A parachutist relies on air resistance mainly on her parachute to decrease her downward velocity. She and her parachutehave a mass of 55.0 kg and air

generals336

generals336

Answered question

2020-11-01

A parachutist relies on air resistance mainly on her parachute to decrease her downward velocity. She and her parachutehave a mass of 55.0 kg and air resistance exerts a total upward force of 620 N on her and her parachute.
a) What is the weight of the parachutist?
b) Draw a free body diagram for the parachutist. Use that diagram to calculate the net force on the parachutist. Is the net force upward or downward?
c) what is the acceleration (magnitude and direction) of the parachutist?

Answer & Explanation

averes8

averes8

Skilled2020-11-02Added 92 answers

w=mg=539 N
b) Downward velocity is decreasing so
a is upward and the net force should beupward. Fair>mg so the net force is upward.
c) Taking the upward direction as positive, the acceleration is
a=Fairmgm=Fair=m9.8=620559.8=1.47 m22
Nick Camelot

Nick Camelot

Skilled2023-05-25Added 164 answers

Result:
a) The weight of the parachutist is 55.0kg×9.8m/s2.
b) The free body diagram shows the weight (W) and the upward force due to air resistance (Fair). The net force (Fnet) is the vector sum of these forces.
c) The acceleration of the parachutist is Fnetmass.
Solution:
a) The weight of an object can be calculated using the formula:
{Weight}={mass}×{acceleration due to gravity}
Given that the mass of the parachutist and her parachute is 55.0 kg, and the acceleration due to gravity is approximately 9.8 m/s2, we can calculate the weight as follows:
{Weight}=55.0kg×9.8m/s2
b) A free body diagram shows all the forces acting on an object. In this case, the forces acting on the parachutist are the weight (W) and the upward force due to air resistance (Fair). The net force (Fnet) is the vector sum of these forces. If the net force is positive, it means the overall force is upward; if it is negative, it means the overall force is downward.
c) The acceleration of the parachutist can be determined using Newton's second law, which states that the net force acting on an object is equal to the mass of the object multiplied by its acceleration:
Fnet=mass×acceleration
Since we know the net force acting on the parachutist (620 N) and the mass of the parachutist (55.0 kg), we can rearrange the equation to solve for the acceleration:
acceleration=Fnetmass
Eliza Beth13

Eliza Beth13

Skilled2023-05-25Added 130 answers

a) The weight of the parachutist can be calculated using the formula:
{Weight}={mass}×{acceleration due to gravity}
Given that the mass of the parachutist is 55.0kg and the acceleration due to gravity is 9.8m/s2, we can substitute these values into the formula to find the weight:
{Weight}=55.0kg×9.8m/s2=539N
Therefore, the weight of the parachutist is 539N.
b) The free body diagram for the parachutist can be represented as follows:
WeightAir Resistance=Net ForceDownwardUpwardForceForce
The weight acts downward, while the air resistance exerts an upward force. The net force can be calculated by subtracting the air resistance force from the weight. Since the air resistance force is directed upward, the net force will be downward.
Net Force=WeightAir Resistance=539N620N=81N
Therefore, the net force on the parachutist is 81N, which means it is directed downward.
c) The acceleration of the parachutist can be determined using Newton's second law:
Net Force=mass×acceleration
Substituting the values we have, we can solve for the acceleration:
81N=55.0kg×acceleration
Dividing both sides by the mass:
acceleration=81N55.0kg=1.47m/s2
The acceleration of the parachutist is 1.47m/s2, directed downward.
Mr Solver

Mr Solver

Skilled2023-05-25Added 147 answers

Step 1:
a) To find the weight of the parachutist, we can use the formula:
{Weight}={mass}×{acceleration due to gravity}
Given that the mass of the parachutist is m=55.0{kg}, and the acceleration due to gravity is approximately 9.8{m/s}2, we can calculate the weight as follows:
{Weight}=55.0{kg}×9.8{m/s}2=539{N}
Therefore, the weight of the parachutist is 539{N}.
Step 2:
b) The free body diagram for the parachutist will include two forces: the weight acting downward and the air resistance acting upward. Let's denote the weight as W and the air resistance as R. The diagram can be represented as:
R{Parachutist}W
The net force on the parachutist can be calculated by finding the vector sum of the forces. Since the air resistance is acting in the opposite direction to the weight, we subtract the magnitude of the air resistance from the magnitude of the weight to obtain the net force:
{Net Force}=WR
Substituting the values we know, the net force becomes:
{Net Force}=539{N}620{N}=81{N}
The net force is negative (-81 N), indicating that it is acting downward.
Step 3:
c) The acceleration of the parachutist can be determined using Newton's second law of motion, which states that the net force acting on an object is equal to the mass of the object multiplied by its acceleration:
{Net Force}=m×a
Rearranging the equation to solve for acceleration gives:
a=Net Forcem
Substituting the known values:
a=81N55.0kg1.47{m/s}2
The acceleration of the parachutist is approximately 1.47{m/s}2, with the negative sign indicating that the acceleration is in the opposite direction to the chosen positive direction (downward in this case).

Do you have a similar question?

Recalculate according to your conditions!

Ask your question.
Get an expert answer.

Let our experts help you. Answer in as fast as 15 minutes.

Didn't find what you were looking for?