Question 3.4: Find the increase in volume of a thin-walled spherical shell...

For a spherical pressure vessel, we know from Eq. (3.4),

\sigma_1=\frac{p r}{2 t}=\sigma_2               (3.4)

Let us consider an element as shown in Figure 3.10:

On this element, on two pairs of orthogonal surfaces stresses \sigma_1 \text { and } \sigma_2 act. From the generalised Hooke’s law [Eq. (1.14)], we can write for two-dimensional cases, that

\begin{aligned} &\in_{x x}=\frac{\sigma_{x x}}{E}-\frac{\left(\sigma_{y y}+\sigma_{z z}\right)}{E} ν \\ &\in_{y y}=\frac{\sigma_{y y}}{E}-\frac{\left(\sigma_{x x}+\sigma_{z z}\right)}{E} ν \\ & \in_{z z}=\frac{\sigma_{z z}}{E}-\frac{\left(\sigma_{x x}+\sigma_{y y}\right)}{E} ν \end{aligned}             (1.14)

\in_x=\frac{\sigma_{x x}}{E}-ν \frac{\sigma_{y y}}{E}           (1)

Using Eq. (1), we can compute the circumferential strain, \in_{ C } as

=\frac{\sigma_1}{E}(1-ν)             \left(\text { as for spherical vessels, } \sigma_1=\sigma_2\right)

As this is linear strain in circumferential direction, change in length of circumference is

(2 \pi r) \times \frac{p r}{2 E t}(1-ν)

Therefore, the new radius of the sphere is

r^{\prime}=\frac{2 \pi r+2 \pi r(p r / 2 t E)(1-ν)}{2 \pi}

=r+\frac{p r^2}{2 t E}(1-ν)

Therefore, the new volume of the sphere is

V^{\prime}=\frac{4}{3} \pi r^{\prime 3}

=\frac{4}{3} \pi\left[r+\frac{p r^2}{2 t E}(1-ν)\right]^3

Hence, the volumetric change is given by

V^{\prime}-V=\frac{4}{3} \pi\left[r+\frac{p r^2}{2 t E}(1-ν)\right]^3-\frac{4}{3} \pi r^3

Expanding and consequently dropping higher order terms involving power of p/E, we get

\text { Volume change }=\frac{2 \pi p r^4}{E t}(1-ν)

Note that why do we drop powers of p/E? It is because generally p/E is around 0.001, which is quite small. Higher order terms are even smaller, so they are neglected.

Alternative Solution: The volumetric change in the above example can also be calculated as follows.
For spherical vessel, V = (4/3)πr³. Therefore, taking differentials, we get

ΔV = 4πr² Δr

where Δr denotes small change in radius of the sphere. The volumetric strain, \in_{ V } is

\in_{ V }=\frac{\Delta V}{V}=\frac{4 \pi r^2 \Delta r}{(4 / 3) \pi r^3}=3\left\lgroup \frac{\Delta r}{r} \right\rgroup

Therefore,

\in_V=3 \in_r

where \in_r is radial strain. But, \in_r=\in_C (circumferential strain). As circumference, C = 2πr so, ΔC = 2πΔr. Thus,

\frac{\Delta C}{C}=\in_{ C }=\frac{2 \pi \Delta r}{2 \pi r}=\frac{\Delta r}{r}=\in_r

Thus,

\in_{ V }=\frac{3 p r}{2 t E}(1-ν)

Hence, volume change is found as

\Delta V=V^{\prime}-V=V \in_{ V }

=\frac{4}{3} \pi r^3 \times \frac{3 p r}{2 t E}(1-ν)

or          \Delta V=\frac{2 \pi p r^4}{t E}(1-ν)                 (as before)