A method for preparing an additive manufacturing program includes a loading step, a dividing step, an overhang calculating step, a subdividing step, a maintaining step, and an outputting step. In the loading step, a three-dimensional model is loaded. In the dividing step, the three-dimensional model is divided into divided layers. In the overhang calculating step, an overhang angle or overhang length of the divided layer is calculated. In the subdividing step, at least a part of the divided layer including an overhang portion is subdivided into two or more in a lamination direction. In the maintaining step, neither subdivision of the divided layer nor addition of a support structure supporting the divided layer is performed. The subdividing step and the maintaining step are selectively performed based on the overhang angle or overhang length. In the outputting step, an additive manufacturing program defining a command pertaining to additive manufacturing is output.

An apparatus for additive manufacturing of a three-dimensional object by successive layer-by-layer selective illumination and thus selective solidification of construction material layers formed in a construction plane, consisting of a solidifiable construction material by at least one energy beam, comprising a housing structure, and a combined coating and illumination assembly firmly arranged or formed on the housing structure of the apparatus, comprising a coating device provided for applying the construction material into the construction plane and for forming construction material layers to be solidified in the construction plane, and an illumination device provided for the selective illumination of respective construction material layers formed in the construction plane by the coating device, and a carrying device.

A method for producing a three-dimensional object on a support by applying layer by layer and selectively solidifying a building material in powder form. The method includes lowering the support to a predetermined height below a working plane, applying a layer of the building material in powder form in the working plane, selectively solidifying the applied powder layer at positions corresponding to a cross-section of the object to be produced and repeating the steps of lowering, applying and selectively solidifying until the object is completed. By doing so, the quantity of applied building material in powder form is reduced in a section in an actively controlled way or substantially no building material in powder form is applied in a section in an actively controlled way.

An additive manufacturing apparatus may include a process chamber, a coating device, a shielding device, and a guiding device. The process chamber may include first and second working plane areas. The first working plane area may include a construction plane, and the second working plane area may house at least a part of the guiding device. The coating device may include a coating element assembly group that is, movably supported relative to the construction plane by the guiding device, and at least one coating element configured to form construction material layers in the construction plane. The shielding device may shield the second working plane area from intrusion of construction material or impurities from the first working plane area. The shielding device may include a shielding band, and the shielding band may be coupled for movement with the coating element assembly group. The shielding band may be guided movably along a plurality of supporting points that define an interior region of the second working plane area, and the guiding device may be arranged or formed above the first working plane area.

In a three-dimensional printing method example, a liquid functional agent is selectively applied. The liquid functional agent includes an alloying agent. A metallic build material is applied. The liquid functional agent is selectively applied before the metallic build material, after the metallic build material, or both before and after the metallic build material. The liquid functional agent patterns the metallic build material to form a composite layer. At least some of the metallic build material is exposed to energy to melt the at least some of the metallic build material to form a layer. Upon contact or after energy exposure, the alloying agent and the build material alter a composition of the composite layer.

In example implementations, a spreading blade is provided. The spreading blade includes a body portion, an ultrasonic vibration source, and a kicker. The ultrasonic vibration source is coupled to a top portion of the body portion to apply a vibration along a cross-sectional length of the body portion. The kicker is coupled to a side facing a process direction at a bottom end of the body portion. The kicker comprises a tip formed by a combination of two angled surfaces that extend from a lateral side of the body portion.

In example implementations, a spreading blade is provided. The spreading blade includes a body portion, an ultrasonic vibration source, and a kicker. The ultrasonic vibration source is coupled to a top portion of the body portion to apply a vibration along a cross-sectional length of the body portion. The kicker is coupled to a side facing a process direction at a bottom end of the body portion. The kicker comprises a tip formed by a combination of two angled surfaces that extend from a lateral side of the body portion.

In example implementations, a spreading blade is provided. The spreading blade includes a body portion, an ultrasonic vibration source, and a kicker. The ultrasonic vibration source is coupled to a top portion of the body portion to apply a vibration along a cross-sectional length of the body portion. The kicker is coupled to a side facing a process direction at a bottom end of the body portion. The kicker comprises a tip formed by a combination of two angled surfaces that extend from a lateral side of the body portion.

A method of manufacturing a three-dimensionally shaped object includes a first powder-layer forming process in which a first portion of at least one thickness determining member forms a powder layer by moving in contact with powder, a solidifying process in which a solidified portion is formed in the powder layer formed in the first powder-layer forming process, a second powder-layer forming process, performed after the solidifying process, in which a second portion of the at least one thickness determining member forms a powder layer by moving in contact with the powder, and a renewal process performed between the first powder-layer forming process and the second powder-layer forming process. In the renewal process, the portion having been in contact with the powder is renewed such that the second portion is different from the first portion.

A method of manufacturing a three-dimensionally shaped object includes a first powder-layer forming process in which a first portion of at least one thickness determining member forms a powder layer by moving in contact with powder, a solidifying process in which a solidified portion is formed in the powder layer formed in the first powder-layer forming process, a second powder-layer forming process, performed after the solidifying process, in which a second portion of the at least one thickness determining member forms a powder layer by moving in contact with the powder, and a renewal process performed between the first powder-layer forming process and the second powder-layer forming process. In the renewal process, the portion having been in contact with the powder is renewed such that the second portion is different from the first portion.