A repair and overhaul methodology for aeroengine components

“…Non-destructive inspection techniques to detect cracks were employed (Diamanti et al 2005). Methodology for repair and overhaul of aero engine has been developed (Yilmaz et al 2010 peening technology has been employed for repairing (Kudryavtsev et al 2007). Repairing operation on different parts has been carried out (Desir 2001) but still in current scenario, no researcher is found successful in diminishing the dilemma between repair processes and manufacturing processes, for example, welding process is a joining process in manufacturing terminology but in repair terminology, welding is a material addition process to prepare surfaces which resulted in a situation where repairer are in no-man's-land.…”

Section: Literature Review In Repair Technologymentioning

confidence: 99%

Transformation from manufacturing process taxonomy to repair process taxonomy: a phenetic approach

Raza

Wasim

Khan³

2018

J Ind Eng Int

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“…Since each blade undergoes complex deformation within the range of design tolerance in the forming process [2], its nominal computer-aided design (CAD) model cannot be directly used for NC tool path generation. In addition, the repair process of serviced blade faces the similar challenge [3]. Reverse engineering (RE) technology has been widely recognized as a crucial role in the secondary NC machining.…”

Section: Introductionmentioning

confidence: 99%

Reverse modeling strategy of aero-engine blade based on design intent

Zhang

Chen

Tao

2015

Int J Adv Manuf Technol

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Blade geometry plays an extremely important role in the aerodynamic performance of aero-engine. However, in the process of secondary machining for near-net shape or serviced blade, the deviation between the actual and nominal blades can raise serious problems for NC tool path generation. It is even worse that inappropriate reverse modeling may change the design intent and deteriorate the aerodynamic performance. This paper presents an innovative strategy for reconstructing actual profiles from measured data. Comparing with conventional reverse modeling, the proposed strategy emphasizes functional significance of the known feature information concerned with implicit design intent. The preservation of design intent has three levels by cognition of the feature information. Firstly, the established technique for rigid registration is improved by means of incorporating accuracy feature into localization. Secondly, the parametric design methodology of aero-engine blade profile is introduced into the free-form deformation (FFD) of cross sections to control geometry feature, and finally, it guarantees aerodynamic performance feature. Some practical examples are given to demonstrate the effectiveness and superiority of the strategy.

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A repair and overhaul methodology for aeroengine components

Cited by 184 publications

References 12 publications

Microstructural and mechanical characterization of Ti6Al4V refurbished parts obtained by laser metal deposition

Microstructural and mechanical characterization of Ti6Al4V refurbished parts obtained by laser metal deposition

Transformation from manufacturing process taxonomy to repair process taxonomy: a phenetic approach

Reverse modeling strategy of aero-engine blade based on design intent

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