A 1500-kg car drives at 30 m/s around a flatcircular track 300 m in diameter. What are the magnitude and direction of t...

Question

Question

A 1500-kg car drives at 30 m/s around a flatcircular track 300 m in diameter. What are the magnitude and direction of the net force on the car?

Answer 1

Answer #1

D 300 The radius of the circular path is R 150 m Since the normal reaction force balances the weight of the car. So the resul

Answer 2

Similar Homework Help Questions

A 1500-kg car drives at 30 m/s around a flat circular track 300 m in diameter. What are the magnitude and direction of...

A 1500-kg car drives at 30 m/s around a flat circular track 300 m in diameter. What are the magnitude and direction of the net force on the car? Sort the following quantities as known, to find, or unneeded. Let m and v be the mass and speed of the car, respectively; μs is the coefficient of static friction, r is the radius of the circular path, n is the magnitude of the normal force acting on the car, and...
A 1500-\rm kg car drives at 30 \rm m/s around a flat circular track 300 \rm m in diameter. What are the magnitude and d...

A 1500-\rm kg car drives at 30 \rm m/s around a flat circular track 300 \rm m in diameter. What are the magnitude and direction of the net force on the car? 9000N Since the net force is equivalent to the force of static friction, your answer to Part D is the magnitude f_s. Based on this value, what is the minimum coefficient mu_s of static friction between the road and the car?
A 1500 kg car drives around a flat 200 m diameter circular track at 25 m/s....

A 1500 kg car drives around a flat 200 m diameter circular track at 25 m/s. what are the magnitude and direction of the net force on the car? What causes this force?

Review A 1700 kg car drives around a flat 190-m- diameter circular track at 23 m/s....

Review A 1700 kg car drives around a flat 190-m- diameter circular track at 23 m/s. Part A What is the magnitude of the net force on the car? Express your answer in newtons. ΡΟΙ ΑΣΦ N Submit Request Answer
A 1500 kg car drives around a flat circular track at a constant speed of 75...

A 1500 kg car drives around a flat circular track at a constant speed of 75 mi/hr. A 26,000-N static friction force provided by the tires is the only force acting toward the center of the circle. Use the given information to determine the radius of the track. 1 mile = 1609 meters.
A car drives around a circular track of diameter 112 m at a constant speed of...

A car drives around a circular track of diameter 112 m at a constant speed of 36.0 m/s. During the time it takes the car to travel 231 degrees around, what is the magnitude of the car s average acceleration? a. 10.36 m/s^2 b. 0 m/s^2 c. 23.14 m/s^2 d. 11.57 m/s^2

A racecar traveling at a constant speed of 50 m/s drives around a flat circular track...

A racecar traveling at a constant speed of 50 m/s drives around a flat circular track that is 1000 m in diameter. What is the magnitude of the coefficient of static friction between the road and the tires of the car? Group of answer choices 0.25 0.51 1.30 0.86
(9.2.70) A car drives around a circular track of radius 50 m. The car starts at...

(9.2.70) A car drives around a circular track of radius 50 m. The car starts at rest at time t = 0, and its speed increases at a rate of 3.00 m/s. (a) Draw a top view illustrating the motion of the car around the circle, and also a side view showing a free-body diagram for the car (b) Find an equation which gives the magnitude of the net acceleration vector as a function of time (incorporating both radial and...
PSS 6.1 Circular dynamics problems

A 1500- car drives at 30 around a flat circular track 300 in diameter. What are the magnitude and direction of the net force on the car?

1. A car with constant acceleration of 2.3 m/s2 drives toward east (positive x-axces). (a)How much...

1. A car with constant acceleration of 2.3 m/s2 drives toward east (positive x-axces). (a)How much time in seconds is required for the car to change its speed from 10 m/s to 35 m/s? (b)Calculate the total distance in meters, covered during that time (c) Calculate the average speed during that time interval (d) Find x- and y- components of the vector of acceleration 2. From the top of a tower, a person drops a pebble. The peble strikes the...