Chapter 7 Work and Energy

Slides:

Advertisements

Similar presentations

Physics 111: Mechanics Lecture 7

Advertisements

Gravitational potential energy. Conservation of energy

AP Physics C I.C Work, Energy and Power. Amazingly, energy was not incorporated into physics until more than 100 years after Newton.

Chapter 6: Conservation of Energy

AP Physics B Summer Course 年AP物理B暑假班

Chapter 5 Energy 1. Dot product of vectors 2. Kinetic Energy 3. Potential Energy 4. Work-Energy Theorem 5. Conservative and non-conservative forces 6.

Kinetic energy. Energy Energy is usually defined as the capacity to do work. One type of energy is kinetic energy.

Work, Energy, And Power m Honors Physics Lecture Notes.

Chapter 5 Work and Energy. Forms of Energy  Mechanical oKinetic, gravitational  Thermal oMicroscopic mechanical  Electromagnetic  Nuclear Energy is.

Work, Energy, and Power Samar Hathout KDTH 101. Work is the transfer of energy through motion. In order for work to take place, a force must be exerted.

Physics 111 Practice Problem Statements 07 Potential Energy & Energy Conservation SJ 8th Ed.: Chap 7.6 – 7.8, 8.1 – 8.5 Contents: 8-4, 8-5, 8-16, 8-19*,

AP Physics I.C Work, Energy and Power.

Mechanical Kinetic, Potential (gravitational, elastic) Thermal Chemical Electromagnetic Nuclear Forms of Energy Energy is conserved!

ENERGY LCHS Dr.E.

Work and Energy Chapter 7.

Conservation of Energy Energy is Conserved!. The total energy (in all forms) in a “closed” system remains constant The total energy (in all forms) in.

Chapter 9:Linear Momentum 8-4 Problem Solving Using Conservation of Mechanical Energy 8-5 The Law of Conservation of Energy 8-6 Energy conservation with.

Chapter 5 Work and Energy

PHYSICS 231 INTRODUCTORY PHYSICS I

D. Roberts PHYS 121 University of Maryland Physic² 121: Phundament°ls of Phy²ics I October 27, 2006.

General Physics 1, Additional questions By/ T.A. Eleyan

Chapter 6 Work and Energy. Forms of Energy Mechanical Kinetic, gravitational Thermal Microscopic mechanical Electromagnetic Nuclear Energy is conserved!

1a. Positive and negative work

T101Q7. A spring is compressed a distance of h = 9.80 cm from its relaxed position and a 2.00 kg block is put on top of it (Figure 3). What is the maximum.

Copyright © 2010 Pearson Education, Inc. Chapter 7 Work and Kinetic Energy.

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.

AP Physics C I.C Work, Energy and Power. Amazingly, energy was not incorporated into physics until more than 100 years after Newton.

Kinetic Energy Chap 5 associated with motion, velocity.

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)

Work and Energy Chapter 7 Conservation of Energy Energy is a quantity that can be converted from one form to another but cannot be created or destroyed.

Chapter 7 Energy and Work. Goals for Chapter 7 Overview energy. Study work as defined in physics. Relate work to kinetic energy. Consider work done by.

Conservative Forces: The forces is conservative if the work done by it on a particle that moves between two points depends only on these points and not.

Work and Energy Work The work done by a constant force is defined as the product of the component of the force in the direction of the displacement and.

Physics 6A Work and Energy examples Prepared by Vince Zaccone For Campus Learning Assistance Services at UCSB.

Physics. Session Work, Power and Energy - 3 Session Objectives.

Work and Energy.

Chapter 7 Energy and Work.

A certain pendulum consists of a 2

Conservation of Energy

332 – UNIT 6 WORK & ENERGY.

Chapter 5: Energy Energy

Work and Energy x Work and Energy 06.

WHITE BOARD TIME !! CONSERVE ENERGY. E T = PE G + KE + PE S When comparing the energy at two different positions on a system, the total energy at one.

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:

Chapter-6 Work and 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.

Conservation of Energy Aim: How does energy transfer from one form to another?

ENGINEERING PHYSICS SEMESTER /2012. ENGINEERING PHYSICS SUB-CHAPTERS: ● Work and standard units ● Power concept & Power Calculation ● Kinetic energy.

60 1. What is the mass M in the system as given in the

Work, Energy & Power AP Physics 1.

1a. Positive and negative work

Work, Energy, and Power Samar Hathout KDTH 101.

Work and energy 1. Work Wf = |fk| |Δx| cos(180°) = -|fk| |Δx| < 0

Work Done by a Constant Force

Work, Energy, and Power Samar Hathout KDTH 101.

from rest down a plane inclined at an angle q with the horizontal.

Chapter 5 Work and Energy

Unit 7: Work, Power, and Mechanical Energy.

Today: Work, Kinetic Energy, Potential Energy

Springs & Conservation of Energy pg

Work AP Physics C.

Work, Energy & Power AP Physics 1.

Last Time: Work, Kinetic Energy, Work-Energy Theorem Today:

Potential Energy Problems

Work and Energy 2/4/2019 SHOW WORK DONE BY A COMPRESSED SPRING

Chapter 8: Potential Energy & Conservation of Energy

Potential Potential Energy

Figure 8.1 The work done by an external agent on the system of the book and the Earth as the book is lifted from a height ya to a height yb is equal to.

Presentation transcript:

Chapter 7 Work and Energy

Forms of Energy Mechanical Kinetic, gravitational Thermal Microscopic mechanical Electromagnetic Nuclear Energy is conserved!

Work Relates force to change in energy Scalar quantity Independent of time

Units of Work and Energy SI unit = Joule 1 J = 1 Nm = 1 kgm2/s2

Work can be positive or negative Man does positive work lifting box Man does negative work lowering box Gravity does positive work when box lowers Gravity does negative work when box is raised

Kinetic Energy Same units as work Remember the Eq. of motion Multiply both sides by m,

Example 5.1 A skater of mass 60 kg has an initial velocity of 12 m/s. He slides on ice where the frictional force is 36 N. How far will the skater slide before he stops? 120 m

Potential Energy If force depends on distance, For gravity (near Earth’s surface)

Conservation of Energy Conservative forces: Gravity, electrical, QCD… Non-conservative forces: Friction, air resistance… Non-conservative forces still conserve energy! Energy just transfers to thermal energy

Example 5.2 A diver of mass m drops from a board 10.0 m above the water surface, as in the Figure. Find his speed 5.00 m above the water surface. Neglect air resistance. 9.9 m/s

Example 5.3 A skier slides down the frictionless slope as shown. What is the skier’s speed at the bottom? start H=40 m finish L=250 m 28.0 m/s

Example 5.4 Two blocks, A and B (mA=50 kg and mB=100 kg), are connected by a string as shown. If the blocks begin at rest, what will their speeds be after A has slid a distance s = 0.25 m? Assume the pulley and incline are frictionless. 1.51 m/s s

Example 5.5 Three identical balls are thrown from the top of a building with the same initial speed. Initially, Ball 1 moves horizontally. Ball 2 moves upward. Ball 3 moves downward. Neglecting air resistance, which ball has the fastest speed when it hits the ground? A) Ball 1 B) Ball 2 C) Ball 3 D) All have the same speed.

Example 5.6 Tarzan swings from a vine whose length is 12 m. If Tarzan starts at an angle of 30 degrees with respect to the vertical and has no initial speed, what is his speed at the bottom of the arc? 5.61 m/s

Springs (Hooke’s Law) Proportional to displacement from equilibrium

Potential Energy of Spring DPE=-FDx Dx F

Example 5.7 A 0.50-kg block rests on a horizontal, frictionless surface as in the figure; it is pressed against a light spring having a spring constant of k = 800 N/m, with an initial compression of 2.0 cm. x b) To what height h does the block rise when moving up the incline? 3.2 cm