Respuesta :
Answer:
Maximum height attained by the model rocket is 2172.87 m
Explanation:
Given,
- Initial speed of the model rocket = u = 0
- acceleration of the model rocket = [tex]a\ =\ 85.0 m/s^2[/tex]
- time during the acceleration = t = 2.30 s
We have to consider the whole motion into two parts
In first part the rocket is moving with an acceleration of a = 85.0 [tex]m/s^2[/tex] for the time t = 2.30 s before the fuel abruptly runs out.
Let [tex]s_1[/tex] be the height attained by the rocket during this time intervel,
[tex]s_1\ =\ ut\ +\ \dfrac{1}{2}at^2\\\Rightarrow s_1\ =\ 0\ +\ 0.5\times 85\times 2.30^2\\\Rightarrow s_1\ =\ 224.825\ m[/tex]
And Final velocity at that point be v
[tex]\therefore v\ =\ u\ +\ at\\\Rightarrow v\ =\ 0\ +\ 85.0\times 2.3\\\Rightarrow v\ =\ 195.5\ m/s.[/tex]
Now, in second part, after reaching the altitude of 224.825 m the fuel abruptly runs out. Therefore rocket is moving upward under the effect of gravitational acceleration,
Let '[tex]s_2[/tex]' be the altitude attained by the rocket to reach at the maximum point after the rocket's fuel runs out,
At that insitant,
- initial velocity of the rocket = v = 195.5 m/s.
- a = [tex]-g\ =\ -9.81\ m/s^2[/tex]
- Final velocity of the rocket at the maximum altitude = [tex]v_f\ =\ 0[/tex]
From the kinematics,
[tex]v^2\ =\ u^2\ +\ 2as\\\Rightarrow 0\ =\ u^2\ -\ 2gs_2\\\Rightarrow s_2\ =\ \dfrac{u^2}{2g}\\\Rightarrow s_2\ =\ \dfrac{195.5^2}{2\times 9.81}\\\Rightarrow s_2\ =\ 1948.02\ m[/tex]
Hence the maximum altitude attained by the rocket from the ground is
[tex]s\ =\ s_1\ +\ s_2\ =\ 224.85\ +\ 1948.02\ =\ 2172.87\ m[/tex]
