1 / 19

Z. JENDLI *, J. FITOUSSI*, F. MERAGHNI** et D. BAPTISTE*. *LM3 UMR CNRS 8006. ENSAM Paris.

Micromechanical analysis of strain rate effect on damage evolution in discontinuous fibre reinforced composites. Z. JENDLI *, J. FITOUSSI*, F. MERAGHNI** et D. BAPTISTE*. *LM3 UMR CNRS 8006. ENSAM Paris. **LMPF-JE 2381. ENSAM Châlons en Champagne. CONTEXT. Passengers safety.

fala
Télécharger la présentation

Z. JENDLI *, J. FITOUSSI*, F. MERAGHNI** et D. BAPTISTE*. *LM3 UMR CNRS 8006. ENSAM Paris.

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Micromechanical analysis of strain rate effect on damage evolution in discontinuous fibre reinforced composites Z. JENDLI*, J. FITOUSSI*, F. MERAGHNI** et D. BAPTISTE*. *LM3 UMR CNRS 8006. ENSAM Paris. **LMPF-JE 2381. ENSAM Châlons en Champagne.

  2. CONTEXT Passengers safety Structures lightweight Interaction Manufacturing ↔ mechanical behaviour Manufacturing and productivity. • advantages of SMCcomposite material • good strength/weightratio • manufacturing process devoted to large series • high-energy dissipation with a diffuse damage.

  3. Development of multi-scaleapproaches. CONTEXT • Industrial requests • Overall mechanical behaviour prediction under dynamicloading. • Inaptitude of current dynamic behaviour laws for the structures calculation in composite materials • Insufficiency of the phenomenological approaches currently used. • Material microstructure integration • Physical description of damage mechanisms.

  4. . Analysing effect in the SMC-R damage ( e ) ( e = 10-4 – 400 s-1 ) AIMS • Experimental analysis (at micro and macroscopic scales) • Behaviour stages • Damage threshold and accumulation • Behaviour modelling using a multi-scale approach • Visco-elastic • Visco-damage.

  5. Introduction of strain rate effect in a micromechanical model Prediction of the dynamic mechanical behaviour and its interaction with the composite microstructure. MODELING COMPOSITE DYNAMIC BEHAVIOUR • Damage mechanisms experimental investigation • Interrupted high-speed tensile tests. • In-situ tensile tests. • SEM observations.

  6. -4 & £ e £ -1 -1 10 s 400 s EXPERIMENTAL INVESTIGATIONS MATERIAL SMC-R26 composite Sheet Molding Compound-Random. glass E/polyester, discontinuous fibres 26%. TESTS PARAMETERS • Hydraulic high speed tensile test machine • 20 m/s, piezo-electric load cell 50 kN • Performed strain rates

  7. . ( e ) Strain rates effects on the SMC-R mechanical characteristics • The composite macroscopic response is widely affected by • Minor variation of the anelastic slope as a function of the strain rate • Insensitivity of the Young’s modulus to strain rate increase.

  8. The first non-linearity Damage threshold is considerably delayed in term of strain and stress. Strain rates effects on the SMC-R mechanical characteristics

  9. Strain rates effects on the SMC-R mechanical characteristics • Behaviour accommodation when increases the strain rate : • Steady rise of the ultimate strain (38 %) • Maximum stress increases considerably.

  10. SMC-R specimen Specimen/fuse Intermediate fixing Ligament Mechanical fuse å Damage analysis INTERRUPTED DYNAMIC TENSILE TEST The specimen geometry is a bar with dimension 36*6,5*2,7 mm3 The fuses material: PMMA (Poly Methyl Methacrylate) Fragile elastic behavior.

  11. D_critical D E = - D 1 0 E Macroscopic damage analysis Macroscopic damage vs. total strain for three strain rate values Damage initiation is considerably delayed in terms of strain thresholds Critical damage level : insensitive to the strain rate effect.

  12. e_ult Microscopic damage analysis Fibre-matrix interface damage description • Strain rate increase: • Delayed damage threshold • Decreased damage growth speed. d_micro = fv_debonded / fv total. Overall behaviour accommodation Microscopic analysis results corroborate those obtained at the macroscopic level.

  13. l1 q l2 Microscopic damage analysis Global damage growth in term of micro-cracks length (including matrix and interface damage) • Delayed damage threshold • Decreased damage growth speed.

  14. Viscosity effects on the fibres-matrix interfaces damage. CONCLUSION • Strain rate effects : • Insensitivity of the material elastic properties. • Delayed damage threshold. • Decreased damage growth speed. • Accommodation of the overall behaviour leading • to an increase of the ultimate characteristics. Integration of the experimental findings to set up physical damage modelling. Prediction of elastic visco-damaged behaviour.

  15. THE END☺

  16. homogeneous • e constant Experimental investigation Specimen optimised geometry : L1= 6 mm, L2 = 80 mm, L3 = 30 mm, R = 7 mm, e=3 mm Evolution of the longitudinal stress for a test calculated at 200/s

  17. Experimental Methodology Analysis on the two scales of material Macroscopic analysis Microscopic analysis

  18. Probabilistic approaches Weibull, Monte Carlo, ... Local criterion PROCESS Pr =1 - exp[(0202m (0 0 m) = f ( ) Matrix Polymer or Metallic Mori Tanaka’s approach Eschelby inclusion theory Matériau Homogène Equivalent . Fibres Architecture, Geometry, quantity, ... Behaviour law Visco-elastic damage Micro discontinuities . Experimental investigation Interrupted dynamic tests SEM and ultrasonic tests Damage growth D=f (e)  . ( e ) MULTI –SCALES MODELLING

More Related