Answer:
33.725 rpm
Explanation:
The relationship between rotational speed in radians per second and acceleration is ...
[tex]\omega=\sqrt{\dfrac{a}{r}}[/tex]
We want the rotation rate in RPM, so we need the conversion ...
[tex]\text{RPM}=\dfrac{\text{rad}}{\text{s}}\cdot\dfrac{1\,\text{rev}}{2\pi\,\text{rad}}\cdot\dfrac{60\,\text{s}}{1\,\text{min}}[/tex]
Then the required rotational speed in RPM is ...
[tex]RPM=\sqrt{\dfrac{a}{r}}\cdot\dfrac{30}{\pi}=\dfrac{30}{\pi}\sqrt{\dfrac{1.4\cdot 9.8}{1.1}}\approx 33.725[/tex]
The rotation rate needs to be about 33.7 rpm to give an acceleration of 1.4g at the astronaut's feet.
