Presentation is loading. Please wait.

Presentation is loading. Please wait.

Chapter 7 - Work and Energy

Published byGordon Knight Modified over 8 years ago

Similar presentations

Presentation on theme: "Chapter 7 - Work and Energy"— Presentation transcript:

1 Chapter 7 - Work and Energy
Definition of Work [units] Work done by a constant force (e.g friction,weight) Work done by a varying force (e.g. a spring) Work in 3 dimensions – General Definition Work and Kinetic Energy Definition of Kinetic Energy Work-Energy Principle

2 Definitions Work - The means of transferring energy by the application of a force. Work is the product of the magnitude of displacement times the component of that force in the direction of the displacement. Work is a scalar Energy - The state of one or more objects. A scalar quantity, it defines the ability to do work.

3 Units Joule (J) N-m kg-m2/s2 Erg Dyne-cm g-cm2/s2 Energy [M-L2/T2]
Ft-lb slug-ft2/s2

4 Problem 1 A 1500 kg car accelerates uniformly from rest to a speed of 10 m/s in 3 s. Find the work done on the car in this time

5 How much work is done by this guy?
Walking at a constant speed

6 Problem 3 m = 50 kg displacement = 40 m force applied = 100 N
37o angle wrt floor mk = 0.1 Find net work done moving the crate

7 Vector Multiplication – Scalar Product

8 A more elegant definition for work

9 Problem 4 How much work is done pulling the wagon 100 m in the direction shown by the boy applying the force:

10 Work done by a varying force

11 Work in three dimensions

12 Problem 5 Fx (N) 3 2 1 10 15 x (m) 5 How much work is done by this force?

13 Hooke’s Law and the work to compress/extend a spring

14 Kinetic Energy and the Work-Energy Principle

15 And you can show this with calculus too!

16 Problem 6 A 3 kg mass has an initial velocity, v = (5i - 3j) m/s.
What is the kinetic energy at this time? The velocity changes to (8i + 4j) m/s. What is the change in kinetic energy? How much work was done?

17 Problem 7 A 2 kg block is attached to a light spring of force constant 500 N/m. The block is pulled 5 cm to the right and of equilibrium. How much work is required to move the block? If released from rest, find the speed of the block as it passes back through the equilibrium position if the horizontal surface is frictionless. the coefficient of friction is 0.35.

Download ppt "Chapter 7 - Work and Energy"

Similar presentations

Newton’s Laws of Motion and Free Body Analysis

Newton’s Laws of Motion and Free Body Analysis
Kinetic Energy and Work Chapter 7. Work and Energy Energy: scalar quantity associated with a state (or condition) of one or more objects. Work and energy.

Kinetic Energy and Work Chapter 7. Work and Energy Energy: scalar quantity associated with a state (or condition) of one or more objects. Work and energy.
Chapter 6: Work & Energy. THE COURSE THEME is NEWTON’S LAWS OF MOTION! Chs. 4, 5: Motion analysis with forces. NOW (Ch. 6): An alternative analysis using.

Chapter 6: Work & Energy. THE COURSE THEME is NEWTON’S LAWS OF MOTION! Chs. 4, 5: Motion analysis with forces. NOW (Ch. 6): An alternative analysis using.
PHYS16 – Lecture 15 Work and Energy October 13, 2010.

PHYS16 – Lecture 15 Work and Energy October 13, 2010.
More Conservation of Mechanical Energy

More Conservation of Mechanical Energy
Instructor: Dr. Tatiana Erukhimova

Instructor: Dr. Tatiana Erukhimova
ENGR 215 ~ Dynamics Sections 14.1 – 14.3. Conservation of Energy Energy can neither be created nor destroyed during a process, it can only change forms.

ENGR 215 ~ Dynamics Sections 14.1 – Conservation of Energy Energy can neither be created nor destroyed during a process, it can only change forms.
Department of Physics and Applied Physics 95.141, F2010, Lecture 12 Physics I 95.141 LECTURE 12 10/18/10.

Department of Physics and Applied Physics , F2010, Lecture 12 Physics I LECTURE 12 10/18/10.
Conservation of Energy

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

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

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.
Physics 111: Mechanics Lecture 6

Physics 111: Mechanics Lecture 6
Chapter 7 Work and Energy

Chapter 7 Work and Energy
Kinetic energy Vector dot product (scalar product) Definition of work done by a force on an object Work-kinetic-energy theorem Lecture 10: Work and kinetic.

Kinetic energy Vector dot product (scalar product) Definition of work done by a force on an object Work-kinetic-energy theorem Lecture 10: Work and kinetic.
A 6. 0-kg object undergoes an acceleration of 2. 0 m/s2

A 6. 0-kg object undergoes an acceleration of 2. 0 m/s2
Wednesday, 12/10/14PHYSICS If you do the same old things, you get the same old results!

Wednesday, 12/10/14PHYSICS If you do the same old things, you get the same old results!
Chapter 7 Work and Energy

Chapter 7 Work and Energy
Physics 111: Mechanics Lecture 6 Wenda Cao NJIT Physics Department.

Physics 111: Mechanics Lecture 6 Wenda Cao NJIT Physics Department.
Work and Kinetic Energy Teacher: Luiz Izola

Work and Kinetic Energy Teacher: Luiz Izola
Chapter 7. Kinetic Energy and Work

Chapter 7. Kinetic Energy and Work

Similar presentations

Ads by Google