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 ΣFx is the x component of the net force acting on the car.
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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-\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 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? 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? Part ASort the following forces as acting on the car or not. Weight: vector w Normal force: vector n Kinetic friction: vectorfk) Static friction:vector...
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?
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.
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 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
Sort the following quantities as known, to find, or unneeded. Let m and v be the mass and speed of the car, respectively: mu_s 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 summation F_z is the x component of the net force acting on the car Use the information you collected in the Prepare step to find the net force on...
A car drives around a flat 119 m radius circular track at 20 m/s. Assume that this speed is the maximum speed that the car can have without out "skidding out" of the curve.The car moves into the next curve. The radius of this new curve is twice as great as the previous. Assume the coefficient of static friction has not changed. Calculate the car's maximum speed in this curve. m/s
(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...
A car is travelling at a flat circular track of radius 25 m and tries to go around at 40 m/sec. a) What should the coefficient of static friction be so the car won’t skid? b) Assume the same car is now travelling at a banked circular track at angle 25o , r=25 m and with same speed. What’s the value of the coefficient of static friction in order for the car not to slide down? c) What would the...