The disclosure relates to a powdery filament composition for 3D printing, a 3D printer, and a method of additively manufacturing an object by the 3D printer, and more particularly to a powdery filament composition for 3D printing, which is suitable for home use because it does not produce toxic substances, a 3D printer, the size of which is suitable for home use because it does not require high power energy, high-temperature processing and the like conditions for additive manufacturing, and a method of additively manufacturing an object by the 3D printer.

The disclosure relates to a powdery filament composition for 3D printing, a 3D printer, and a method of additively manufacturing an object by the 3D printer, and more particularly to a powdery filament composition for 3D printing, which is suitable for home use because it does not produce toxic substances, a 3D printer, the size of which is suitable for home use because it does not require high power energy, high-temperature processing and the like conditions for additive manufacturing, and a method of additively manufacturing an object by the 3D printer.

A connecting device for receiving a cartridge container and for positioning at a connection point in an installation for producing three-dimensional components by successively solidifying layers of a powdered building material, having a housing, having a cartridge receiver which is provided at the housing and to which the cartridge container can be fastened, having a connection side on the housing opposite the cartridge receiver, which connection side has a passage for delivering powdered building material from the cartridge container or for feeding powdered building material into the cartridge container, having a closure member which is provided between the cartridge receiver and the connection side and by which the passage can be activated for opening and closing the passage.

A method of creating a reinforced dental prosthesis is provided that can include providing a three-dimensional (3D) printed dental prosthesis, and applying a coating solution to at least a portion of an outer surface of the 3D printed dental prosthesis. The coating solution can include a polymerizable resin and filler particles distributed within the polymerizable resin. The method can include curing the coating solution on the 3D printed dental prosthesis to create the reinforced dental prosthesis.

A stereolithography method of manufacture of a polymer structure having a spatially gradient dielectric constant, including: providing a volume of a liquid, radiation-curable composition; irradiating a portion of the liquid, radiation-curable composition with activating radiation in a pattern to form a layer of the polymer structure; contacting the layer with the liquid, radiation-curable composition; irradiating the liquid, radiation-curable composition with activating radiation in a pattern to form a second layer on the first layer; and repeating the contacting and irradiating to form the polymer structure, wherein the polymer structure comprises a plurality of unit cells wherein each unit cell is integrally connected with an adjacent unit cell, each unit cell is defined by a plurality of trusses formed by the irradiation, wherein the trusses are integrally connected with each other at their respective ends, and the trusses of each unit cell are dimensioned to provide the spatially gradient dielectric constant.

Methods and systems for additively casting of a metallic object include constructing a mold region of a current production layer before producing the object region of the current production layer; depositing molten metal at a predetermined temperature in working areas at the object region of the current production layer according to a building plan; and moving one or more heaters over the deposition path and heating the working areas. The heating includes (1) heating the working areas to a pre-deposition target temperature before depositing metal on the working areas to affect a bonding of the molten metal with the working areas, and/or (2) heating the working areas to a post-deposition target temperature after depositing metal on the working areas to affect a thermal cooling profile of the working areas. the heating also includes providing annealing heating to earlier production layers by heat conduction through the current production layer.

Methods and systems for additively casting of a metallic object include constructing a mold region of a current production layer before producing the object region of the current production layer; depositing molten metal at a predetermined temperature in working areas at the object region of the current production layer according to a building plan; and moving one or more heaters over the deposition path and heating the working areas. The heating includes (1) heating the working areas to a pre-deposition target temperature before depositing metal on the working areas to affect a bonding of the molten metal with the working areas, and/or (2) heating the working areas to a post-deposition target temperature after depositing metal on the working areas to affect a thermal cooling profile of the working areas. the heating also includes providing annealing heating to earlier production layers by heat conduction through the current production layer.

An example of a multi-fluid kit for three-dimensional (3D) printing kit includes a fusing agent and a build material reactive functional agent. The fusing agent includes water and an electromagnetic radiation absorber. The build material reactive functional agent includes a vehicle and trifluoroacetic anhydride. The multi-fluid kit may also be part of a 3D printing kit.

An example of a multi-fluid kit for three-dimensional (3D) printing kit includes a fusing agent and a build material reactive functional agent. The fusing agent includes water and an electromagnetic radiation absorber. The build material reactive functional agent includes a vehicle and trifluoroacetic anhydride. The multi-fluid kit may also be part of a 3D printing kit.

In one example in accordance with the present disclosure, an additive manufacturing system is described. The additive manufacturing system includes a build material distributor to deposit metal powder build material and an agent distribution system to selectively deposit a binding agent on the metal powder build material in a pattern of a layer of a three-dimensional (3D) object to be printed. The additive manufacturing system also includes an ultraviolet (UV) energy source. The UV energy source, in a layer-by-layer fashion 1) cures the binding agent to join together metal powder build material with binding agent disposed thereon and 2) evaporates a solvent of the binding agent.