Question 21.P.10: A short length of hollow tube 32 mm external diameter and 25...
A short length of hollow tube 32 mm external diameter and 25 mm internal diameter yielded in a compression test at a load of 70 kN. When a 2.5 m length of the same tube was tested as a column with fixed ends the failure load was 24.1 kN. Assuming that \sigma_{S} in the Rankine formula is given by the first test find the value of the constant k and hence the crippling load for a column 1.5 m in length when used as a column with pinned ends.
In Eq. (21.27) P=\frac{\sigma_{S} A}{1+k\left(L_{e} / r\right)^{2}} \sigma_{\mathrm{S}} A = 70 kN. Also the area of the cross section of the column is
A=\frac{\pi}{4}\left(32^{2}-25^{2}\right)=313.4 \mathrm{~mm}^{2}
and its second moment of area is
I=\frac{\pi}{64}\left(32^{4}-25^{4}\right)=32297.1 \mathrm{~mm}^{4}
The radius of gyration of the column cross section is then
r=\sqrt{(32297.1 / 313.4)}=10.15 \mathrm{~mm}
The equivalent length, L_{e} , of the column is equal to 0.5 × 2.5 × 10³ = 1250 mm. Now substituting the above in Eq. (21.27)
24.1 \times 10^{3}=\frac{70 \times 10^{3}}{1+k(1250 / 10.15)^{2}}
which gives
k = 0.000126
For a column with pinned ends L_{e} is equal to the actual length of the column which in this case is 1500 mm. Therefore, from Eq. (21.27) the crippling load is
P=\frac{70 \times 10^{3}}{1+0.000126(1500 / 10.15)^{2}}=18700 \mathrm{~N}
or
P = 18.7 kN