Cold Spray of Al Alloys as Repair Technology in Aeronautics
Tuesday, May 12, 2015: 5:00 PM
Room 102A (Long Beach Convention and Entertainment Center)
Dr. Simone Vezzù
,
Veneto Nanotech, Venice, Italy
Enrico Vedelago
,
Veneto Nanotech, Venice, Italy
Mr. Peter Richter Sr
,
Impact Innovations GmbH, Rattenkirchen, Germany
Mr. Peter Richter Jr
,
Impact Innovations GmbH, Rattenkirchen, Germany
Prof. Mario Guagliano
,
Politecnico di Milano, Milano, Italy
Mrs. Atieh Moridi
,
Politecnico di Milano, Milano, Italy
Dr. Pedro Poza
,
Univeridad Rey Juan Carlos, Mostoles, Spain
Dr. C.J. Munez
,
Univeridad Rey Juan Carlos, Mostoles, Spain
Dr. Giovanni Paolo Zanon
,
GE Avio s.r.l., Rivalta di Torino, Italy
Dr. Giovanni Alfeo
,
GE Avio s.r.l., Brindisi, Italy
Dr. Seyyed Mostafa Hassani Gangaraj
,
Politecnico di Milano, Milano, Italy
In view of the high cost for manufacturing high performance aero engine components, the importance of maintenance and repair is crucial. In particular, the use of thermal techniques such as welding or thermal spray deposition to repair aluminium aircraft components could affect noticeably the substrate-coating interface as well as the residual stress state and microstructure of the whole zone subjected to the thermal input. In this field, the Cold Spray technology is gaining more and more interest from the aeronautic industry for the deposition of thick coatings with a low temperature approach and the attention of European Union on this technological development is very high as confirmed by the 7
thFP CORSAIR project wherein this study is framed.
Currently, a wide range of Al alloy based coatings are deposited by high-pressure cold spray using a polymeric nozzle that limits the maximum operating gas temperature to 350°C. This study goes beyond this limit by employing a water cooled SiC nozzle that allows to preheat the process gas to temperatures higher than 350°C and therefore to reduce significantly the critical velocity of sprayed materials. The deposition of A2024 and A357 coatings on similar base materials was studied as the base interest for aeronautic MRO processes of aircraft parts (A2024), and housings and gearboxes (A357), respectively. The evolution of morphology, microstructure and mechanical properties with the spray temperature were studied. Furthermore, the coating adhesion and residual stress profiles were determined for the coatings sprayed with the polymeric nozzle at 350°C and those sprayed with the SiC nozzle at higher temperatures. Finally, repair trials were performed on industrial prototypes following standard procedures and recommendations by the aerospace partnerns.