The following data were collected from a 10.16 mm-diameter test specimen of polyvinyl chloride (e, - 50.8 mm): Load (AN) AE (mm) Stress (MPa) Strain (mm/mm) O 0.0000 O 0.0 1.334 0.1895 16.45492 0.00373 2.668 0.38 32.90983 0.00748 4.003 0.603 49.37708 0.01187 5.34 0.813 6.67 1.168 7.38 1.778 (maximum load) 65.869 0.016 82.27458 0.023 91.03244 0.035 7.12 2.388 87.82534 0.047 6.316 3.048 (fracture) 77.90798 0.06 After fracture, the total length was 53.086 mm and the diameter was 9.982 mm. Plot the engineering stress strain curve and calculate (a) the 0.2% offset yield strength; (b) the tensile strength; (c) the modulus of elasticity: (d) the % elongation; (e) the % reduction in area; () the engineering stress at fracture

The following data were collected from a 10.16 mm-diameter test specimen of polyvinyl chloride (e, - 50.8 mm): Load (AN) AE (mm) Stress (MPa) Strain (mm/mm) O 0.0000 O 0.0 1.334 0.1895 16.45492 0.00373 2.668 0.38 32.90983 0.00748 4.003 0.603 49.37708 0.01187 5.34 0.813 6.67 1.168 7.38 1.778 (maximum load) 65.869 0.016 82.27458 0.023 91.03244 0.035 7.12 2.388 87.82534 0.047 6.316 3.048 (fracture) 77.90798 0.06 After fracture, the total length was 53.086 mm and the diameter was 9.982 mm. Plot the engineering stress strain curve and calculate (a) the 0.2% offset yield strength; (b) the tensile strength; (c) the modulus of elasticity: (d) the % elongation; (e) the % reduction in area; () the engineering stress at fracture

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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Question Following experimental data are obtained from tensile test of a rectangular test specimen with original thickness of 2,5 mm, gauge width of 24 mm and gauge length of 101 mm: Load (N) Elongation (mm) 0 0 24372 0,183 23008 0,315 28357 5,777 35517 12,315 27555 17,978 23750 23,865 Based on the information above; draw stress-strain diagram of the material and answer the following questions. - Calculate the yield strength (in MPa) of the material. - Calculate the percent elongation of the specimen at yield point. (Use at least five decimal units) - Calculate the stiffness (in MPa) of the specimen material. - Calculate the ultimate strength (in MPa) of the material. - Calculate the percent elongation of the specimen at point of ultimate strength.
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