A method for additive manufacturing includes: at a build tray arranged over a build window and containing a resin reservoir of a resin, heating the resin reservoir toward a target bulk resin temperature less than a heat deflection temperature of the resin in a photocured state; at a resin interface between a surface of the build window and the resin reservoir, heating an interface layer of the resin reservoir toward a target reaction temperature; and, in response to the resin reservoir exhibiting a first temperature proximal the target bulk resin temperature and to the interface layer exhibiting a second temperature proximal the target reaction temperature: at the resin interface, selectively photocuring a first volume of the resin to form a first layer of a build adhered to a build platform; and retracting the build platform away from the build window.

In a process for the lithography-based generative production of three-dimensional shaped bodies, wherein material that is solidifiable by exposure to electromagnetic radiation is present on a material support that is permeable in at least a region thereof, a building platform is positioned at a distance from the material support, material located between the building platform and the material support is heated and in the heated state is location-selectively irradiated by a first radiation source and solidified, wherein the electromagnetic radiation is introduced into the material from below through the material support that is at least partially permeable to radiation from the first radiation source, the heating of the material is performed by irradiating the material support with electromagnetic radiation of a second radiation source, wherein the material support is substantially impermeable for the radiation of the second radiation source.

In a process for the lithography-based generative production of three-dimensional shaped bodies, wherein material that is solidifiable by exposure to electromagnetic radiation is present on a material support that is permeable in at least a region thereof, a building platform is positioned at a distance from the material support, material located between the building platform and the material support is heated and in the heated state is location-selectively irradiated by a first radiation source and solidified, wherein the electromagnetic radiation is introduced into the material from below through the material support that is at least partially permeable to radiation from the first radiation source, the heating of the material is performed by irradiating the material support with electromagnetic radiation of a second radiation source, wherein the material support is substantially impermeable for the radiation of the second radiation source.

One embodiment of the present disclosure provides a nozzle device for an FDM-type 3D printer, comprising: a filament supply unit to which a filament for FDM is supplied; a filament nozzle which is positioned on the lower part of the filament supply unit, and which melts the filament received from the filament supply unit so as to output the molten filament; a heater block provided on the circumference of the filament nozzle to melt the filament inside the filament nozzle; a humidifier for generating vapor; and a transfer pipeline, which transfers the vapor of the humidifier to spray same onto the molten filament.

One embodiment of the present disclosure provides a nozzle device for an FDM-type 3D printer, comprising: a filament supply unit to which a filament for FDM is supplied; a filament nozzle which is positioned on the lower part of the filament supply unit, and which melts the filament received from the filament supply unit so as to output the molten filament; a heater block provided on the circumference of the filament nozzle to melt the filament inside the filament nozzle; a humidifier for generating vapor; and a transfer pipeline, which transfers the vapor of the humidifier to spray same onto the molten filament.

An apparatus (1) for manufacturing a three-dimensional object from particulate material, the apparatus comprising: a work space (100) bounded by a first side wall (100A) on a first side of the work space, and a second side wall (100B) on a second side of the work space, the first side wall opposing the second side wall; a build bed (170) having a build bed surface (160), the build bed surface being comprised in the floor of the work space and having a first edge (160′) on the first side of the work space, towards the first side wall, and a second edge (160″) on the second side of the work space, towards the second side wall; a first gas inlet (101A) at or near the first side wall; a second gas inlet (101B) at or near the second side wall; a first gas outlet (102A) above the floor (100C) of the work space, the position of the first gas outlet being coincident with the first edge of the build bed surface, or between the first edge of the build bed surface and the first gas inlet; and a second gas outlet (102B) above the floor of the work space, the position of the second gas outlet being coincident with the second edge of the build bed surface, or between the second edge of the build bed surface and the second gas inlet; wherein the first gas outlet is positioned higher in the work space than the first gas inlet, and the second gas outlet is positioned higher in the work space than the second gas inlet; and wherein one or more flow devices (210, 211, 212) are operable to create first and second gas flows between the first gas inlet and the first gas outlet, and between the second gas inlet and the second gas outlet, respectively, such as to create respective first and second gas curtains on the first and second sides of the work space in use.

An apparatus (1) for manufacturing a three-dimensional object from particulate material, the apparatus comprising: a work space (100) bounded by a first side wall (100A) on a first side of the work space, and a second side wall (100B) on a second side of the work space, the first side wall opposing the second side wall; a build bed (170) having a build bed surface (160), the build bed surface being comprised in the floor of the work space and having a first edge (160′) on the first side of the work space, towards the first side wall, and a second edge (160″) on the second side of the work space, towards the second side wall; a first gas inlet (101A) at or near the first side wall; a second gas inlet (101B) at or near the second side wall; a first gas outlet (102A) above the floor (100C) of the work space, the position of the first gas outlet being coincident with the first edge of the build bed surface, or between the first edge of the build bed surface and the first gas inlet; and a second gas outlet (102B) above the floor of the work space, the position of the second gas outlet being coincident with the second edge of the build bed surface, or between the second edge of the build bed surface and the second gas inlet; wherein the first gas outlet is positioned higher in the work space than the first gas inlet, and the second gas outlet is positioned higher in the work space than the second gas inlet; and wherein one or more flow devices (210, 211, 212) are operable to create first and second gas flows between the first gas inlet and the first gas outlet, and between the second gas inlet and the second gas outlet, respectively, such as to create respective first and second gas curtains on the first and second sides of the work space in use.

The present invention addresses the problem of providing: a method for manufacturing a three-dimensional modeled object, with which it is possible to fabricate a three-dimensional modeled object having high strength, using electron beam irradiation. In order to solve said problem, this method for manufacturing a three-dimensional modeled object comprises: a thin layer formation step in which a composition containing a radical polymerizable compound is applied to form a thin layer; and an electron beam irradiation step in which said thin layer is subjected to electron beam irradiation, and the radical polymerizable compound is cured to form a modeled object layer. The thin layer formation step and the electron beam irradiation step are repeated a number of times to layer the modeled object layer. The electron beam irradiation step is carried out in an atmosphere having an oxygen concentration from 50 ppm to less than 5,000 ppm.

The present invention addresses the problem of providing: a method for manufacturing a three-dimensional modeled object, with which it is possible to fabricate a three-dimensional modeled object having high strength, using electron beam irradiation. In order to solve said problem, this method for manufacturing a three-dimensional modeled object comprises: a thin layer formation step in which a composition containing a radical polymerizable compound is applied to form a thin layer; and an electron beam irradiation step in which said thin layer is subjected to electron beam irradiation, and the radical polymerizable compound is cured to form a modeled object layer. The thin layer formation step and the electron beam irradiation step are repeated a number of times to layer the modeled object layer. The electron beam irradiation step is carried out in an atmosphere having an oxygen concentration from 50 ppm to less than 5,000 ppm.

An additive manufacturing method including repeatedly applying a layer of building material on a previously selectively solidified building material layer and scanning the layer at positions corresponding to the cross-section of the object in this layer, where the laser radiation is generated by a laser light source and is directed onto the building material layer via optical components. An optics compartment is encased by an optics compartment housing and accommodates the optical components. A defined gas atmosphere is maintained inside of the optics compartment, wherein the relative humidity of the defined gas atmosphere is kept below 3%.