* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Chapter 9.7 - Fort Thomas Independent Schools
Efficient energy use wikipedia , lookup
Potential energy wikipedia , lookup
Open energy system models wikipedia , lookup
William Flynn Martin wikipedia , lookup
Kinetic energy wikipedia , lookup
Energy subsidies wikipedia , lookup
Energy storage wikipedia , lookup
100% renewable energy wikipedia , lookup
Low-Income Home Energy Assistance Program wikipedia , lookup
Public schemes for energy efficient refurbishment wikipedia , lookup
Zero-energy building wikipedia , lookup
World energy consumption wikipedia , lookup
Regenerative brake wikipedia , lookup
Energy Charter Treaty wikipedia , lookup
Energy policy of Australia wikipedia , lookup
Low-carbon economy wikipedia , lookup
Alternative energy wikipedia , lookup
International Energy Agency wikipedia , lookup
Internal energy wikipedia , lookup
Distributed generation wikipedia , lookup
Energy returned on energy invested wikipedia , lookup
Energy harvesting wikipedia , lookup
Energy efficiency in transport wikipedia , lookup
Life-cycle greenhouse-gas emissions of energy sources wikipedia , lookup
Energy policy of the United Kingdom wikipedia , lookup
Energy policy of Finland wikipedia , lookup
Energy in the United Kingdom wikipedia , lookup
Negawatt power wikipedia , lookup
Energy policy of the European Union wikipedia , lookup
United States energy law wikipedia , lookup
Energy Independence and Security Act of 2007 wikipedia , lookup
Conservation of energy wikipedia , lookup
Chapter 9.7 Conservation of Energy 9.6 Work-Energy Theorem For moving objects such as cars: The more kinetic energy it has, the more work is required to stop it. Twice as much kinetic energy means twice as much work. Brakes do work on wheels (you do work by pushing the brake pedal). When a car brakes, the work is the friction force (supplied by the brakes) multiplied by the distance over which the friction force acts. KE is transformed by work (friction) into thermal energy, sound energy and larger-scale vibrations. 9.7 Conservation of Energy The law of conservation of energy states that energy cannot be created or destroyed. It can be transformed from one form into another, but the total amount of energy never changes. For any system in its entirety—as simple as a swinging pendulum or as complex as an exploding galaxy—there is one quantity that does not change: energy. Energy may change form, but the total energy stays the same. 9.7 Conservation of Energy When energy is transformed, it is conserved, meaning that it will change form without losing its original amount of energy. 9.7 Conservation of Energy When the woman leaps from the burning building, the sum of her PE and KE remains constant at each successive position all the way down to the ground. 9.7 Conservation of Energy Elastic potential energy will become the kinetic energy of the arrow when the bow does work on the arrow. As you draw back the arrow in a bow, you do work stretching the bow. The bow then has potential energy. When released, the arrow has kinetic energy equal to this potential energy. It delivers this energy to its target. 9.7 Conservation of Energy Part of the PE of the wound spring changes into KE. The remaining PE goes into heating the machinery and the surroundings due to friction. No energy is lost. 9.7 Conservation of Energy Same energy transformation applies The 2 J of heat can be called nonuseful work (work that is not part of the object’s total mechanical energy). 10 J of PE does 8 J useful work on the arrow and 2 J of non-useful work on the molecules that compose the bow and string and arrow. The arrow has 8 J of KE. 9.7 Conservation of Energy Everywhere along the path of the pendulum bob, the sum of PE and KE is the same. Because of the work done against friction, this energy will eventually be transformed into heat. Non-useful work can also be called non-useful energy! Useful vs. Non-Useful Energy • Useful energy is total mechanical energy TME = PE + KE • Non-useful energy are those forms that cause the TME to decrease. Otherwise known as non-mechanical energy! – Thermal energy (heat from friction) – Sound energy – Vibrations not related to the original motion of the object • Example: friction decreases KE, causing the object to decrease in speed and causing the object and it surrounding to increase in temperature. • Can also be referred to as useful and non-useful work. 9.7 Conservation of Energy • Why does a tennis ball eventually stop bouncing? • Eventually, all of the total mechanical energy is transformed into non-useful energy (heat, sound, movement of fibers) 50 J PE New height less than before means less PE stored 35 J PE 20 J PE 50 J KE Bounce! 35 J KE Bounce! 20 J KE (bounce and so on!) Slides showing transformation of KE and PE • Source: http://www.physicsclassroom.com/mmedia /index.cfm Watch how KE and gravitational PE transform Where is the KE at the maximum? Where is the PE at the maximum? How is PE stored? Watch the change in height vs. the change in speed! How does the change in height affect KE and PE? What happens to KE and TME when the brakes are applied? What work is being done? Watch the transfer of KE and PE. What happens to the PE when the skier moves down the hill? What happens to the KE and TME when the skier travels over the unpacked snow? What work is done? Same work, more force, less displacement (from left to right) 9.7 Conservation of Energy Each atom that makes up matter is a concentrated bundle of energy. When the nuclei of atoms rearrange themselves, enormous amounts of energy can be released. The sun shines because some of its nuclear energy is transformed into radiant energy. In nuclear reactors, nuclear energy is transformed into heat. 9.7 Conservation of Energy Enormous compression due to gravity in the deep, hot interior of the sun causes hydrogen nuclei to fuse and become helium nuclei. • This high-temperature welding of atomic nuclei is called thermonuclear fusion. • This process releases radiant energy, some of which reaches Earth. • Part of this energy falls on plants, and some of the plants later become coal. 9.7 Conservation of Energy • Another part supports life in the food chain that begins with microscopic marine animals and plants, and later gets stored in oil. • Part of the sun’s energy is used to evaporate water from the ocean. • Some water returns to Earth as rain that is trapped behind a dam. 9.7 Conservation of Energy The water behind a dam has potential energy that is used to power a generating plant below the dam. • The generating plant transforms the energy of falling water into electrical energy. • Electrical energy travels through wires to homes where it is used for lighting, heating, cooking, and operating electric toothbrushes. 9.7 Conservation of Energy What does the law of conservation of energy state?