A build platform of an additive manufacturing apparatus is disclosed. The build platform includes a surface formed of a material having a first emissivity; and a plurality of reference markers disposed on the surface. The reference markers have a second emissivity that is different from the first emissivity. A thermal imaging unit calibration method and additive manufacturing apparatus are also disclosed.

A three-dimensional shaping apparatus shapes a first shaped article by ejecting a material from an ejection section, forms a first portion of a second shaped article by adjusting an output of a temperature adjusting section while measuring a temperature of the first shaped article by a temperature sensor so that a viscosity of the first shaped article calculated based on the temperature of the first shaped article measured by the temperature sensor and first relational data representing a relationship between a temperature and a viscosity of the material becomes a predetermined viscosity or less, and ejecting the material from the ejection section, and forms a second portion that is a portion adjacent to the first portion of the second shaped article by ejecting the material from the ejection section while adjusting a temperature of the first portion by the temperature adjusting section with the adjusted output.

We describe a calibration method for calibrating one or more optical elements of an additive layer manufacturing apparatus useable for producing a three-dimensional workpiece, the method comprising: projecting, using the one or more optical elements, an optical pattern onto a material in order to prepare, from said material, solidified material layers using an additive layer manufacturing technique to form a test sample; determining a geometry of the test sample; comparing the determined geometry with a nominal geometry to generate calibration data; and calibrating the one or more optical elements using said calibration data.

We describe a calibration method for calibrating one or more optical elements of an additive layer manufacturing apparatus useable for producing a three-dimensional workpiece, the method comprising: projecting, using the one or more optical elements, an optical pattern onto a material in order to prepare, from said material, solidified material layers using an additive layer manufacturing technique to form a test sample; determining a geometry of the test sample; comparing the determined geometry with a nominal geometry to generate calibration data; and calibrating the one or more optical elements using said calibration data.

In a method for producing a three-dimensional workpiece (12), a first raw material powder (50) is applied to a substrate (18) in order to produce a raw material powder layer consisting of the first raw material powder (50). The raw material powder layer consisting of the first raw material powder (50) is selectively irradiated with electromagnetic radiation or particle radiation in order to produce a solidified first workpiece layer portion (52) from the first raw material powder (50). Non-solidified first raw material powder (50) is then removed from the substrate (18). In the next step, a second raw material powder (54) is applied to the substrate (18), in order to produce a raw material powder layer portion consisting of the second raw material powder (54) adjacent to the first workpiece layer portion (52), The raw material powder layer portion is selectively irradiated with electromagnetic radiation or particle radiation in order to produce a solidified second workpiece layer portion (56) from the second raw material powder (54) adjacent to the first workpiece layer portion (52). The non-solidified second raw material powder (54) is heated in order to produce a continuous porous sintered layer portion (58) from the second raw material powder (54) adjacent to the first workpiece layer portion (52) and the second workpiece layer portion (56).

In a method for producing a three-dimensional workpiece (12), a first raw material powder (50) is applied to a substrate (18) in order to produce a raw material powder layer consisting of the first raw material powder (50). The raw material powder layer consisting of the first raw material powder (50) is selectively irradiated with electromagnetic radiation or particle radiation in order to produce a solidified first workpiece layer portion (52) from the first raw material powder (50). Non-solidified first raw material powder (50) is then removed from the substrate (18). In the next step, a second raw material powder (54) is applied to the substrate (18), in order to produce a raw material powder layer portion consisting of the second raw material powder (54) adjacent to the first workpiece layer portion (52), The raw material powder layer portion is selectively irradiated with electromagnetic radiation or particle radiation in order to produce a solidified second workpiece layer portion (56) from the second raw material powder (54) adjacent to the first workpiece layer portion (52). The non-solidified second raw material powder (54) is heated in order to produce a continuous porous sintered layer portion (58) from the second raw material powder (54) adjacent to the first workpiece layer portion (52) and the second workpiece layer portion (56).

A stirring device for a powder tank of an apparatus for manufacturing a three-dimensional object. The stirring device is configured to rotate within the powder tank about an axis of rotation, and comprises a base plate and a strut. The strut extends from the base plate and is arranged to extend into the powder tank forming an obtuse angle with the outer edge of the base plate

An accessory device used in combination with a solid-state additive manufacturing system is described. In some configurations, the accessory device can be used in combination with an additive manufacturing system, such as a solid-state additive manufacturing system, to enable printing of large-scale and complex objects, where the objects are much larger than those printed with existing solid-state manufacturing systems. The disclosed accessory device used in conjunction with the a solid-state additive manufacturing system is capable of manufacturing non-hollow (solid), partially-hollow or completely-hollow objects via different methods.

An accessory device used in combination with a solid-state additive manufacturing system is described. In some configurations, the accessory device can be used in combination with an additive manufacturing system, such as a solid-state additive manufacturing system, to enable printing of large-scale and complex objects, where the objects are much larger than those printed with existing solid-state manufacturing systems. The disclosed accessory device used in conjunction with the a solid-state additive manufacturing system is capable of manufacturing non-hollow (solid), partially-hollow or completely-hollow objects via different methods.

A three-dimensional shaping device includes a nozzle that discharges a shaping material, a stage that includes a stacking surface on which the shaping material is stacked, a moving mechanism that changes a relative position between the nozzle and the stage, a distance measurement mechanism that is disposed at a position facing the nozzle, a cleaning mechanism that cleans a tip end surface of the nozzle, and a control unit that controls the moving mechanism while discharging the shaping material from the nozzle towards the stacking surface so as to shape a three-dimensional shaped object. The control unit measures a first value relating to a distance between the tip end surface of the nozzle and the stacking surface after the tip end surface of the nozzle is cleaned, and controls the moving mechanism based on the first value to adjust the distance between the stacking surface and the tip end surface of the nozzle to a predetermined distance to shape the three-dimensional shaped object.