Mechanical Properties of Metals

Mechanical Properties Stiffness - Elastic Modulus or Young’s Modulus (MPa) Strength - Yield, Ultimate, Fracture, Proof, Offset Yield. Measured as stress (MPa) Ductility - Measure of ability to deform plastically without fracture - Elongation, Area Reduction, Fracture Strain - (no units or mm/mm) Toughness, Resilience - Measure of ability to absorb energy (J/m 3 ). Hardness - Resistance to indentation/abrasion (Various scales, e.g.; Rockwell, Brinell, Vickers.)

Stress and Strain In a simplistic sense, stress may be thought of as Load/Area . Similarly, strain is the deformation of the component/original length. A stress may be direct , shear , or torsional - leading to corresponding deformations. Stress cannot be measured directly, but deformation can be.

Direct Stress Examples Direct Stress - Tension Direct Stress - Compression Engineering Stress Engineering Strain

Tension Test Typical Universal Testing Machine Extensometer Measures  L Measures P

Modern Materials Testing System Hydraulic Wedge Grips Specimen Extensometer

ASTM Tension Test Specimen 2” Gauge Length A o =0.20 in 2 L o

Raw Data Obtained Elongation,  L (mm) Load, P (kN) Uniform Deformation Total Elongation Elastic Deformation X Maximum Load, P max Load, P f

Engineering Stress-Strain Curve Elongation 0.2% offset yield stress Proportional Limit E E (Ultimate) Engineering Strain, e =  L/Lo) Engineering Stress, S=P/Ao S y S u

Duke’s Quick Tip! Express Load in Newtons (N) and Area in mm 2 to get Stress in MPa. Mechanical properties of metals are almost always given in MPa or ksi. Imperial units: Load in kips (1000 lbf) & Area as in 2 gives Stress in ksi (kips/in 2 ) 1000 psi = 1 ksi = 6.89 MPa

Hooke’s Law Elastic Deformation Elastic deformation is not permanent; it means that when the load is removed, the part returns to its original shape and dimensions. For most metals, the elastic region is linear. For some materials, including metals such as cast iron, polymers, and concrete, the elastic region is non-linear. If the behavior is linear elastic, or nearly linear-elastic, Hooke’s Law may be applied: Where E is the modulus of elasticity (MPa)

Modulus of Elasticity - Stiffness

Shear Stress and Strain shear stress,  = Shear Load / Area shear strain,  = angle of deformation (radians) shear modulus, G =  /  (elastic region) Shear Stress Shear Strain

Elastic Properties of Materials Poisson’s ratio: When a metal is strained in one direction, there are corresponding strains in all other directions. For a uniaxial tension strain, the lateral strains are constrictive. Conversely, for a uniaxial compressive strain, the lateral strains are expansive. i.e.; the lateral strains are opposite in sign to the axial strain. The ratio of lateral to axial strains is known as Poisson’s ratio,  .

Poisson’s Ratio,  For most metals, 0.25 <  < 0.35 in the elastic range Furthermore :

Plastic Deformation Stress Strain 0.002 0.002 0.002 S y S y S y Most Metals - Al, Cu Clad Al-Alloys Low carbon Steel Elastic Plastic Elastic Plastic Elastic Plastic

Microstructural Origins of Plasticity Slip, Climb and Slide of atoms in the crystal structure. Slip and Climb occur at Dislocations and Slide occurs at Grain Boundaries.  

Elastic and Plastic Strain Stress Strain Plastic Elastic e e e p P Total Strain (e,S) The 0.2% offset yield stress is the stress that gives a plastic (permanent) strain of 0.002.

Elastic Recovery Strain Stress Loading Unloading Loading Unloading Reloading elastic strain Strain

Ductility - EL% & AR% El ongation A rea R eduction L o A o L f A f

Ductile Vs Brittle Materials Only Ductile materials will exhibit necking . Ductile if EL%>8% (approximately) Brittle if EL% < 5% (approximately) Engineering Stress Engineering Strain

Toughness & Resilience Toughness: A measure of the ability of a material to absorb energy without fracture. (J/m 3 or N.mm/mm 3 = MPa) Resilience: A measure of the ability of a material to absorb energy without plastic or permanent deformation. (J/m 3 or N.mm/mm 3 = MPa) Note: Both are determined as energy/unit volume

Toughness, U t Engineering Strain, e =  L/Lo) Engineering Stress, S=P/Ao S u S y

Resilience, U r Engineering Strain, e =  L/Lo) Engineering Stress, S=P/Ao S u S y E e y

Typical Mechanical Properties Metals in annealed (soft) condition

Mechanical Properties of Metals

More Related Content

What's hot (20)

Similar to Mechanical Properties of Metals (20)

Recently uploaded (20)

Mechanical Properties of Metals