9. A car moving initially with a speed of S m/s brakes to a stop in...

Question

Question

Answer 1

Answer #1

(9) Initial speed of the car, u = 5.0 m/s

The car stop in time, t = 10.0 s

Final speed of the car, v = 0

Suppose, a = acceleration of the car

Use the expression –

v= u + a*t

put the values –

0 = 5.0 m/s + a*10.0 s

=> a = -5/10 = -0.50 m/s^2

So, magnitude of the acceleration, a = 0.50 m/s^2

Negative sign shows that the car is slowing down.

Again. suppose, m = mass of the car

Average force, F = 700 N (given)

Now –

F = m*a

=> m = F/a = 700 N / (0.50 m/s^2) = 1400.0 kg

Hence, mass of the car = 1400.0 kg (Answer)

Answer 2

Similar Homework Help Questions

A car that weighs 1.4×104 N is initially moving at a speed of 50 km/h when...

A car that weighs 1.4×104 N is initially moving at a speed of 50 km/h when the brakes are applied and the car is brought to a stop in 15 m. Assuming that the force that stops the car is constant, find the magnitude of that force. Incorrect. Tries 5/20 Previous Tries Find the time required for the change in speed. Tries 0/20 If the initial speed is, instead, twice as great, and the car experiences the same force during...
A car that weighs 1.27 x104 N is initially moving at 44.91 km/h when the brakes...

A car that weighs 1.27 x104 N is initially moving at 44.91 km/h when the brakes are applied and the car is brought to a stop in 12.9 m. Assuming the force that stops the car is constant, find the magnitude of that force.
A driver in a moving car applies the brakes. The car slows to a final speed...

A driver in a moving car applies the brakes. The car slows to a final speed of 1.30 m/s over a distance of 40.0 m and a time interval of 8.20 s. The acceleration while braking is approximately constant. (a) What is the car's original speed before braking? What is its acceleration during this time? (The car's initial velocity is in the positive direction. Indicate the direction with the sign of your answer.)

Chapter 5 Q:6 A car that weighs 1.2 x 104 N is initially moving at a...

Chapter 5 Q:6 A car that weighs 1.2 x 104 N is initially moving at a speed of 37 km/h when the brakes are applied and the car is brought to a stop in 20 m. Assuming that the force that stops the car is constant, find (a) the magnitude of that force and (b) the time required for the change in speed. If the initial speed is doubled, and the car experiences the same force during the braking, by...
A car moving initially at a speed of 52.0 mi/h and weighing 3,000 lb is brought...

A car moving initially at a speed of 52.0 mi/h and weighing 3,000 lb is brought to a stop in a distance of 205 ft. Find (a) the breaking force (b) the time required to stop. Assuming the same braking force find (a) the distance and (d) the time required to stop if the car were going 26.0mi/h initially. (Hint: Convert to SI units)
A car of mass 2.0 x 103 kg is initially moving at 75 km/h when the...

A car of mass 2.0 x 103 kg is initially moving at 75 km/h when the brakes are applied and the car is brought to a stop in 25 m. Assuming the force that stops the car is constant, find the magnitude of that force that stop the car. A. - 15.73x103 N B. -17.3x103 N C. 16.73x103 N D. 12.73x103 N

A car moving at 48 m/s brakes to a stop in 6 seconds. What is its...

A car moving at 48 m/s brakes to a stop in 6 seconds. What is its acceleration?
Question 181 A car moving at 20 m/s brakes and slides to a stop. If the...

Question 181 A car moving at 20 m/s brakes and slides to a stop. If the coefficient of kinetic friction between the pavement and the tires of the car is 0.1, how far does the car slide? O A. 50 m O B. 100 m O C. 200 m O D. 400 m
A car is moving at a speed of 60 m/s, when the driver applies the brakes,...

A car is moving at a speed of 60 m/s, when the driver applies the brakes, which causes a deceleration of 2 m/s2. How many seconds will it take for the car to stop and how far will it travel till it stops? 30 sec, 450 meters 25 sec, 800 meters 30 sec, 1800 meters 20 sec, 900 meters 30 sec, 900 meters

The driver of a car of mass M which is moving along a straight road with...

The driver of a car of mass M which is moving along a straight road with initial speed v0 sees a deer in her headlights, and reacts quickly, lifting her foot of the gas and applying the brake pedal with maximum force. The anti-lock brakes cause the largest possible static friction force to be applied on the tires by the road, which continue to roll so the car does not skid. The coefficient of static friction between the tires and...