Process Simulation of Composites. Dr. Roland Hinterhölzl
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1 Process Simulation of Composites Dr. Roland Hinterhölzl
2 Process Simulation Why? Aviation industry approx. 50% of the structure are made out of composite: fuselage, frames, stringers, skins, High volume, bigger parts Need for process optimization, for automation [Airbus] Automotive industry Serial production with very high volume, short cycle time, robust processes [BMW] From hand lay up to (partly) automated serial production Automation Shorter cycle times Process reliability Short design and development time new developments and optimization of manufacturing processes Process Simulation of Composites 2
3 Manufacturing in Aerospace and Automotive Industry Aerospace Automotive [FACC] [BMW] Hours, Days Seconds, Minute(s) Process Simulation of Composites 3
4 Overview Motivation Introduction of LCC Forming Simulation Draping Simulation Automated Fiber Placement (AFP) Process Simulation Braiding Process Simulation Simulation of Liquid Composite Moulding (LCM) processes Determination of Process Induced Deformations (PID) & Curing Simulation Simulation Platform Conclusion - Outlook Process Simulation of Composites 4
5 Institute for Carbon Composites Founded in Mai 2009 financially supported by the SGL Carbon Group Professor Dr.-Ing. Klaus Drechsler ~60 Researchers 1 Team Assistant 5 Technical Employees 2 Office locations in Garching 3 lab locations in Garching and Ottobrunn Process Simulation of Composites 5
6 Research Groups Process Technology for Fibers + Textiles Process Technology for Matrix Materials Simulation Material Behavior and Testing Automated Fiber Placement Hybrid Materials +Structures Preform + Flow Process Simulation Composite Testing Lab Braiding Tooling Systems Compaction, Curing and Deformation Test Method Development Tailored Textiles Production Systems Material Modeling and Structural Analysis High Strain Rate Behavior Process Simulation of Composites 6
7 Simulation of composites Semi-finished part structure: semi-finished micro-/mesomechanics part FE draping simulation preforming (here: draping) LCM simulation: flow front matrix-injection Structural component component simulation [FACC AG] Curing- and distortion simulation curing Process Simulation of Composites 7
8 Preform Process Simulation Process Simulation of Composites Kap.-8
9 Overview Motivation for Process Simulation: Analyze the influence of process parameters on produced preforms increase knowledge of the process Optimization of the process and of produced geometry Generate input for further analysis (LCM, Curing/PID, Material Modeling) Main research activities Draping Simulation Automated Fiber Placement Braiding Process Simulation Process Simulation of Composites 9
10 Draping Process Simulation Process Simulation of Composites Kap.-10
11 Goals of Draping Simulation Process development / optimization Geometry and alignment of the flat preform Drapeability (feasibility study) Prediction of draping defects Part design (design to process) Prediction of fiber alignment Prediction of fiber volume fraction tool lay-up of the preform Forming (draping) in required shape preform Embedding in process simulation platform: LCM simulation Curing and PID simulation Structural simulation BMW i3 Airbus fully A380 automated Pressure draping Bulkhead process [BMW] Process Simulation of Composites 11
12 Requirements for Draping Simulation Textiles woven, Non-Crimp Fabrics (NCF), UD, etc. dry or pre-impregnated Deformation modes plain weave twill weave NCF Shear Defects Bending Elongation Inter-ply Motion Intra-ply Motion Wrinkling / Folds Loops Gaps / Voids Fiber Pull-Out Damage of Stitching Process Simulation of Composites 12
13 Numerical Approaches for Draping Simulation Kinematic Approach P pin-joint method [Mack 1950] purely geometrical approach computation of the fiber direction direct cut geometry generation Finite Element Approach modeling of the preform on ply-level with shell elements simulation of the draping process and the tools consideration of forces, friction, velocities, etc. prediction of deformation modes and defects in the preforms L 2 L 1 level of detail shear elongation bending Process Simulation of Composites 13
14 Comparison of the Different Approaches Kinematic Approach + fast & easy to use + many software available + good interface to structural analysis - no material behavior - no process influence - poor results for complex shapes Finite Element Approach + accurate results even for complex shapes + accounts for material and process influence + prediction of draping defects possible (wrinkles, gaps, etc.) - higher computational effort - material testing required Catia CPD (Kinematic Simulation) Experiment PAM-FORM (FE Simulation) Process Simulation of Composites 14
15 Finite Element Approaches for Draping Simulation Macro-FE Approach modeling of the preform on ply-level with shell elements simulation of the draping process and the tools consideration of forces, friction, velocities, etc. prediction of deformation modes and defects in the preforms Meso-FE Approach modeling of the preform on yarn-level with 2D/3D elements simulation of Unit Cells deformations consideration of friction between yarns, weaving structure, prediction of deformation modes and behavior of units cells Not yet suitable for forming simulation (computational cost) on part scale shear elongation bending [Voith] Process Simulation of Composites 15
16 Simulation Procedure Material characterization (simulation of the material behavior) Picture Frame Test Parameter Determination Validation on test geometry Hemisphere Double Dome Process simulation (design and optimization) Diaphragm draping Drape forming Hand lay-up Validation Saertex Process Simulation ECD Process Simulation of Composites 16
17 Material Characterization Devices at LCC Bias Extension Test Picture Frame Test Tensile Test Cantilever Test Friction Test Process Simulation of Composites 17
18 Validation Material card has to be validated before applying the simulation on actual processes 1. Set up of validation process 2. Simulation of validation process 3. Measurement method to compare simulation and test results Validation Process (INSA Lyon) Simulation Measurement Process Simulation of Composites 18
19 Example: FE Simulation of Diaphragm Process Process Simulation of Composites Kap.-19
20 Example Simulation of Single Diaphragm Process Principle: Draping of a textile with a silicone membrane (diaphragm) Membrane Textile Table Tool Placing the fabric over the tool Lowering the edges of the membrane Applying a vacuum between tool and membrane Thermal binder activation [AHD] Demoulding Process Simulation of Composites 20
21 Simulation of the Diaphragm Process Modeling Macro-scale simulation with PAM-Form (ESI Group) Material 140 biphase shell element material with thermovisco-elastic matrix and elastic fibers Setup Draping of a biaxial NCF over a generic helicopter frame Modeling of membrane, fabric, tool and table Same sequence as in experiment Components of MAT 140 (ESI) applying vacuum initial model lowering edges Process Simulation of Composites 21
22 Characteristics of the Diaphragm Process Relative movement between membrane and textile --> Results in high friction forces x-displacement y-displacement high friction Anisotropic friction between membrane and textile --> Orthotropic friction coefficient needs to be defined Fiber Fiber dirc1 dirc1 Fiber dirc2 Fiber dirc2 low friction Process Simulation of Composites 22
23 Simulation Results for Single Ply Draping +/-45 NCF Experiment Simulation -/+45 NCF (Eurocopter DE) Process Simulation of Composites 23
24 Example: FE Simulation of locally stitched NCF Forming Process Simulation of Composites 24
25 Local Stitching NCF preform stacks are locally stitched together for better handling Stitching can influence the draping result Influence of the local stitching needs to be investigated Final Part: Pitch Horn Sewing of Preform Stack Draping of Stitched Preform Stack Lay-up on Tool Process Simulation of Composites 25
26 Single-Lap Shear Test Purpose of test Investigation of initial state: pretensed stitch <> slack in stitch Influence of the stitching on the textile Stress-Strain behavior of the textile in the stitching vicinity Local stitching Lap Shear Test Setup Clamping areas Test Setup of Lap Shear Test Tensile Force applied on Lap Shear Test Process Simulation of Composites 26
27 Modeling the Stress-Strain behavior of the Stitching Only normal stress are applied on PLINKS Definition of a Load-Displacement curve for PLINKS elements F max Phase I: Slack phase -> Lap Shear Test I II III Phase II: Fibers deformation -> Lap Shear Test Phase III: Stitching thread elongation -> Bias Extension Test F max : Maximum bearable force -> Lap Shear Test Load-Displacement Curve for PLINKS elements Process Simulation of Composites 27
28 Simulation of double diaphragm forming process Stitching shape Cut-out line Stitching and cut-out lines Overview of the simulation model Comparison on a real forming process : generic double curved helicopter frame FE meshing automatically created from CAD data Process Simulation of Composites 28
29 Comparison Region a Region b Region c Layup Region Average angle difference Standard deviation [0/90 // -/+45] a 1,89 1,07 b 4,7 5,28 c 13,15 6,85 Margossian et al, Comp. Part A, Process Simulation of Composites 29
30 Automated Fiber Placement (AFP) Process Simulation Process Simulation of Composites Kap.-30
31 Overview Simulation of the AFP Process Placement scenario Validation Simulation Model Therm. and mech. material models [LCC] Process Simulation of Composites 31
32 Research Activities at the LCC 1D Simulation: Calculation of the time-dependent mech. compaction behaviour Simulation of the transient heat transfer ε [Δl / l] Zeit [s] 2D Simulation: Prediction of the mech. and therm. behaviour of the process Simulation of bridging of the tape Modeling of tack 3D Simulation: Mech. placement on complex geometry possible Prediction of the complete thermal history of the placement process Process Simulation of Composites 32
33 AFP Process Simulation: Example Gap- / Overlap detection Compaction / Debulking Bridging Temperature distribution Fig. 2: Compaction behaviour of a Slit-Tape Define reliable process window Fig. 3: Sim. Bridging Fig. 1: Gap in Simulation Fig. 4: Surface temperature distribution Process Simulation of Composites 33
34 Braiding Process Simulation Process Simulation of Composites Kap.-34
35 Braiding Process Simulation Goals of braiding process simulation Process parameters have a strong influence on braided structure Mandrel shape defines contour of structure Modeling the real manufacturing process using an explicit FE-Solver (e.g. Abaqus/Explicit, PAM-Crash) to analyze correlation between process parameters and braided structure Rovings are represented by truss- or beamelements Consideration of friction between roving-roving rovings-guide ring rovings-mandrel diamond/ half regular/ full triaxial Process Simulation of Composites 35
36 Simulation of Liquid Composite Moulding (LCM) processes Process Simulation of Composites Kap.-36
37 Motivation Goals Prediction of process parameters Tool pressure Flow front velocity Fill time Prediction of defects (dry spots, pores) Cure kinetics / Heat transport Fig.1: Sportscar Monocoque Optimization of injection schemes Tool design Design of robust processes Challenges Material characterization Preform Resin Capturing influences of preceding process steps (such as textile handling, preforming) Fig.2: Filling simulation (flow front plot) of a Sportscar Monocoque Process Simulation of Composites 37
38 Physics of LCM Processes Flow processes in porous media can be described by the Navier-Stokes equation ρ v t = P + T + f By homogenization of the media (e.g. by volume averaging) and introducing some assumptions the flow can be described by Darcy s law v = K μ P ρg K μ P Darcy s law relates the flow front velocity v to the applied pressure gradient P with the proportionality constants permeability K and viscosity μ. Permeabiliy is a material parameter of the fiber preform Material Layup Fiber orientation Compaction state Fig.1: Illustration of flow fronts (Real vs. Darcy) within an textile preform Newtonian Fluid Constant Viscosity Homogeneous, Inelastic Porous Medium Neglecting of Gravity and Capillary Forces Low Flow Velocity (Re < 1) Saturated Flow Neglecting Intra Yarn Flow Tab.1: Summary of assumptions for validity of Darcy s law Process Simulation of Composites 38
39 Permeability Testing for LCM Processes (lat.: permeare = to pass ) Description In the 3D case the permeability can be noted as a 2nd order tensor. The tensor can be diagonalized with a rotation of the global coordinate system to a coordinate system spanned by the major permeabilities (cf. Eq.1). Determination Experimental 1D-flow method Radial-flow method (2D) 3D-flow method K = ln-plane components / 2D tensor K K K 33 Fig.1: 3D permeability tensor Off-Plane component/ through thickness perm. Numerical (Multi-scale approach) CFD-calculation on meso-level based on representative volume elements (RVE) Abstraction of the results to the macro level as permeability tensor Fig.2: In-plane test setup Fig.3: Off-plane test setup Process Simulation of Composites 39
40 Numerical Method - Overview Fabric Scan Info Grey Box Software Tool (Matlab) Material Card RTM Process Simulation (PAM-RTM) Image Analysis Textile Modeling Permeability Calculation Material Data Draping Simulation Process Parameter CAD Fig.1: Fabric Scan Fig.2: Image Analysis Fig.3: Textile Model [WiseTex, KU Leuven] Process Simulation of Composites 40
41 Determination of Process Induced Deformations (PID) & Curing Simulation Process Simulation of Composites Kap.-41
42 Motivation: Dimensional Control on Stiff Structures Geometrical deviations on stiff structures result in Deformed frame section Magnification factor: 30 Additional rework effort and / or high mounting forces required, Expensive iterative tooling adaption. Picture: DLR Deformed frame after curing Magnification factor: Process Simulation of Composites 42
43 Curing simulation - goals Primary: Determination of process induced deformations (dimensional accuracy) Evaluation of the effects of residual stress (dimensioning) Secondary: process optimization (cycle time) process control (interaction between parallel simulation of physical curing process) Shrinkage Spring-In / Spring - Back PID Fernlund et al, 2003 Warpage Svanberg, 2002 Twigg, Process Simulation of Composites 43
44 Methodologies for determination of process induced deformations (PID) Increasing level of detail and modeling effort Experimental: Iterative optimization of final part shape Phenomenological: Summarization of different mechanisms with one actuating variable (enhanced CTE) Curing simulation: Simulation of all relevant mechanisms (e.g. reaction kinetics, modulus development, ) Analytical: Estimation of deformation for simple geometries Evaluation of Residual Stresses, Optimization of Process Control PID Quantification (Dimensional Control) Process Simulation of Composites 44
45 [ deg] Position1 Position2 Position3 Position4 Position5 Simplified Approaches for PID Determination Utilization of simplified approaches for strain anisotropy Cure m eq m therm m chem Fig. 1: Thermal and effective chemical shrinkage are projected on the matrix coefficient of thermal expansion x z 1 0 z meq "Reiner" Spring-In, MS1-17, MS1-18, MS1-19 Fig. 4: Application of α m,eq for particular material and process on a frame structure Fig. 3: Verification of α m,eq on linearelastic FEA of cool down step Fig. 2: Experimental Spring-In data presents target variable for determination of α M,eq Process Simulation of Composites 45
46 Process simulation including curing: application flow on the example COMPRO Virtual autoclave heat transfer autoclave gas part-tooling-assembly feedback control autoclave Thermo-chemical module reaction kinetics heat conduction Figure: Experimental determination of effective HTC Stress module modulus development related to resin degree of cure, temperature resin cure shrinkage and thermal expansion coefficients control routine status variables (,T) Figure: Time-Temperature-Transition-(TTT) Diagram Flow Module resin flow due to laminate compaction (viscosity, permeability) variations in wall thickness and fiber volume content Johnston A., Hubert P., 1996 Figure: modulus development COMPRO is a commercial composite processing software: Convergent Manufacturing Technologies, Canada Figure: Force-Displacement-Diagram Fiber Bed Compaction Process Simulation of Composites 46
47 Residual dalpha / dt [1/s] alpha [1] dalpha / dt [1/s] Characterization for Process Simulation Resin Cure Kinetics Viscosity Development Karkanas, Partridge: Cure Modeling and Monitoring of Epoxy/Amine Resin Systems. II. Network Formation and Chemoviscosity Modeling Cure Shrinkage 8 x 10-4 dalpha / dt of the model solution Database alpha of the model solution time [min] x 10-5 residual dalpha / dt of the model solution time [min] 1 Modulus Development time [min] Process Simulation of Composites 47
48 Curing / PID simulation - results Quantities: Deformations Residual stress Spatial distribution of fiber volume fraction Time history of temperature evolution on the part Final degree of cure distribution Glass transition temperatures Assessment a priori concerning: Mounting tolerances, dimensions of tooling Load bearing capacity Part s quality (sufficient degree of cure, glass transition temperatures, hot spots (resin degradation)) Optimization via variation of Geometry Material selection Lay-up Process cycle Deformed frame section Magnification factor: 30 Fig. 1: Spring-In of a generic C-frame after curing Fig. 2: Temperature Distribution on a Frame Section at the End of 2 nd Ramp [simulated utilizing Compro2D and Raven, Convergent Manufacturing Technologies, Vancouver, Canada] Process Simulation of Composites 48
49 Simulation Platform Process Simulation of Composites Kap.-49
50 Simulation Platform Forming Simulation Material Modeling Flow Process Simulation [FACC AG] Structural Analysis Compaction, Curing and Consolidation Process Simulation of Composites 50
51 Process Simulation Platform - Example Preforming Draping, Braiding, Filament winding, Simulation of the preform process Preform Characterization Experimental Numerical LCM-Simulation Tool design, Process time prediction (Flow front velocity, pressure distribution) Process optimization Curing simulation (for PID investigations) Process Simulation of Composites 51
52 Conclusion - Outlook Process Simulation of Composites Kap.-52
53 Geometry Manufacturing Geometry, Quality (Waviness, Porosity, etc.) In-service, Recycling Allowable Damages Repair Effects Robust Design via Simulation as Built Material Product Development Design, Process Simulation, Structural Analysis, Testing, Quality Assurance, Thank you for your attention! Process Simulation of Composites 53
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