The results obtained during the first reporting period remain limited, as the DCs’ activities began at M13. Nevertheless, significant advancements beyond the current state of the art have already been achieved across the three technical/scientific Work Packages (WPs).
WP2: Knowledge-Based Customization of CS Deposits (Microstructural and Mechanical Aspects)
DC11-UoN: Focused on customized feedstock powders, particularly powder pre-treatment for cold spray applications. Work has centered on defining a new interlacing strategy to exploit the characteristics of Al alloy powders. Two powders (Al2024 and AlSi7Mg) have been selected and will undergo heat treatment to optimize cold spray repair performance in aeronautics.
DC2-TCD: Developed an advanced experimental setup for in-depth analysis of particle–substrate interactions to investigate cold spray adhesion mechanisms. Experimental tests are ongoing, with partial results under varying atmospheres and process pressures already discussed.
DC3-URJC: Conducted a detailed study on the relationship between particle velocity and process parameters using advanced experimental tools, achieving strong agreement with numerical simulations.
DC4-IPP: Investigating fatigue crack propagation in cold-sprayed free-standing deposits, obtaining unprecedented insights into the influence of process parameters on Kth and fatigue crack growth rates.
WP3: Real-Time Monitoring, Control, Automation, and Digitalization of the CS Process
DC5-SchuF: Completed preliminary material screening of high-entropy alloys (HEAs) with superior erosion, corrosion, and thermal resistance for CS deposition. Applied these concepts to industrial valve components, performing structural analysis to identify high-risk erosion zones. Proposed an improved check valve design integrating CS coatings for disc surface protection.
DC6-TAU: Addressing challenges in achieving geometric accuracy and consistent coating quality. Developing a fully automated CS system with real-time, in-situ monitoring and closed-loop control. The system integrates laser profilometry and imaging to measure deposit profiles and particle properties, enabling dynamic robot motion adjustments during spraying.
DC7-UB: Delivered the first version of a digital twin of the CS process, featuring ABB IRB 2400/16 and PlasmaGiken PCS 100, modeled in Rhinoceros with export capability to ABB RobotStudio.
DC8-POLIMI: Conducted an extensive survey of 3D scanning technologies and photogrammetry for real-time optical monitoring and shape correction. Initial results demonstrate strong potential for improving CS accuracy and reducing post-processing costs.
WP4: Innovative Applications Beyond Conventional Thermal Energy-Based Technologies
DC09-POLIMI: Exploring CS as an alternative joining technique to welding. Developed a numerical model predicting joint shape with accuracy surpassing current standards.
DC10-POLIMI: Investigating CS for repair in Oil & Gas applications. Proposed a novel approach for applying CS under elastic load conditions to enhance mechanical properties of repairs.
DC1-CNRS: Established a robust interdisciplinary foundation combining thermodynamic modeling, process design, robotic integration, and material characterization. Experimental and simulation work validated alloy compositions and enabled controlled CSAM trials. Positioned to advance toward high-strength, high-conductivity copper-based structures for magnetic applications in Year 2.