Presentation is loading. Please wait.

Presentation is loading. Please wait.

Work.

Published byTapani Kapulainen Modified over 5 years ago

Similar presentations

Presentation on theme: "Work."— Presentation transcript:

1 Work

2 Work has a specific physics meaning

3 Work W=Fd Energy transferred to an object over a distance
WORK IS ENERGY GAINED OR LOST W=Fd Where: W – Work (J) F – Magnitude of Force (N) d – distance (m)

4 Work is scalar (so no direction needed)
BUT Force and distance need to be in the same direction

5 Work Against Gravity To lift an object (at a constant speed), the force applied is equal to the force of gravity If you are lifting up, positive work If you are lowering down, negative work

6 Example 1 Jacob pushes a shopping cart with a force of 500N through 2.0 m. What is the work done?

7 Example 1b If the shopping cart has a mass of 40kg and all energy is transferred to kinetic energy, how fast will it be moving after the push?

8 Example 2 Krinal lifts an object with a mass of 10kg. The object gains 1000J of gravitational potential energy. How high does she lift it? How high could you lift a 10kg mass using all the energy in a piece of gum?

9 Negative Work Occurs if the force opposes motion
In most cases negative work is done by friction – the energy is taken away and turned into thermal energy W=-Fd Where: W – Work (J) F – Magnitude of Force opposing motion (N) d – distance (m)

10 Example 3 Two students are pushing on a car as shown below. The car moves 10m to the right. How much work does person 1 do? How much work does person 2 do? How much energy is gained by the car?

11 Work Pg 135 # 1,3,4 Pg 136 # 8-10

Download ppt "Work."

Similar presentations

WHAT IS FRICTION?. WHAT IS FRICTION? WHAT IS FRICTION? Friction is the force resisting the relative motion of solid surfaces, fluid layers, and material.

WHAT IS FRICTION?. WHAT IS FRICTION? WHAT IS FRICTION? Friction is the force resisting the relative motion of solid surfaces, fluid layers, and material.
a) The kinetic energy of the car. b) The distance it takes to stop.

a) The kinetic energy of the car. b) The distance it takes to stop.
Phy100: More on Energy conservation Mechanical energy (review); Goals: Work done by external forces; Understand conservation law for isolated systems.

Phy100: More on Energy conservation Mechanical energy (review); Goals: Work done by external forces; Understand conservation law for isolated systems.
Mechanical Work: More Practice. Gravitational Potential Energy: More Practice.

Mechanical Work: More Practice. Gravitational Potential Energy: More Practice.
The apple is ……. Vel ocity = = = x x  :. The apple is ……. = =  : x x =x.

The apple is ……. Vel ocity = = = x x  :. The apple is ……. = =  : x x =x.
Chapter 12: Energy & Work Unit Integrated Science I.

Chapter 12: Energy & Work Unit Integrated Science I.
Work, Power, Energy.

Work, Power, Energy.
Explaining Motion P4. Speed In real life, it’s pretty rare for an object to go at exactly the same speed for a long period of time Objects usually start.

Explaining Motion P4. Speed In real life, it’s pretty rare for an object to go at exactly the same speed for a long period of time Objects usually start.
2.10 : WORK, ENERGY, POWER AND EFFICIENCY

2.10 : WORK, ENERGY, POWER AND EFFICIENCY
Chapter 8 Work and Energy. Definition Work is the way that energy is transferred between objects. The amount of work done equals the amount of energy.

Chapter 8 Work and Energy. Definition Work is the way that energy is transferred between objects. The amount of work done equals the amount of energy.
Kinetic Energy A moving object has energy because of its motion. This energy is called kinetic energy.

Kinetic Energy A moving object has energy because of its motion. This energy is called kinetic energy.
Aim: What are Potential and Kinetic Energy? Do Now: A girl lifts a 10 kg object 1.5 m straight up. How much work has she done? W = Fd W = F g d W = (10.

Aim: What are Potential and Kinetic Energy? Do Now: A girl lifts a 10 kg object 1.5 m straight up. How much work has she done? W = Fd W = F g d W = (10.
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. Work a force that causes a displacement of an object does work on the object W = Fdnewtons times meters (N·m) or joules (J)
CHAPTER 10 WORK, ENERGY, AND POWER. STANDARDS SP3. Students will evaluate the forms and transformations of energy. a. Analyze, evaluate, and apply the.

CHAPTER 10 WORK, ENERGY, AND POWER. STANDARDS SP3. Students will evaluate the forms and transformations of energy. a. Analyze, evaluate, and apply the.
Physics 221 Chapter 7 Problem 1... Work for slackers! WORK = Force x Distance W = F. D Units: Nm = J Newton meters = Joules Problem 1 : You push a car.

Physics 221 Chapter 7 Problem 1... Work for slackers! WORK = Force x Distance W = F. D Units: Nm = J Newton meters = Joules Problem 1 : You push a car.
Energy Lecture Slide 1 Work & Energy. Energy Lecture Slide 2 Work Work = (Force in direction of motion)*distance W, Joule (J) = N-m 1 J is work done in.

Energy Lecture Slide 1 Work & Energy. Energy Lecture Slide 2 Work Work = (Force in direction of motion)*distance W, Joule (J) = N-m 1 J is work done in.
Le WORK AND ENERGY Show!!!. Work is defined as a force that moves through a distance. The equation used to calculate work is: W=f d If the 60kg cart is.

Le WORK AND ENERGY Show!!!. Work is defined as a force that moves through a distance. The equation used to calculate work is: W=f d If the 60kg cart is.
Energy, Work, and Transfer of Energy Physical Science Chapter 12.

Energy, Work, and Transfer of Energy Physical Science Chapter 12.
Work Work is a scalar quantity and has the following conditions: a force must be exerted on an object the object must be displaced by the force at least.

Work Work is a scalar quantity and has the following conditions: a force must be exerted on an object the object must be displaced by the force at least.
Work and Energy. Work O Work is defined as the force parallel to the direction of motion times the distance. W = F (parallel)  d = F d cos θ O If the.

Work and Energy. Work O Work is defined as the force parallel to the direction of motion times the distance. W = F (parallel)  d = F d cos θ O If the.

Similar presentations

Ads by Google