Presentation is loading. Please wait.

Presentation is loading. Please wait.

What speed will allow a given mass to revolve at a given angle

Published byLynne Adams Modified over 6 years ago

Similar presentations

Presentation on theme: "What speed will allow a given mass to revolve at a given angle"— Presentation transcript:

1 What speed will allow a given mass to revolve at a given angle
What speed will allow a given mass to revolve at a given angle? More speed should increase the angle. Derive a formula relating speed to angle in the situation below.

2 ……M and . Now derive an equation
T should depend on …… ……M and  Now derive an equation Reality check: as m increases, T increases. As  increases…. Fy= ma =..? T cos  - mg = 0 T = mg/ cos  …cos decreases and T increases What speed will allow a given mass to revolve at a given angle? More speed should increase the angle. Derive a formula. Fx= ma =..? …mv2/r T = mv2/r sin  = mv2/L sin2 Tsin = mv2/r R = Lsin  V = (TL sin2 /m)

3  = v2/rg ..on r, v, m Derive a formula for  = f(m,v,r) Fy= ma
How big a  is needed to round the curve without skidding? Depends… ..on r, v, m “radius of curvature” Derive a formula for  = f(m,v,r) Fy= ma Fx= ma =..? …mv2/r f = mv2/r = N But I don’t want N as a variable… N-mg = 0 f = mv2/r = mg N = mg  = v2/rg What questions can you do to reality check this equation? High v and tight turns (small r) * What v and r require the highest coef of friction? * Is the equation dimensionally consistent? Yes! No unit = (m/s)2/ m(m/s2)

4 What’s the advantage to banking a roadway at the turns?
The normal force actually provides a centripetal component Yes, but it wouldn’t be car racing…..it would be the luge! Is this possible without friction? But the luge is progressively banked. If this were a car on ice at constant  we will see that only one possible speed will maintain equilibrium. Go too fast and you slide up and over….too slow and you slide down hill! Let’s first do the unreal frictionless analysis…then the more real case of friction adding a second centripetal force to keep the car in the circle.

5 Find the velocity necessary to stay on track in terms
Find the velocity necessary to stay on track in terms of m,g, r and  : Fc= mv2/r Nsin = mv2/r Fy=0 Now get N out of equation and introduce m Ncos - mg = 0 Nsin = mv2/r N = mg/cos How would introducing friction change the resulting v needed to stay on track? mg sin /cos = mv2/r mg tan = mv2/r rmg tan/m = v2 A new  term would lower the v needed to stay on track. rg tan = v

6 Factor out N, then solve for N, then substitute N away
Fy=0 mg Ncos + f sin - mg = 0 Fc = mv2/r And f = N Nsin - f cos = mv2/r Nsin - N cos = mv2/r Ncos + N sin - mg = 0 Factor out N, then solve for N, then substitute N away N( cos +  sin) - mg = 0 N (sin -  cos) = mv2/r v = r N (sin -  cos)/m N = mg/ ( cos +  sin) v = {r mg { (sin -  cos)/m ( cos +  sin)} Wow !!!

7 rg tan = v v = {r g { (sin -  cos)/( cos +  sin)}
Reality check: This equation should, when frictionless, reduce to rg tan = v It does! So we trust are new equations because they are MATHEMATICALLY CONSISTANT with the other equations we have developed so far. Now use this awesome new equation to calculate the minimum speed that a car would have to go to avoid slipping on a curve of 10 meter radius if the μ between the tire and rod were 0.5 and the bank were 30⁰. v = {10x10{ (sin30 – 0.5 cos30)/( cos sin30)} v = {10 { (.5 – 0.433)/( )} = 10  { (.067)/(1.116)} = 2.4 m/s

8 rg tan = v v = {r g { (sin -  cos)/( cos +  sin)}
Reality check: This equation should, when frictionless, reduce to rg tan = v It does! So we trust are new equations because they are MATHEMATICALLY CONSISTANT with the other equations we have developed so far. Now use this awesome new equation to calculate the minimum speed that a car would have to go to avoid slipping on a curve of 10 meter radius if the μ between the tire and rod were 0.5 and the bank were 30⁰.

9 Toy plane circling on a string at constant speed
Lift is normal to the wing’s lower surface. Create a formula relating the tension in the string to speed, m, Flift,  & R

10 Toy plane circling on a string at constant speed
Lift is normal to the wing’s lower surface. r Create formulas relating speed, m, Flift, T,  & R: Fy= ma =..? Fx= ma =..? …mv2/r Flift cos 2 – mg – T sin 1= 0 T cos 1 + Flift sin 2 = mv2/r

11 Derive a formula for  = f(m,v,r)
How big a  is needed to round the curve without skidding? Depends… Derive a formula for  = f(m,v,r) What questions can you do to reality check this equation? * What v and r require the highest coef of friction? * Is the equation dimensionally consistent?

12 What’s the advantage to banking a roadway at the turns?
Is this possible without friction?

Download ppt "What speed will allow a given mass to revolve at a given angle"

Similar presentations

Circular Motion & Highway Curves

Circular Motion & Highway Curves
CHAPTER-6 Force and Motion-II.

CHAPTER-6 Force and Motion-II.
Centripetal Acceleration and Centripetal Force

Centripetal Acceleration and Centripetal Force
CIRCULAR MOTION We will be looking at a special case of kinematics and dynamics of objects in uniform circular motion (constant speed) Cars on a circular.

CIRCULAR MOTION We will be looking at a special case of kinematics and dynamics of objects in uniform circular motion (constant speed) Cars on a circular.
Calculate the Tension:  Fy= ma =..? 0 T cos  - mg = 0 T = mg/ cos  = 620*10/cos40 Calculate the Drag:  Fx= ma =..? T sin  - D = 0 D = T sin  = mg.

Calculate the Tension:  Fy= ma =..? 0 T cos  - mg = 0 T = mg/ cos  = 620*10/cos40 Calculate the Drag:  Fx= ma =..? T sin  - D = 0 D = T sin  = mg.
Centripetal Force & the Road

Centripetal Force & the Road
Circular Motion.

Circular Motion.
L-9 Conservation of Energy, Friction and Circular Motion Kinetic energy, potential energy and conservation of energy What is friction and what determines.

L-9 Conservation of Energy, Friction and Circular Motion Kinetic energy, potential energy and conservation of energy What is friction and what determines.
Horizontal Circular Motion. Car rounding a flat-curve.

Horizontal Circular Motion. Car rounding a flat-curve.
1© Manhattan Press (H.K.) Ltd. Cyclists rounding bends on a level road Vehicles rounding bends on a level road Vehicles rounding bends on a level road.

1© Manhattan Press (H.K.) Ltd. Cyclists rounding bends on a level road Vehicles rounding bends on a level road Vehicles rounding bends on a level road.
Chapter Opener. Caption: Newton’s laws are fundamental in physics

Chapter Opener. Caption: Newton’s laws are fundamental in physics
Example 1: A 3-kg rock swings in a circle of radius 5 m

Example 1: A 3-kg rock swings in a circle of radius 5 m
Assume stopper is at constant 2 m/s. Is it accelerating. Does it have F net. What causes F net ? Direction of F net ? Direction of acceleration? Velocity.

Assume stopper is at constant 2 m/s. Is it accelerating. Does it have F net. What causes F net ? Direction of F net ? Direction of acceleration? Velocity.
Chapter 5 Dynamics of Uniform Circular Motion. 5.1 Uniform Circular Motion DEFINITION OF UNIFORM CIRCULAR MOTION Uniform circular motion is the motion.

Chapter 5 Dynamics of Uniform Circular Motion. 5.1 Uniform Circular Motion DEFINITION OF UNIFORM CIRCULAR MOTION Uniform circular motion is the motion.
L-9 Conservation of Energy, Friction and Circular Motion Kinetic energy, potential energy and conservation of energy What is friction and what determines.

L-9 Conservation of Energy, Friction and Circular Motion Kinetic energy, potential energy and conservation of energy What is friction and what determines.
Curves. Rounding A Curve Friction between the tires and the road provides the centripetal force needed to keep a car in the curve.

Curves. Rounding A Curve Friction between the tires and the road provides the centripetal force needed to keep a car in the curve.
Uniform Circular Motion Centripetal forces keep these children moving in a circular path.

Uniform Circular Motion Centripetal forces keep these children moving in a circular path.
Circular Motion Part 2 By: Heather Britton. Circular Motion Part 2 According to Newton’s 2nd Law, an accelerating body must have a force acting on it.

Circular Motion Part 2 By: Heather Britton. Circular Motion Part 2 According to Newton’s 2nd Law, an accelerating body must have a force acting on it.
Circular Motion. Rotating Turning about an internal axis Revolving Turning about an external axis.

Circular Motion. Rotating Turning about an internal axis Revolving Turning about an external axis.
Chapter 6.2. Uniform Circular Motion Centripetal forces keep these children moving in a circular path.

Chapter 6.2. Uniform Circular Motion Centripetal forces keep these children moving in a circular path.

Similar presentations

Ads by Google