Post on 22-Dec-2015
Chapter 14
Fatigue
• Initiation region (usually at thesurface)• Propagation of fatiguecrack (evidenced by beachmarkings)•Catastrophic rupture when crack lengthexceeds a critical value at theapplied stress.
Fatigue Fracture Surface
(i) Stress-life approach(ii) Strain-life approach
(iii) Fracture mechanics approach
Analysis of Fatigue: Approaches
Parameters of the S N Tests
cyclic stress range, σ = σmax − σ min
cyclic stress amplitude, σa = (σmax − σmin)/2
mean stress, σm = (σmax + σmin)/2
stress ratio, R = σmin/σmax
Basquin’s Law : High cycle Fatigue
S–N (Wöhler) Curves
(a) S (stress)–N (cyclesto failure) curves. (A) Ferrous and(B) nonferrous metals; SL is theendurance limit.
b) S–N curves forpolymeric materials. Polymers thatform crazes, such aspolymethylmethacrylate (PMMA)and polystyrene (PS), may show aflattened portion in the verybeginning, indicated as stage I.
(c) An example of an actual S–N curve showing the three stages in thecase of polystyrene.
Coffin-Manson Law: Low Cycle Fatigue
Basquin + Coffin -Manson
S–N curves for typical metals and polymers
Superposition of elastic and plastic curves gives the fatigue life in terms of total strain.
(Adapted with permission fromR. W. Landgraf, in American Society for Testing and Materials, Special Technical Publication (ASTM STP) 467 (Philadelphia: ASTM, 1970),p. 3.)
Fatigue Strength
Fatigue life in terms of strain for an 18%-Ni maraging steel
from R. W. Landgraf, in ASTMSTP 467, ASTM,1970), p. 3.
Fatigue Life: HCF and LCF
Effect of mean stress on S–N curves Fatigue life decreases as the mean stress increases
Mean Stress on S-N curves
Goodman
Gerber
Soderberg
Effect of Mean Stress on Fatigue Life
Effect of frequency on the fatigue life of a reactor pressure vessel steel. The fatigue life decreases at 1,000 Hz compared to that at 20 Hz.
(Used with permission from P. K. Liaw, B. Yang, H. Tian et al., ASTM STP 1417 (West Conshohocken, PA: American Society for Testing and Materials, 2002.)
Effect of Frequency on the Fatigue Life
(a) Damage accumulation, in a high-to-low loading sequence. (Adapted with permission from B. I. Sandor, Fundamentals of Cyclic Stress and Strain (Madison, WI: University of Wisconsin Press, 1972.) (b) Sequence of block loadings at four different mean stresses and amplitudes.
Cumulative Damage
Fatigue Crack Nucleation
(a) Persistent slipbands in vein structure.Polycrystalline copper fatigued at atotal strain amplitude of 6.4 ×10−4 for 3 × 105 cycles. Fatiguingcarried out in reverse bending atroom temperature and at afrequency of 17 Hz. The thin foilwas taken 73 μm below thesurface. (Courtesy of J. R.Weertman and H. Shirai.)(b) Cyclic shear stress, τ , vs.plastic cyclic shear strain, γ pl.,curve for a single crystal of copperoriented for single slip. (AfterH. Mughrabi, Mater. Sci. Eng., 33(1978) 207.) The terms γ pl,M. andγ pl,PSB refer to cyclic plastic shearstrain in the matrix and persistentslip bands, respectively.(c) Intrusions/extrusions in atin-based solder due to thermalfatigue. (Courtesy of N. Chawlaand R. Sidhur.)
Well-developed maze structure, showing dislocation walls on {100} in Cu–Ni alloy fatigued to saturation.
(From P. Charsley, Mater. Sci. Eng., 47 (1981) 181.)
Maze Structure
Fatigue Crack Nucleation at Slip Bands
(a) Fatigue crack nucleation at slip bands.
(b) SEM of extrusions and intrusions in acopper sheet.
(Courtesy of M. Judelwicz and B. Ilschner.)
Some mechanisms of fatigue crack nucleation.
(After J. C. Grosskreutz, Tech. Rep. AFML-TR-70–55 (Wright– Patterson AFB, OH: Air Force Materials Laboratory), 1970.)
Fatigue Crack Nucleation
(a) Residual stressprofile generated by shot peeningof a surface; CS and TS indicatecompressive and tensile stress,respectively.
(b) Effect of shot peening on fatigue life, σ of steels with different treatments as a function of ultimate tensile strength, σUTS.
(After J. Y. Mann, Fatigue of Materials (Melbourne, Melbourne University Press, 1967).)
Fatigue Life
Stages I, II, and III of fatigue crack propagation
Fatigue striations in2014-T6 aluminum alloy; two-stagecarbon replica viewed in TEM. (a)Early stage. (b) Late stage.(Courtesy of J. Lankford.)
Fatigue Striations
Fatigue crack growthby a plastic blunting mechanism. (a) Zero load. (b) Small tensile load.(c) Maximum tensile load. (d) Small compressive load. (e) Maximum compressive load. (f) Small tensileload. The loading axis is vertical
(After C. Laird, in Fatigue CrackPropagation, ASTM STP 415(Philadelphia: ASTM, 1967),p. 131.)
Fatigue Crack Growth
Microscopic fracture modes in fatigue. (a) Ductilestriations triggering cleavage. (b)Cyclic cleavage. (c) α − β interfacefracture. (d) Cleavage in an α − βphase field. (e) Forkedintergranular cracks in a hardmatrix. (f) Forked intergranularcracks in a soft matrix. (g) Ductileintergranular striations. (h)Particle-nucleated ductileintergranular voids. (i)Discontinuous intergranular facets.
(Adapted from W. W. Gerberichand N. R. Moody, in FatigueMechanisms, ASTM STP 675(Philadelphia: ASTM, 1979) p. 292.)
Microscopic Fracture Modes
Discontinuous crack growth through a craze at the tip of a fatigue crack.
(After L. Konczol, M. G. Schincker and W. Do¨ ll, J. Mater. Sci., 19 (1984) 1604.)
Fatigue Crack Path in Polymer
(a) Failure locus. (b) Schematic of crack length a as a function of number of cycles,N.
Fracture Mechanics Applied to Fatigue
Crack Propagation Rate: Paris Erdogan Relationship
Paris Relationship: Integration
Fatigue crack propagation in an AISI 4140 steel.(a) Longitudinal direction (parallel to rolling direction). (b) Transversedirection (perpendicular to rolling direction).
(Reprinted with permission from E. G. T. De Simone, K. K. Chawla, and J. C. Miguez Su´arez, Proc. 4th CBECIMAT (Florian ´ opolis, Brazil, 1980), p. 345)
Fatigue Crack Propagation in an AISI 4140 Steel
Fatigue crack propagation rates for a number of polymers.
(After R. W. Hertzberg, J. A. Manson, and M. Skibo, Polymer Eng. Sci., 15 (1975) 252.)
Fatigue Crack Propagation in Polymers
Variation in fatigue crack propagation rates, at fixedvalues of K (= 0.6 MPa m1/2) and test frequency v (= 10 Hz), as a function of reciprocal of molecular weight for PMMA and PVC.
(After S. L. Kim, M. Skibo, J. A. Manson, and R. W. Hertzberg, Polymer Eng. Sci., 17 (1977) 194.)
Fatigue Crack Propagation for PMMA and PVC
Fatigue crack growth rate da/dN in alumina as a functionof the maximum stress intensity factor Kmax under fully reversedcyclic loads (v = 5 Hz). Also indicated are the rates of crackgrowth per cycle derived from static-load fracture data.
(After M. J. Reece, F. Guiu, and M. F. R. Sammur, J. Amer. Ceram. Soc., 72(1989) 348.)
Fatigue Crack Growth Under Cyclic Loading
Intrinsic and extrinsic mechanisms of fatigue damage.
(After R. O. Ritchie, Intl. J. Fracture, 100 (1999) 55.)
Fatigue Damage
Fatigue crackpropagation rates forpyrolitic-carbon coated graphite specimens in a physiological environment; leaflet andcompact-tensionspecimens.
(Adapted from R. O. Ritchie, J.Heart Valve Dis., 5 (1996) S9.)
Fatigue Crack Propagation
Effect of the applied stress range σ on temperature rise in PTFE subjected to stress-controlled fatigue. The symbol x denotes failure of the specimen.
(After M. N. Riddell, G. P. Koo, and J. L. O’Toole, Polymer Eng. Sci. 6 (1966) 363.)
Hysteretic Heating in Fatigue
A schematic of fatigue crack propagation rate as a function of cyclic stress intensity factor in air and seawater. At any given K, the crack propagation rate is higher in seawater than in air.
Effects in Fatigue
A fatigue threshold curve.
(After A. K. Vasudevan, K. Sadananda, and N. Louat, Mater. Sci. Eng., A188 (1994) 1.)
Two-parameters Approach
Fatigue crack growth rates for long and short cracks
Various loadingconfigurations used in fatiguetesting. (a) In cantilever loading,the bending moment increasestoward the fixed end. (b) Intwo-point beam loading, thebending moment is constant. (c)Pulsating tension, ortension–compression, axialloading.
Fatigue Testing
S–N curve showinglog-normal distribution of lives at various stress levels.
Statistical Analysis of S-N Curves
q-values for S--N Data
Family of curvesshowing the probability of survivalor failure of a component.
Survival and Failure
Line diagram of a hydraulically operated closed-loop system
Block diagram of a low-cycle fatigue-testing system