Presentation is loading. Please wait.

Presentation is loading. Please wait.

Energy IN = Energy OUT Means ALL Energy

Published bySuhendra Budiono Modified over 5 years ago

Similar presentations

Presentation on theme: "Energy IN = Energy OUT Means ALL Energy"— Presentation transcript:

1 Energy IN = Energy OUT Means ALL Energy
Work to Overcome Friction

2 We now consider problems in which Q ≠ 0
Energy “Loss” Energy can never by truly destroyed, but it can be converted into non-mechanical forms (mainly heat) that are not ‘useful’. We now consider problems in which Q ≠ 0

3 Example #1 – Lifting a Load
5200 joules of work are done in lifting a 50 kilogram object a distance of 10 meters. Determine the amount of potential energy gained by lifting this object. In the “real world” it takes more energy to lift an object than the gain in gravitational PE would suggest. ΔPE = mgΔh ΔPE = (50 kg)(9.81 m/s2)(10 m) ΔPE = 4905 J

4 Example #1 – Lifting a Load
5200 joules of work are done in lifting a 50 kilogram object a distance of 10 meters. How much energy must have been used to overcome friction? W = Fd = ΔET = 5200 J ET = PE + KE + Q 5200 J = 4905 J Q Q = 295 J

5 Example #2 – Missing KE A 4.0 kilogram object begins at rest at the top of an incline that is 2.0 meters above the ground and slides down to the bottom. The object reaches a speed of 5.0 meters per second at the bottom of the incline. Determine the total energy of the object at the top of the incline. In the “real world” potential energy is not completely converted into kinetic energy when objects lose height. ET = PE + KE + Q ET = mgh + ½ mv2 + Q ET = (4.0 kg)(9.81 m/s2)(2.0 m) ET = J

6 Example #2 – Missing KE Determine the amount of energy used to overcome friction as the block slides down the incline. ET = PE + KE + Q 78.48 J = mgh + ½ mv2 + Q 78.48 J = 0 + ½ (4 kg)(5.0 m/s)2 + Q Q = J

7 Example #3 – Constant Velocity
A 2.0 kilogram object is pulled along a flat surface at a constant speed with a force of 30 newtons. Calculate the amount of work done in moving the object 4.0 meters. In the “real world” we must constantly add energy to a system (do work) to keep things moving at a constant speed. W = Fd = ΔET W = (30 N)(4.0 m) W = 120 J

8 Example #3 – Constant Velocity
A 2.0 kilogram object is pulled along a flat surface at a constant speed with a force of 30 newtons. How much work must have been done against friction in moving this object? W = Fd = ΔET = 120 J ET = PE + KE + Q 120 J = Q Q = 120 J

9 End of PRACTICE

Download ppt "Energy IN = Energy OUT Means ALL Energy"

Similar presentations

Practice Problem #1 A weightlifter bench presses 80kg (approx. 175lbs.) 0.75m straight up. a. How much work does she do, assuming constant velocity, in.

Practice Problem #1 A weightlifter bench presses 80kg (approx. 175lbs.) 0.75m straight up. a. How much work does she do, assuming constant velocity, in.
Work, Potential Energy, Kinetic Energy & Power

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

Energy Problems Review for Potential energy, Kinetic energy, Total Energy work, power.
Energy Kinetic and potential Energy can be classified as potential or kinetic Potential energy: energy of position Potential energy: energy of position.

Energy Kinetic and potential Energy can be classified as potential or kinetic Potential energy: energy of position Potential energy: energy of position.
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.
Emech at 1 + W = Emech at 2 mgh1 = mgh2

Emech at 1 + W = Emech at 2 mgh1 = mgh2
Work, power and energy(2)

Work, power and energy(2)
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.
Potential and Kinetic Energy Problems

Potential and Kinetic Energy Problems
Notes on Chapter 8 Work & Energy

Notes on Chapter 8 Work & Energy
Physics 121 6. Work and Energy 6.1 Work 6.3 Kinetic Energy 6.4 Potential Energy 6.5 Conservative and Non-conservative forces 6.6 Mechanical Energy /

Physics Work and Energy 6.1 Work 6.3 Kinetic Energy 6.4 Potential Energy 6.5 Conservative and Non-conservative forces 6.6 Mechanical Energy /
ENERGY Part I.

ENERGY Part I.
Chapter 5 – Work and Energy If an object is moved by a force and the force and displacement are in the same direction, then work equals the product of.

Chapter 5 – Work and Energy If an object is moved by a force and the force and displacement are in the same direction, then work equals the product of.
Unit 5 Mechanical Principles and Applications

Unit 5 Mechanical Principles and Applications
ENERGY The measure of the ability to do work Conservation of energy -energy can change forms but can not be destroyed -the total amount of energy in the.

ENERGY The measure of the ability to do work Conservation of energy -energy can change forms but can not be destroyed -the total amount of energy in the.
How much work does a 154 lb. student do when climbing a flight of stairs that are 6 meters in height and 30 meters in length? If the stairs are climbed.

How much work does a 154 lb. student do when climbing a flight of stairs that are 6 meters in height and 30 meters in length? If the stairs are climbed.
Regents Physics Work and Energy. Energy and Work Energy is the ability to Work Work is the transfer of energy to an object, or transformation of energy.

Regents Physics Work and Energy. Energy and Work Energy is the ability to Work Work is the transfer of energy to an object, or transformation of energy.
Physics 3.3. Work WWWWork is defined as Force in the direction of motion x the distance moved. WWWWork is also defined as the change in total.

Physics 3.3. Work WWWWork is defined as Force in the direction of motion x the distance moved. WWWWork is also defined as the change in total.
Work IN, Work OUT The Work/Energy Principle. Kinetic Energy KE depends on mass and velocity Work done on an object will change KE.

Work IN, Work OUT The Work/Energy Principle. Kinetic Energy KE depends on mass and velocity Work done on an object will change KE.
Units: 1Newton . 1 meter = 1 joule = 1J

Units: 1Newton . 1 meter = 1 joule = 1J

Similar presentations

Ads by Google