Chapter 6 Work and Energy.

Slides:



Advertisements
Similar presentations
Work, Energy, And Power m Honors Physics Lecture Notes.
Advertisements

Phy100: More on Energy conservation Mechanical energy (review); Goals: Work done by external forces; Understand conservation law for isolated systems.
Conservation of Energy
1a. Positive and negative work
Chapter 6 Work and Energy. 6.1 Work Done by a Constant Force.
Chapter 6 Work and Energy. 6.1 Work Done by a Constant Force.
Chapter 8. Potential Energy and Energy Conservation 8.1. What is Physics? 8.2. Work and Potential Energy 8.3. Path Independence of Conservative Forces.
Chapter 6 Work and Energy. Main thrust Work done by a constant force –Projection, Scalar product (force that result in positive work). –negative work?,
Chapter 6 Work, Energy, Power Work  The work done by force is defined as the product of that force times the parallel distance over which it acts. 
Chapter 5 Work, Energy, Power Work The work done by force is defined as the product of that force times the parallel distance over which it acts. The.
Work, Energy, Power. Work  The work done by force is defined as the product of that force times the parallel distance over which it acts.  The unit.
Energy Energyis anything that can be con- verted into work; i.e., anything that can exert a force through a distance Energy is anything that can be con-
Chapter 6 Work and Energy.
Ch 6 Work and Energy.
Copyright © by Holt, Rinehart and Winston. All rights reserved. ResourcesChapter menu Section 1 Work Chapter 5 Definition of Work Work is done on an object.
Copyright © 2010 Pearson Education, Inc. Chapter 7 Work and Kinetic Energy.
Work done by individual forces
Potential Energy and Conservative Forces
Energy m m Physics 2053 Lecture Notes Energy.
Chapter 8 - Potential Energy and Conservation of Energy Conservative vs. Non-conservative Forces Definition of Potential Energy Conservation Of Mechanical.
Work and Energy. Work a force that causes a displacement of an object does work on the object W = Fdnewtons times meters (N·m) or joules (J)
1 Physics for Scientists & Engineers, with Modern Physics, 4 th edition Giancoli Piri Reis University / Physics -I.
Units: 1Newton . 1 meter = 1 joule = 1J
1 Work When a force moves something, work is done. Whenever work is done, energy is changed into a different form. Chemical energy → Kinetic energy.
Chapter 6 Work and Energy. Units of Chapter 6 Work Done by a Constant Force Work Done by a Varying Force Kinetic Energy, and the Work-Energy Principle.
6-4: Conservative and Nonconservative Forces The gravitational force has an interesting property that when an object is moved from one place to another,
Physics 1D03 - Lecture 22 Potential Energy Work and potential energy Conservative and non-conservative forces Gravitational and elastic potential energy.
Chapter 6 Work and Energy. Units of Chapter 6 Work Done by a Constant Force Kinetic Energy, and the Work-Energy Principle Potential Energy Conservative.
Monday, Mar. 24, 2008 PHYS , Spring 2008 Dr. Jaehoon Yu 1 PHYS 1441 – Section 002 Lecture #16 Monday, Mar. 24, 2008 Dr. Jaehoon Yu Potential Energy.
Work and Energy.
Reading Quiz - Work & Energy
© 2010 Pearson Education, Inc. Lecture Outline Chapter 5 College Physics, 7 th Edition Wilson / Buffa / Lou.
NAZARIN B. NORDIN What you will learn: Define work, power and energy Potential energy Kinetic energy Work-energy principle Conservation.
Chapter 6 Work and Energy. Force,displacement  WORK.
Work and Energy.
Energy Examples Serway and Jewett 8.1 – 8.3 Physics 1D03 - Lecture 22.
5.3 The Conservation of Mechanical Energy THE PRINCIPLE OF CONSERVATION OF ENERGY The term conserved means constant.
Chapter 6: Work and Energy Essential Concepts and Summary.
Chapter 6 Work and Energy.
Work - Work is calculated by multiplying the force applied by the distance the object moves while the force is being applied. W = Fs.
6-4: Conservative and Non-conservative Forces A force is a conservative force if the net work it does on a particle moving around any closed path, from.
Motion, Forces and Energy Lecture 7: Potential Energy & Conservation The name potential energy implies that the object in question has the capability of.
Chapter-6 Work and Energy Work Done by a Constant Force Work is done when a force F pushes a car through a displacement s. Work = Force X Displacement.
 E is always constant, but KE and PE can change  If PE and KE change, they must change in such a way as to keep E constant Example Consider the 1D free-fall.
Objectives: The students will be able to: Solve problems using the law of conservation of energy. Solve problems using the law of conservation of energy.
1. Work [W] = N*m = J Units: Work done by forces that oppose the direction of motion will be negative. Work and energy A. PositiveB. NegativeC. Zero Example:
Work and Energy. Work… …is the product of the magnitude of displacement times the component of force parallel to the displacement. W = F ‖ d Units: N.
Conservation of Energy
Chapter 6: Work and Energy  Alternative method for the study of motion  In many ways easier and gives additional information  Kinetic energy: consider.
Chapter 5 Part 2 Mechanical energy: Kinetic Potential Gravitational Potential Elastic.
Ch 6. Work and Energy Example 1 Suitcase-on-Wheels Find work done if force is 45.0-N, angle is 50.0 degrees, and displacement is 75.0 m.
Chapter-6 Work and Energy
 Work  Energy  Kinetic Energy  Potential Energy  Mechanical Energy  Conservation of Mechanical Energy.
Chapter 5 Work and Energy. Mechanical Energy  Mechanical Energy is the energy that an object has due to its motion or its position.  Two kinds of mechanical.
Section 6-3 Gravitational Potential Energy. Warm-Up #1 A sailboat is moving at a constant velocity. Is work being done by a net external force acting.
PHY 101: Lecture Work Done by a Constant Force
Chapter 5 Work and Energy. Question A crate of mass 10 kg is on a ramp that is inclined at an angle of 30⁰ from the horizontal. A force with a magnitude.
Potential Energy (PE or U) Definition: The energy that an object has by virtue of its position relative to the surface of the earth. PE = mgh Compare the.
Work-Energy Relationship Already understand that lifting an object will increase the object’s gravitational potential energy. W=ΔPE= mgΔh No friction.
PHY 102: Lecture 4A 4.1 Work/Energy Review 4.2 Electric Potential Energy.
Chapter 7 WORK, ENERGY, AND ENERGY RESOURCES
Chapter 7 WORK, ENERGY, AND ENERGY RESOURCES
1a. Positive and negative work
Work -   Work is calculated by multiplying the force applied by the distance the object moves while the force is being applied.   W = Fs.
Work and Energy Chapter 6.
Chapter 5 Definition of Work 5.1 Work
Chapter 6 Work and Energy.
PHYS 1441 – Section 002 Lecture #16
Work, Energy, Power.
Energy.
Presentation transcript:

Chapter 6 Work and Energy

6.1 Work Done by a Constant Force

6.1 Work Done by a Constant Force

6.2 The Work-Energy Theorem and Kinetic Energy DEFINITION OF KINETIC ENERGY The kinetic energy KE of an object with mass m and speed v is given by

6.2 The Work-Energy Theorem and Kinetic Energy When a net external force does work on an object, the kinetic energy of the object changes from its initial value of KE0 to a final value of KEf , the difference between the two values being equal to the work:

6.3 Gravitational Potential Energy DEFINITION OF GRAVITATIONAL POTENTIAL ENERGY The gravitational potential energy PE is the energy that an object of mass m has by virtue of its position relative to the surface of the earth. That position is measured by the height h of the object relative to an arbitrary zero level:

6.4 Conservative Versus Nonconservative Forces A force is conservative when the work it does on a moving object is independent of the path between the object’s initial and final positions.

6.4 Conservative Versus Nonconservative Forces Non-conservative force – a force is non-conservative if the work it does on an object moving between two points depends on the path of motion between the points. The work done by the kinetic frictional force is always negative.

6.4 Conservative Versus Nonconservative Forces In normal situations both conservative and nonconservative forces act simultaneously on an object, so the work done by the net external force can be written as

6.4 Conservative Versus Nonconservative Forces THE WORK-ENERGY THEOREM

6.5 The Conservation of Mechanical Energy If the net work on an object by nonconservative forces is zero, then its energy does not change:

6.5 The Conservation of Mechanical Energy THE PRINCIPLE OF CONSERVATION OF MECHANICAL ENERGY The total mechanical energy (E = KE + PE) of an object remains constant as the object moves, provided that the net work done by external nononservative forces is zero.

6.5 The Conservation of Mechanical Energy

6.5 The Conservation of Mechanical Energy Example 8 A Daredevil Motorcyclist A motorcyclist is trying to leap across the canyon by driving horizontally off a cliff 38.0 m/s. Ignoring air resistance, find the speed with which the cycle strikes the ground on the other side.

6.5 The Conservation of Mechanical Energy

6.5 The Conservation of Mechanical Energy

DEFINITION OF AVERAGE POWER Average power is the rate at which work is done, and it is obtained by dividing the work by the time required to perform the work.

6.7 Power

6.8 Other Forms of Energy and the Conservation of Energy THE PRINCIPLE OF CONSERVATION OF ENERGY Energy can neither be created nor destroyed, but can only be converted from one form to another.

Problems To Be Solved 6.12, 6.23, 6.39, 6.60, 6.63, 6.65 B6.1 The heart may be regarded as an intermittent pump that forces about 70cm3 of blood into the 1.0cm radius aorta about 75 times a minute. Measurements show that the average force with which the blood is pushed into the aorta is about 5.0N. What is the approximate power used in moving the blood to the aorta? Ans: 1.39W

B6. 2 A dieter lifts a 10kg mass a distance of 0. 5m 1000 times B6.2 A dieter lifts a 10kg mass a distance of 0.5m 1000 times. (a) How much work does he do against gravitational force? (b) Fat supplies 3.8×107J of energy per kilogram, which is converted to mechanical energy with a 20% efficiency rate. How much fat will the dieter use up? Ans: (a) 49000J; (b) 6.4×10-3kg

B6. 3 A beer can is dropped from a window 30m above the ground B6.3 A beer can is dropped from a window 30m above the ground. How fast will it be moving just before it lands?(Neglect air resistance) Ans: 24.25m/s

B6. 4 A 55kg carton of bananas with an initial speed of 0 B6.4 A 55kg carton of bananas with an initial speed of 0.45m/s slides down a ramp inclined at an angle of 23⁰ with the horizontal. If the coefficient of friction between the carton and the ramp is 0.24, how fast will the carton be moving after it has travelled a distance of 2.1m down the ramp? Ans: 2.68m/s