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Abstract

Ultrasonic fatigue tests at the frequency of 20 kHz were carried out on the hot rolled low alloy steel grade (known as R5), which according to the International Classification Society of offshore systems, it is a steel with the highest ultimate tensile strength to manufacture mooring chains and accessories intended to position mooring applications. Tests were carried out at constant load ratio R = −1 on pre-corroded and no-corroded hourglass shape specimens; pre-corrosion was implemented according to ASTM standard G85. Stress concentration between two and three close hemispherical pitting holes on hourglass shape specimen undergoing uniaxial loading were obtained by finite element method. Experimental results show that fatigue life decreases with the proximity of two close pitting holes on the fracture surface. An exponential law is proposed for the stress concentration factor evolution with the proximity of two close pitting holes of identical radius; the trend of this law is confirmed by experimental results. Finally, fracture surfaces were analyzed and conclusions were listed concerning fatigue life, proximity of pitting holes on fracture surface, and the associated stress concentration factors.

Keywords

Ultrasonic fatigue tests pre-corroded specimens pitting holes stress concentration factor mooring chains steel

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References

Abolikhina

Molyar

(2003) Corrosion of aircraft structures made of aluminum alloys. Materials Science 39: 889–894.

Bates

Watts

(2008) Nonlinear Regression Analysis and its Applications, Hoboken, NJ: John Wiley & Sons, Inc.

Cerit

Genel

Eksi

(2009) Numerical investigation on stress concentration of corrosion pit. Engineering Fracture 16: 2467–2472.

Chandler

(1985) Marine and Offshore Corrosion, 1st ed. Stoneham, MA: Butterworth Publishers.

Dolley

Lee

Wei

(2000) The effect of pitting corrosion on fatigue life. Fatigue and Fracture of Engineering Materials and Structures 23: 555–560.

Dominguez Almaraz

(2008) Prediction of very high cycle fatigue failure for highstrength steels, based on the inclusion geometrical properties. Mechanics of Materials 40: 636–640.

Domínguez Almaraz

Mercado Lemus

Villalón López

(2010) Rotating bending fatigue tests for aluminum alloy 6061-T6, close to elastic limit and with artificial pitting holes. Procedia Engineering 2: 805–813.

DuQuesnay

Underhill

Britt

(2003) Fatigue crack growth from corrosion damage in 7075-T6511 aluminum alloy under aircraft loading. International Journal of Fatigue 25: 371–377.

Galtier

Bertrand

(2002) Fracture case studies of industrial structures under corrosion-fatigue loading. Revue de Métalurgie 99: 395–400.

10.

Green

(1991) Stress amplitude analysis in a generalized ultrasonic fatigue dumbbell specimen. Journal of Physics D: Applied Physics 24: 469–477.

11.

Jacobson

(2005) Corrosion of silicon-based ceramics in combustion. Journal of the American Ceramic Society 76: 3–28.

12.

Koeppe

Hamann

(1980) A program for non-linear regression analysis to be used on desk-top computers. Computer Programs in Biomedicine 12: 121–128.

13.

Loganathan

Purbolaksono

Inayat-Hussain

(2010) Pitting corrosion of triggering initial fractures of palm oil screw press machine shafts. Engineering Failure Analysis 17: 1086–1093.

14.

Maa

Zhang

Wang

(2010) Anisotropic 3D growth of corrosion pits initiated at MnS inclusions for A537 steel during corrosion fatigue. Corrosion Science 52: 2867–2877.

15.

MacClelland

Reifel

(1986) Planning and Design of Fixed Offshore Platforms, 1st ed. Florence, KY: Van Nostrand Reinhold Co., Inc.

16.

Marines

Dominguez

Baudry

(2003) Ultrasonic fatigue tests on bearing steel AISI-SAE 52100 at frequency of 20 kHz and 30 kHz. International Journal of Fatigue 25: 1037–1046.

17.

Medved

Breton

Irving

(2004) Corrosion pit size distributions and fatigue lives – a study of the EIFS technique for fatigue design in the presence of corrosion. International Journal of Fatigue 26: 71–80.

18.

Paris

Palin-Luc

Tada

(2009) Stresses and crack tip stress intensity factors around spherical and cylindrical voids and inclusions of differing elastic properties and with misfit sizes. Crack Paths 2009, Vicenza, Italy. 23–25 September 2009, pp.495–502.

19.

Pilkey

(2007) Peterson’s Stress Concentrations Factors, 3rd ed. Hoboken, NJ: John Wiley & Sons.

20.

Rokhlin

Kim

Nagy Zoofan

(1999) Effect of pitting corrosion on fatigue crack initiation and fatigue life. Engineering Fracture Mechanics 62: 425–444.

21.

Salama

Lamerand

(1982) The prediction of fatigue life using ultrasound. In: Ultrasonic fatigue: proceedings of the first international conference on fatigue and corrosion fatigue up to ultrasonic frequencies. 25–30 October 1981. Champion, PA109–118.

22.

Shi

Mahadevan

(2001) Damage tolerance approach for probabilistic pitting corrosion fatigue life prediction. Engineering Fracture Mechanics 68: 1493–1507.

23.

Shi

Mahadevan

(2003) Corrosion fatigue and multiple site damage reliability analysis. International Journal of Fatigue 25: 457–469.

24.

Song

Saraswathy

(2007) Corrosion monitoring of reinforced concrete structures – a review. International Journal of Electrochemical Science 2: 1–28.

25.

Wang

Kawagoishi

Chen

(2003) Effect of pitting corrosion on the very high cycle life fatigue behavior. Scripta Materialia 49: 711–716.

Ultrasonic fatigue testing on high strength steel: Effect of stress concentration factors associated with corrosion pitting holes

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