Jiangyu Li, University of Washington Yielding and Failure Criteria Plasticity Fracture Fatigue Jiangyu Li University of Washington Mechanics of Materials Lab

Jiangyu Li, University of Washington Failure Criteria Materials Assumed to be perfect: –Brittle Materials Max Normal Stress –Ductile Materials Max Shear Stress Octahedral Shear Stress Materials have flaw or crack in them: –Linear Elastic Fracture Mechanics (LEFM) Stress intensity factor (K) describes the severity of the existing crack condition If K exceeds the Critical stress intensity (K c ), then failure will occur

Jiangyu Li, University of Washington Maximum Normal Stress Fracture Criterion

Jiangyu Li, University of Washington Octahedral Shear Stress Criterion

Jiangyu Li, University of Washington Safety Factor and Load Factor A circular bar must support a axial loading of 200 kN and a torque of 1.5 kN.m. Its yield strength is 260 MPa. –What diameter is needed if load factors Y P =1.6 and Y T =2.5 are required.

Jiangyu Li, University of Washington Stress Strain Curve Bauschinger Effect

Jiangyu Li, University of Washington Elastic-Perfect Plastic and Linear Hardening

Jiangyu Li, University of Washington Power Hardening and Ramberg- Osgood Relation

Jiangyu Li, University of Washington Secant Modulus

Jiangyu Li, University of Washington Stress-Strain Curve

Jiangyu Li, University of Washington Displacement Mode Opening mode Sliding mode Tearing mode

Jiangyu Li, University of Washington Stress Concentration

Jiangyu Li, University of Washington Stress Intensity Factor: Tension

Jiangyu Li, University of Washington Stress Intensity Factor: Bending

Jiangyu Li, University of Washington Stress Intensity Factor: Circumferential Crack -

Jiangyu Li, University of Washington Stress Intensity Factor

Jiangyu Li, University of Washington Superposition

Jiangyu Li, University of Washington Brittle vs. Ductile Behavior

Jiangyu Li, University of Washington Plastic Zone

Jiangyu Li, University of Washington Limitation of LEFM

Jiangyu Li, University of Washington Effect of Thickness

Jiangyu Li, University of Washington Correlation with Strength

Jiangyu Li, University of Washington

Energy Release Rate

Jiangyu Li, University of Washington Strain Energy Modulus of toughness & modulus of resilience Increasing the strain rate increase strength, but decrease ductility

Jiangyu Li, University of Washington Impact Test Charpy V-notch & Izod tests most common Energy calculated by pendulum height difference Charpy – metals, Izod - plastics

Jiangyu Li, University of Washington Trend in Impact Behavior Toughness is generally proportional to ductility Also dependent on strength, but not so strongly Brittle Fractures –Lower energy –Generally smooth in appearance Ductile Fracture –Higher energy –Rougher appearance on interior with 45° shear lips

Jiangyu Li, University of Washington Effect of Temperature Decrease temperature increase strength, but decrease ductility

Jiangyu Li, University of Washington Ductile-Brittle Transition

Jiangyu Li, University of Washington Static Failure Load is applied gradually Stress is applied only once Visible warning before failure

Jiangyu Li, University of Washington Cyclic Load and Fatigue Failure Stress varies or fluctuates, and is repeated many times Structure members fail under the repeated stresses Actual maximum stress is well below the ultimate strength of material, often even below yield strength Fatigue failure gives no visible warning, unlike static failure. It is sudden and catastrophic!

Jiangyu Li, University of Washington Characteristics Primary design criterion in rotating parts. Fatigue as a name for the phenomenon based on the notion of a material becoming “tired”, i.e. failing at less than its nominal strength. Cyclical strain (stress) leads to fatigue failure. Occurs in metals and polymers but rarely in ceramics. Also an issue for “static” parts, e.g. bridges. Cyclic loading stress limit<static stress capability.

Jiangyu Li, University of Washington Characteristics Most applications of structural materials involve cyclic loading; any net tensile stress leads to fatigue. Fatigue failure surfaces have three characteristic features: –A (near-)surface defect as the origin of the crack –Striations corresponding to slow, intermittent crack growth –Dull, fibrous brittle fracture surface (rapid growth). Life of structural components generally limited by cyclic loading, not static strength. Most environmental factors shorten life.

Jiangyu Li, University of Washington Fatigue Failure Feature Flat facture surface, normal to stress axis, no necking Stage one: initiation of microcracks Stage two: progress from microcracks to macrocracks, forming parallel plateau-like facture feature (beach marks) separated by longitudinal ridge Stage three: final cycle, sudden, fast fracture. Bolt, unidirectional bending

Jiangyu Li, University of Washington Fatigue-Life Method Stress-life method Facture mechanics method

Jiangyu Li, University of Washington Alternating Stress  a = (  max -  min )/2  m = (  max +  min )/2

Jiangyu Li, University of Washington S-N Diagram Note the presence of a fatigue limit in many steels and its absence in aluminum alloys. log N f aa  mean 1  mean 2  mean 3  mean 3 >  mean 2 >  mean 1 The greater the number of cycles in the loading history, the smaller the stress that the material can withstand without failure.

Jiangyu Li, University of Washington S-N Diagram Endurance limit

Jiangyu Li, University of Washington Safety Factor

Jiangyu Li, University of Washington Facture Mechanics Method of Fatigue

Jiangyu Li, University of Washington Crack Growth > >

Jiangyu Li, University of Washington Fatigue Life

Jiangyu Li, University of Washington Crack Growth Rate

Jiangyu Li, University of Washington Fatigue Failure Criteria

Jiangyu Li, University of Washington Effect of Mean Stress

Jiangyu Li, University of Washington Fatigue Failure Criteria Multiply the stress By safety factor n

Jiangyu Li, University of Washington Example: Gerber Line AISI 1050 cold-drawn bar, withstand a fluctuating axial load varying from 0 to16 kip. Kf=1.85; Find Sa and Sm and the safety factor using Gerber relation Sut=100kpsi; Sy=84kpsi; Se’=0.504Sut kpsi Change over Table

Jiangyu Li, University of Washington Safety Factor with Mean Stress