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Mechanical energy

January 01, 1970

In physical sciences, mechanical energy is the sum of potential energy and kinetic energy. The principle of conservation of mechanical energy states that if an isolated system is subject only to conservative forces, then the mechanical energy is constant. If an object moves in the opposite direction of a conservative net force, the potential energy will increase; and if the speed (not the velocity) of the object changes, the kinetic energy of the object also changes. In all real systems, however, nonconservative forces, such as frictional forces, will be present, but if they are of negligible magnitude, the mechanical energy changes little and its conservation is a useful approximation. In elastic collisions, the kinetic energy is conserved, but in inelastic collisions some mechanical energy may be converted into thermal energy. The equivalence between lost mechanical energy and an increase in temperature was discovered by James Prescott Joule.

An example of a mechanical system: A satellite is orbiting the Earth influenced only by the conservative gravitational force; its mechanical energy is therefore conserved. The satellite's acceleration is represented by the green vector and its velocity is represented by the red vector. If the satellite's orbit is an ellipse the potential energy of the satellite, and its kinetic energy, both vary with time but their sum remains constant.

Many devices are used to convert mechanical energy to or from other forms of energy, e.g. an electric motor converts electrical energy to mechanical energy, an electric generator converts mechanical energy into electrical energy and a heat engine converts heat to mechanical energy.

General edit

Energy is a scalar quantity and the mechanical energy of a system is the sum of the potential energy (which is measured by the position of the parts of the system) and the kinetic energy (which is also called the energy of motion):[1][2]

 

The potential energy, U, depends on the position of an object subjected to gravity or some other conservative force. The gravitational potential energy of an object is equal to the weight W of the object multiplied by the height h of the object's center of gravity relative to an arbitrary datum:

 

The potential energy of an object can be defined as the object's ability to do work and is increased as the object is moved in the opposite direction of the direction of the force.[nb 1][1] If F represents the conservative force and x the position, the potential energy of the force between the two positions x1 and x2 is defined as the negative integral of F from x1 to x2:[4]

 

The kinetic energy, K, depends on the speed of an object and is the ability of a moving object to do work on other objects when it collides with them.[nb 2][8] It is defined as one half the product of the object's mass with the square of its speed, and the total kinetic energy of a system of objects is the sum of the kinetic energies of the respective objects:[1][9]

 

The principle of conservation of mechanical energy states that if a body or system is subjected only to conservative forces, the mechanical energy of that body or system remains constant.[10] The difference between a conservative and a non-conservative force is that when a conservative force moves an object from one point to another, the work done by the conservative force is independent of the path. On the contrary, when a non-conservative force acts upon an object, the work done by the non-conservative force is dependent of the path.[11][12]

Conservation of mechanical energy edit

MIT professor Walter Lewin demonstrating conservation of mechanical energy

According to the principle of conservation of mechanical energy, the mechanical energy of an isolated system remains constant in time, as long as the system is free of friction and other non-conservative forces. In any real situation, frictional forces and other non-conservative forces are present, but in many cases their effects on the system are so small that the principle of conservation of mechanical energy can be used as a fair approximation. Though energy cannot be created or destroyed, it can be converted to another form of energy.[1][13]

Swinging pendulum edit

 
A swinging pendulum with the velocity vector (green) and acceleration vector (blue). The magnitude of the velocity vector, the speed, of the pendulum is greatest in the vertical position and the pendulum is farthest from Earth in its extreme positions.
Main article: Pendulum

In a mechanical system like a swinging pendulum subjected to the conservative gravitational force where frictional forces like air drag and friction at the pivot are negligible, energy passes back and forth between kinetic and potential energy but never leaves the system. The pendulum reaches greatest kinetic energy and least potential energy when in the vertical position, because it will have the greatest speed and be nearest the Earth at this point. On the other hand, it will have its least kinetic energy and greatest potential energy at the extreme positions of its swing, because it has zero speed and is farthest from Earth at these points. However, when taking the frictional forces into account, the system loses mechanical energy with each swing because of the negative work done on the pendulum by these non-conservative forces.[2]

Irreversibilities edit

Main article: Irreversible process

That the loss of mechanical energy in a system always resulted in an increase of the system's temperature has been known for a long time, but it was the amateur physicist James Prescott Joule who first experimentally demonstrated how a certain amount of work done against friction resulted in a definite quantity of heat which should be conceived as the random motions of the particles that comprise matter.[14] This equivalence between mechanical energy and heat is especially important when considering colliding objects. In an elastic collision, mechanical energy is conserved – the sum of the mechanical energies of the colliding objects is the same before and after the collision. After an inelastic collision, however, the mechanical energy of the system will have changed. Usually, the mechanical energy before the collision is greater than the mechanical energy after the collision. In inelastic collisions, some of the mechanical energy of the colliding objects is transformed into kinetic energy of the constituent particles. This increase in kinetic energy of the constituent particles is perceived as an increase in temperature. The collision can be described by saying some of the mechanical energy of the colliding objects has been converted into an equal amount of heat. Thus, the total energy of the system remains unchanged though the mechanical energy of the system has reduced.[1][15]

Satellite edit

Main article: Vis-viva equation
 
plot of kinetic energy  , gravitational potential energy,   and mechanical energy   versus distance away from centre of earth, r at R= Re, R= 2*Re, R=3*Re and lastly R = geostationary radius

A satellite of mass   at a distance   from the centre of Earth possesses both kinetic energy,  , (by virtue of its motion) and gravitational potential energy,  , (by virtue of its position within the Earth's gravitational field; Earth's mass is  ). Hence, mechanical energy   of the satellite-Earth system is given by

 
 

If the satellite is in circular orbit, the energy conservation equation can be further simplified into

 
since in circular motion, Newton's 2nd Law of motion can be taken to be
 

Conversion edit

Today, many technological devices convert mechanical energy into other forms of energy or vice versa. These devices can be placed in these categories:

Distinction from other types edit

The classification of energy into different types often follows the boundaries of the fields of study in the natural sciences.

References edit

Notes

  1. ^ It is important to note that when measuring mechanical energy, an object is considered as a whole, as it is stated by Isaac Newton in his Principia: "The motion of a whole is the same as the sum of the motions of the parts; that is, the change in position of its parts from their places, and thus the place of a whole is the same as the sum of the places of the parts and therefore is internal and in the whole body."[3]
  2. ^ In physics, speed is a scalar quantity and velocity is a vector. Velocity is speed with a direction and can therefore change without changing the speed of the object since speed is the numerical magnitude of a velocity.[5][6][7]

Citations

  1. ^ a b c d e Wilczek, Frank (2008). . AccessScience. McGraw-Hill Companies. Archived from the original on 2013-07-19. Retrieved 2011-08-26.
  2. ^ a b "mechanical energy". The New Encyclopædia Britannica: Micropædia: Ready Reference. Vol. 7 (15th ed.). 2003.
  3. ^ Newton 1999, p. 409
  4. ^ . Texas A&M University–Kingsville. Archived from the original on 2012-04-14. Retrieved 2011-08-25.
  5. ^ Brodie et al. 1998, pp. 129–131
  6. ^ Rusk, Rogers D. (2008). . AccessScience. McGraw-Hill Companies. Archived from the original on 2013-07-19. Retrieved 2011-08-28.
  7. ^ Rusk, Rogers D. (2008). . AccessScience. McGraw-Hill Companies. Archived from the original on 2013-07-19. Retrieved 2011-08-28.
  8. ^ Brodie et al. 1998, p. 101
  9. ^ Jain 2009, p. 9
  10. ^ Jain 2009, p. 12
  11. ^ Department of Physics. "Review D: Potential Energy and the Conservation of Mechanical Energy" (PDF). Massachusetts Institute of Technology. Retrieved 2011-08-03.
  12. ^ Resnick, Robert and Halliday, David (1966), Physics, Section 8-3 (Vol I and II, Combined edition), Wiley International Edition, Library of Congress Catalog Card No. 66-11527
  13. ^ E. Roller, Duane; Leo Nedelsky (2008). "Conservation of energy". AccessScience. McGraw-Hill Companies. Retrieved 2011-08-26.
  14. ^ "James Prescott Joule". Scientists: Their Lives and Works. Gale. 2006. as cited on "Student Resources in Context". Gale. Retrieved 2011-08-28.
  15. ^ Schmidt, Paul W. (2008). "Collision (physics)". AccessScience. McGraw-Hill Companies. Retrieved 2011-09-03.
  16. ^ Kopicki, Ronald J. (2003). "Electrification, Household". In Kutler, Stanley I. (ed.). Dictionary of American History. Vol. 3 (3rd ed.). New York: Charles Scribner's Sons. pp. 179–183. as cited on "Student Resources in Context". Gale. Retrieved 2011-09-07.
  17. ^ Lerner, K. Lee; Lerner, Brenda Wilmoth, eds. (2008). "Electric motor". The Gale Encyclopedia of Science (4th ed.). Detroit: Gale. as cited on "Student Resources in Context". Gale. Retrieved 2011-09-07.
  18. ^ "Electric motor". U*X*L Encyclopedia of Science. U*X*L. 2007. as cited on "Student Resources in Context". Gale. Retrieved 2011-09-07.
  19. ^ "Generator". U*X*L Encyclopedia of Science. U*X*L. 2007-07-16. as cited on "Student Resources in Context". Gale. Retrieved 2011-10-09.
  20. ^ "Hydroelectric Power". Water Encyclopedia. Retrieved 2013-08-23
  21. ^ Lerner, K. Lee; Lerner, Brenda Wilmoth, eds. (2008). "Internal combustion engine". The Gale Encyclopedia of Science (4th ed.). Detroit: Gale. as cited on "Student Resources in Context". Gale. Retrieved 2011-10-09.
  22. ^ "Steam engine". U*X*L Encyclopedia of Science. U*X*L. 2007-07-16. as cited on "Student Resources in Context". Gale. Retrieved 2011-10-09.
  23. ^ Lerner, K. Lee; Lerner, Brenda Wilmoth, eds. (2008). "Turbine". The Gale Encyclopedia of Science (4th ed.). Detroit: Gale. as cited on "Student Resources in Context". Gale. Retrieved 2011-10-09.
  24. ^ Atkins, Peter W. (2008). . AccessScience. McGraw-Hill Companies. Archived from the original on 2013-07-19. Retrieved 2011-10-17.
  25. ^ Duckworth, Henry E.; Wilkinson, D. H. (2008). . AccessScience. McGraw-Hill Companies. Archived from the original on 2013-07-19. Retrieved 2011-10-17.
  26. ^ Hartwig, William H. (2008). . AccessScience. McGraw-Hill Companies. Archived from the original on 2013-07-19. Retrieved 2011-10-17.
  27. ^ Smythe, William R. (2008). . AccessScience. McGraw-Hill Companies. Archived from the original on 2013-07-19. Retrieved 2011-10-17.
  28. ^ Gerjuoy, Edward (2008). . AccessScience. McGraw-Hill Companies. Archived from the original on 2013-07-19. Retrieved 2011-10-17.
  29. ^ March-Russell, John (2008). . AccessScience. McGraw-Hill Companies. Archived from the original on 2013-07-19. Retrieved 2011-10-17.

Bibliography

  • Brodie, David; Brown, Wendy; Heslop, Nigel; Ireson, Gren; Williams, Peter (1998). Terry Parkin (ed.). Physics. Addison Wesley Longman Limited. ISBN 978-0-582-28736-5.
  • Jain, Mahesh C. (2009). Textbook of Engineering Physics, Part I. New Delhi: PHI Learning Pvt. Ltd. ISBN 978-81-203-3862-3. Retrieved 2011-08-25.
  • Newton, Isaac (1999). I. Bernard Cohen; Anne Miller Whitman (eds.). The Principia: mathematical principles of natural philosophy. United States of America: University of California Press. ISBN 978-0-520-08816-0.

January 01, 1970
mechanical, energy, physical, sciences, mechanical, energy, potential, energy, kinetic, energy, principle, conservation, mechanical, energy, states, that, isolated, system, subject, only, conservative, forces, then, mechanical, energy, constant, object, moves,. In physical sciences mechanical energy is the sum of potential energy and kinetic energy The principle of conservation of mechanical energy states that if an isolated system is subject only to conservative forces then the mechanical energy is constant If an object moves in the opposite direction of a conservative net force the potential energy will increase and if the speed not the velocity of the object changes the kinetic energy of the object also changes In all real systems however nonconservative forces such as frictional forces will be present but if they are of negligible magnitude the mechanical energy changes little and its conservation is a useful approximation In elastic collisions the kinetic energy is conserved but in inelastic collisions some mechanical energy may be converted into thermal energy The equivalence between lost mechanical energy and an increase in temperature was discovered by James Prescott Joule An example of a mechanical system A satellite is orbiting the Earth influenced only by the conservative gravitational force its mechanical energy is therefore conserved The satellite s acceleration is represented by the green vector and its velocity is represented by the red vector If the satellite s orbit is an ellipse the potential energy of the satellite and its kinetic energy both vary with time but their sum remains constant Many devices are used to convert mechanical energy to or from other forms of energy e g an electric motor converts electrical energy to mechanical energy an electric generator converts mechanical energy into electrical energy and a heat engine converts heat to mechanical energy Contents 1 General 2 Conservation of mechanical energy 2 1 Swinging pendulum 2 2 Irreversibilities 2 3 Satellite 3 Conversion 4 Distinction from other types 5 ReferencesGeneral editEnergy is a scalar quantity and the mechanical energy of a system is the sum of the potential energy which is measured by the position of the parts of the system and the kinetic energy which is also called the energy of motion 1 2 E mechanical U K displaystyle E text mechanical U K nbsp The potential energy U depends on the position of an object subjected to gravity or some other conservative force The gravitational potential energy of an object is equal to the weight W of the object multiplied by the height h of the object s center of gravity relative to an arbitrary datum U W h displaystyle U Wh nbsp The potential energy of an object can be defined as the object s ability to do work and is increased as the object is moved in the opposite direction of the direction of the force nb 1 1 If F represents the conservative force and x the position the potential energy of the force between the two positions x1 and x2 is defined as the negative integral of F from x1 to x2 4 U x 1 x 2 F d x displaystyle U int x 1 x 2 vec F cdot d vec x nbsp The kinetic energy K depends on the speed of an object and is the ability of a moving object to do work on other objects when it collides with them nb 2 8 It is defined as one half the product of the object s mass with the square of its speed and the total kinetic energy of a system of objects is the sum of the kinetic energies of the respective objects 1 9 K 1 2 m v 2 displaystyle K 1 over 2 mv 2 nbsp The principle of conservation of mechanical energy states that if a body or system is subjected only to conservative forces the mechanical energy of that body or system remains constant 10 The difference between a conservative and a non conservative force is that when a conservative force moves an object from one point to another the work done by the conservative force is independent of the path On the contrary when a non conservative force acts upon an object the work done by the non conservative force is dependent of the path 11 12 Conservation of mechanical energy edit source source source source track track track MIT professor Walter Lewin demonstrating conservation of mechanical energy According to the principle of conservation of mechanical energy the mechanical energy of an isolated system remains constant in time as long as the system is free of friction and other non conservative forces In any real situation frictional forces and other non conservative forces are present but in many cases their effects on the system are so small that the principle of conservation of mechanical energy can be used as a fair approximation Though energy cannot be created or destroyed it can be converted to another form of energy 1 13 Swinging pendulum edit nbsp A swinging pendulum with the velocity vector green and acceleration vector blue The magnitude of the velocity vector the speed of the pendulum is greatest in the vertical position and the pendulum is farthest from Earth in its extreme positions Main article Pendulum In a mechanical system like a swinging pendulum subjected to the conservative gravitational force where frictional forces like air drag and friction at the pivot are negligible energy passes back and forth between kinetic and potential energy but never leaves the system The pendulum reaches greatest kinetic energy and least potential energy when in the vertical position because it will have the greatest speed and be nearest the Earth at this point On the other hand it will have its least kinetic energy and greatest potential energy at the extreme positions of its swing because it has zero speed and is farthest from Earth at these points However when taking the frictional forces into account the system loses mechanical energy with each swing because of the negative work done on the pendulum by these non conservative forces 2 Irreversibilities edit Main article Irreversible process That the loss of mechanical energy in a system always resulted in an increase of the system s temperature has been known for a long time but it was the amateur physicist James Prescott Joule who first experimentally demonstrated how a certain amount of work done against friction resulted in a definite quantity of heat which should be conceived as the random motions of the particles that comprise matter 14 This equivalence between mechanical energy and heat is especially important when considering colliding objects In an elastic collision mechanical energy is conserved the sum of the mechanical energies of the colliding objects is the same before and after the collision After an inelastic collision however the mechanical energy of the system will have changed Usually the mechanical energy before the collision is greater than the mechanical energy after the collision In inelastic collisions some of the mechanical energy of the colliding objects is transformed into kinetic energy of the constituent particles This increase in kinetic energy of the constituent particles is perceived as an increase in temperature The collision can be described by saying some of the mechanical energy of the colliding objects has been converted into an equal amount of heat Thus the total energy of the system remains unchanged though the mechanical energy of the system has reduced 1 15 Satellite edit Main article Vis viva equation nbsp plot of kinetic energy K displaystyle K nbsp gravitational potential energy U displaystyle U nbsp and mechanical energy E mechanical displaystyle E text mechanical nbsp versus distance away from centre of earth r at R Re R 2 Re R 3 Re and lastly R geostationary radius A satellite of mass m displaystyle m nbsp at a distance r displaystyle r nbsp from the centre of Earth possesses both kinetic energy K displaystyle K nbsp by virtue of its motion and gravitational potential energy U displaystyle U nbsp by virtue of its position within the Earth s gravitational field Earth s mass is M displaystyle M nbsp Hence mechanical energy E mechanical displaystyle E text mechanical nbsp of the satellite Earth system is given byE mechanical U K displaystyle E text mechanical U K nbsp E mechanical G M m r 1 2 m v 2 displaystyle E text mechanical G frac Mm r frac 1 2 mv 2 nbsp If the satellite is in circular orbit the energy conservation equation can be further simplified intoE mechanical G M m 2 r displaystyle E text mechanical G frac Mm 2r nbsp since in circular motion Newton s 2nd Law of motion can be taken to be G M m r 2 m v 2 r displaystyle G frac Mm r 2 frac mv 2 r nbsp Conversion editToday many technological devices convert mechanical energy into other forms of energy or vice versa These devices can be placed in these categories An electric motor converts electrical energy into mechanical energy 16 17 18 A generator converts mechanical energy into electrical energy 19 A hydroelectric powerplant converts the mechanical energy of water in a storage dam into electrical energy 20 An internal combustion engine is a heat engine that obtains mechanical energy from chemical energy by burning fuel From this mechanical energy the internal combustion engine often generates electricity 21 A steam engine converts the heat energy of steam into mechanical energy 22 A turbine converts the kinetic energy of a stream of gas or liquid into mechanical energy 23 Distinction from other types editThe classification of energy into different types often follows the boundaries of the fields of study in the natural sciences Chemical energy is the kind of potential energy stored in chemical bonds and is studied in chemistry 24 Nuclear energy is energy stored in interactions between the particles in the atomic nucleus and is studied in nuclear physics 25 Electromagnetic energy is in the form of electric charges magnetic fields and photons It is studied in electromagnetism 26 27 Various forms of energy in quantum mechanics e g the energy levels of electrons in an atom 28 29 References editNotes It is important to note that when measuring mechanical energy an object is considered as a whole as it is stated by Isaac Newton in his Principia The motion of a whole is the same as the sum of the motions of the parts that is the change in position of its parts from their places and thus the place of a whole is the same as the sum of the places of the parts and therefore is internal and in the whole body 3 In physics speed is a scalar quantity and velocity is a vector Velocity is speed with a direction and can therefore change without changing the speed of the object since speed is the numerical magnitude of a velocity 5 6 7 Citations a b c d e Wilczek Frank 2008 Conservation laws physics AccessScience McGraw Hill Companies Archived from the original on 2013 07 19 Retrieved 2011 08 26 a b mechanical energy The New Encyclopaedia Britannica Micropaedia Ready Reference Vol 7 15th ed 2003 Newton 1999 p 409 Potential Energy Texas A amp M University Kingsville Archived from the original on 2012 04 14 Retrieved 2011 08 25 Brodie et al 1998 pp 129 131 Rusk Rogers D 2008 Speed AccessScience McGraw Hill Companies Archived from the original on 2013 07 19 Retrieved 2011 08 28 Rusk Rogers D 2008 Velocity AccessScience McGraw Hill Companies Archived from the original on 2013 07 19 Retrieved 2011 08 28 Brodie et al 1998 p 101 Jain 2009 p 9 Jain 2009 p 12 Department of Physics Review D Potential Energy and the Conservation of Mechanical Energy PDF Massachusetts Institute of Technology Retrieved 2011 08 03 Resnick Robert and Halliday David 1966 Physics Section 8 3 Vol I and II Combined edition Wiley International Edition Library of Congress Catalog Card No 66 11527 E Roller Duane Leo Nedelsky 2008 Conservation of energy AccessScience McGraw Hill Companies Retrieved 2011 08 26 James Prescott Joule Scientists Their Lives and Works Gale 2006 as cited on Student Resources in Context Gale Retrieved 2011 08 28 Schmidt Paul W 2008 Collision physics AccessScience McGraw Hill Companies Retrieved 2011 09 03 Kopicki Ronald J 2003 Electrification Household In Kutler Stanley I ed Dictionary of American History Vol 3 3rd ed New York Charles Scribner s Sons pp 179 183 as cited on Student Resources in Context Gale Retrieved 2011 09 07 Lerner K Lee Lerner Brenda Wilmoth eds 2008 Electric motor The Gale Encyclopedia of Science 4th ed Detroit Gale as cited on Student Resources in Context Gale Retrieved 2011 09 07 Electric motor U X L Encyclopedia of Science U X L 2007 as cited on Student Resources in Context Gale Retrieved 2011 09 07 Generator U X L Encyclopedia of Science U X L 2007 07 16 as cited on Student Resources in Context Gale Retrieved 2011 10 09 Hydroelectric Power Water Encyclopedia Retrieved 2013 08 23 Lerner K Lee Lerner Brenda Wilmoth eds 2008 Internal combustion engine The Gale Encyclopedia of Science 4th ed Detroit Gale as cited on Student Resources in Context Gale Retrieved 2011 10 09 Steam engine U X L Encyclopedia of Science U X L 2007 07 16 as cited on Student Resources in Context Gale Retrieved 2011 10 09 Lerner K Lee Lerner Brenda Wilmoth eds 2008 Turbine The Gale Encyclopedia of Science 4th ed Detroit Gale as cited on Student Resources in Context Gale Retrieved 2011 10 09 Atkins Peter W 2008 Chemical energy AccessScience McGraw Hill Companies Archived from the original on 2013 07 19 Retrieved 2011 10 17 Duckworth Henry E Wilkinson D H 2008 Nuclear binding energy AccessScience McGraw Hill Companies Archived from the original on 2013 07 19 Retrieved 2011 10 17 Hartwig William H 2008 Electrical energy measurement AccessScience McGraw Hill Companies Archived from the original on 2013 07 19 Retrieved 2011 10 17 Smythe William R 2008 Electromagnetic radiation AccessScience McGraw Hill Companies Archived from the original on 2013 07 19 Retrieved 2011 10 17 Gerjuoy Edward 2008 Quantum mechanics AccessScience McGraw Hill Companies Archived from the original on 2013 07 19 Retrieved 2011 10 17 March Russell John 2008 Energy level quantum mechanics AccessScience McGraw Hill Companies Archived from the original on 2013 07 19 Retrieved 2011 10 17 Bibliography Brodie David Brown Wendy Heslop Nigel Ireson Gren Williams Peter 1998 Terry Parkin ed Physics Addison Wesley Longman Limited ISBN 978 0 582 28736 5 Jain Mahesh C 2009 Textbook of Engineering Physics Part I New Delhi PHI Learning Pvt Ltd ISBN 978 81 203 3862 3 Retrieved 2011 08 25 Newton Isaac 1999 I Bernard Cohen Anne Miller Whitman eds The Principia mathematical principles of natural philosophy United States of America University of California Press ISBN 978 0 520 08816 0 Retrieved from https en wikipedia org w index php title Mechanical energy amp oldid 1222722586 Conservation of mechanical energy, wikipedia, wiki, book, books, library,

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