Question

Question #33891

Answer 1

`sf(102.5color(white)(x)s)`

Explanation:

I will consider the motion in two stages.

1. The Powered Stage

To get the final velocity at the end of the powered stage we can use:

`sf(v=u+at)`

This becomes:

`sf(v=0+((9.81)/(3))xx60=196.2color(white)(x)"m/s")`

To find the height h reached we can use:

`sf(v^2=u^2+2as)`

This becomes:

`sf(196.2^2=0+(2xx9.81)/(3)xxh)`

`:.` `sf(h=(3.849xx10^4xx3)/(2xx9.81)=588.6color(white)(x)m)`

2. The Unpowered Stage

The rocket is now moving under the influence of gravity.

We can use:

`sf(s=ut+1/2at^2)`

I will use the convention that "up is positive".

The equation becomes:

`sf(-588.6=196.2t-1/2xx9.81xxt^2)`

`:.` `sf(4.9t^2-196.2t-588.6=0)`

Applying the quadratic formula:

`sf(t=(196.2+-sqrt(37,094.76-[4xx4.9xx(-588.6)]))/(9.8)`

`sf(t=(196.2+-220.5)/(9.8))`

Ignoring the -ve root:

`sf(t=42.5color(white)(x)s)`

To get the total time of flight `(sf(t_("tot")))`, we add this to the time taken for the powered part of the flight which we know is 1 minute.

`:.` `sf(t_("tot")=60+42.5=102.5color(white)(x)s)`