1. Fracture Mechanics in �Rock Breaking John Kemeny
2. What is Fracture Mechanics? Traditionally, material failure based on the concept of strength (i.e., stress>strength)
Cannot take into account presence of flaws or propagation of single fractures => airplane wing!
In the 20s, Griffith and later Irwin pioneered energy concept for crack growth
LEFM - linear elastic fracture mechanics
Applications in rocks => blasting, mechanical excavation, drilling, earthquake rupture, etc.
3. Some General Concepts Crack growth from pre-existing flaws (microcracks, pores, grains, etc.)
Crack growth in the direction of the maximum compressive principal stress (perpendicular to maximum tensile stress)
4. Crack Growth in Rock Breaking Blasting => internal pressure creates compressive radial stress and tensile hoop stress
5. Crack Growth in Rock Breaking Drilling and mechanical excavation => indenter creates chips which allows tool to advance
6. Crack Growth in Rock Breaking Drilling and mechanical excavation => indenter creates chips which allows tool to advance
7. Crack Growth in Rock Breaking Caving => compression and shearing due to the draw results in crack growth
8. Stress Intensity Factors 3 Modes (KI, KII, KIII), we will only consider Mode I today
Actually rock tends to fracture in Mode I no matter how you load it
9. Stress Intensity Factors KI relates the stress field around a crack tip to far field boundary conditions
Stress becomes infinite at the crack tip!
Square root singularity
KI has the unit of stress vdistance, and it remains finite
10. Stress Intensity Factors Stress intensity factor solution for a single crack under tension
Analytic, numerical solutions for KI
11. Crack Growth Criteria Clever idea => use stress intensity factor as criteria for crack growth
KI = KIC => crack growth
KI < KIC => no crack growth
KIC is the fracture toughness, a material property that can be measured in the lab
Indiana limestone => KIC = 0.99 MPavm
Tennessee sandstone => KIC = 0.54 MPavm
12. Crack Growth Example 1 Estimate the tensile strength of Indiana limestone
Based on grain size (why?), assume the largest cracks in the limestone are about 4 mm (why the largest?)
The crack keeps growing across the sample, because KI keeps increasing with increasing crack length
13. Crack Growth Example 2 Use the star crack KI solution to estimate how long blasting cracks will grow and the optimal number of cracks around the hole
14. Crack Growth Example 2 For R=1.5 inches, P=100 MPa, E=50 GPa, KIC=1.25MPavm, set KI=KIC and solve for a to get stable crack length
For n=2 => a=11.5 meters
For n=3 => a=9.1 meters
For n=4 => a=7.0 meters
For n=5 => a=5.6 meters
For n=6 => a=4.7 meters
15. Crack Growth and Energy It takes energy to create crack surface area
Crack growth will occur when a critical energy is supplied
G = GC => crack growth
G is the energy release rate, ?Ue/?a
GC is the critical value of G, a material property
Energy required = GC * surface area
16. Crack Growth and Energy G and KI are related by the relationship:
From KI solution, can calculate energy to create cracks
Optimal configuration is the one that maximizes the strain energy (uses up as much strain energy as possible as the crack grows)
17. Crack Growth and Energy Back to the star crack example, can integrate to get strain energy for n=1, n=2, etc. :
For n=2 => Ue=3842 Joules
For n=3 => Ue=4404 Joules
For n=4 => Ue=4291 Joules
For n=5 => Ue=4136 Joules
=> optimal configuration for n=3! (depends on properties)
21. Energy Example Surface area => 48 m2/m3
Assume: 80% of fractures pre-existing, 18% tensile, 2% compressive
Gc values:
Pre-existing fractures: 10 J/m2
New tensile fractures: 100 J/m2
New compressive fractures: 5000 J/m2
Energy per m3: 6,050 J/m3
Energy supplied:1.5 MJ/m3 (1,500,000)
Difference of 250. Where does the rest of the energy go?
22. Things To Think About Create as many microcracks in blasting as possible, it helps in crushing and grinding
Grinding takes the more energy than blasting or crushing, why?
Other ways to create cracks => thermal, laser, water, etc.
23. Energy Problems Electricity
Environment => global warming, acid rainfall, nuclear waste
Supply and demand => Calif. (and US) crisis
Transportation
Traffic congestion
Safety
Supply and demand => gas prices
24. Energy solutions Electricity
Alternatives to fossil fuels
Wind, solar, PV cells
Conservation, efficiency
Transportation
Conservation, efficiency => incentives
Alternatives to the auto
Alternative fuels for autos => hydrogen
25. Basic sciences in energy Thermodynamics
Conversion losses
Energy units
Heat transfer
Electricity and Magnetism
Relationship between E and M
Generating electricity
26. The Scientific Method Careful observation
Formulation of rules of empirical laws
Develop a hypothesis
Test the hypothesis
27. Scientific Method Example Observation => low pH in lakes
More observations => associated with acid rainfall, areas where no soil buffering
28. Scientific Method Example Empirical law => always occurs in areas downwind of power plants that burn fossil fuels, or a major city
Hypothesis => SO2 emissions from power plant and/or Nox (power plants and smog) main cause of acid lakes
29. Scientific Method Example Test => reduce SO2, NOx emissions
30. Other Similar Examples Grand Canyon haze
Global warming
High cancer rates in certain neighborhoods in certain cities
31. For Wednesday Read first chapter in book
Print out first activity and bring to class
