Title :
Robotic approach to improve turbine surface finish
Author :
Sabourin, M. ; Paquet, F. ; Hazel, B. ; Côté, J. ; Mongenot, P.
Abstract :
This paper describes the approach taken by Alstom and Hydro-Quebec (HQ) in the development of robotic polishing to improve turbine efficiency by reducing surface roughness. Modern, large hydraulic turbines are profiled by a 5-axis milling machine and are polished manually. By robotizing the polishing, it becomes possible to obtain a better surface finish at a reasonable cost, and to reduce hydrodynamic friction loss. HQ´s portable robot Scompi was used to perform the polishing. Recent developments made by the supplier of the abrasives have resulted in their increased durability and improved productivity. A technique was developed to select the polishing process parameters best suited to a given surface waviness and roughness. A polishing test was carried out on a full-scale Francis turbine blade. The surface finish was lowered from Ra=15μm to Ra=0.1μm and the waviness (scallop 0.2mm tall and 30mm wide) was grinded away at a rate of 5 hour/m2.
Keywords :
hydraulic turbines; hydrodynamics; industrial robots; milling machines; polishing machines; 5-axis milling machine; Alstom; Francis turbine blade; Hydro-Quebec; Scompi; hydraulic turbines; hydrodynamic friction loss; robotic approach; robotic polishing; turbine efficiency; turbine surface finish improvement; Blades; Robot kinematics; Robot sensing systems; Rough surfaces; Surface roughness; Turbines; Grinding; Hydrodynamic Friction; Polishing; Robot; Roughness; Turbine; Waviness;
Conference_Titel :
Applied Robotics for the Power Industry (CARPI), 2010 1st International Conference on
Conference_Location :
Montreal, QC
Print_ISBN :
978-1-4244-6633-7
DOI :
10.1109/CARPI.2010.5624446
