Chapter 14 Work, Power, and Machines. Section 1 Work and Power.

Slides:



Advertisements
Similar presentations
Work and Power 1. Describe the conditions that must exist
Advertisements

Work = F X D. Work: Work is done when a force causes an object to move in the same direction that the force is applied.
Work, Power, and Machines
Chapter 5 Lesson 1.
What is Work? Book M: Section 4.1.
WORK 8.2.
Ch. 14. Newton’s 2 nd Law ??? F = m a Kinetic Energy = energy in motion Potential Energy = energy at rest.
The weight lifter applies a large force to hold the barbell over his head. Because the barbell is motionless, no work is done on the barbell.
14-1 cornell p. 412 What is work Calculating work What is power?
Work and Machines.
Physical Science Coach Kelsoe Pages 410–440 C HAPTER 14: W ORK, P OWER, AND M ACHINES.
The weight lifter applies a large force to hold the barbell over his head. Because the barbell is motionless, no work is done on the barbell.
Work & Power.
14.1 Work and Power notes 14.1 for background and also for lab on calculating horsepower... also have notes for 15.1 on same day... This unit will be 14.1,
Work, Power, and Machines
Physical Science Chapter 13
Work and Machines Chapter 5 Section 1.
Work and Power. Assignment I will number you into groups. You will be working in chapter 8 of the book. Your group number will represent your section.
Chapter 14 Work, Power and Simple Machines Do work, son!
The weight lifter applies a large force to hold the barbell over his head. Because the barbell is motionless, no work is done on the barbell.
Work and Power. Work Work is the product of force and distance. Work is done when a force acts on an object in the direction the object moves. Work is.
In your notebooks – define the terms work and joule. You do not have to do a vocabulary square on them. They can be found in chapter 12, sec. 1. February.
Chapter 14 Work, Power, and Machines
OBJECTIVE/LEARNING GOAL(S) 1. I will know the difference between the non-scientific and scientific definition of work. 2. I will know the difference.
WORK.
Chapter Eight: Work 8.1 Work 8.2 Efficiency and Power.
O BJECTIVE D AY 1 OBJECTIVE/LEARNING GOAL(S) 1. I will know the difference between the non- scientific and scientific definition of work. 2. I will.
CH 14.1 Work and Power. TrueFalseStatementTrueFalse Work is the product of force, distance and time Power is the amount of work done in a certain time.
NOTES 11 – Energy, Work, & Power. What is energy & why do we need it? Energy – the ability to do work Work – moving an object by exerting a force Force.
Chapter 4.1- Work & Power. What is Work?  For work to occur two things must happen:  Work is done when an object moves in the same direction in which.
Chapter 14 Work, Power, and Machines Physical Science.
14.1 & Work The weight lifter applies a large force to hold the barbell over his head. Because the barbell is motionless, no work is done on the.
POWER: What is it?.
Thursday, February 18 th Agenda  Pass Back/Go Over Chapter 7 Tests  Begin Chapter 8: Work, Power, and Machines  Work, joules, power, watts  In-class.
Section 14 Work, Power, and Energy. More Power!!!!! What does he mean?
WorkMathPowerMachinesMisc Question What is the SI unit for work?
What is WORK? A – The Meaning of Work 1 – Work – is done on an object when the object moves in the SAME direction in which the force is exerted. Example:
How they are defined by science
Work and Power Chapter 13.1 Notes. What is work? Work is done only when force is applied to an object AND the object moves in the same direction as the.
Work, Power & Energy.
Work and Power Chapter 3, Lesson 1.
POWER.
Chapter Eight: Work 8.1 Work 8.2 Efficiency and Power.
Chapter Eight: Work 8.1 Work 8.2 Efficiency and Power.
Work and Power Chapter 4.
Chapter 14 Section 1.
What Is Work? Chapter 12 Section 1.
Work and Power.
What is work ? The product of the force applied to an object and the distance through which that force is applied.
Because the barbell is motionless, no work is done on the barbell.
WORK.
Chapter 12, Section 1: What is work?
Essential Question: What are the different types of energy?
Work = when a force is applied on an object and it moves in the direction of the force.
Work and Power.
Part 1: Work, Power, & Machines
Machines - Work Power Energy.
Chapter Eight: Work 8.1 Work 8.2 Efficiency and Power.
Work and Power.
Chapter Eight: Work 8.1 Work 8.2 Efficiency and Power.
Physical Science Work and Power.
What is work Chapter 4 section 1.
Work.
Work 5.1 What is work? To many people, the word work means something they do to earn money. The word work also means exerting a force with your muscles.
Energy, Work & Power How the world works…..
WORK AND POWER Lesson 6.
Chapter 14 Work, Power, and Machines
Sci. 4-1 Work and Power Pages
Work & Power.
Physical Science Chapter 5
Presentation transcript:

Chapter 14 Work, Power, and Machines

Section 1 Work and Power

What Is Work? Recall that an object begins moving only when an unbalanced force acts on it. Work is done when a force acts on an object in the direction the object moves. the product of force and distance

Work Requires Motion For a force to do work on an object, some of the force must act in the same direction as the object moves. If there is no movement, no work is done. The weight lifter applies a large force to hold the barbell over his head. However, because the barbell is motionless, no work is done on the barbell.

Work Depends on Direction The amount of work done on an object, if any, depends on the direction of the force and the direction of the movement. Any part of a force that does not act in the direction of motion does no work on an object Force and motion in same direction Part of force in direction of motion Lifting force not in direction of motion Force This force does work This force does no work. Force

Calculating Work Formula Work = Force x Distance

Units of Work The joule (J) is the SI unit of work When a force of 1 newton moves an object 1 meter in the direction of the force, 1 joule of work is done. The joule is named after James Prescott Joule (1818–1889), a British scientist famous for researching the relationship between work and heat.

Using the Work Formula A weight lifter who lifts a 1600-newton barbell 2.0 meters over his head. How much work had been done?

What Is Power? Power is the rate of doing work. Doing work at a faster rate requires more power. To increase power, you can increase the amount of work done in a given time, or you can do a given amount of work in less time. Power is the rate of doing work. Because the snow blower can remove more snow in less time, it requires more power than hand shoveling does.

Calculating Power You can calculate power by dividing the amount of work done by the time needed to do the work. Formula: Power = Work Time or Force x Distance Time

Units for Power Scottish scientist, James Watt, was looking for a way to compare the power outputs of steam engines he had designed. The SI unit of power is the watt (w) equal to one joule per second Although the horse drawn plow and the gasoline powered engine get their power from different sources, both are capable of doing work at a rate of about four horsepower.

Your family is moving to a new apartment. While lifting a box 1.5 m straight up to put it on a truck, you exert an upward force of 200 N for 1.0 s. How much power is required to do this?

You lift a book from the floor to a bookshelf 1.0 m above the ground. How much power is used if the upward force is 15.0 N and you do the work in 2.0 s?

Reviewing Concepts 1. What conditions must exist in order for a force to do work on an object? 2. What formula relates work and power? 3. How much work is done when a vertical force acts on an object moving horizontally?