Presentation is loading. Please wait.

Presentation is loading. Please wait.

CONSERVATION OF MECHANICAL ENERGY

Published byFranklin Sanders Modified over 9 years ago

Similar presentations

Presentation on theme: "CONSERVATION OF MECHANICAL ENERGY"— Presentation transcript:

1 CONSERVATION OF MECHANICAL ENERGY
What is Mechanical Energy?

2 Mechanical Energy The sum of kinetic energy and all forms of potential energy within a system.

3 The sum of kinetic energy and all forms of potential energy
Mechanical Energy The sum of kinetic energy and all forms of potential energy “ME” ME = KE + PE

4 Conservation of Mechanical Energy
Conserved means stays constant The law is MEi = MEf or Initial mechanical energy = Final mechanical energy (in the absence of friction)

5 Conservation of Mechanical Energy
Another way to write the law is MEi = MEf Or 0.5 mvi2 + mghi = 0.5 mvf2 + mghf

6 Conservation of Mechanical Energy
Example 1 Starting from rest, a child zooms down a frictionless slide with an initial height of 3.00m. What is her speed at the bottom of the slide? Assume she has a mass of 25.0 kg. Here is the formula – you try it first: 0.5 mvi2 + mghi = 0.5 mvf2 + mghf

7 Conservation of Mechanical Energy
Example 1 Starting from rest, a child zooms down a frictionless slide with an initial height of 3.00m. What is her speed at the bottom of the slide? Assume she has a mass of 25.0 kg. Here is the formula – you try it first: 0.5 mvi2 + mghi = 0.5 mvf2 + mghf 0.5 (25kg)(0) + 25kg(9.8m/s2)(3m) = 0.5 (25kg)vf2 + 25kg(9.8m/s2)(0 m) J = 12.5 vf2 + 0 7.67m/s = vf

8 Conservation of Mechanical Energy
Example 2 A small 10.0 g ball is held to a slingshot that is stretched 6.0 cm. The spring constant is 200 N/m. a. What is the elastic PE of the slingshot before it is released?

9 Conservation of Mechanical Energy
Example 2 A small 10.0 g ball is held to a slingshot that is stretched 6.0 cm. The spring constant is 200 N/m. a. What is the elastic PE of the slingshot before it is released? PEi = 0.5 kx2 = 0.5 (200N/m)(.06m)2 = .36J

10 Conservation of Mechanical Energy
Example 2 A small 10.0 g ball is held to a slingshot that is stretched 6.0 cm. The spring constant is 200 N/m. a. What is the elastic PE of the slingshot before it is released? PEi = 0.5 kx2 = ½ (200N/m)(.06m)2 = .36J b. What is the KE of the ball just after the slingshot is released?

11 Conservation of Mechanical Energy
Example 2 A small 10.0 g ball is held to a slingshot that is stretched 6.0 cm. The spring constant is 200 N/m. a. What is the elastic PE of the slingshot before it is released? PEi = 0.5 kx2 = ½ (200N/m)(.06m)2 = .36J b. What is the KE of the ball just after the slingshot is released? KEf = same as PEi = .36J, all the initial PE was converted to the final KE

12 Conservation of Mechanical Energy
Example 2 continued c. What is the ball’s speed at the instant it is released?

13 Conservation of Mechanical Energy
Example 2 continued c. What is the ball’s speed at the instant it is released? KEf = 0.5 mv2 .36J = 0.5 (10.0kg)v2 8.5m/s = v

14 Conservation of Mechanical Energy
Video Clip:

Download ppt "CONSERVATION OF MECHANICAL ENERGY"

Similar presentations

ConcepTest 7.2 KE and PE You and your friend both solve a problem involving a skier going down a slope, starting from rest. The two of you have chosen.

ConcepTest 7.2 KE and PE You and your friend both solve a problem involving a skier going down a slope, starting from rest. The two of you have chosen.
Chapter 5 – WORK and ENERGY. 5.2 MECHANICAL ENERGY.

Chapter 5 – WORK and ENERGY. 5.2 MECHANICAL ENERGY.
Energy.

Energy.
Principles of Physics - Foederer. Energy is stored in a spring when work is done to compress or elongate it Compression or elongation= change in length.

Principles of Physics - Foederer. Energy is stored in a spring when work is done to compress or elongate it Compression or elongation= change in length.
Aim: How can we calculate the energy of a spring? HW #33 due tomorrow Do Now: An object is thrown straight up. At the maximum height, it has a potential.

Aim: How can we calculate the energy of a spring? HW #33 due tomorrow Do Now: An object is thrown straight up. At the maximum height, it has a potential.
Energy By. Jonathan Lee and Harry Chun. What is “energy”? Energy is the ability to do work Potential Energy (PE) is the “possible” ability to do work.

Energy By. Jonathan Lee and Harry Chun. What is “energy”? Energy is the ability to do work Potential Energy (PE) is the “possible” ability to do work.
Bellringer 10/25 A 95 kg clock initially at rest on a horizontal floor requires a 650 N horizontal force to set it in motion. After the clock is in motion,

Bellringer 10/25 A 95 kg clock initially at rest on a horizontal floor requires a 650 N horizontal force to set it in motion. After the clock is in motion,
Herriman High Honors Physics Chapter 5 Work, Power and Energy What You Need to Know.

Herriman High Honors Physics Chapter 5 Work, Power and Energy What You Need to Know.
Objectives Recognize the difference between the scientific and ordinary definitions of work. Define work by relating it to force and displacement. Identify.

Objectives Recognize the difference between the scientific and ordinary definitions of work. Define work by relating it to force and displacement. Identify.
Chapter 5 Work and Energy. Force, displacement  WORK.

Chapter 5 Work and Energy. Force, displacement  WORK.
More Common Problems/Situations Involving Work and/or Energy and Its Conservation Elastic Collisions Ballistic Pendulum Compressed Spring Pendulum.

More Common Problems/Situations Involving Work and/or Energy and Its Conservation Elastic Collisions Ballistic Pendulum Compressed Spring Pendulum.
WORK AND ENERGY 1. Work Work as you know it means to do something that takes physical or mental effort But in physics is has a very different meaning.

WORK AND ENERGY 1. Work Work as you know it means to do something that takes physical or mental effort But in physics is has a very different meaning.
Physics Chapter 11 Energy.

Physics Chapter 11 Energy.
Energy and Conservation Physics Chapter 5-2 (p172-178) Chapter 5-3 (p179-183)

Energy and Conservation Physics Chapter 5-2 (p ) Chapter 5-3 (p )
Week.  Student will: laws of conservation of energy  Demonstrate and apply the laws of conservation of energy in terms of  KineticPotential Energy.

Week.  Student will: laws of conservation of energy  Demonstrate and apply the laws of conservation of energy in terms of  KineticPotential Energy.
Chapter 5 Work and Energy. Review  x = v i  t + ½ a  t 2  x = ½ (v i + v f )  t v f = v i + a  t v f 2 = v i 2 + 2a  x.

Chapter 5 Work and Energy. Review  x = v i  t + ½ a  t 2  x = ½ (v i + v f )  t v f = v i + a  t v f 2 = v i 2 + 2a  x.
November 16 th 2009 Objectives SWBAT Relate the concepts of energy, power, and time SWBAT Calculate power in two different ways Catalyst Can the KE of.

November 16 th 2009 Objectives SWBAT Relate the concepts of energy, power, and time SWBAT Calculate power in two different ways Catalyst Can the KE of.
Kinetic and Potential Energy

Kinetic and Potential Energy
Physics Chp 5. Work is done when a force acts to displace an object. Units are Nm which is also J W = Fd but the force and displacement have to be parallel.

Physics Chp 5. Work is done when a force acts to displace an object. Units are Nm which is also J W = Fd but the force and displacement have to be parallel.
ADV PHYSICS Chapter 5 Sections 2 and 4. Review  Work – force applied over a given distance W = F Δ x [W] = Joules, J  Assumes the force is constant.

ADV PHYSICS Chapter 5 Sections 2 and 4. Review  Work – force applied over a given distance W = F Δ x [W] = Joules, J  Assumes the force is constant.

Similar presentations

Ads by Google