A molding device that molds a stereoscopic molding object through a layered molding method, where after molding of at least one molding object is started and before the molding of the at least one molding object is completed, molding of another molding object is started. The molding device 10, for example, includes an ejection head, and a molding object supporter, the molding object supporter includes, for example, a plurality of molding tables, at least an opposing surface of each molding table is independently movable, an ejection head ejects a material toward the opposing surface of at least one molding table to mold the molding object on the molding table, and at least the opposing surface of the molding table on which the molding object is molded is moved in a perpendicular direction to move the molding object in the perpendicular direction.

A molding device that molds a stereoscopic molding object through a layered molding method, where after molding of at least one molding object is started and before the molding of the at least one molding object is completed, molding of another molding object is started. The molding device 10, for example, includes an ejection head, and a molding object supporter, the molding object supporter includes, for example, a plurality of molding tables, at least an opposing surface of each molding table is independently movable, an ejection head ejects a material toward the opposing surface of at least one molding table to mold the molding object on the molding table, and at least the opposing surface of the molding table on which the molding object is molded is moved in a perpendicular direction to move the molding object in the perpendicular direction.

An apparatus for the additive manufacturing of three-dimensional structures from a material that is to be solidified by way of location-selective solidification thereof as a result of light-induced chemical and/or physical processes in the material includes a laser source for producing a laser beam, a focusing optical unit for focusing the laser beam so as to form a laser focus, and a beam-splitter optical unit for splitting the laser beam into at least two partial laser beams. The laser source, the focusing optical unit and the beam-splitter optical unit are arranged such that the laser beam, starting from the laser source, passes first through the focusing optical unit and then through the beam-splitter optical unit and the partial laser beams finally are each directed to different locations on the material that is to be solidified.

A method for producing a component from two or more sub-components includes the steps of: producing each of the sub-components using an additive manufacturing process in which a resin, which is radiant-energy-curable, is partially cured using a selective application of radiant energy, wherein each sub-component includes a joint surface in which the resin is partially cured which is cured to a lesser degree than the remainder of the respective sub-component, so as to leave the joint surfaces in a condition suitable for bonding; assembling the sub-components with their respective joint surfaces in mutual contact; and performing a secondary cure of the partially-cured resin at the joint surfaces using an application of radiant energy, so as to further cure the partially-cured resin and bond the sub-components to each other, thereby forming the component.

A method for producing a component from two or more sub-components includes the steps of: producing each of the sub-components using an additive manufacturing process in which a resin, which is radiant-energy-curable, is partially cured using a selective application of radiant energy, wherein each sub-component includes a joint surface in which the resin is partially cured which is cured to a lesser degree than the remainder of the respective sub-component, so as to leave the joint surfaces in a condition suitable for bonding; assembling the sub-components with their respective joint surfaces in mutual contact; and performing a secondary cure of the partially-cured resin at the joint surfaces using an application of radiant energy, so as to further cure the partially-cured resin and bond the sub-components to each other, thereby forming the component.

A device for simultaneous 3D printing of a plurality of objects, including a plurality of printing heads and a plurality of object holders each associated with one of the printing heads, wherein: the printing heads and the object holders can be moved relative to one another along three translation axes in three spatial dimensions by at least three translation actuators; the printing heads are arranged on exactly one carrier element and the object holders are arranged on one or more object holder carriers, or the printing heads are arranged on a plurality of carrier elements and the object holders are arranged on exactly one object holder carrier; the printing heads are arranged on the one carrier element or the plurality of carrier elements at an offset along at least two of the three translation axes.

A device for simultaneous 3D printing of a plurality of objects, including a plurality of printing heads and a plurality of object holders each associated with one of the printing heads, wherein: the printing heads and the object holders can be moved relative to one another along three translation axes in three spatial dimensions by at least three translation actuators; the printing heads are arranged on exactly one carrier element and the object holders are arranged on one or more object holder carriers, or the printing heads are arranged on a plurality of carrier elements and the object holders are arranged on exactly one object holder carrier; the printing heads are arranged on the one carrier element or the plurality of carrier elements at an offset along at least two of the three translation axes.

Disclosed are a system for and a method of manufacturing a three-dimensional (3D) structure. The method may include injecting a fluid with a first pressure toward a surface of a first output layer to form a softening layer in the first output layer, injecting the fluid with a second pressure toward the softening layer to form an uneven structure in the softening layer, the second pressure being higher than the first pressure, and forming a second output layer on the softening layer with the uneven structure.

Disclosed are a system for and a method of manufacturing a three-dimensional (3D) structure. The method may include injecting a fluid with a first pressure toward a surface of a first output layer to form a softening layer in the first output layer, injecting the fluid with a second pressure toward the softening layer to form an uneven structure in the softening layer, the second pressure being higher than the first pressure, and forming a second output layer on the softening layer with the uneven structure.

According to some aspects, a system for identifying a printed object is provided. The system may include an imaging device configured to image a three-dimensional (3D) printed object and a processor coupled to the imaging device. The processor may be configured to receive information generated as a result of imaging the 3D printed object with the imaging device, identify a set of features for the 3D printed object using the received information, compare the set of features with multiple reference sets of features, each of the multiple reference sets of features being associated with a respective 3D object in a plurality of 3D objects, and identify, based at least in part on results of the comparison, a 3D object from the plurality of 3D objects that matches the 3D printed object.