Car turning with friction: maximum speed for a car rounding a level curve.
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- Опубліковано 9 жов 2023
- In this problem, we find the maximum speed for a car rounding a level turn.
To analyze a car turning with friction, we begin with a complete force diagram. We view the turning car from overhead and rear views, and we observe that the car accelerates toward the center of curvature. This means a horizontal force must push toward the center of curvature, and that's the static friction force. To complete the force diagram, we include the weight of the car, mg, and the normal force, which is also mg because there are no other forces tampering with the vertical direction.
Next, we apply Newton's second law F_net=ma in the horizontal direction, defining the positive direction to be "toward the center of curvature" to keep the math as simple as possible. The net horizontal force is just the static friction force pointing to the center of curvature, and the observed acceleration is the centripetal acceleration a=v^2/r.
Now we assume the static friction force is maximized, because we are looking for the maximum speed just before the tires start to slip. Subbing in the formula for maximum static friction force and canceling mass out of the equation, we are able to solve for the maximum speed for a car rounding a level curve: v_max=sqrt(mu_s*g*r).
Gajab 👍🤙❤🫡🙏🏻🫡
Thanks! -- Zak
I like it❤
cool -z
Super underrated
thanks . . . working on it . . . .slowly - Zak
Where does the 9.8 come from?
9.8m/s^2 is the acceleration induced by gravity near the surface of the Earth. Early in a physics course you're usually just told that the acceleration is 9.8 or 9.81 m/s^2, then we discover that the weight of a mass m is actually mg. Here's a link to a short video on why that's true: ua-cam.com/users/shortswKkDcpHGkjs Later in the course, students get the opportunity to determine the acceleration of gravity by using Newton's Law of Gravitation F=GMm/r^2 to derive g from more fundamental principles, which is done in this video: ua-cam.com/video/xGmkiL5RzJg/v-deo.html z