Answer:
Explanation:
FromTable A - 20; the values of yield strength and tensile strength are derived by using the "Deterministic ASTM Minimum Tensile and yield strength for some Hot-Rolled (HR) and Cold - Drawn (CD) steels for cold drawn AISI 1020 sheet steel:
[tex]Yield \ Strength (S_y) = 57 \ kpsi[/tex]
[tex]Tensile \ Strength (S_{ut} ) = 68 \ kpsi[/tex]
We calculate the ratio of the radius in relation to the thickness of the spherical vessel by using the formula:
[tex]\dfrac{r}{t} = \dfrac{7.5 \ in}{0.0625 \ in} = 120[/tex]
Since the fraction from the ration is higher than 1°, then the shell can be regarded to be a thin spherical shell.
From here; we estimate the tensile stress induced by using the formula:
[tex]\sigma_t = \dfrac{Pd}{4t}[/tex]
[tex]\sigma_t = \dfrac{P(15)}{4(0.0625)}[/tex]
[tex]\sigma_t =60 P[/tex]
Therefore; the tensile stress is equal to the stress-induced in the transverse direction; i.e.
[tex]\sigma_2 = 60 P[/tex]
Thus, since [tex]\sigma _1 = \sigma _2 = 60P;[/tex]
Then the radial stress [tex]\sigma_r = \sigma _3 = -P[/tex]
By the application of Von Mises Stress; the resultant stress can be estimated as follows:
[tex](\sigma ') = \sqrt{\dfrac{1}{2} ( \sigma_1 -\sigma_2)^2+ ( \sigma_2 - \sigma_3)^2 + ( \sigma_3-\sigma_1)^2}[/tex]
[tex](\sigma ') = \sqrt{\dfrac{1}{2} ( 60P -60P)^2+ ( 60P -(-P))^2 + ( (-P) -(60P))^2}[/tex]
[tex](\sigma ') =61P[/tex]
Then: by relating the Von Mises stress at yield condition:
[tex]S_y = \sigma '[/tex]
[tex](57)= 61P[/tex]
[tex]P = \dfrac{57}{61}[/tex]
P = 0.934 kpsi
P = 934 psi
Hence, the pressure at the yield condition is 934 psi
Similarly, relating Von Mises stress at the rupture condition
[tex](S_{ut} )= \sigma'[/tex]
68 = 61 P
[tex]P = \dfrac{68}{61}[/tex]
P = 1.11 kpsi
Hence, the pressure at rupture condition is 1.11 kpsi
