A rocket, fired from rest at time t=0, has an initial mass of m0 (including its fuel). Assuming that the fuel is consumed at a constant rate k, the mass m of the rocket, while fuel is being burned, will be given by m0−kt. It can be shown that if air resistance is neglected and the fuel gases are expelled at a constant speed c relative to the rocket, then the velocity v of the rocket will satisfy the equation m(dv/dt)=ck−mg where g is the acceleration due to gravity. (a) Find v(t) keeping in mind that the mass m is a function of t. (b) Suppose that the fuel accounts for 60% of the initial mass of the rocket and that all of the fuel is consumed at 90 s. Find the velocity of the rocket in meters per second at the instant the fuel is exhausted. [ Note: Take g=9.8m/s2 and c=2500m/s.]
A rocket, fired from rest at time t=0, has an initial mass of m0 (including its fuel). Assuming that the fuel is consumed at a constant rate k, the mass m of the rocket, while fuel is being burned, will be given by m0−kt. It can be shown that if air resistance is neglected and the fuel gases are expelled at a constant speed c relative to the rocket, then the velocity v of the rocket will satisfy the equation
where g is the acceleration due to gravity.
(a) Find v(t) keeping in mind that the mass m is a function of t.
(b) Suppose that the fuel accounts for 60% of the initial mass of the rocket and that all of the fuel is consumed at 90 s. Find the velocity of the rocket in meters per second at the instant the fuel is exhausted.
[ Note: Take g=9.8m/s2 and c=2500m/s.]
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