What`s Already Done
Transcription
What`s Already Done
Future Challenges of Advanced Polymer Composites Introduction into Aircraft Engines Artem Korotygin Project Manager (Polymer Composites) NPO Saturn www.npo-saturn.ru April 2015 1 EVOLUTION OF CIVIL AIRCRAFT ENGINES GE90 Trent 800 GEnx Trent 900 Trent 1000 PW4000-112 Trent XWB GP7200 LEAP-X GE9x Trent XWB+ PW1000G GTF+ SaM146 1990 1995 2000 2005 2010 2015 2020 2 ACTUALITY OF COMPOSITES APPLICATION Absence of composite parts leads to lack of competitive strength of Russian aircraft engines 3 COMPOSITE PARTS DEVELOPMENT CYCLE NPO Saturn maturity – high level of skills and knowledge – medium – basic 4 COMPOSITE TECHNOLOGY TENDENCIES 1 2 3 Cheap Composite Part • High-Performance Thermoplastic Composites (PEEK, PPS, PEI, etc) forming methods: thermoforming, injection molding and hybrid technologies • 2.5D & 3D-preform manufacturing (3D-Weaving, Braiding, Stitching) and RTM forming • Automated prepreg lay-up Cost Reduction Repeatability Improvement Manual Work Minimization Automation 5 Cost and time of part manufacturing EVOLUTION OF COMPOSITE TECHNOLOGIES Compression Autoclave RTM+Fabrics AFP+ATL RTM+Braiding RTM+3D-Weaving Thermoforming Injection Molding 1980 1990 2000 2010 2020 Start of intensive introduction, year 6 HP THERMOPLASTIC COMPOSITES TECHNOLOGIES Thermoforming Injection Molding 7 HP THERMOPLASTIC COMPOSITES ADVANTAGES Advantages: + Working temperatures up to 260 °С + High radiation resistance + High impact resistance + Excellent tribologic properties and environmental resistance + Highly repairable + Almost unlimited storage time + Wide list of technological processes (molding, bending, welding, etc) + Reprocessing of items and waste + Shortened molding time + Low emission + High fire-retarding quality + Energy efficient cheaper serial production 8 3D-WEAVING ADVANTAGES 3D-Weaving + RTM Advantages: + Preform manufacturing process automation + No delamination + Shear strength increase + Foreign object damage resistance increase + 3D-preform geometry is very similar with final part geometry + Material design with required performance in all dimensions: 3D-material + Waste material reduction => The technology is not developed by Russian industrial facilities 9 NPO SATURN COMPOSITE PROJECT Overview OGV Blade Fan Fairing Weight, kg Now 4 Target 1.7 Cost 100% 60% Weight, kg Now 18 Target 10 Cost 100% 60% OGV Shroud Weight, kg Now 5 Target 1.8 Cost 100% 50% Internal Panels Weight reduction ~16.5 kg Cost reduction ~1 mln. RUB Weight, kg Now 4 Target 1 Cost 100% 90% 10 NPO SATURN COMPOSITE PROJECT Internal Panels What’s Already Done Parts Design Static Strength and Modal Analysis Tooling Design Tooling Production First Prototypes Production Current Status: Production of Parts for Testing 11 NPO SATURN COMPOSITE PROJECT Fan Fairing What’s Already Done f2D f3D f4D f5D f24D Static Strength and Modal Analysis Composite + Titanium Part Design Bird Strike Imitation Modeling Tooling Design & Production Composite-Titanium Joints Adhesion Tests Current Status: First Prototypes Production 12 NPO SATURN COMPOSITE PROJECT OGV Blade What’s Already Done V Static Strength and Modal Analysis Bird Strike Imitation Modeling Technological Modeling Weld Lines Analysis Tooling Design Material Properties Research Current Status: Tooling Production 13 NPO SATURN COMPOSITE PROJECT OGV Shroud What’s Already Done Part Design Technological Modeling FBO Strength Analysis Static Strength and Modal Analysis Distortion Analysis Tooling Design Current Status: Tooling Production 14 NPO SATURN COMPOSITE PROJECT 3D-Weaving What’s Already Done 2-2 1-1 1-2 2-1 2-3 2-4 3D-Weaving Structures Choice & Design Tooling Design & Production Production of Specimens Preforms by 3D-Weaving Specimens Production Current Status: Mass Production of Specimens for Testing 15 WHAT’S NEXT? 4 questions, that must be answered to leap forward How to design a 3D-reinforced part? ? Modeling of 3D-weaving process ? Simulation of 3D-preform deformation process in the RTM mould ? Simulation of RTM process for 3D-preform ? Strength analysis of a 3D-reinforced part + Reduction of technological iterations + Low number of impregnation defects + Ability to design a 3D-structure with predetermined mechanical properties How to impregnate a 3D-reinforced preform with HP thermoplastic resin? ? High viscosity of resin blocks impregnation ? It is hard to achieve high fiber content ? Possibility of fiber deformation during RTM + Repairability of the part + Significant reduction of part production time + High resistance to erosion and climatic factors How to create thermoplastic composite part with a hybrid reinforcement ? ? Adhesion between different reinforcements ? Selection of injection process parameters ? Minimizing of consolidation time + Benefits of long and short-fiber reinforcement + High part strength with low production time How to repair thermoplastic composite engine parts ? ? Determination of critical damage criteria ? Design of tools for on-site repairs + Exclude of main operational advantage of metals over composites – their high on-site repairability 16 Thank you for your attention 17