Geodesic
Determination of the Williams series expansion's coefficients using digital photoelasticity method and finite element method
Vestnik Samarskogo universiteta. Estestvennonaučnaâ seriâ, Tome 25 (2019) no. 3, pp. 62-82 Cet article a éte moissonné depuis la source Math-Net.Ru

Voir la notice de l'article

In the present work, photoelastic and finite element methods have been employed to study the near crack tip fields in isotropic linear elastic cracked bodies under mixed mode loading. The investigated fracture results have been obtained for a series of cracked specimens by testing plates with two parallel cracks, two inclined parallel cracks, three-point bend specimens, four-point bend specimens, inclined edge crack triangular shape specimens subjected to symmetric three point bend loading. The multi-parameter Williams series expansion is used for the crack tip field characterization. Digital photoelasticity method is utilized for determination of the Williams series expansion’s coefficients. The unknown coefficients in the multi-parameter equation are determined using a linear least squares method in an over-deterministic manner. Together with the experimental determination of the fracture mechanics parameters finite element method is invoked to describe the crack tip stress field. Coefficients of higher order terms are either found numerically by finite element method. A good agreement is found between the numerical and experimental results. The significant advantages using multi-parameter equations in the analysis of the stress field are shown and the errors that a study with a limited number of terms produce is demonstrated. The comparison with finite element analysis highlighted the importance and precision of the photoelastic observation for the evaluation of the fracture mechanics parameters. The experimental SIF, T-stress values and coefficients of higher-order terms estimated using the digital photoelasticity method for the extensive series of cracked specimens are compared with finite element analysis (FEA) results, and are found to be in good agreement.
Keywords: digital photoelasticity, finite element method, crack tip stress and strain fields, multi-parameter stress field description, mixed-mode loading, stress intensity factor, T-stress, coefficients of higher-order terms, asymptotic methods and perturbation theory in solid mechanics. 
@article{VSGU_2019_25_3_a5,
     author = {L. V. Stepanova and O. N. Belova and V. A. Turkova},
     title = {Determination of the {Williams} series expansion's coefficients using digital photoelasticity method and finite element method},
     journal = {Vestnik Samarskogo universiteta. Estestvennonau\v{c}na\^a seri\^a},
     pages = {62--82},
     year = {2019},
     volume = {25},
     number = {3},
     language = {ru},
     url = {http://geodesic.mathdoc.fr/item/VSGU_2019_25_3_a5/}
}
TY  - JOUR
AU  - L. V. Stepanova
AU  - O. N. Belova
AU  - V. A. Turkova
TI  - Determination of the Williams series expansion's coefficients using digital photoelasticity method and finite element method
JO  - Vestnik Samarskogo universiteta. Estestvennonaučnaâ seriâ
PY  - 2019
SP  - 62
EP  - 82
VL  - 25
IS  - 3
UR  - http://geodesic.mathdoc.fr/item/VSGU_2019_25_3_a5/
LA  - ru
ID  - VSGU_2019_25_3_a5
ER  - 
%0 Journal Article
%A L. V. Stepanova
%A O. N. Belova
%A V. A. Turkova
%T Determination of the Williams series expansion's coefficients using digital photoelasticity method and finite element method
%J Vestnik Samarskogo universiteta. Estestvennonaučnaâ seriâ
%D 2019
%P 62-82
%V 25
%N 3
%U http://geodesic.mathdoc.fr/item/VSGU_2019_25_3_a5/
%G ru
%F VSGU_2019_25_3_a5
L. V. Stepanova; O. N. Belova; V. A. Turkova. Determination of the Williams series expansion's coefficients using digital photoelasticity method and finite element method. Vestnik Samarskogo universiteta. Estestvennonaučnaâ seriâ, Tome 25 (2019) no. 3, pp. 62-82. http://geodesic.mathdoc.fr/item/VSGU_2019_25_3_a5/

[1] T. M. Jobin, S. N. Khanderi, M. Ramji, “Experimental of the strain intensity factor at the inclusion tip using digital elasticity”, Optics and Lasers in Engineering, 126 (2020), 105855 (in English) | DOI

[2] T. M. Jobin, S. N. Khaderi, M. Ramji, “Experimental evaluation of the strain intensity factor at the rigid line inclusion tip embedded in an epoxy matrix using digital image correlation”, Theoretical and Applied Fracture Mechanics, 106 (2019) (in English) | DOI

[3] J. C. Brinez, A. R. Martinez, J. W. Branch, “Computational hydrid phase shifting technique applied to digital photoelasticity”, Optik, 157 (2018), 287–297 (in English) | DOI

[4] M. P. Hariprasad, K. Ramesh, “Analysis of contact zones from whole field isochromatics using reflection photoelasticity”, Optics and Lasers in Engineering, 105 (2018), 86–92 (in English) | DOI

[5] K. Ramesh, A. Pandey, “An improved normalization technique for white light photoelasticity”, Optics and Lasers in Engineering, 109 (2018), 7–16 (in English) | DOI

[6] P. C. Sung, W. C. Wang, C. H. Hwang, G. T. Lai, “A low-level stress measurement method by integrating white light photoelasticity and spectometry”, Optics and Laser Technology, 98 (2018), 33–45 (in English) | DOI

[7] P. Patil, C. P. Vysasarayani, M. Ramji, “Linear least squares approach for evaluating crack tip fracture parameters using isochromatic and isoclinic data from digital photoelasticity”, Optics and Lasers in Engineering, 93 (2017), 182–194 (in English) | DOI

[8] V. Ramakrishnan, K. Ramesh, “Scanning schemes in white light Photoelasticity. Part II: Novel fringe resolution guided scanning scheme”, Optics and Lasers in Engineering, 92 (2017), 141–149 (in English) | DOI

[9] V. Ramakrishnan, K. Ramesh, “Scanning schemes in white light Photoelasticity. Part I: Critical assessment of existing schemes”, Optics and Lasers in Engineering, 92 (2017), 129–140 (in English) | DOI

[10] B. Katachi, N. Choupani, J. Khalil-Allafi, M. Baghani, “Photostress analysis of stress-induced martensite phase transformation in superelastic NiTi”, Materials and Science and Engineering, 688 (2017), 202–209 (in English) | DOI

[11] S. Yu. Googe, I. S. Tabolin, L. B. Shron, “Photoelasticity and trajectory of fracture cracks. The theoretical basis”, Scientific notes of the Crimean Engineering and Pedagogical University, 2017, no. 4 (58), 120–128 (in Russian)

[12] S. Yu. Googe, I. S. Tabolin, L. B. Shron, “Photoelasticity and trajectory of fracture cracks. Continuation. Results of the experiment”, Scientific notes of the Crimean Engineering and Pedagogical University, 2018, no. 1 (59), 176–182 (in Russian)

[13] A. S. Demidov, “Photoelasticity method and its application in MAI”, Dvigatel', 2018, no. 3 (117), 10–11 (in Russian)

[14] E. V. Bryukhovetskaya, O. V. Konischeva, I. V. Kudryavcev, “Research of the Stress State of the Rail by Three-Exposition Method of Holographic Photoelasticity”, Journal of Siberian Federal University. Engineering and Technologies, 12:3 (2019), 323–330 (in Russian) | DOI | MR

[15] O. I. Chelyapina, V. M. Isachenko, “Automation of residual stress study by digital photoelasticity method”, Tambov Univeristy Reports. Series: Natural and Technical Sciences, 2018, 307–309 (in Russian) | DOI

[16] V. S. Pisarev, Y. G. Matvienko, S. I. Eleonsky, I. N. Odintsev, “Combining the crack compliance method and speckle interferometry data for determination of stress intensity factors and T-stress”, Engineering Fracture Mechanics, 179 (2017), 348–374 (in English) | DOI

[17] J. M. Vasco-Olmo, B. Yang, M. N. James, F. A. Diaz, “Investigation of effective stress intensity factors during overload fatigue cycles using photoelastic and DIC techniques”, Theoretical and Applied Fracture Mechanics, 97 (2018), 73–86 (in English) | DOI

[18] Luciano Lamberti, Ming-Tzer Lin and others (eds.), Advancement of Optical Methods and Digital Image Correlation in Experimental Mechanics by Luciano Lamberti, Ming-Tzer Lin and others, Springer, 2018, 242 pp. (in English) | DOI

[19] J. Molimard, Experimental Mechanics of Solids and Structures, Willey, London, 2016, 149 pp. (in English) https://b-ok.cc/book/2713894/fbbb66

[20] Experimental Stress Analysis for Materials and Structures: Stress Analysis Models for Developing Design Methodologies (Springer Series in Solid and Structural Mechanics), Springer Series in Solid and Structural Mechanics, Springer, New York, 2015, 498 pp. (in English) | DOI

[21] M. Grediac, F. Hild, Full-field Measurements and Identification in Solid Mechanics, ISTE, London, 2011 (in English) https://avidreaders.ru/read-book/full-field-measurements-and-identification-in.html

[22] F. Pierron, M. Grediac, The Virtual Fields Method, Extracting Constitutive Mechanical Parameters from Full-Field Deformation Measurements, Springer, New York, 2012 | DOI

[23] V. E. Vildemann (ed.), Experimental study of material properties under complex thermomechanical loadings, Fizmatlit, M., 2012, 204 pp. (in Russian)

[24] S. Yoshida, L. Lamberti, S. Sciammarella (eds.), Advancement of Optical Methods in Experimental Mechanics, Proceedings of the 2016 Annual Conference on Experimental and Applied Mechanics, v. 3, Springer, 2016, 219 pp. (in English) | DOI

[25] H. Jin, C. Sciammarella (eds.), Advancement of Optical Methods in Experimental Mechanics, Proceedings of the 2014 Annual Conference on Experimental and Applied Mechanics, v. 3, Springer, 2015, 421 pp. (in English) | DOI

[26] A Conference and Exposition on Dynamics of Multiphysical Systems: From Active Materials to Vibroacoustic, Proceedings of the 34th IMAC, v. 8, Springer, Berlin, 2016, 462 pp. (in English) | DOI

[27] A. Shukla, J. W. Dally, Experimental Solid Mechanics, College House Enterprises, 2014, 688 pp.

[28] A. S. Chernyatin, I. A. Razumovsky, Yu. G. Matvienko, “Evaluation of the Size of Inelastic Strain Zone at the Top of the Crack Based on Analysis of the Displacement Fields”, Industrial Laboratory. Diagnostics of Materials, 82:12 (2016), 45–51 (in Russian)

[29] I. A. Razumovskii, A. S. Chernyatin, A. V. Fomin, “Experimental and Computational Methods for Determining the Stress-Strain State of Structural Elements”, Industrial Laboratory. Diagnostics of Materials, 79:10 (2013), 57–64 (in Russian)

[30] T. M. Grabois, J. Heggers, L. Ponson, F. Hild, R. D.T. Filho, “On the validation of the integrated DIC with taperd double cantilever beams test”, Engineering Fracture Mechanics, 191 (2018), 311–323 (in English) | DOI

[31] V. A. Levin, Models and methods. Formation and development of defects. Nonlinear computational mechanics of strength, v. I, Fizmatlit, M., 2015, 456 pp. (in Russian)

[32] V. A. Levin, V. A. Vershinin, Numerical methods. Parallel calculations on computers. Nonlinear computational mechanics of strength, v. II, Fizmatlit, M., 2015, 544 pp. (in Russian)

[33] U. Galvanetto, M. H. F. Aliabadi (eds.), Multiscale Modeling in Solid Mechanics: Computational Approaches, Computational and Experimental Methods in Structures, Imperial College Press, London, 2009, 352 pp. (in English) https://ru.b-ok.org/book/1059039/7e5258 | DOI

[34] G. M. Carlomagno, D. Poljak, C. A. Brebbia, Computational Methods and Experimental Measurements XVII (Wit Transactions on Modelling and Simulation), WIT Press, 2015, 564 pp.

[35] V. Vesely, J. Sobek, S. Seitl, “Multi-parameter approximation of the stress field in a cracked body in the moredistant surrounding of the crack tip”, International Journal of Fatigue, 89 (2016), 20–35 (in English) | DOI

[36] L. Malikova, V. Vesely, S. Seitl, “Crack propagation direction in a mixed mode geometry estimated via multi-parameter fracture criteria”, International Journal of Fatigue, 89 (2016), 99–107 (in English) | DOI

[37] L. Malikova, “Multi-parameter fracture criteria for the estimation of crack propagation direction applied to a mixed-mode geometry”, Engineering Fracture Mechanics, 143 (2015), 32–46 (in English) | DOI

[38] A. S. Chernyatin, “Evaluation of the Mutual Effect of Through Crossing Cracks”, Proceedings of Higher Educational Institutions. Machine Building, 2015, no. 11 (668), 62–67 (in Russian)

[39] L. V. Stepanova, P. S. Roslyakov, “Complete asymptotic expansion M. Williams near the crack tips of collinear cracks of equal lengths in an infinite plane medium”, PNRPU Mechanics Bulletin, 2015, no. 4, 188–225 (in Russian) | DOI

[40] A. Lopez-Moreno, M. Zanganeh, “Evaluation of crack-tip fields from DIC data: A parameter study”, International Journal of Fatigue, 89 (2016), 11–19 (in English) | DOI

[41] V. S. Pisarev, Y. G. Matvienko, S. I. Eleonsky, I. N. Odintsev, “Combining the crack compliance method and speckle interferometry data for determination of stress intensity factors and T-stress”, Engineering Fracture Mechanics, 179 (2017), 348–374 (in English) | DOI

[42] V. Pisarev, I. Odintsev, S. Eleonsky, A. Apalkov, “Residual stress determination by optical interferometric measurements of hole diameter increments”, Optics and Lasers in Engineering, 110 (2018), 437–456 (in English) | DOI

[43] I. N. Odintsev, T. P. Plugatar, “Compensation for rigid body displacements in study of local deformations using electronic speckle pattern interferometry”, IOP Conference Series: Materials Science and Engineering, 489:1 (2019), 012021 | DOI

[44] I. Odintsev, A. Apal'kov, A. Komarov, T. Pluginuri, S. Usov, “The application of optical correlation techniques in problems of experimental mechanics”, Progressive technologies and systems of mechanical engineering, 2015, no. 1 (51), 152–160 (in Russian)

[45] S. I. Eleonskii, I. N. Odintsev, V. S. Pisarev, A. V. Chernov, “Study of the crack propagation process using measements of strain field. I. Stress field”, TsAGI Science Journal, 46:7 (2015), 55–80 (in Russian)

[46] G. Hello, M. B. Tahar, J. M. Roelandt, “Analytical determination of coefficients in crack-tip stress expansions for a finite crack in an infinite plane medium”, International Journal of Solids and Structures, 49 (2012), 556–566 (in English) | DOI

[47] G. Hello, “Derivation of complete crack-tip stress expansions from Westergaard-Sanford solutions”, International Journal of Solids and Structures, 144–145 (2018), 265–275 (in English) | DOI

[48] L. V. Stepanova, “Asymptotic analysis of the crack tip stress field consideration of higher order terms”, Numerical Analysis and Applications, 12:3 (2019), 284–296 | DOI | MR

[49] L. V. Stepanova, “Influence of the higher order terms in Williams' series expansion of the stress field on the stress-strain state in the vicinity of the crack tip. Part I”, Vestnik of Samara University. Natural Science Series, 25:1 (2019), 63–79 (in Russian) | DOI | MR

[50] L. V. Stepanova, “Influence of the higher order terms in Williams' series expansion of the stress field on the stress-strain state in the vicinity of the crack tip. Part II”, Vestnik of Samara University. Natural Science Series, 25:1 (2019), 80–96 (in Russian) | DOI | MR

[51] V. S. Dolgikh, A. V. Pulkin, E. A. Mironova, A. A. Peksheva, L. V. Stepanova, “Theoretical and experimental investigation of crack propagation direction. Part I”, Vestnik of Samara University. Natural Science Series, 2:2 (2019), 30–54 (in Russian) | DOI

[52] V. S. Dolgikh, A. V. Pulkin, E. A. Mironova, A. A. Peksheva, L. V. Stepanova, “Theoretical and experimental investigation of crack propagation direction. Part II”, Vestnik of Samara University. Natural Science Series, 25:2 (2019), 55–74 (in Russian) | DOI

[53] B. L. Karihaloo, Q. Z. Xiao, “Accurate determination of the coefficients of elastic crack tip asymptotic field by a hibrid crack element with p-adaptivity”, Engineering Fracture Mechanics, 2001, no. 68, 1609–1630 (in English) | DOI

[54] L. V. Stepanova, P. S. Roslyakov, “Complete Williams asymptotic expansion of the stress field near the crack tip: analytical solutions, interference-optic methods and numerical experiments”, AIP Conference Proceedings of the 10th International Conference on Mechanics, Resource and Diagnostics of Materials and Structures, 2016, 030029 (in English) | DOI | MR

[55] L. V. Stepanova, E. M. Yakovleva, “Asymptotic stress field in the vicinity of a mixed-mode crack under plane stress conditions for a power-law hardening material”, Journal of Mechanics of Materials and Structures, 10:3 (2015), 367–393 (in English) | DOI | MR

[56] A. Vivekanandan, K. Ramesh, “Study of interaction effects of asymmetric cracks under biaxial loading using digital photoelasticity”, Theoretical and applied Fracture Mechanics, 99 (2019), 104–117 (in English) | DOI

[57] L. V. Stepanova, P. S. Roslyakov, P. N. Lomakov, “A photoelastic study for multiparametric analysis of the near crack tip stress field under mixed mode loading”, Procedia Structural Integrity, 2 (2016), 1797–1804 (in English) | DOI

[58] A. N. Kosygin, L. N. Kosygina, “Digital processing of interferograms obtained by the photoelasticity method”, Vestnik of Samara University. Natural Science Series, 25:2 (2019), 75–91 (in Russian) | DOI

[59] K. Ramesh, M. Gupta, A. A. Kelkar, “Evaluation of stress field parameters in fracture mechanics by photoelastisity-revisited”, Engineering Fracture Mechanics, 56 (1997), 1–25 (in English) | DOI | MR

[60] M. Gupta, R. C. Alderliesten, R. Benedictus, “A review of T-stress and it's effects in fracture mechanics”, Solid State Phenomena, 134 (2015), 218–241 (in English) | DOI

[61] K. V. N. Surendra, K. R.Y. Simha, “Design and analysis of novel compression fracture specimen with constant form factor: Edge cracked semicircular disk (ECSD)”, Engineering Fracture Mechanics, 102 (2013), 235–248 (in English) | DOI