Material Properties I
Tensile Test:
Tensile test determines the strength of the material when subjected to a simple stretching operation. Typically, standard dimension test samples are pulled slowly at a uniform rate in a testing machine while the strain is defined as :
Engineering Strain = Change in Length / Original Length
The engineering stress is defined as:
Engineering Stress = Applied Force / Original Area
Slide 1 shows the stress-strain diagram of a ductile material where the linear portion of the graph indicates elastic deformation.
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| Slide 1-Stress -Strain Diagram | Slide 2-Fracture of a Flat Tensile Test Specimen |
The initial slope of the curve, related directly to the strength of the atomic bonds. This modulus indictes the stiffness of the material. (Modulus Elasticity is also known as Young's Modulus)
Modulus of Elasticity = E = Change in Stress/ Change in Strain
The maximum stress applied to the specimen. Tensile strength is also known as Ultimate Strength. (The highest point on the stress-strain diagram)
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| Slide 3- Modulus of Elasticity | Slide 4-Tensile Strength |
The total elongation of the specimen due to plastic deformation, neglecting the elastic stretching.
: The total area under the curve, which indicates the energy absorbed by the specimen in the process of breaking.
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| Slide 5-Ductility | Slide 6-Toughness |
Extensometer: The instrument that measures the elongation of a material while applying tension.
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| Slide 7-Tensile Test Machine | Slide 8-Extensometer |
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| Slide 9-Measurement of Elongation | Slide 10-Comparison of Breaks |
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| Slide 1 | Slide 2 |
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| Slide 3 | |
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| Slide 4 | Slide 5 |
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| Slide 6 | |
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| Slide 7 | Slide 8 |
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| Slide 9 | |
Material Properties I
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Tensile Test:
Tensile test determines the strength of the material when subjected to a simple stretching operation. Typically, standard dimension test samples are pulled slowly at a uniform rate in a testing machine while the strain is defined as :
Engineering Strain = Change in Length / Original Length
The engineering stress is defined as:
Engineering Stress = Applied Force / Original Area
Slide 1 shows the stress-strain diagram of a ductile material where the linear portion of the graph indicates elastic deformation.
|
|
|
| Slide 1-Stress -Strain Diagram | Slide 2-Fracture of a Flat Tensile Test Specimen |
The initial slope of the curve, related directly to the strength of the atomic bonds. This modulus indictes the stiffness of the material. (Modulus Elasticity is also known as Young's Modulus)
Modulus of Elasticity = E = Change in Stress/ Change in Strain
The maximum stress applied to the specimen. Tensile strength is also known as Ultimate Strength. (The highest point on the stress-strain diagram)
|
|
|
| Slide 3- Modulus of Elasticity | Slide 4-Tensile Strength |
The total elongation of the specimen due to plastic deformation, neglecting the elastic stretching.
: The total area under the curve, which indicates the energy absorbed by the specimen in the process of breaking.
|
|
|
| Slide 5-Ductility | Slide 6-Toughness |
Extensometer: The instrument that measures the elongation of a material while applying tension.
|
|
|
| Slide 7-Tensile Test Machine | Slide 8-Extensometer |
|
|
|
| Slide 9-Measurement of Elongation | Slide 10-Comparison of Breaks |
|
|
|
| Slide 1 | Slide 2 |
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| |
| Slide 3 | |
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| Slide 4 | Slide 5 |
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| Slide 6 | |
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| Slide 7 | Slide 8 |
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| Slide 9 | |
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