A large area sintering platform, system, and methodology. The system includes a convection oven with a projection window disposed within a top surface of the oven. A platform is disposed within the oven below the window at a spaced distance away from the window. A powder is positioned on top of the platform, with a thermocouple positioned within the powder on the platform. A high intensity projector moves in sync with the platform, and uses low intensities and long exposure times to project an image through the window onto the powder and sinter the powder to fabricate the desired model layer by layer.

A large area sintering platform, system, and methodology. The system includes a convection oven with a projection window disposed within a top surface of the oven. A platform is disposed within the oven below the window at a spaced distance away from the window. A powder is positioned on top of the platform, with a thermocouple positioned within the powder on the platform. A high intensity projector moves in sync with the platform, and uses low intensities and long exposure times to project an image through the window onto the powder and sinter the powder to fabricate the desired model layer by layer.

This invention teaches a quality assurance system for additive manufacturing. This invention teaches a multi-sensor, real-time quality system including sensors, affiliated hardware, and data processing algorithms that are Lagrangian-Eulerian with respect to the reference frames of its associated input measurements. The quality system for Additive Manufacturing is capable of measuring true in-process state variables associated with an additive manufacturing process, i.e., those in-process variables that define a feasible process space within which the process is deemed nominal. The in-process state variables can also be correlated to the part structure or microstructure and can then be useful in identifying particular locations within the part likely to include defects.

Device for the additive production of three-dimensional components (2), namely a laser melting device or laser sintering device, in which a component (2) is produced by successive solidifying of individual layers (3) made from solidifiable construction material, by the effect of radiation (4), through melting of the construction material (5), wherein the dimensions and/or temperature of the melt area (6) generated by a point-shaped or line-shaped energy input can be captured by a sensor device (8) of a process monitoring system, and sensor values for evaluation of a component quality can be deduced therefrom, wherein the radiation (9) created by the melt area and used for the generation of the sensor values passes through the scanner used for the melt energy input, and is guided from there to the sensor device (8) of the process monitoring system, wherein an optical focus tracking device (20) is arranged in the radiation path used for generation of the sensor values between the scanner (10) and the sensor device (8) of the process monitoring system, which optical focus tracking device can be controlled by electronic machine data for focus tracking.

A method of operating an apparatus (10) for producing a three-dimensional work piece (18) by irradiating layers of a raw material powder with electromagnetic or particle radiation comprises the steps of a) applying a layer of raw material powder onto a carrier (12); b) selectively irradiating the layer of raw material powder with electromagnetic or particle radiation in accordance with a geometry of a corresponding layer of the work piece (18) to be produced; and c) repeating steps a) and b) until the work piece (18) has reached the desired shape and size. For at least a portion of at least some of the layers, a scanning time (t.sub.s) from the beginning of the exposure of a respective raw material powder layer portion to electromagnetic or particle radiation until the beginning of the exposure of a new raw material powder layer applied on top of said layer portion to electromagnetic or particle radiation is controlled so as to not fall below a specific minimum value which is individually set for said layer portion in dependence on a layer portion specific quality parameter. layer portion specific quality parameter

A method of operating an apparatus (10) for producing a three-dimensional work piece (18) by irradiating layers of a raw material powder with electromagnetic or particle radiation comprises the steps of a) applying a layer of raw material powder onto a carrier (12); b) selectively irradiating the layer of raw material powder with electromagnetic or particle radiation in accordance with a geometry of a corresponding layer of the work piece (18) to be produced; and c) repeating steps a) and b) until the work piece (18) has reached the desired shape and size. For at least a portion of at least some of the layers, a scanning time (t.sub.s) from the beginning of the exposure of a respective raw material powder layer portion to electromagnetic or particle radiation until the beginning of the exposure of a new raw material powder layer applied on top of said layer portion to electromagnetic or particle radiation is controlled so as to not fall below a specific minimum value which is individually set for said layer portion in dependence on a layer portion specific quality parameter. layer portion specific quality parameter

An additive manufacturing apparatus manufactures a shaped object by stacking a bead that is a solidified product of a filler metal caused to be melted. The additive manufacturing apparatus includes: a feeding unit that feeds the filler metal to a workpiece; a beam source that outputs a beam for melting the filler metal that is fed; and a position calculation unit that calculates a tip position of the filler metal, the tip position being a position where a temperature reaches a melting point of the filler metal by irradiation with the beam, on the basis of a feeding speed of the filler metal to be fed to the workpiece and beam power from the beam source.

An additive manufacturing apparatus manufactures a shaped object by stacking a bead that is a solidified product of a filler metal caused to be melted. The additive manufacturing apparatus includes: a feeding unit that feeds the filler metal to a workpiece; a beam source that outputs a beam for melting the filler metal that is fed; and a position calculation unit that calculates a tip position of the filler metal, the tip position being a position where a temperature reaches a melting point of the filler metal by irradiation with the beam, on the basis of a feeding speed of the filler metal to be fed to the workpiece and beam power from the beam source.

Estimation algorithms, methods, and systems are provided that estimate the internal temperatures inside of a part being built using powder bed fusion (PBF). Closed-loop state estimation is applied to the problem of monitoring temperature fields within parts during the PBF build process. A simplified linear time-invariant (LTI) model of PBF thermal physics with the properties of stability, controllability and observability is presented. In some aspects, Model Predictive Control (MPC) may be used as an expanded application of an Ensemble Kalman Filter (EnKF) methods to control the PBF process. MPC is used to forecast the PBF build process behavior N time steps into the future and identifies inputs that drive the temperature of a corresponding node in a mesh of n nodes towards a predetermined target temperature. The inputs are

A device is provided, for analyzing sensor data of a sensor arranged in an apparatus for producing a three-dimensional work piece via irradiation of layers of raw material with an energy beam. Further, a corresponding method and a corresponding computer program product are provided.