Calculating Modulus of Elasticity for Material and Failure Point

In summary, the conversation is about calculating the Young's modulus of a material and determining its failure point. The participants discuss the correct way to compute the area and stress, and how to use the strain values to obtain the modulus of elasticity. They also mention the importance of being consistent and clarifying the problem statement.
  • #1
boyblair
8
0
Hello, having some problems with calculating young's modulus, please help.

1. A Strain gauge records the following strain when a block of material is pulled:

Force(N) Strain(%)
100 0.01
1000 0.1
2000 0.179
3100 0.9

Area of block = 10cmx10cm

Work out the modulus of elasticity and when the material fails?


The Attempt at a Solution



Area over which force acts = 3.14x5x5
= 78.5cm2

In inches = 78.5/2.54
= 30.9 inch2

Stress = force/area
= 3100/30.9
=100.3 psi

E = Stress/Strain
= 100.3/0.9
= 111.4psi
 
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  • #2
Perhaps first study how to compute the area of a square. If the material cross-sectional area is not a square, please clarify the problem statement. Also, try to avoid converting to a nondecimal, nonstandard, incoherent measurement system. Just convert cm to mm, and all stresses will be in MPa. Also study how to compute the slope of a straight line.
 
  • #3
Thanks for the advice. I have made another attempt.

Area = 10x10
= 100cm2 or 10000mm2

E = Force applied x original length/area of cross section x change in length
= 1700 x 100/10000 x 0.17
= 100 Mpa

Not sure where I should use slope of straight line calculation.
 
  • #4
boyblair: Yes, use 10 000 mm^2 for the area. You could compute the stress (force divided by area) at point 1 or 2. Then, to obtain E, in your particular case, you could divide stress by strain at point 1 or 2. I don't quite understand from where you got 1700 N and 0.17 %, but you somehow got the correct answer, nonetheless (except the unit symbol for megapascal is spelled MPa).
 
  • #5
You are going to have to clarify the problem. Is the length of the bar given? Strain is a dimensionless quantity (change in length divided by original length). You indicate it as a percent; if that's the case, under the 100N load, for example, the strain is 0.0001, and the change in length (elongation) is 0.01 mm, if the bar is 100 mm long. The stress strain curve is linear for the first 2 load cases. I'd use one of those values for determining E. Then the strain goes way up (non linear) under the 3100N load. Is that the failure load? This value of strain under that load condition should not be used for determining E. Then be consistent in determining E. You can use either of your formulas
(E = stress/strain or E = FL/A(elongation)), but watch your units and values to use.
 

1. What is the modulus of elasticity for a material?

The modulus of elasticity, also known as Young's modulus, is a measure of the stiffness or rigidity of a material. It represents the amount of stress that a material can withstand before it permanently deforms, and is typically measured in units of force per unit area.

2. How is the modulus of elasticity calculated?

The modulus of elasticity is calculated by dividing the stress applied to a material by the strain that results from that stress. This can be represented by the equation E = σ/ε, where E is the modulus of elasticity, σ is stress, and ε is strain.

3. What is the significance of the modulus of elasticity in material design?

The modulus of elasticity is a crucial factor in material design as it helps engineers and scientists determine the strength and durability of a material. It is used to select the appropriate materials for specific applications and to ensure that the material can withstand the expected loads and stresses without failing.

4. How does the modulus of elasticity relate to the failure point of a material?

The modulus of elasticity is directly related to the failure point of a material. As the stress on a material increases, the strain also increases until it reaches a point where the material can no longer withstand the load and permanently deforms or breaks. This point is known as the failure point, and the modulus of elasticity helps to predict and prevent failures in materials.

5. Can the modulus of elasticity change for a material?

Yes, the modulus of elasticity can change for a material depending on various factors such as temperature, stress level, and the material's microstructure. Extreme temperatures can cause a decrease in the modulus of elasticity, while high stress levels can cause an increase. Changes in the material's microstructure can also affect its modulus of elasticity, making it an important consideration in material design and testing.

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