Sage Journals: Discover world-class research

Abstract

The fictitious notch rounding concept is applied here to V-shaped notches with root holes subjected to mode I loading. The fictitious notch radius ρ_f is determined as a function of the real notch radius ρ, the microstructural support length ρ* and the notch opening angle 2α, at first using the normal stress criterion. Two analytical methods have been developed resulting in closed-form expressions for the multiaxiality factor s in the well-known relationship ρ_f = ρ + sρ*. The first method expresses the notch stress averaged over the microstructural support length at pointed V-notches by the maximum notch stress of fictitiously rounded V-notches (with root hole), taking advantage of a newly developed analytical solution. The second method considers V-notches with root holes both in the real and in the fictitious configuration. It uses a procedure given by Neuber. Finally, different failure criteria are considered using the first method. Plane stress and plane strain conditions, respectively, are evaluated.

Keywords

Fictitious notch rounding V-notches with root hole mode I loading microstructural support

Get full access to this article

View all access options for this article.

References

Lazzarin

Zambardi

. A finite-volume-energy based approach to predict the static and fatigue behaviour of components with sharp V-shaped notches. Int J Fracture 2001; 112: 275–298.

Matvienko

Morozov

. Calculation of the energy J-integral for bodies with notches and cracks. Int J Fracture 2004; 125: 249–261.

Hills

Dini

Magadu

. A review of asymptotic procedures in stress analysis: known solutions and their applications. J Strain Analysis Engng Des 2004; 39: 553–568.

Berto

Croccolo

Cuppini

. Fatigue strength of a fork-pin equivalent coupling in terms of the local strain energy density. Mater Des 2008; 29: 1780–1792.

Zappalorto

Lazzarin

. Stress fields due to inclined notches and shoulder fillets in shafts under torsion. J Strain Analysis Engng Des 2011; 46: 187–199.

Barati

Berto

. A comparison between rapid expressions for evaluation of the critical J-integral in plates with U-notches under mode I loading. J Strain Analysis Engng Des 2011; 48(8): 852–865.

Barati

Aghazadeh Mohandesi

Alizadeh

. The effect of notch depth on J-integral and critical fracture load in plates made of functionally graded aluminum–silicone carbide composite with U-notches under bending. Mater Des 2010; 31: 4686–469.

Neuber

. Kerbspannungslehre, 2nd ed. Berlin: Springer-Verlag, 1958.

Neuber

. Uber die Berücksichtigung der Spannungskonzentration bei Festigkeitsberechnungen. Konstruktion 1968; 20: 245–251.

10.

Neuber

. Kerbspannungslehre. 3rd ed. Berlin: Springer-Verlag, 1985.

11.

Filippi

Lazzarin

Tovo

. Developments of some explicit formulas useful to describe elastic stress fields ahead of notches in plates. Int J Solids Structs 2002; 39: 4543–4565.

12.

Berto

Lazzarin

Radaj

. Fictitious notch rounding concept applied to sharp V-notches: evaluation of the microstructural support factor for different failure hypotheses. Part I: Basic stress equations. Engng Fracture Mech 2008; 75: 3060–3072.

13.

Berto

Lazzarin

Radaj

. Fictitious notch rounding concept applied to sharp V-notches: evaluation of the microstructural support factor for different failure hypotheses. Part II: Microstructural support analysis. Engng Fracture Mech 2009; 76: 1151–1175.

14.

Wieghardt

. Über das Spalten und Zerreiβen elastischer Körper. Z. Mathematik u. Physik 1907; 55: 60–103; translated in English by Rossmanith

. Fatigue Fract Engng Mater Structs 1995; 18: 1371–1405.

15.

Weiss

. Eine Bruchmechanik fur Kerben. Schweiz Arch Angew Wiss Techn 1971; 37: 1–7.

16.

Neuber

. Zur Theorie des technischen Formzalhl. Forzschg Ing Wes 1936; 7: 271–274.

17.

Radaj

. Näherungsweise Berechnung der Formzahl von Schweiβnähten. Schw Schn 1969; 21: 97–105, and 1969; 2: 151–158.

18.

Radaj

. Design and Analysis of Fatigue Resistant Welded Structures. Cambridge: Abington Publishing, 1990.

19.

Radaj

. Ermüdungsfestigkeit. 2nd ed. Berlin: Springer Verlag, 2003.

20.

Radaj

Sonsino

Fricke

. Fatigue Assessment of Welded Joints by Local Approaches, 2nd ed. Cambridge: Woodhead Publishing; Boca Raton, FL: CRC Press, 2006.

21.

Hobbacher

. (Ed) Recommendations for fatigue design of welded joints and components. IIW Document XIII-1823-07, update 2008.

22.

Radaj

Zhang

. On the relations between notch stress and crack stress intensity in plane shear and mixed mode loading. Engng Fract Mech 1993; 44: 691–704.

23.

Berto

Lazzarin

. Fictitious notch rounding approach of pointed V-notch under in-plane shear. Theor Appl Fracture Mech 2010; 53: 127–135.

24.

Zappalorto

Lazzarin

. In-plane and out-of-plane stress field solutions for V-notches with end holes. Int J Fracture 2011; 168: 167–180.

25.

Lazzarin

Tovo

. A unified approach to the evaluation of linear elastic fields in the neighbourhood of cracks and notches. Int J Fracture 1996; 78: 3–19.

26.

Gross

Mendelson

. Plane elastostatic analysis of V-notched plates. Int J Fracture Mech 1972; 8: 267–276.

27.

Williams

Stress singularities resulting from various boundary conditions in angular corners on plates in tension. J Appl Mech 1952; 19: 526–528.

The fictitious notch rounding approach applied to V-notches with root holes subjected to mode I loading

Abstract

Keywords

Get full access to this article

References