13.[2pt] A curve in a highway has radius of curvature 120 m and is banked at...
A curve in a highway has radius of curvature 130 m and is banked at 3.4°. The coefficients of friction are μs= 0.28 and μk = 0.15. What is the fastest safe speed to drive this curve? You must take into account the coefficient of friction for this problem. The answer is not 8.70 m/s nor 27.37 m/s. Thank you for your help.
A highway curve of radius 70 m is banked at a 15° angle. At what speed vo can a car take this curve without assistance from friction?
A car rounds a curve that is banked inward. The radius of curvature of the road is R = 140 m, the banking angle is θ = 26°, and the coefficient of static friction is μs = 0.39. Find the minimum speed that the car can have without slipping. A car rounds a curve that is banked inward. The radius of curvature of the road is R 140 m, the banking angle is 26e, and the coefficient of static minimum...
A concrete highway curve of radius 70.0 m is banked at a 19.0° angle. What is the maximum speed with which a 1900 kg rubber-tired car can take this curve without sliding? (Take the static coefficient of friction of rubber on concrete to be 1.0.)
The radius of curvature of a highway exit is r = 64.5 m. The surface of the exit road is horizontal, not banked. (See figure.) Top view YY I Exit X Back view If the coefficient of static friction between the tires of the car and the surface of the road is us = 0.573, then what is the maximum speed at which the car can safely exit the highway without sliding? Submit Answer Tries 0/20
A highway curve of radius 68.0 m is banked at 21.4 degree so that a car traveling at 26.4 m/s (95 km/hr) will utilize both banking and friction to keep it on the curve. Determine the minimum coefficient of static friction between the tires and the road to keep the car on the road at this speed on this curve.
A concrete highway curve of radius 80.0 m is banked at a 19.0 ∘ angle. Part A What is the maximum speed with which a 1400 kg rubber-tired car can take this curve without sliding? (Take the static coefficient of friction of rubber on concrete to be 1.0.)
A concrete highway curve of radius 70.0 m is banked at an 11 degree angle. What is the maximum speed with which a 1200 kg rubber-tired car can take this curve without sliding? (Take the static coefficient of friction of rubber on concrete to be 1.0.)
A concrete highway curve of radius 80.0 m is banked at a 13.0 ∘ angle. Part A What is the maximum speed with which a 1200 kg rubber-tired car can take this curve without sliding? (Take the static coefficient of friction of rubber on concrete to be 1.0.) Express your answer with the appropriate units.
A curve on a road has a radius of curvature of 500.0m and is banked at an angle of 10.00 degrees, if a 1700.0Kg car is traveling at a speed of 27.0m/s around the curve, what is the magnitude and direction of the static frictional force needed to keep the car around the curve at this speed?