International Journal of Fracture

, Volume 169, Issue 1, pp 85–95 | Cite as

On the mechanics of edge chipping from spherical indentation

Original Paper
First Online:
Received:
Accepted:

Abstract

Edge chipping is a basic failure mode in brittle materials which is dictated by a wealth of material and geometric variables. Here we examine the effect of indenter bluntness on chipping load and chip dimensions. Soda-lime glass and YTZP plates are subject to surface-normal loading near an edge by a W/C ball or a Vickers tool. The ball radius r is varied from 0.2 to 8.7 mm while the indent distance h is varied from several millimeters down to a few microns. Although cone cracks are a common feature under spherical indentation, the chipping event is dominated by median-radial cracks formed under the contact. The fracture behavior is characterized by a “large” indent distance regime where the median cracks progress stably up to chipping and a “small” one where they grow unstably to form a chip once initiated. Closed-form relations for chipping load P F under spherical indentation is developed with the aid of the test data and non-dimensional arguments. While in the “large” distance regime P F is proportional to h 3/2 irrespective of tool bluntness, in the “small” regime P F is proportional to r 1/2 h 3/4. Interestingly, the chip dimensions are virtually independent of ball radius, varying linearly with h. Beyond relevance to structural integrity, the chipping test facilitates a simple means for determining fracture toughness K C as well as the load needed to initiate median cracks in opaque brittle materials. An attempt is made to extend the static analysis to low-velocity impact. The results show that the damage formed during the fracture process has a major influence on dynamic chipping.

Keywords

Edge chipping Indentation Ball Vickers Median cracks Toughness 
This is a preview of subscription content, log in to check access.

Preview

Unable to display preview. Download preview PDF.

Unable to display preview. Download preview PDF.

References

  1. Atkins T (2009) The science and engineering of cutting. Elsevier, AmsterdamGoogle Scholar
  2. Chai H, Lawn BR (2007a) A universal relation for edge chipping from sharp contacts in brittle materials and its use as a simple means of toughness evaluation. Acta Mater 55: 2555–2561CrossRefGoogle Scholar
  3. Chai H, Lawn BR (2007b) Edge chipping of brittle materials: effect of side-wall inclination and loading angle. Int J Fract 145:159–165CrossRefGoogle Scholar
  4. Chai H, Ravichandran G (2007) On the mechanics of surface and side-wall chipping from line-wedge indentation. Int J Fract 148: 221–231CrossRefGoogle Scholar
  5. Chai H, Lee JJ-W, Lawn BR (2010) On the chipping and splitting of teeth. J Mech Behav Biomed Mater. doi: 10.1016/j.jmbbm.2010.10.011
  6. Constantinides G, Tweedie CA, Savva A, Smith JF, van Vliet KJ (2009) Quantitative impact testing of energy dissipation at surfaces. Exp Mech 49: 511–522CrossRefGoogle Scholar
  7. Constantino PJ, Lee JJ-W, Chai H, Zipfel B, Ziscovici C, Lawn BR, Lucas PW (2010) Tooth chipping can reveal the diet and bite forces of fossil hominins. Biol Lett 6: 826–829CrossRefGoogle Scholar
  8. Cotterell B, Kamminga J (1987) The formation of flakes. Am Antiq 52: 675–708CrossRefGoogle Scholar
  9. Danzer R, Hangl M, Paar R (1997) How to design with brittle materials against edge flaking. In: Proceedings of 6th international symposium on ceramic materials and components for engines, pp 658–662Google Scholar
  10. Gogotsi GA, Galenko VI, Mudrik SP, Ozersky BI, Khvorostyany VV, Khristevich TA (2010a) Fracture resistance estimation of elastic ceramics in edge flaking: EF baseline. J Eur Ceram Soc 30: 1223–1228CrossRefGoogle Scholar
  11. Gogotsi GA, Mudrik SP (2010b) Glasses: new approach to fracture behavior analysis. J Non-Cryst Solids 356: 1021–1026CrossRefGoogle Scholar
  12. Knight CG, Swain MV, Chaudhri MM (1975) Impact of small steel spheres on glass surfaces. J Mater Sci 12: 1573–1586CrossRefGoogle Scholar
  13. Lawn BR, Fuller ER (1975) Equilibrium penny-like cracks in indentation fracture. J Mater Sci 10: 2016–2024CrossRefGoogle Scholar
  14. McCormick NJ (1982) Edge flaking as a measure of material performance. Metals Mater 8: 154–156Google Scholar
  15. Mohajerani A, Spelt JK (2010) Erosive wear of borosilicate glass edges by unidirectional low velocity impact of steel balls. Wear 269: 900–910CrossRefGoogle Scholar
  16. Morrell R, Gant AJ (2001) Edge chipping of hard materials. Int J Refract Metals Hard Mater 19: 293–301CrossRefGoogle Scholar
  17. Morrell R (2005) Edge flaking—similarity between quasistatic indentation and impact mechanisms for brittle materials. Key Eng Mater 290: 14–22CrossRefGoogle Scholar
  18. Pelcin A (1997a) The effect of indenter type on flake attributes: evidence from a controlled experiment. J Archaeol Sci 24: 613–621CrossRefGoogle Scholar
  19. Pelcin AW (1997b) The formation of flakes: the role of platform thickness and exterior platform angle in the production of flake initiations and terminations. J Archaeol Sci 24: 1107–1113CrossRefGoogle Scholar
  20. Petit F, Vandeneede V, Cambier F (2009) Ceramic toughness assessment through edge chipping measurements—influence of interfacial friction. J Eur Ceram Soc 29: 2135–2141CrossRefGoogle Scholar
  21. Quinn GD, Bradt RC (2007) On the Vickers indentation fracture toughness test. J Am Ceram Soc 90: 673–680CrossRefGoogle Scholar
  22. Quinn J, Su L, Flanders L, Lloyd L (2000) “Edge toughness” and material properties related to the machining of dental ceramics. Mach Sci Technol 4: 291–304CrossRefGoogle Scholar
  23. Seifried R, Minamoto H, Eberhard P (2010) Viscoplastic effects occurring in impacts of aluminum and steel bodies and their influence on the coefficient of restitution. J Appl Mech 77: 041008CrossRefGoogle Scholar
  24. Speth JD (1975) Miscellaneous studies in hard-hammer percussion flaking: the effects of oblique impact. Am Antiq 40: 203–207CrossRefGoogle Scholar
  25. Timoshenko SP, Goodier JN (1970) Theory of elasticity. McGraw-Hill, New YorkGoogle Scholar
  26. Weir G, Tallon S (2005) The coefficient of restitution for normal incident, low velocity particle impacts. Chem Eng Sci 60: 3637–3647CrossRefGoogle Scholar
  27. Whittaker JC (1994) Flintknapping: making and understanding stone tools. University of Texas Press, AustinGoogle Scholar
  28. Zaayman E, Morrison G, Field JE (2009) Edge flaking in diamond. Int J Refrac Metals Hard Mater 27: 409–416CrossRefGoogle Scholar

Copyright information

© Springer Science+Business Media B.V. 2011

Authors and Affiliations

  1. 1.School of Mechanical Engineering, Faculty of EngineeringTel-Aviv UniversityTel-AvivIsrael

Personalised recommendations