Presentation is loading. Please wait.

Presentation is loading. Please wait.

Unit 3 Work, Energy & Power Serway Chapters 7 & 8 1 Unit 3 Section 2 Energy and the Work-Energy Theorem.

Published byCordelia Patrick Modified over 8 years ago

Similar presentations

Presentation on theme: "Unit 3 Work, Energy & Power Serway Chapters 7 & 8 1 Unit 3 Section 2 Energy and the Work-Energy Theorem."— Presentation transcript:

1 Unit 3 Work, Energy & Power Serway Chapters 7 & 8 1 Unit 3 Section 2 Energy and the Work-Energy Theorem

2 Unit 3 Section 2 Lesson 1 Kinetic Energy and the Work-Energy Theorem Unit 3 Section 2 Lesson 1 Kinetic Energy Objectives: ▫Show understanding of the Physics concept of Kinetic Energy ▫Correctly identify Kinetic Energy from given situations ▫Recall and show understanding of the formula to calculate Kinetic Energy ▫Solve related problems involving Change in Kinetic Energy ▫KE = ½ mv 2 ▫Work = ΔKE = (½ mv 2 ) final – (½ mv 2 ) initial ▫Do NOW: Charles is vacuuming room 3. He pushes the vacuum with a 5.00 N force at an angle of 30.0 degrees to the horizontal. If he pushes the vacuum 3.00 meters across the carpet, what is the work he did? ▫Unit 3 Section 2 Lesson 1 HOMEWORK: DUE MON Jan 14 ▫Serway PAGE:209 : #’s 27, 30, 31, 33, 34, 37, 40, 41 2

3 Energy – Energy is the capacity to do WORK SI Unit: Joule (J) Many forms Common ones: ▫Kinetic ▫Potential ▫Electric ▫Chemical ▫Solar ▫Nuclear 3

4 Kinetic Energy KE = ½ (mv 2 ) A form of energy that a body in motion possess. Examples: ▫ Bullet shot out from pistol ▫ Helicopter flying at 120km/h A body a rest, will NOT possess any KE! The amount of KE of a moving body depends on: ▫ Mass of body (kg) ▫ Velocity (m/s) When either mass or velocity of moving body is increased, KE will also increase. Kinetic Energy = ½ (Mass)(Velocity) 2 = ½ (mv 2 )  [ J ] = [kg] [m/s] 2 Mass Doubles Kinetic Energy Doubles Velocity Doubles Kinetic Energy QUADRUPLES 4 Mass = m Velocity, V

5 DO NOW: Examples of KE Find the KE of an empty van of mass 1000kg moving at 2m/s. Find the KE of van when it is loaded with goods to give a total mass of 2000kg, and moving at 2m/s. Find KE of unloaded van when it speeds up to 4m/s. 5 KE of van at 2m/s = ½ x 1000 x (2) 2 = 2000 J = 2 kJ KE of van at 2m/s = ½ x 2000 x (2) 2 = 4000 J = 4 kJ KE of van at 2m/s = ½ x 1000 x (4) 2 = 8000 J = 8 kJ

6 Work – Kinetic Energy Theorem Serway page 195 W = ∫ F dx  ∫ ma x dx Work = ΔKE = (½ mv 2 ) final – (½ mv 2 ) initial If you push a 6.0 Kg object from rest along a frictionless surface with a force of 12.0 N what will the velocity be after 3 meters? Romac loads a refrigerator for Claire onto his truck using a frictionless ramp. He claims that less work is required to load the truck if the ramp is lengthened. Is he correct? Serway page 196 Exp 7.7 – 7.8 6 CY:3.5 AL: 3.6 CC: 3.4 EW: 2.8 PP:0.0 DH: 3.1

Download ppt "Unit 3 Work, Energy & Power Serway Chapters 7 & 8 1 Unit 3 Section 2 Energy and the Work-Energy Theorem."

Similar presentations

Energy.

Energy.
Unit 3 Section 2 Lesson 2 Potential Energy PE Objectives Unit 3 Section 2 Lesson 2 Potential Energy Objectives: ▫ Show understanding of the Physics concept.

Unit 3 Section 2 Lesson 2 Potential Energy PE Objectives Unit 3 Section 2 Lesson 2 Potential Energy Objectives: ▫ Show understanding of the Physics concept.
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.

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.
E W Work and Energy Work Done By a Constant Force Work is defined as the product of the constant force and the distance through which the point of application.

E W Work and Energy Work Done By a Constant Force Work is defined as the product of the constant force and the distance through which the point of application.
Work & Energy Chapter 6 (C&J) Chapter 10(Glencoe).

Work & Energy Chapter 6 (C&J) Chapter 10(Glencoe).
Adv Physics Chapter 5 Sections 3 & 4.

Adv Physics Chapter 5 Sections 3 & 4.
Work & Energy. Energy is Conserved Energy is “Conserved” meaning it can not be created nor destroyed –Can change form –Can be transferred Total Energy.

Work & Energy. Energy is Conserved Energy is “Conserved” meaning it can not be created nor destroyed –Can change form –Can be transferred Total Energy.
Energy.

Energy.
Dr. Jie Zou PHY 1151G Department of Physics1 Chapter 7 Work and Kinetic Energy (Continued)

Dr. Jie Zou PHY 1151G Department of Physics1 Chapter 7 Work and Kinetic Energy (Continued)
By-Tanmaye Gupta ENERGY IGCSE PHYSICS What is Energy? Energy is the capacity to do work. The S.I. unit of energy is Joules 1Joule = 10 7 erg

By-Tanmaye Gupta ENERGY IGCSE PHYSICS What is Energy? Energy is the capacity to do work. The S.I. unit of energy is Joules 1Joule = 10 7 erg
LESSON 3 – KE and PE (4.2) LEARNING OUTCOMES: State and be able to use the equation: change in gravitational potential energy (PE) = mass (m) x gravitational.

LESSON 3 – KE and PE (4.2) LEARNING OUTCOMES: State and be able to use the equation: change in gravitational potential energy (PE) = mass (m) x gravitational.
What factors affect the kinetic energy of a moving object?

What factors affect the kinetic energy of a moving object?
Work is only done by a force on an object if the force causes the object to move in the direction of the force. Objects that are at rest may have many.

Work is only done by a force on an object if the force causes the object to move in the direction of the force. Objects that are at rest may have many.
Kinetic and Potential Energy

Kinetic and Potential Energy
A force that causes a Displacement of an object does Work on that object.

A force that causes a Displacement of an object does Work on that object.
Chapter 4. The nature of energy Energy: The ability to do work or cause change All energy involves either motion or position Where are we using energy.

Chapter 4. The nature of energy Energy: The ability to do work or cause change All energy involves either motion or position Where are we using energy.
Unit 3 Work, Energy & Power Serway Chapters 7 & 8 Glencoe Chapter 10 & 11 1 Unit 3 Section 2 Energy and the Work-Energy Theorem.

Unit 3 Work, Energy & Power Serway Chapters 7 & 8 Glencoe Chapter 10 & 11 1 Unit 3 Section 2 Energy and the Work-Energy Theorem.
The ability of a body to perform work is, Energy. The unit of energy is, joule (J). Larger unit of energy is kilo joule (kJ). 1 kJ = 1000 J. There are.

"The ability of a body to perform work is, Energy". The unit of energy is, joule (J). Larger unit of energy is kilo joule (kJ). 1 kJ = 1000 J. There are.
Work and Kinetic Energy Teacher: Luiz Izola

Work and Kinetic Energy Teacher: Luiz Izola
Sect. 7-4: Kinetic Energy; Work-Energy Principle.

Sect. 7-4: Kinetic Energy; Work-Energy Principle.

Similar presentations

Ads by Google