In the context of an extrusion deposition modeling to form three-dimensional objects, adhesion of extruded materials to a build surface is achieved by preparing the build surface using an intermediary coating that substantially adheres to the build surface, and a bondable particulate material, applied to the intermediary coating, that becomes affixed to the intermediary coating and provides a surface to which the extruded materials may attach.

A spacecraft includes an additive manufacturing (A/M) subsystem and one or both of a thermal control arrangement and a contamination control arrangement. The A/M subsystem includes an A/M tool, feedstock and a workpiece and is configured to additively manufacture the workpiece using material from the feedstock. The thermal control arrangement is operable, in an on-orbit space environment characterized by near vacuum pressure and near zero-g force, to maintain temperature of at least one of the A/M tool, the feedstock, and the workpiece within respective specified ranges. The contamination control arrangement is operable, in the on-orbit space environment, to control outgassing of volatile organic compounds (VOCs).

Various methods and systems are provided for manufacturing a radiation shielding component of an imaging apparatus. In one embodiment, the radiation shielding component may be manufactured by infiltrating metal particles with a binder solution and then curing the binder solution impregnated with the metal particles. In another embodiment, the radiation shielding component may be printed with metal powder, infiltrated with a binding agent, and then cured to polymerize the binding agent.

Various methods and systems are provided for manufacturing a radiation shielding component of an imaging apparatus. In one embodiment, the radiation shielding component may be manufactured by infiltrating metal particles with a binder solution and then curing the binder solution impregnated with the metal particles. In another embodiment, the radiation shielding component may be printed with metal powder, infiltrated with a binding agent, and then cured to polymerize the binding agent.

A three-dimensional shaping device includes a laser irradiation unit (10), a shroud (20), and a protection member (14). The laser irradiation unit includes an optical system (12). The shroud (20) includes an inside space (S0) that extends from one end opening portion (202) to another end opening portion (206). The protection member (14) is formed of a transparent material and is arranged at the one end opening portion (202) of the shroud (20) and causes a laser light emitted from the laser irradiation unit (10) to be transmitted therethrough so that a three-dimensional shaped object is fabricated in a shaping area by sintering or melting and solidifying a powder. The shroud (20) further includes a side wall portion (22) that demarcates a first inside space (S1) and a second inside space (S2), an air supply port (210), an exhaust port (220), and ventilation members (212, 214).

A three-dimensional shaping device includes a laser irradiation unit (10), a shroud (20), and a protection member (14). The laser irradiation unit includes an optical system (12). The shroud (20) includes an inside space (S0) that extends from one end opening portion (202) to another end opening portion (206). The protection member (14) is formed of a transparent material and is arranged at the one end opening portion (202) of the shroud (20) and causes a laser light emitted from the laser irradiation unit (10) to be transmitted therethrough so that a three-dimensional shaped object is fabricated in a shaping area by sintering or melting and solidifying a powder. The shroud (20) further includes a side wall portion (22) that demarcates a first inside space (S1) and a second inside space (S2), an air supply port (210), an exhaust port (220), and ventilation members (212, 214).

According to one example, there is provided a method of cleaning a filter in a filter housing. The filter has a dirty side at which a dirty airflow is received, and a clean side through which a cleaned airflow flows. The method comprises generating a cleaning airflow at the dirty side of the filter, the cleaning airflow having a predetermined volume and pressure, and generating an extraction airflow to extract from the filter housing the same volume and pressure of air from the filter housing as that generated in the filter housing by the cleaning airflow.

A method of changing the gas content of a device (100) which comprises a first chamber (110). The method comprises: arranging the device in a first configuration, wherein the first chamber has a first internal volume; providing a flow of a first gas to the first chamber so that the gas content of the first chamber is at least partially changed; transitioning the device from the first configuration to a second configuration, wherein the first chamber has a second internal volume which is grater than the first internal volume.

A three-dimensional shaping device includes a chamber that has a shaping space; a heating unit configured to heat the shaping space; a base that has a shaping surface exposed to the shaping space; a discharge unit configured to discharge a shaping material toward the shaping surface while moving in a first direction in the shaping space heated by the heating unit and shape a three-dimensional shaped article; a first drive unit configured to move the base in a second direction crossing the first direction; and a tubular first heat resistant member that is disposed between a peripheral part of a first opening formed in a partition wall of the chamber and the base, configured to extend and contract in the second direction in accordance with a movement of the base in the second direction, and defines a separation space separated from the shaping space, in which at least a part of the first drive unit is disposed in the separation space.

A manufacturing installation for the additive manufacturing of components, each provided with at least one material overhang, has at least one building platform on which the particular component can at least partially be additively manufactured. In order to reduce the material consumption and the time to produce additively manufactured components, the manufacturing installation has at least one preferably electrically controllable support device with at least one movable support arm for the at least temporary holding of at least one support element, arranged on the support arm, during the additive manufacture of the particular component above the building platform.