Abstract Powder-bed-based additive manufacturing involves melting of a powder bed using a moving laser or electron beam as a heat source. In this paper, we formulate an optimization scheme that aims to control this type of melting. The goal consists of tracking maximum temperatures on lines that run along the beam path. Time-dependent beam parameters (more specifically, beam power, spot size, and speed) act as control functions. The scheme is greedy in the sense that it exploits local properties of the melt pool in order to divide a large optimization problem into several small ones. As illustrated by numerical examples, the scheme can resolve heat conduction issues such as concentrated heat accumulation at turning points and non-uniform me...
High demand for components with complex geometries at macro and micro levels drives the development ...
Laser and electron beam powder bed melting additive technologies are being rapidly adapted by indust...
This work investigates path planning optimization for powder bed fusion additive manufacturing proce...
Powder-bed-based additive manufacturing involves melting of a powder bed using a moving laser or ele...
Powder-bed-based additive manufacturing involves melting of a powder bed using a moving laser or ele...
In powder-bed additive manufacturing, a laser beam melts a thin layer of metallic powder, which soli...
AbstractProcess optimization is an important area requiring further research in the field of rapid p...
International audienceAdditive Manufacturing (AM) through a Laser Powder Bed Fusion (LPBF) process c...
In this paper, scanning paths optimization for the powder bed fusion additive manufacturing process ...
Temperature distribution gradient in metal powder bed additive manufacturing (MPBAM) directly contro...
We developed and applied a model-driven feedforward control approach to mitigate thermal-induced fla...
Additive Manufacturing based on Powder Bed Fusion processes enables the construction of end-use func...
High demand for components with complex geometries at macro and micro levels drives the development ...
Laser and electron beam powder bed melting additive technologies are being rapidly adapted by indust...
This work investigates path planning optimization for powder bed fusion additive manufacturing proce...
Powder-bed-based additive manufacturing involves melting of a powder bed using a moving laser or ele...
Powder-bed-based additive manufacturing involves melting of a powder bed using a moving laser or ele...
In powder-bed additive manufacturing, a laser beam melts a thin layer of metallic powder, which soli...
AbstractProcess optimization is an important area requiring further research in the field of rapid p...
International audienceAdditive Manufacturing (AM) through a Laser Powder Bed Fusion (LPBF) process c...
In this paper, scanning paths optimization for the powder bed fusion additive manufacturing process ...
Temperature distribution gradient in metal powder bed additive manufacturing (MPBAM) directly contro...
We developed and applied a model-driven feedforward control approach to mitigate thermal-induced fla...
Additive Manufacturing based on Powder Bed Fusion processes enables the construction of end-use func...
High demand for components with complex geometries at macro and micro levels drives the development ...
Laser and electron beam powder bed melting additive technologies are being rapidly adapted by indust...
This work investigates path planning optimization for powder bed fusion additive manufacturing proce...