Mr. Smet’s Scientific Studies APPLIED POTENTIAL AND KINETIC ENERGY.

Slides:

Advertisements

Similar presentations

Activity 54 Follow-up On the page following activity 54, write the U portion of your RERUNS conclusion: U- Uncertainties Here is where you explain what.

Advertisements

-”the ability to cause change”

Vocabulary Law of conservation of energy - Energy (E) CANNOT be created or destroyed, only changed in form!!! Energy = property of an object /system that.

Chapter 4: Energy.

Energy Problems Review for Potential energy, Kinetic energy, Total Energy work, power.

ENERGY REVIEW. What is energy? The ability to do work or make change in matter.

PART 2 Energy. Learning Goals for Section 2 Conservation of Energy Describe how energy can be transformed from one form to another. Explain how the mechanical.

Energy & the Roller Coaster

Do Now How is most electricity made? Explain the materials needed and physically how its produced. Be specific. Write your answers in your science journal.

 Chapter 3. Lesson 1 Energy  The ability of a system to do work. Two types of energy: Kinetic Energy Potential Energy.

Kinetic and Potential Energy

Energy 12/11/14. Chapter 6 – Work and Energy Major Concepts: Work Power Conservative and Non-Conservative Forces Mechanical and Non-Mechanical Energies.

Chapter 12: Energy & Work Unit Integrated Science I.

Big Idea 11 : Energy Transfer and Transformations

Energy Lesson Goal: Explain the different forms of energy that are present while on a roller coaster and what those forms of energy turn into. At the.

Unit 3 Section 3 Notes Conservation of Energy. Energy Transformations Energy is most noticeable as it transforms from one type to another. What are some.

Conservation of Energy and Momentum. Conservation If you gave me a dollar and asked for change, how many dimes would you want back? How about quarters?

Chapter 9 H.W.-type your homework here Warm-up #40- page 238

Unit 2 Energy. Energy Transformations Law of Conservation of Energy Energy cannot be created or destroyed only transformed to another type of Energy.

Ch.9, Sec.3 – Conservation of Energy Where Does the Energy Go? Where Does the Energy Go?  friction: a force that opposes motion between two surfaces that.

Conservation of Energy IT’S THE LAW. Lifting a Ball When you lift a ball to a certain height you do work on it. When you lift a ball to a certain height.

Conservation of Energy. The Law of Conservation of Energy Energy cannot be CREATED or DESTROYED. Energy is just CONVERTED from one form to another.

Kinetic and Potential Energy Physics 6(B). Learning Objectives Explain the differences between kinetic and potential energy and their sources Describe.

Potential Energy and Kinetic Energy Day 2

Energy Transformations and Conservation It’s the Law!

Energy and Energy Resources Sections 1 and 2. What is Energy? The ability to do work Involves motion or position Work occurs when a force causes an object.

Work and Power Notes What Work and Power are not… Work is not where you go to earn a check! Power is not how strong you are!

Conservation of Energy

Conservation of Energy IT’S THE LAW. Lifting a Ball When you lift a ball to a certain height you __________________. This work (W) is equal to the weight.

ENERGY. A. Kinetic Energy (KE) 1. Energy in the form of motion. 2. Energy Depends On: a. Mass of the object. b. Velocity of the object.

Ideas about Work and Energy What exactly is energy?

Thursday, February 16th Mechanical Energy. Today’s Goals Goal 1: SWBAT use the Law of Conservation of Energy to explain why a situation in which mechanical.

Ch. 8 Lesson 2 Conservation of Energy Study Jams Video: Energy and Mat ter.

Forms and Transformations

Chapter 5.2. What do you think? What is meant when scientists say a quantity is conserved? Describe examples of quantities that are conserved. Are they.

Energy Physics 4 th Six Weeks. What is Energy? Energy is defined as the ability to produce a force. Energy is also defined as the ability to cause a change.

Chapter 10: Section 2.  Describe the First Law of Thermodynamics  Make calculations involving changes in internal energy  Create and analyze energy.

Forms and Transformation of Energy Chapter 13 Sections 3-4 (pages )

Energy of Motion Physics of Fun (26min). Energy Any change in motion requires – Energy. – Work is done when a change occurs. Work can’t be done without.

Conservation of Energy Ch. 8 Lesson 2. Mechanical Energy Form of energy associated with the motion, position, or shape of an object. Mechanical energy.

Conservation of Energy IT’S THE LAW. Lifting a Ball When you lift a ball to a certain height you do work on it. When you lift a ball to a certain height.

Section 4 Conservation of Energy. I. Energy Transformations PE = mgh PE = (515 kg)(9.8 m/s 2 )(70.0 m) PE = 353,290 J At the top of the hill, PE is at.

Starter Directions: Copy the following examples. Answer using the following terms: Mechanical, Thermal, Chemical, Electrical 1.Hydroelectric dam 2.A horse.

Warm up: what energy transformations are happening in the situations below? Activity 57: Conservation of Energy.

Conservation of Energy Chapter 13.4 Notes. Energy Transformations Energy readily changes from one form to another For example, think about when you ride.

Dissipative Forces. Reality? In reality, non-conservative forces cannot be ignored: friction really does act Dissipative force is one that reduces the.

Energy (REVIEW). Two Forms of Energy Kinetic Energy – of MOTION KE = ½ mv 2 Potential Energy – Energy of POSITION PE = mgh (gravitational PE) (g = 9.8.

Work and Energy. What is WORK? Work is equal to the amount of force it takes for an object to move a distance. Formula: Work = Force X Distance W = F.

Conservation of Energy. Changing Forms of Energy  Energy is most noticeable as it transforms from one type to another.  What are some examples of transforming.

Energy Conversions & Conservation. Bellringer  Where does the energy that makes a roller coaster car move come from? Where does the energy go?

May 2, A ball can experience 30 J of work if it falls off the counter. How massive is the ball if it is at a height of 2 m? 2.How much PE does the.

Energy Lesson Goal: Become familiar with various forms of energy.

What type of energy is being used in a pulley system?

Energy Ch. 4-1.

Wednesday September 13, 2017 YOU NEED YOUR NOTEBOOK.

Thursday, January 11, 2018 Warm-Up: Explain the gravitational potential energy, potential energy, and kinetic energy when a book is dropped from a table.

قطار التعرج مجلس أبوظبي للتعليم منطقة العين التعليمية

November 23, 2015 Work and Power Quiz moved to Dec. 1

Work, Power, & Energy.

8.2 Conservation of Energy

Energy transformations and the conservation of energy!

1 a. PE store decreases as the ball drops. The thermal energy store of the roller coaster braking system and surroundings increases. Energy is.

Conservation of Energy

Physical Science: Chapter 13 Section 4

CHAPTER 15: ENERGY!.

At what point in the journey of the roller coaster is potential energy transforming into kinetic energy? Point A Point B Point C Point D.

Potential and Kinetic Energy in the real world.

Presentation transcript:

Mr. Smet’s Scientific Studies APPLIED POTENTIAL AND KINETIC ENERGY

1.Place your homework on the table in front of you. 2.Answer the following:  What is the law of conservation of energy?  Explain how a roller coaster works using the Law of Conservation of Energy. DO NOW

1.Do Now 2.Introduction 3.Homework Review 4.Calculations 5.Calculation W.S. 6.W.S. part 2 7.Exit Slip 8.Closing AGENDA

5.6.1 SWBAT define the Law of Conservation of Energy SWBAT explain how potential and kinetic energies are related using the conservation of energy. OBJECTIVES:

1.Do Now 2.Introduction 3.Homework Review 4.Calculations 5.Calculation W.S. 6.W.S. part 2 7.Exit Slip 8.Closing AGENDA

 At which point does a train on this roller coaster:  Have the most gravitational potential energy? Explain your choice.  have the most kinetic energy? Explain your choice.  Have both kinetic and gravitational potential energy? Explain your choice. QUESTION 1

 a. The train has the most potential energy at Point B because it is the highest point on the track.  b. The train has the most kinetic energy at Point G because it has converted the most energy (PE from Point B) into kinetic from the first hill.  c. The train has both kinetic energy and potential energy at points D, E and F because it has both height (PE) and speed (KE) at those points.

Kinetic energy is related to the speed of an object. In which place, Point E or Point F, is the train moving faster? Explain in terms of kinetic energy. QUESTION 2

The train is moving faster at point E because it has more kinetic energy there. When the train climbs the hill to point F, it has less kinetic energy and less speed. QUESTION 2 ANSWER

As the train travels on the track, the energy of the train changes back and forth from gravitational potential to kinetic. What other energy transformations occur as the train travels the track? Explain. QUESTION 3

Some of the kinetic energy is turned into thermal energy and sound due to the friction between the train and the tracks. Friction between the air and the train also transforms some kinetic energy into wind and thermal energy. QUESTION 3 ANSWER

Why can’t a roller coaster go up a hill that is higher than the hill it just came down? QUESTION 4

Because in order to climb a bigger hill, energy must be added to the train. The role-play pointed out that a roller coaster is at its maximum energy at the first hill. After that, no energy is put into the system and some energy is lost by heating and sound as the roller coaster travels. So there is less energy available to transform from kinetic to potential for each subsequent hill. QUESTION 4 ANSWER

1.Do Now 2.Introduction 3.Homework Review 4.Calculations 5.Calculation W.S. 6.W.S. part 2 7.Exit Slip 8.Closing AGENDA

 Last week, we learned about the Conservation of Energy. CONCEPT

 Last week, we learned about the Conservation of Energy.  Energy cannot be lost or destroyed. CONCEPT

 Total energy is the amount of energy an object has. TOTAL ENERGY

 Total energy (TE) is the amount of energy an object has.  Total Energy = Potential Energy + Kinetic Energy TE = PE + KE TOTAL ENERGY

EXAMPLE:

A. PE = 7J KE = 6J B. PE = 12 J KE = 8 J B. PE = 32 J KE = 49 J CFU

 If you know both Total Energy and Potential Energy/Kinetic Energy, you can find the other.  KE = TE – PE  PE = TE - KE DETERMINING PE OR KE

A. PE = 17J KE = 6 J TE = ? B. PE = 15 J KE = ? B. PE = ? KE = 20 J CFU

A. PE = 6J KE = 12 J TE = ? B. PE = 11 J KE = ? B. PE = ? KE = 15 J CFU

1.Do Now 2.Introduction 3.Homework Review 4.Calculations 5.Calculation W.S. 6.W.S. part 2 7.Exit Slip 8.Closing AGENDA