An additive manufacturing apparatus that forms an object by repeating additive machining of melting a machining material and adding, onto a workpiece, the machining material solidified includes: a height measurement unit that measures a height of the object formed at a machining position; and a control unit that controls a machining condition for adding the machining material to the machining position on the basis of a measurement result provided by the height measurement unit.

One of the objects of the present application is to provide a technique capable of preventing the generation of excessive metallic vapor during fabrication according to an AM technique. Further, one of the objects of the present application is to provide a technique for reducing machining processing after the fabrication as much as possible or eliminating the necessity thereof. According to one aspect, an AM apparatus configured to manufacture a fabrication object is provided. This AM apparatus includes a first DED nozzle configured to fabricate a contour of a fabrication target and a second DED nozzle configured to fabricate an inner portion of the contour.

One of the objects of the present application is to provide a technique capable of preventing the generation of excessive metallic vapor during fabrication according to an AM technique. Further, one of the objects of the present application is to provide a technique for reducing machining processing after the fabrication as much as possible or eliminating the necessity thereof. According to one aspect, an AM apparatus configured to manufacture a fabrication object is provided. This AM apparatus includes a first DED nozzle configured to fabricate a contour of a fabrication target and a second DED nozzle configured to fabricate an inner portion of the contour.

Laser additive manufacturing and a method for preparing thin-walled preforms by laser metal deposition and follow-up rolling. This can solve the problems that when the existing laser metal deposition technology prepares the thin-walled preforms, the limit width size of a molten pool at high power affects the forming wall thickness of the preforms so that it is difficult to prepare preforms with wall thickness less than 2 mm, and the problems of poor surface quality and low accuracy of preforms due to convex and concave peaks caused by the interlayer overlapping, but also can solve the problems that a laser beam with a preset trajectory cannot act on the end surfaces of the preforms due to preform deformation caused by residual stress in a printing process so that the preforms cannot be continuously formed.

A three-dimensional printing system includes a build platform, a movement mechanism, a coating module, a consolidation module, and a controller. The controller is configured to (1) operate the movement mechanism and the coating module to deposit a new powder layer over an upper surface of the build platform or powder, (2) operate the consolidation module to selectively consolidate the new powder layer, and (3) repeat (1) and (2) until a three-dimensional article is fabricated from a plurality of layers. Step (1) includes, at least one of the plurality of layers (a) operate the movement mechanism and the coating module to deposit a first sublayer of powder having a thickness T1 over the upper surface, and (b) operate the movement mechanism and the coating module to deposit a second sublayer of powder having at thickness T2 over the first sublayer of powder. T2 is less than 20% of T1.

An additive manufacturing system includes an additive manufacturing unit configured to shape an object including a plurality of layers, a measurement unit configured to measure a state of each of the plurality of layers, and a control unit. The control unit includes a storage unit configured to store reference information based on internal defect information indicating a defect existing inside a sample object shaped by the additive manufacturing unit and including the plurality of layers, based on an electromagnetic wave which has passed through the sample object, and sample measurement information indicating a measurement result of the plurality of layers of the sample object measured by the measurement unit, and an estimation unit configured to estimate whether a defect occurs inside the object, based on measurement information indicating a measurement result of the plurality of layers of the object measured by the measurement unit and the reference information.

An additive manufacturing system includes an additive manufacturing unit configured to shape an object including a plurality of layers, a measurement unit configured to measure a state of each of the plurality of layers, and a control unit. The control unit includes a storage unit configured to store reference information based on internal defect information indicating a defect existing inside a sample object shaped by the additive manufacturing unit and including the plurality of layers, based on an electromagnetic wave which has passed through the sample object, and sample measurement information indicating a measurement result of the plurality of layers of the sample object measured by the measurement unit, and an estimation unit configured to estimate whether a defect occurs inside the object, based on measurement information indicating a measurement result of the plurality of layers of the object measured by the measurement unit and the reference information.

The disclosure provides methods and systems for measuring a base element of a construction cylinder arrangement in machines for the additive manufacture of 3D objects using a high-energy beam, wherein a measurement pattern is produced from laser light that illuminates the base element, and sites of incidence of the laser light are monitored and evaluated with a camera to produce measuring data about the base element, e.g., position information, orientation information, and/or information about the shape of the surface of the base element. The measurement patterns are produced by deflecting measuring laser beams by an optical scanner system towards the base element, and the camera is arranged laterally offset from the deflected laser beams. The new methods and systems enable measuring base elements in a simple and flexible manner, and require only a small amount of space in the processing chamber.

The disclosure provides methods and systems for measuring a base element of a construction cylinder arrangement in machines for the additive manufacture of 3D objects using a high-energy beam, wherein a measurement pattern is produced from laser light that illuminates the base element, and sites of incidence of the laser light are monitored and evaluated with a camera to produce measuring data about the base element, e.g., position information, orientation information, and/or information about the shape of the surface of the base element. The measurement patterns are produced by deflecting measuring laser beams by an optical scanner system towards the base element, and the camera is arranged laterally offset from the deflected laser beams. The new methods and systems enable measuring base elements in a simple and flexible manner, and require only a small amount of space in the processing chamber.

Provided is a method for manufacturing a three-dimensional shaped object of shaping a three-dimensional shaped object by discharging a shaping material from a discharge unit provided in a three-dimensional shaping device to laminate a plurality of layers according to shaping data for shaping the three-dimensional shaped object layer by layer. The shaping data is generated based on shape data indicating a shape of the three-dimensional shaped object. The method for manufacturing a three-dimensional shaped object includes: a first lamination step of laminating an n-th layer, n being any integer of 2 or more; a measurement step of measuring a physical quantity of an (n−1)-th layer; a data processing step of preparing shaping data for an (n+1)-th or more layer; and a second lamination step of laminating the (n+1)-th or more layer according to the shaping data prepared in the data processing step. The data processing step includes executing a correction step of preparing the shaping data for the (n+1)-th or more layer by correcting shaping data generated in advance based on the physical quantity, or a generation step of generating the shaping data for the (n+1)-th or more layer based on the physical quantity and the shape data.