CHAPTER 10 WORK, ENERGY, AND POWER. STANDARDS SP3. Students will evaluate the forms and transformations of energy. a. Analyze, evaluate, and apply the.

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Presentation transcript:

CHAPTER 10 WORK, ENERGY, AND POWER

STANDARDS SP3. Students will evaluate the forms and transformations of energy. a. Analyze, evaluate, and apply the principle of conservation of energy and measure the components of work-energy theorem by describing total energy in a closed system. identifying different types of potential energy. calculating kinetic energy given mass and velocity. relating transformations between potential and kinetic energy. g. Analyze and measure power.

WHAT IS WORK? Simple form: work = force  distance W = F · d Work can be done by you, as well as on you Are you the pusher or the pushee? Work is a measure of expended energy Work makes you tired Unit of work: Joules (j) Work is a scalar quantity

WORK DEPENDS ON The amount of force applied to the object. The distance that the object moves while the force is applied. The direction of the force with respect to the direction the object moves.

CALCULATING WORK If the force on the object is in the direction the object moves, the work done is: W= f x d F d

CALCULATING WORK If the direction of the force is opposite the direction the object moves, work is: W = - f x d F d

CALCULATING WORK Work can be positive or negative Man does positive work lifting box Man does negative work lowering box Gravity does positive work when box lowers Gravity does negative work when box is raised

FORCE AND WORK Force and Work do not mean the same thing If the force is perpendicular to the direction the object moves, the work done is 0. If the object doesn’t move, the work done is 0. W = 0 F d

EXAMPLE A person pushes a car with a 110 N force for a distance of 30 m. How much work was done? W = f x d W = 110 N x 30m W = 3300 Nm or 3300 j

WHAT IF THERE IS AN ANGLE? Sometimes there is an angle between force and displacement The equation becomes: W = f x d x cosθ

ANGLE AND WORK Same amount of work, however the force needed is greater

WHAT IS POWER? Power is energy exchanged per unit of time How fast you get work done Power = work over time W P t

UNITS OF POWER Units of power: 1 Joule/sec = 1 Watt 1000 Watts = 1 kilowatt Power is a scalar quantity. 1 horsepower = 746 watts

EXAMPLE The minimum work required to raise a 800 N person up 10 m, is: W = F x d W = (800 N) (10 m) = 8000 J If this work is done in 60 sec, then what is the power? W P = t 8000 J = 60 sec J sec = 133= 133 watts

EXAMPLE A ‘Big Mac’ contains about 2,000,000 J of chemical energy. If all this energy could be used to power a 60 watt light bulb, how long could it run? E P = t E P t = 2,000,000 J 60 watt = t = 33,000 J J/sec t = 33,000 sec( ~ 9 hr )

WHAT IS ENERGY? Energy is the capacity to do work Two main categories of energy Kinetic Energy: Energy of motion Potential Energy: Stored (latent) capacity to do work Energy can be converted between types

KINETIC ENERGY Energy of motion An object’s kinetic energy depends on: the object’s mass. Kinetic energy is directly proportional to mass. the object’s speed. Kinetic energy is directly proportional to the square of the object’s speed.

WORK-ENERGY THEOREM Work is equal to the change in kinetic energy. W =  KE

KINETIC ENERGY Kinetic energy is a scalar quantity. Common units of kinetic energy: Joules

What is the KE of 100 kg of water moving at 1.2 m/sec? K E = 72 ( kg m )/s 22 K E = 72 J K E = mv K E = ( 100 kg ) ( 1.2 m/s ) K E = ( 100 kg ) ( 1.44 m /s ) EXAMPLE

STOPPING DISTANCE Kinetic energy becomes important in calculating braking distance.

EXAMPLE A car with a mass of 1,300 kg is going straight ahead at a speed of 30 m/sec (67 mph). The brakes can supply a force of 9,500 N. Calculate: a) The kinetic energy of the car. b) The distance it takes to stop.

EXAMPLE Kinetic energy KE = 1/2 mv 2 KE = (1/2)(1,300 kg)(30 m/sec) 2 KE = 585,000 J To stop the car, the kinetic energy must be reduced to zero by work done by the brakes. Work, W = Fd 585,000 J = (9,500 N) × d d = 62 meters

POTENTIAL ENERGY Sometimes work is not converted directly into kinetic energy. Instead it is “stored”, or “hidden”. Potential energy is stored energy or stored work. Potential energy is energy that an object (system) has due to its position or arrangement.

GRAVITATIONAL POTENTIAL ENERGY Potential energy that is dependent on mass, height, and acceleration due to gravity Essentially this is work done against gravity GPE = mgh

EXAMPLE A cart with a mass of 102 kg is pushed up a ramp. The top of the ramp is 4 meters higher than the bottom. How much potential energy is gained by the cart? If an average student can do 50 joules of work each second, how much time does it take to get up the ramp?

EXAMPLE, CONT Use the formula for potential energy PE = mgh. PE = (102 kg)(9.8 N/kg)(4 m) PE = 3,998 J At a rate of 50 J/sec, it takes: 3,998 ÷ seconds to push the cart up the ramp.

RELATIONSHIP OF PE AND KE