A molding device includes a color inkjet head that ejects a color ink, and a clear inkjet head that ejects a clear ink. The color ink is ejected from the color inkjet head and layered to color and form a molded object, and the clear ink is ejected from the clear inkjet head to compensate the layering amount of the color ink. The molding device includes an input part that inputs the compensation amount of the clear ink such that the impact frequency of the clear ink becomes low at a place where the impact frequency of the color ink in coloring and forming the molded object is high, and the impact frequency of the clear ink becomes high at a place where the impact frequency of the color ink is low for each layer forming the molded object.

A three-dimensional object production process and system comprising providing a thermoset printing apparatus comprising a mixing chamber to receive and mix at least a first reactive component and a second reactive component to provide a thermosetting material, an extrusion nozzle, at least one actuator coupled to the extrusion nozzle, and a controller, wherein the controller generates a printing path for the 3D printing process, executes a translation start command, a flow start command, a translation command, a flow command, a translation stop command, a flow stop command, and a reverse translation command to the thermoset printing apparatus during the 3D printing process, identifies an at least one discontinuity in the printing path, executes the flow stop command before the extrusion nozzle reaches the at least one discontinuity, executes the translation stop command before the at least one discontinuity, and executes a reverse translation command

A three-dimensional (“3D”) printing system for printing on a substrate, the printing system including a plurality of powder feeders, the plurality of powder feeders dispensing a powder on the substrate in a first direction and in a second direction; and a powder uniformization device located adjacent to the plurality of powder feeders, the powder uniformization device rotatable along the substrate in directions opposing the first direction and the second direction.

A method of additive manufacturing an object featuring properties of a hard bodily tissue, comprises: dispensing and solidifying a plurality of non-biological material formulations to sequentially form a plurality of hardened layers in a configured pattern corresponding to a shape of the object. The method forms voxel elements containing different material formulations at interlaced locations to provide a three-dimensional textured region spanning over the portion. The material formulations and the interlaced locations are selected such that the textured region exhibits, once hardened, a stress variation of at most ±20% over a strain range of from about 0.1% to about 0.3%.

A method of additive manufacturing an object featuring properties of a hard bodily tissue, comprises: dispensing and solidifying a plurality of non-biological material formulations to sequentially form a plurality of hardened layers in a configured pattern corresponding to a shape of the object. The method forms voxel elements containing different material formulations at interlaced locations to provide a three-dimensional textured region spanning over the portion. The material formulations and the interlaced locations are selected such that the textured region exhibits, once hardened, a stress variation of at most ±20% over a strain range of from about 0.1% to about 0.3%.

A system for producing pharmaceutical objects, such as tablets, granules and capsules, via 3D printing. The system comprises a 3D printing machine (2) with a mechanical system (3) movable in one or more directions, at least one print head (5) with a nozzle (37) being movable by the mechanical system and a base system (4) carrying a print base (6) for receiving a prepared mixture (27) applied by the print head (5). The system comprises at least one carrier (35) for holding a cartridge (28). Printing is done at formatted print locations (49) on the base (6). A method for producing pharmaceutical objects by providing at least one pharmaceutical substance in at least one cartridge, placing the cartridge in a carrier, establishing a fluid connection between a cartridge and a print head, moving the print head nozzle according to a program and dispensing the pharmaceutical substance to a print base.

A system for producing pharmaceutical objects, such as tablets, granules and capsules, via 3D printing. The system comprises a 3D printing machine (2) with a mechanical system (3) movable in one or more directions, at least one print head (5) with a nozzle (37) being movable by the mechanical system and a base system (4) carrying a print base (6) for receiving a prepared mixture (27) applied by the print head (5). The system comprises at least one carrier (35) for holding a cartridge (28). Printing is done at formatted print locations (49) on the base (6). A method for producing pharmaceutical objects by providing at least one pharmaceutical substance in at least one cartridge, placing the cartridge in a carrier, establishing a fluid connection between a cartridge and a print head, moving the print head nozzle according to a program and dispensing the pharmaceutical substance to a print base.

A radio frequency (RF) waveguide comprising a channel, a filter, and a support bridge. The channel can comprise an outer wall defining an inner cavity configured to propagate electromagnetic waves. The filter can be disposed in the inner cavity of the channel and can comprise a perimeter edge and an aperture. The support bridge can comprise a first interface connected to an inner surface of the outer wall at a first location, and a second interface connected to the filter at a position between the perimeter edge and the aperture of the filter to support the filter within the channel. The support bridge can remain in place as connected to the filter, and the filter and waveguide can operate without interference from the support bridge, meaning that the waveguide meets all performance specifications and functions as intended for a particular application even with the support bridge left in place.

A radio frequency (RF) waveguide comprising a channel, a filter, and a support bridge. The channel can comprise an outer wall defining an inner cavity configured to propagate electromagnetic waves. The filter can be disposed in the inner cavity of the channel and can comprise a perimeter edge and an aperture. The support bridge can comprise a first interface connected to an inner surface of the outer wall at a first location, and a second interface connected to the filter at a position between the perimeter edge and the aperture of the filter to support the filter within the channel. The support bridge can remain in place as connected to the filter, and the filter and waveguide can operate without interference from the support bridge, meaning that the waveguide meets all performance specifications and functions as intended for a particular application even with the support bridge left in place.

A 3D printing tool and assembly for dispensing multiple materials includes a barrel holder assembly having at least two barrel orifices extending from a top end of the barrel holder assembly through to a bottom end of the barrel holder assembly, where at least one of the at least two barrel orifices is oriented at an angle from the vertical. A method for operating the 3D printing tool includes positioning a first material distribution barrel within a first barrel orifice, where a first barrel tip is disposed at a first end of the first material distribution barrel. The method further includes dispensing building material from the first material distribution barrel when the first material distribution barrel is substantially vertically oriented and a second material distribution barrel is oriented at an angle from the vertical.