Lifetime prediction of filled elastomers in consideration of multiaxial stress states. London, 14 th of October

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Colin Patterson
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1 Lifetime prediction of filled elastomers in consideration of multiaxial stress states London, 14 th of October 2010

2 Motivation Fatigue of elastomer products Failure of a clutch Firestone Case Fatigue tests for reliability and quality of elastomer products 2

3 Literature survey Concepts for lifetime estimation of rubber Crack nucleation maximum principal stress Wöhler (1867) Bathias et al. (1998) André et al. (1999) Flamm et al. (2004) Abraham et al. (2005) Saintier et al. (2006) maximum principal strain Cadwell et al. (1940) Fielding (1943) Robert & Benzies (1977) Roach (1982) Ro (1989) strain energy density Robert & Benzies (1977) Ro(1989) André et al. (1999) Abraham et al. (2005) Crack propagation energy release rate Inglis (1913) Griffith (1920) Thomas (1955) Paris et al. (1961) fracture mechanics Rivlin & Thomas (1953) Kadir & Thomas (1981) Mazich et al. (1989) Young (1990) Mars (2001) crack plane Mars & Fatemi (2002) Andriyana & Verron (2006) Verron & Andriyana. (2008) What kind of criterion is reliable? 3

Wöhler concept Wöhler concept Der Bruch des Materials läßt sich auch durch vielfach wiederholte Schwingungen, von denen keine die absolute Bruchgrenze erreicht, herbeiführen.

4 Wöhler concept Wöhler concept Der Bruch des Materials läßt sich auch durch vielfach wiederholte Schwingungen, von denen keine die absolute Bruchgrenze erreicht, herbeiführen. Die Differenz der Spannungen, welche die Schwingung eingrenzen, sind daher für die Zerstörung des Zusammenhanges maßgebend. from A. Wöhler, Zeitschrift für Bauwesen, 1871 August Wöhler * 22. Juni 1819 in Soltau 21. März 1914 in Hannover Investigation of the cyclic resistance of materials (metals) Cyclic, sinusoidal loading till failure Logarithmic relation between load amplitude and resistance time 4 Wöhler curve

5 Wöhler concept Wöhler curve Cyclic loading at varied amplitudes until failure of the material Load [N] Miner s Rule Displacement [mm] Log S Palmgren, Langer and Miner (1924, 1937, 1945) R S LCF S HCF N LCF N HCF Log N 5

6 Uniaxial fatigue behavior Cycled uniaxial tension test Load [N] Displacement [mm] 6

7 MORPH (MOdel for Rubber PHenomenology) Decompositon of stresses Auxiliary stress Basic stress Basic and cladding stresses Total stress Cladding stress History function 7

Uniaxial fatigue behavior Cyclic loading of a notched strip u = 2 x 20 mm 1 x 25 mm 2 x 20 mm Exp. Morph Yeoh 50 mm 8 Morph: p 1 = 0.

8 Uniaxial fatigue behavior Cyclic loading of a notched strip u = 2 x 20 mm 1 x 25 mm 2 x 20 mm Exp. Morph Yeoh 50 mm 8 Morph: p 1 = p 5 = p 2 = p 6 = 5.92 p 3 = p 7 = 5.70 p 4 = 3.09 p 8 = Yeoh: C 10 = C 20 = C 30 = mm

9 Uniaxial fatigue behavior Cyclic loading of a strip with fillet Yeoh 5th loading cycle MORPH 9

10 Uniaxial fatigue behavior Variation of amplitude and preload Wöhler curve Log σ [MPa] Load [N] Displacement [mm] Abraham et al. (2005) Log N Load [N] Max. stress or strain criterion reliable? Dissipative energy seems to play an important role! 10 Displacement [mm]

11 Multiaxial fatigue behavior Deformation states varying loading conditions! 11

Multiaxial fatigue behavior Load types tension/compression Drawbacks: Repeating the same loading condition/direction Load-specific lifetime Dissipative energy is fully

12 Multiaxial fatigue behavior Load types tension/compression Drawbacks: Repeating the same loading condition/direction Load-specific lifetime Dissipative energy is fully coupled to the loading process shear simple shear with rotating axes Advantages: Loading with changing directions Besides the dissipative energy, no further energy is inserted 12

Multiaxial fatigue behavior Simple shear with rotating axes 1. Double-Sandwich-layered specimen 3. Applying a continuous rotation 1. 2. F R 2.

13 Multiaxial fatigue behavior Simple shear with rotating axes 1. Double-Sandwich-layered specimen 3. Applying a continuous rotation F R 2. Initiation of simple shear by moving the middle part 3. F R 4. F R F U 4. Measuring the resulting force due to the restriction of the deflection 13

14 Multiaxial fatigue behavior Corresponding forces F R F U F R For rce [N] F U 14

15 Multiaxial fatigue behavior Response of the material until failure (experiments) Extraction for Micro-CT F R Failure 1000 Lo oad [N] F U Number of revolutions

16 Multiaxial fatigue behavior Micro-CT pictures of inner N st plane 2nd plane 3rd plane 4th plane already dead! 16

17 Summary Results Lifetime prediction of filled elastomers by using a hyperelastic material model without considering inelastic effects is not reliable Investigation of the influence of the loading direction on the lifetime by using simple shear with rotating axes A criterion based on the dissipative energy appears to be more sophisticated than stress or strain criteria The resulting crack geometry implies a dependence of the loading direction on the material failure Future work Combining the relation of dissipative energy and the loading direction into a new failure criterion 17

Small crack energy release rate from configurational force balance in hyperelastic materials

Small crack energy release rate from configurational force balance in hyperelastic materials M. Aït-Bachir, E. Verron, W. V. Mars, and P. Castaing Institut de Recherche en Génie Civil et Mécanique, Ecole