other object the lifting bale is attached to, upward from the single point while maintaining the concrete saw or other object in a generally level position.

Abstract: Methods of collecting in-situ materials on a celestial body for return to Earth or another location and associated devices are described. These devices and methods facilitate collection of samples and creation of portions of the return spacecraft via an additive manufacturing device contained within the lander craft. The additive manufacturing device is configured to produce portions of the return spacecraft (e.g., sample return container, spacecraft structure, heat shield) and may also be configured to place samples within the spacecraft for return and analysis.

Abstract: A method is provided for partially or completely manufacturing a spacecraft in an extraterrestrial environment, thereby allowing the spacecraft to be transported from Earth in a form that is better able to withstand forces associated with a rocket launch and traversing Earth's atmosphere. Such a form may allow the spacecraft to be significantly smaller than it would need to be if it had to be in a completed form at the time of transportation. Two forms of spacecraft that may be built by such method are also disclosed. In an aspect, the disclosed devices may be configured to be manufactured, assembled, deployed, and utilized in a timely and efficient manner.

Abstract: Recycling devices for producing additive manufacturing filament from received materials including objects to be recycled, discarded objects, obsolete objects, and the like. A recycling device may include a material processing system an extrusion mechanism and a spooling assembly. The material processing system receives material, reduces the size of the received material via a material size reducer and actively pushes the material through at least a portion of the device. The extrusion mechanism produces filament from the material and the spooling assembly loads the filament onto a spool for later use. The spooling assembly may include detachable elements configured to interface with and supply filament to an additive manufacturing device. Depending on configuration, recycling devices may create filament from plastic, metal, in-situ material, or a combination thereof.

Abstract: What is disclosed is a lifting bale that has at least two side supports, at least two cross support, and at least one center support and ideally configured to fit over the motor of a concrete saw, to provide handles for lifting the saw, and to provide an attachment point for a lifting mechanism to attach to the lifting bale and to lift the concrete saw, or other object the lifting bale is attached to, upward from the single point while maintaining the concrete saw or other object in a generally level position.

Abstract: Apparatus and methods for creating cast metal objects in space and other environments. Molds are created using additive manufacturing and are injected with a castable metal having a melting point lower than a mold melting point. In some aspects, the additive manufacturing device and the metal casting unit are contained in the same unit.

Abstract: Node-based remote operations of additive manufacturing device are disclosed. In an aspect, a system for operating a remote additive manufacturing device is disclosed. Each computing device is a node in a communications path and contains an instance of a command software program configured to receive and send a single set of commands, ensure the integrity of such commands and/or operate communicatively connected additive manufacturing devices.

Abstract: Additive manufacturing devices operable in various external force environments are disclosed. In an aspect, an additive manufacturing device operable in microgravity is disclosed. In other aspects, devices which are operable in high-vibration environments or varying external force environments are disclosed. Additive manufacturing devices herein may produce parts from metal, polymer, or other feedstocks.

Abstract: An extended structure additive manufacturing device and method are provided. The device includes a movable material bonding component and a movement mechanism which enable the device to create parts outside the conventional additive manufacturing device print volumes defined by the device and its print-head. Methods of making parts involve creating a portion of a part and moving the extended structure additive manufacturing device relative to the part and printing a second portion of the part. Parts incapable of being formed using a conventional additive manufacturing device may be made using the extended structure additive manufacturing device and/or methods disclosed herein.

Abstract: A method for formatting images for angle specific viewing in a scanning aperture dimensional display device. Input images are rearranged into slices or sections to create a set of output images. The images derived from the output images are formed by rearranging the image slices or sections and disposing the image to be viewed directly behind an open aperture in an aperture plate in a scanning aperture display device. By cycling the images in relation to the cycling of the open apertures of the aperture plate, angle specific viewing of the scanning aperture display can be provided. The number angles for angle specific viewing can be varied and can range from 2-1000 distinct viewing angles from a single scanning aperture display device.

Abstract: The backlight for use in scanning aperture display device utilizes a light or LED bank arranged in a predetermined configuration, a light carrying device for carrying the light generated by the LED bank to the scanning apertures of the display device, and a mask adapted to capture and focus the light generated by each LED into the respective light carrying device. The backlight is positioned behind the transmissive display of the scanning aperture display device.

Abstract: A device and method for retrofitting a 2D display monitor to provide 3D stereoscopic displays is provided. The device includes a shutter plate that is releasably connectable to the front of 2D display monitor, and an interface device connects the shutter plate to the computer driving the display. Through the use of time-multiplexed techniques, the shutter plate of the present invention provides true 3D stereoscopic displays from 2D display devices.