1 Answer

Ask a Question

Adrian McCarthy · Answer 1 · 2023-12-27T03:00:48+0000

Answer:

Kinetic energy of the projectile at the vertex of the trajectory:
$900\; {\rm J}$ .

Work done when firing this projectile:
$2500\; {\rm J}$ .

Step-by-step explanation:

Since the drag on this projectile is negligible, the horizontal velocity
v_(x) of this projectile would stay the same (at
$30\; {\rm m\cdot s^(-1)}$ ) throughout the flight.

The vertical velocity
v_(y) of this projectile would be
$0\; {\rm m\cdot s^(-1)}$ at the vertex (highest point) of its trajectory. (Otherwise, if
v_(y) > 0 , this projectile would continue moving up and reach an even higher point. If
v_(y) < 0 , the projectile would be moving downwards, meaning that its previous location was higher than the current one.)

Overall, the velocity of this projectile would be
$v = 30\; {\rm m\cdot s^(-1)}\!$ when it is at the top of the trajectory. The kinetic energy
$\text{KE}$ of this projectile (mass
$m = 2.0\; {\rm kg}$ ) at the vertex of its trajectory would be:

$\begin{aligned} \text{KE} &= (1)/(2)\, m\, v^(2) \\ &= (1)/(2) * 2.0\; {\rm kg} * (30\; {\rm m\cdot s^(-1)})^(2) \\ &= 900\; {\rm J} \end{aligned}$ .

Apply the Pythagorean Theorem to find the initial speed of this projectile:

$\begin{aligned}v &= \sqrt{(v_(x))^(2) + (v_(y))^(2)} \\ &= \left(√(900 + 1600)\right)\; {\rm m\cdot s^(-1)} \\ &= 50\; {\rm m\cdot s^(-1)}\end{aligned}$ .

Hence, the initial kinetic energy
$\text{KE}$ of this projectile would be:

$\begin{aligned} \text{KE} &= (1)/(2)\, m\, v^(2) \\ &= (1)/(2) * 2.0\; {\rm kg} * (50\; {\rm m\cdot s^(-1)})^(2) \\ &=2500\; {\rm J} \end{aligned}$ .

All that energy was from the work done in launching this projectile. Hence, the (useful) work done in launching this projectile would be
$2500\; {\rm J}$ .

0 Comments

Please log in or register to add a comment.

Please log in or register to answer this question.

1 Answer

0 Comments

Please log in or register to add a comment.

Other Questions