Chapter 5 Outline Applying Newton’s Laws • Statics • Dynamics • Friction • Kinetic friction • Static friction • Fluid resistance • Circular Motion • Fundamental forces
Chapter 5 Outline Applying Newton’s Laws Statics Dynamics Friction Kinetic friction Static friction Fluid resistance Circular Motion Fundamental forces.
Jan 17, 2016
Welcome message from author
This document is posted to help you gain knowledge. Please leave a comment to let me know what you think about it! Share it to your friends and learn new things together.
Transcript
Chapter 5 OutlineApplying Newton’s Laws
• Statics
• Dynamics
• Friction
• Kinetic friction
• Static friction
• Fluid resistance
• Circular Motion
• Fundamental forces
Statics
• When a body is not accelerating, we say that it is in equilibrium.
• Statics is the study of bodies in equilibrium.
• Since the acceleration is zero, we use Newton’s first law to solve these problems.
; ;
• Carefully draw a free body diagram that shows all forces acting on the body.
• Choose an appropriate coordinate system.
Normal Force
• When an object is resting on a surface, the surface is exerting a force on the object, called the normal force.
• The normal force is always perpendicular to the surface.
• The textbook uses the letter for the normal force. It is also common to use .
Statics Example
Dynamics
• Now we consider a body that is accelerating.
• Dynamics is the study of bodies not in equilibrium.
• Since the acceleration is not zero, we use Newton’s second law to solve these problems.
; ;
• Carefully draw a free body diagram that shows all forces acting on the body.
• Choose an appropriate coordinate system.
Apparent Weight
• Consider the case of a person standing on a scale in an elevator.
• If the elevator is still or moving at a constant velocity, the scale will read the person’s actual weight, .
• If the elevator is acceleration, the scale will read the apparent weight.
• If the body is accelerating downward at the acceleration due to gravity, that is , it experiences apparent weightlessness.
• This is the case during free fall, or while in orbit.
Dynamics Example
Frictional Forces
• So far, we have ignored one of the most important types of force: the force of friction.
• Contact force
• Parallel to surface
Kinetic Friction
• When the surfaces are moving relative to each other, we have kinetic friction.
• The force of kinetic friction is proportional to the normal force, , and the coefficient of kinetic friction, .
• depends on both surfaces.
• Does not depend on contact area!
Static Friction
• When the surfaces are still with respect to each other, we have static friction.
• The force of static friction is proportional to the normal force, , and the coefficient of static friction, .
• depends on both surfaces.
• Generally, for a given pair of surfaces.
Static and Kinetic Friction
Coefficient of Rolling Friction
• In practice, we often use wheels to reduce the frictional forces involved in moving objects.
• Still, we have to consider the frictional force involved.
• The coefficient of rolling friction, :
• The frictional force takes into account the deformation of the wheels.
• For steel on steel (trains), values of are typically to .
Friction Example
Fluid Resistance
• In the case of the contact between solid surfaces, we find that the frictional force is roughly independent of the relative speed or contact area.
• For motion through fluids, the resistive force is quite sensitive to the speed.
• For small objects moving at very low speeds, the fluid resistance force, , is approximately proportional to the speed.
• At higher speeds, the fluid resistance force, , is approximately proportional to the square of the speed.
Terminal Speed
• Since the fluid resistance force is speed dependent, there will be some speed at which the weight of a falling body is balanced by the drag force.
• At this point, the acceleration is zero, and the body has reached its terminal speed.
• From , the terminal speed is:
Fluid Resistance Example
Circular Motion
• Recall from Chapter 3 that circular motion is produced by a centripetal acceleration towards the center of curvature.
• The period, , is the time for one full circle.
• The acceleration towards the center must be provided by some force.
• Planet in orbit: Gravity
• Ball on a string: Tension
• Car going around turn?
Circular Motion Example
Consider a racecar going around a turn with a radius of curvature of . The static and kinetic coefficients of friction between the track and the tires are and , respectively.
• What is the maximum speed at which the car can take the corner without skidding if the track is (a) flat or (b) banked at ?
Fundamental Forces
• We have talked about a lot of different kinds of forces.
• Gravitational, friction, normal, fluid resistance, tension…
• Are these all actually different in nature?
• Four fundamental forces (we think):
• Gravitational
• Electromagnetic
• Strong
• Weak
• All interactions arise through one of these fundamental forces.
• All of the interactions we have dealt with so far were electromagnetic or gravitational.
Chapter 5 OutlineApplying Newton’s Laws
• Statics:
• Dynamics:
• Friction
• Kinetic friction:
• Static friction:
• Rolling resistance:
• Fluid resistance: or
• Terminal velocity:
• Circular Motion
• Fundamental forces
Related Documents
