Examine the forces acting on a race car on a banked curve. A view of the caras it goes around a banked curve is drawn below.Draw a FBD of the car as it speeds around the banked surface. Don'tforget the net or centripetal force in this situation must be towards thecenter of the circular horizontal path which in this diagram is to theleft. If the car was stationary the frictional force would act up the inclineto stop the car from sliding down the track. However, in this situationassume that the car is moving with sufficient speed that the frictionalforce is acting down the track.а.What forces, or components of forces, act towards the center of circularmotion and stop the car from sliding up and off the track? Draw thehorizontal components of those forces.b.Figure 7-174.

here,f is the friction (downwards as the car is moving with high velocity makingf work downwards)N…

Examine the forces acting on a race car on a banked curve. A view of the car as it goes around a banked curve is drawn below. 4. Draw a FBD of the car as it speeds around the banked surface. Don't forget the net or centripetal force in this situation must be towards the center of the circular horizontal path which in this diagram is to the left. If the car was stationary the frictional force would act to stop the car from sliding down the track. However, in this situation assume that the car is moving with sufficient speed that the frictional force is acting down the track. а. the incline dn b. What forces, or components of forces, act towards the center of circular motion and stop the car from sliding up and off the track? Draw the horizontal components of those forces.

Examine the forces acting on a race car on a banked curve. A view of the car as it goes around a banked curve is drawn below. 4. Draw a FBD of the car as it speeds around the banked surface. Don't forget the net or centripetal force in this situation must be towards the center of the circular horizontal path which in this diagram is to the left. If the car was stationary the frictional force would act to stop the car from sliding down the track. However, in this situation assume that the car is moving with sufficient speed that the frictional force is acting down the track. а. the incline dn b. What forces, or components of forces, act towards the center of circular motion and stop the car from sliding up and off the track? Draw the horizontal components of those forces.

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

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