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Work and energy

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Aditya Chowdhary
Aditya Chowdhary

work and energy

Science
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WORK AND ENERGY PHYSICS ASSIGNMENT
About the chapter • In the previous chapters we have been discussing about motion of the objects and their cause of motion and gravitation. In this chapter we are going to learn about another concept which will help us to understand many natural phenomena is ‘work’. All living beings need to take food because all of them have to perform several activities to live. These activities are known as ‘Life Processes’. These processes require energy which comes from food. The requirement of energy depends upon the type of work.
Work • There is difference in the way we use the term Work in day to day life and the way we use it in science. • For ex - Kamali is preparing for examinations. She spends a lot of time in studies. She read books, practice diagrams, organizes her thoughts, discusses the problems with her friends. She expends a lot of energy in performing these activities. In common parlance she is ‘working hard ’.All this hard work involve many ‘little work’ if we go by the scientific definition of work. You stand still for a few minutes with a heavy load on your head. You get tired , you have exerted yourself and have spent quite a bit of energy .Are you doing work on the load ? The way we understand the term work in science , work is not done.
Work done by a constant force • To understand this, we shall first consider the case when the force is acting in the direction of displacement. • Let a constant force, F act on an object. Let the object be displaced through a distance, s in the direction of the force. Let W be the work done. We define work to be equal to the product of the force and displacement. Work done = force* displacement W =Fs
Energy • Life is impossible without energy. The demand for energy is ever increasing. But where do we get energy from ? The Sun is the biggest source of energy to us. Many of our energy resources are derived from the Sun. We can also get energy from the nuclei of atoms, the interior of the earth, and the tides. The word energy is very often used in our daily life, but in science we give it a definite and precise meaning.
Examples of energy • Let us consider the following examples :when a fast moving cricket ball hits a stationary wicket, the wicket is thrown away. • When a raised hammer falls on a nail placed on apiece of wood, it drives the nail into the wood. • When a balloon filled with air is pressed we see a change in its shape. However, if we press the balloon hard, it can even explode producing a blasting sound.
Forms of energy • Fortunately the world we live in provides energy in many different forms. The various forms include mechanical energy(potential energy+kinetic energy), heat energy, chemical energy, electrical energy and light energy. James Prescott Joule was an outstanding British physicist. He is best known for his research in electricity and thermodynamics. Amongst other things, he formulated a law for the heating effect of electric current. He also verified experimentally the law of conservation of energy and discovered the value of the mechanical equivalent of heat. The unit of energy and work called joule is named after him. James Prescott Joule 1818 --- 1889
Law of conservation of Energy • Whenever energy gets transformed, the total energy remains unchanged. This is the consequence of law of conservation of energy. According to this law, energy can only be converted from one form to another; it can neither be created nor destroyed. The total energy before and after the transformation remains the same. The law of conservation of energy is valid in all situations and for all kinds of transformations. • Consider a simple example. Let an object of mass, m be made to fall freely from a height, h. At the start, the potential energy is mgh and the kinetic energy is zero. It is zero because its velocity is also zero. The total energy of the object is thus mgh. As it falls, its potential energy will change into kinetic energy. If v is the velocity of the object at a given instant, the kinetic energy would be 1/2mv². As the fall continues, the potential energy would decrease while the kinetic energy would increase. When the object is about to reach the ground, h=0 and v will be the highest. Therefore, the kinetic energy would be the largest and potential energy the least. However, the sum of the potential energy and kinetic energy of the object would be the same at all points. That is potential energy + kinetic energy =constant or mgh+1/2mv²=constant The sum of kinetic energy and potential energy of an object is its total mechanical energy
Rate of doing work • All of us do not work at the same rate. A stronger person will be able to do more work in a certain period of time than an ordinary person. We talk of cars and motorcycles in terms of power of engines. What is power? It measures the speed with which work is done. • Power is defined as the rate of doing work or rate of transfer of energy. If ‘W’ joule of work is done in ‘t’ seconds, power P = work done/time taken =w/t • The unit of power is watt. 1watt of the power machine or an agent that does work at the rate of 1joule per second. 1000watts = 1kilowatt 1000kilowatt =1 megawatt 1kw = 1000j sˉ¹ The power agent may vary with time. This means that the agent may be doing work at different rates at different intervals of time. Therefore the concept of average power is useful. We obtain average power by dividing the total energy consumed by the total time taken.
Commercial unit of Energy • The unit joule is too small and hence is inconvenient to express large quantities of energy. We use bigger unit of energy called kilowatt hour (kW h). • Let us say we have a machine that uses 1000j of energy every second. If this machine is used continuously for one hour, it will consume 1kW of energy. Thus, 1kW h is the energy used in one hour at the rate of 1000j sˉ¹ (or 1kW). 1kW h =1kW *1h =1000W *3600s =3600000j 1kW h = 3.6 *10‘ j. • The energy used in households, industries, and commercial establishments are usually expressed in kilowatt hour. For example electrical energy used during a month is expressed in terms of ‘units’. Here, 1 unit means 1kilowatt hour.
Guided by Mr.Gopikrishna MADE BY: ADITYA CHOWDHARY IX

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Work and energy

  • 2. About the chapter • In the previous chapters we have been discussing about motion of the objects and their cause of motion and gravitation. In this chapter we are going to learn about another concept which will help us to understand many natural phenomena is ‘work’. All living beings need to take food because all of them have to perform several activities to live. These activities are known as ‘Life Processes’. These processes require energy which comes from food. The requirement of energy depends upon the type of work.
  • 3. Work • There is difference in the way we use the term Work in day to day life and the way we use it in science. • For ex - Kamali is preparing for examinations. She spends a lot of time in studies. She read books, practice diagrams, organizes her thoughts, discusses the problems with her friends. She expends a lot of energy in performing these activities. In common parlance she is ‘working hard ’.All this hard work involve many ‘little work’ if we go by the scientific definition of work. You stand still for a few minutes with a heavy load on your head. You get tired , you have exerted yourself and have spent quite a bit of energy .Are you doing work on the load ? The way we understand the term work in science , work is not done.
  • 4. Work done by a constant force • To understand this, we shall first consider the case when the force is acting in the direction of displacement. • Let a constant force, F act on an object. Let the object be displaced through a distance, s in the direction of the force. Let W be the work done. We define work to be equal to the product of the force and displacement. Work done = force* displacement W =Fs
  • 5. Energy • Life is impossible without energy. The demand for energy is ever increasing. But where do we get energy from ? The Sun is the biggest source of energy to us. Many of our energy resources are derived from the Sun. We can also get energy from the nuclei of atoms, the interior of the earth, and the tides. The word energy is very often used in our daily life, but in science we give it a definite and precise meaning.
  • 6. Examples of energy • Let us consider the following examples :when a fast moving cricket ball hits a stationary wicket, the wicket is thrown away. • When a raised hammer falls on a nail placed on apiece of wood, it drives the nail into the wood. • When a balloon filled with air is pressed we see a change in its shape. However, if we press the balloon hard, it can even explode producing a blasting sound.
  • 7. Forms of energy • Fortunately the world we live in provides energy in many different forms. The various forms include mechanical energy(potential energy+kinetic energy), heat energy, chemical energy, electrical energy and light energy. James Prescott Joule was an outstanding British physicist. He is best known for his research in electricity and thermodynamics. Amongst other things, he formulated a law for the heating effect of electric current. He also verified experimentally the law of conservation of energy and discovered the value of the mechanical equivalent of heat. The unit of energy and work called joule is named after him. James Prescott Joule 1818 --- 1889
  • 8. Law of conservation of Energy • Whenever energy gets transformed, the total energy remains unchanged. This is the consequence of law of conservation of energy. According to this law, energy can only be converted from one form to another; it can neither be created nor destroyed. The total energy before and after the transformation remains the same. The law of conservation of energy is valid in all situations and for all kinds of transformations. • Consider a simple example. Let an object of mass, m be made to fall freely from a height, h. At the start, the potential energy is mgh and the kinetic energy is zero. It is zero because its velocity is also zero. The total energy of the object is thus mgh. As it falls, its potential energy will change into kinetic energy. If v is the velocity of the object at a given instant, the kinetic energy would be 1/2mv². As the fall continues, the potential energy would decrease while the kinetic energy would increase. When the object is about to reach the ground, h=0 and v will be the highest. Therefore, the kinetic energy would be the largest and potential energy the least. However, the sum of the potential energy and kinetic energy of the object would be the same at all points. That is potential energy + kinetic energy =constant or mgh+1/2mv²=constant The sum of kinetic energy and potential energy of an object is its total mechanical energy
  • 9. Rate of doing work • All of us do not work at the same rate. A stronger person will be able to do more work in a certain period of time than an ordinary person. We talk of cars and motorcycles in terms of power of engines. What is power? It measures the speed with which work is done. • Power is defined as the rate of doing work or rate of transfer of energy. If ‘W’ joule of work is done in ‘t’ seconds, power P = work done/time taken =w/t • The unit of power is watt. 1watt of the power machine or an agent that does work at the rate of 1joule per second. 1000watts = 1kilowatt 1000kilowatt =1 megawatt 1kw = 1000j sˉ¹ The power agent may vary with time. This means that the agent may be doing work at different rates at different intervals of time. Therefore the concept of average power is useful. We obtain average power by dividing the total energy consumed by the total time taken.
  • 10. Commercial unit of Energy • The unit joule is too small and hence is inconvenient to express large quantities of energy. We use bigger unit of energy called kilowatt hour (kW h). • Let us say we have a machine that uses 1000j of energy every second. If this machine is used continuously for one hour, it will consume 1kW of energy. Thus, 1kW h is the energy used in one hour at the rate of 1000j sˉ¹ (or 1kW). 1kW h =1kW *1h =1000W *3600s =3600000j 1kW h = 3.6 *10‘ j. • The energy used in households, industries, and commercial establishments are usually expressed in kilowatt hour. For example electrical energy used during a month is expressed in terms of ‘units’. Here, 1 unit means 1kilowatt hour.