Robust Linear Quadratic Optimal Control of Cementitious Material Extrusion
This addresses flow stability and dimensional fidelity issues in cementitious material extrusion for 3D printing applications, but it is incremental as it builds on existing control methods.
The study tackled the problem of disturbances and uncertainties in extrusion-based 3D printing of cementitious materials by proposing a robust linear quadratic optimal control framework, which in simulations guaranteed acceptable convergence of tracking errors under bounded disturbances.
Extrusion-based 3D printing of cementitious materials enables fabrication of complex structures, however it is highly sensitive to disturbances, material property variations, and process uncertainties that decrease flow stability and dimensional fidelity. To address these challenges, this study proposes a robust linear quadratic optimal control framework for regulating material extrusion in cementitious direct ink writing systems. The printer is modeled using two coupled subsystems: an actuation system representing nozzle flow dynamics and a printing system describing the printed strand flow on the build plate. A hybrid control architecture combining sliding mode control for disturbance rejection with linear quadratic optimal feedback for energy-efficient tracking is developed to ensure robustness and optimality. In simulation case studies, the control architecture guarantees acceptable convergence of nozzle and strand flow tracking errors under bounded disturbances.