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Work

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Title: Work


1
Chapter 5
  • Work
  • and
  • Energy

2
WORK
  • Work is the energy transferred into or out of a
    system through the action of a force.
  • Work is the change in energy of a system from the
    application of a force acting over a distance.
  • Work is the product of the magnitudes of the
    component of a force along the direction of
    displacement and the displacement.
  • Work Force ? Distance
  • Units Newton?meters (N?m) or Joules (J)
  • 1 N?m 1 J
  • 1 J 0.7376 ft?lb (U.S. Customary Units)
  • 1 ft?lb 1.356 J

3
WORK
  • At the heart of the concept of work is the notion
    of movement against resistance (gravity,
    friction, inertia, etc.)
  • Consider the following
  • A student holds a heavy weight at arms length for
    several minutes.
  • A student carries a heavy weight along a
    horizontal path while walking at a constant
    velocity.
  • Which student did work?

4
WORK
  • As long as the object moves along the
    line-of-action of the force while the force acts
    on it, work is being done.
  • Example
  • A man sitting on a sheet of plastic is pulled a
    distance of 2.0 m along a smooth floor by a woman
    exerting a force of 20 N, how much work is done?

5
WORK
  • Positive work is done on an object when the point
    of application of the force moves in the
    direction of the force.
  • Negative work is done on an object when the point
    of application of the force moves in the opposite
    direction of the force.
  • Example
  • Raise a 100-kg barbell into the air against the
    downward weight and you do positive work.
  • Lower the barbell to the floor and you have done
    negative work.

6
WORK
  • The sign of work is important because it will
    tell you whether the object is speeding up or
    slowing down.
  • If the net work is positive, the object is
    speeding up and the net force does work on the
    object.
  • If the net force is negative, the object slows
    down and work is done by the object on another
    object.

7
WORK
  • Example
  • A locomotive exerts a constant forwardly directed
    force of 400 kN on a train that it pulls for 500
    m along a straight run. How much work does the
    engine do on the train?

8
WORK
  • Example
  • Coming toward a station, the locomotive in the
    previous example slows the train, applying a
    constant force of 100 kN in the opposite
    direction. How much work does it then do on the
    train over a distance of 1000 m?

9
WORK
  • Imagine an object being pulled along by a person
    tugging on a rope that makes an angle (?) with
    the direction of motion.
  • Part of the force acts upward tending to lift the
    object and lessen the load, and part acts in the
    direction of the motion and does work.
  • The force is a vector it has two perpendicular
    components, one vertical (F sin ?) and the other
    horizontal (F cos ?).

10
WORK
  • Work can only be done by a force if it is applied
    to an object that subsequently begins to move or
    is already moving.
  • The work done on a body by a constant applied
    force is the product of the component of the
    force in the direction of the motion multiplied
    by the distance over which it acts.
  • Work (F cos ?)d

11
WORK
  • Example
  • A man sitting on a sheet of plastic is pulled a
    distance of 2.0 m along a smooth floor by a woman
    exerting a force of 20 N at an angle of 30?, how
    much work is done?

12
WORK
  • Example
  • A truck is dragging a stalled car up a 20?
    incline. The tensile force on the towline is
    constant, and the two vehicles accelerate at a
    constant rate. If the cable makes an angle of 30?
    with the road and the tension is 1600 N, how much
    work was done by the truck on the car in pulling
    it 0.50 km up the incline?

13
WORK
  • Example
  • How much work is done on a vacuum cleaner pulled
    3.0 m by a force of 50.0 N at an angle of 30.0?
    above the horizontal?

14
WORK
  • In general, work is done to overcome some force,
    and one of the most common situations involves
    simply raising a mass against gravity.
  • The work done against gravity can be calculated
    by the following equation
  • Work Weight ? height mgh

15
WORK
  • Example
  • A rigid 1.0 kg block is raised at a constant
    speed through a vertical distance of 2.0 m at the
    Earths surface. Determine the work done on the
    block by the hand in overcoming gravity.

16
WORK
  • Think about an object being pushed at a constant
    speed in a straight line along the floor by an
    applied force.
  • Because the object is not accelerating, the sum
    of the forces must be zero and F must be equal in
    magnitude and opposite in direction to the force
    of kinetic friction (Fk).
  • Since the force of kinetic friction is constant,
    the work done in overcoming kinetic friction is
  • Work Fkd ?kFnd

17
WORK
  • Example
  • A youngster weighing 250 N is sitting on the
    grass holding on to a large dog via a leash
    stretched horizontally. The dog pulls on the
    leash with a force of 100 N and drags the kid at
    a constant speed 20 m straight across the yard
    and then stops. How much work did the dog do on
    the child and the ground in overcoming kinetic
    friction?

18
WORK
  • Example
  • A locked car weighing 6.0 kN has its parking
    brake on. The coefficient of kinetic friction for
    rubber on concrete is 1.
  • What will be the value of the friction force on
    the car once it is set in motion?
  • What force must be exerted horizontally to slide
    the car at a slow constant speed?
  • How much work will be expended in pushing the
    car, very slowly, 10.0 m horizontally?

19
ENERGY
  • What is energy?
  • The nontechnical usage derives from the Greek en
    (which means in) and ergon (which means work).
  • Energy is the capacity to do work.
  • In very general terms, energy describes the state
    of a system in relation to the action of the four
    forces.
  • It is a property of all matter and is observed
    indirectly through changes in speed, mass,
    position, and so forth.

20
ENERGY
  • Force is the agent of change energy is a measure
    of change.
  • Energy is the measure of the change that has
    occurred, and the change that is yet to occur.
  • Energy is a scalar quantity associated in various
    amounts with all the things that exist.
  • Energy is not an entity in and of itself there
    is no such thing as pure energy.
  • There cannot be energy without matter.

21
ENERGY
  • We call the energy that is associated with
    motion, Kinetic Energy (KE).
  • Under the influence of a net force (?0), a body
    accelerates as positive work is done on it to
    overcome inertia.
  • It increases its speed and gains kinetic energy
    in the process.
  • Kinetic energy of any object is equal to
  • KE ½ mv2

22
ENERGY
  • Since energy is the ability to do work, we can
    relate energy and work together by the following
    equation
  • Work ?KE
  • Work KEfinal - KEinitial
  • Units for energy are the same as the units for
    work, Joules (J).
  • All forms of energy will be measured in joules.

23
ENERGY
  • Example
  • A Boeing 747 airliner, weighing 2.2 ? 106 N at
    takeoff, is cruising at a ground speed of 268
    m/s. Compute its kinetic energy.

24
ENERGY
  • Example
  • If 1 kg of TNT yields 4.6 ? 106 J, how much TNT
    is the planes KE equivalent to?
  • The atom bomb dropped on Hiroshima in 1945
    delivered the energy of about 12.5 kilotons of
    TNT, where 1 kiloton 4 ? 1012 J.

25
ENERGY
  • Example
  • How much KE does a person have if they have a
    mass of 70 kg and a velocity of 8 m/s?
  • A 7.00 kg bowling ball moves at 3.0 m/s. How much
    KE does the bowling ball have?
  • How fast must a 2.45 g ping-pong ball move in
    order to have the same KE?

26
ENERGY
  • Example
  • According to the record books, Aleksandr Zass
    (known to his admirers as Samson) would catch a
    104 lb woman fired from a cannon at around 45
    mph. Assuming that Samson brought her to rest
    uniformly in a distance of 1.00 m, compute the
    average force he exerted on our heroine. As a
    guess, take her landing speed to be 8.94 m/s.

27
ENERGY
  • Another type of energy is Gravitational Potential
    Energy (GPE).
  • GPE is the energy associated with an object due
    to its position relative to the Earth or some
    other gravitational source.
  • GPE mgh
  • Units Joules
  • Since GPE is a result of an objects position, it
    must be measured relative to some zero level.
  • When dealing with GPE, only vertical height is
    important.
  • The work done raising a mass equals the increase
    in its potential energy.

28
ENERGY
  • Example
  • A flagpole painter is carrying a 2.00 kg can of
    white paint. She has climbed 10.0 m up the pole
    from its base, where she just finished having
    lunch on the roof of a 30.0 m tall tower. What is
    the increase in GPE of the can as a result of her
    climbing the pole? What is the total increase in
    the cans GPE above the value it had while it sat
    on the ground?

29
ENERGY
  • Example
  • What is the GPE of a 6.00 kg ball that is located
    0.5 m above the floor?
  • What is the change in GPE of a 50.0 kg person who
    climbs a flight of stairs with a height of 3.0 m
    and a horizontal extent of 5.0 m?

30
ENERGY
  • Another type of energy is Mechanical Energy (ME).
  • ME is the sum of kinetic energy and all forms of
    potential energy.
  • ME KE GPE
  • Units Joules
  • Law of Conservation of Energy maintains that
    energy can be transformed, but it can neither be
    created or destroyed.

31
ENERGY
  • Consider the following
  • A ball being tossed into the air
  • As the ball rises, what happens to its KE?
  • Where does the KE go?
  • As the ball returns to Earth, what happens to its
    KE?
  • What happens to the ME during the entire trip?
  • At every instant in the motion, the total
    mechanical energy is constant if the bodys KE
    increases, its GPE must decrease and vice-versa.

32
ENERGY
  • Example
  • If we release a pendulum bob with a mass of 1.0
    kg from a height of 1.0 m, what is the pendulums
    GPE before it is released?
  • What is its ME?
  • What is the pendulums KE at the bottom of its
    swing?

33
ENERGY
  • Example
  • Starting from rest, a child zooms down a
    frictionless slide with an initial height of 3.00
    m. What is her speed at the bottom of the slide?
    Assume that she has a mass of 25.0 kg.

34
ENERGY
  • Example
  • A vaulter carrying a graphite-fiberglass pole is
    about to make a jump. At what speed must he run
    in order to clear the 20.0 ft mark? Neglect all
    possible energy losses, take his center to be
    1.00 m above the floor while standing, and
    presume that he just clears the bar?

35
ENERGY
  • Example
  • A 60 kg skier starts from rest at the top of a 60
    m high slope. She descends without using her
    poles. What is her GPE with respect to the level
    ground at the bottom? Assume friction is
    negligible and compute at what speed she will
    ideally arrive at the bottom.
  • Now if she reaches the bottom of the run,
    traveling 25 m/s, what is the net energy
    transferred via friction (i.e. lost to warming
    her, the skis, the slope, and the air)?

36
power
  • Power is the rate at which energy is transferred
    into or out of a system.
  • Power ?Work/?Time
  • P ?W/?t
  • James Watt found that a large draft horse could
    exert a pull of about 150 lbs while walking at
    about 2.5 mph for a considerable amount of time.
  • That rate is equivalent to 33 000 ft?lbs per
    minute or 550 ft?lb/sec, which is called 1
    horsepower (hp).
  • In SI, the unit of power is the watt (W), equal
    to 1 joule of work done per 1 second (1 W 1
    J/s).
  • Since a watt is a fairly small amount of power,
    the more convenient kilowatt (1000 watts) is used.

37
power
  • Example
  • The express elevator in the Sears Tower in
    Chicago averages a speed of 9.144 m/s in its
    climb to the 103rd floor, 408.4 m above the
    ground. Assuming a load of 1.0 ? 103 kg, what
    average power must the lifting motor supply?

38
power
  • When a constant force acts on a body that, in the
    process, moves through a distance, an amount of
    work is done (W Fcos? d).
  • If this occurs in a time interval,
  • Power (Fcos?)(d/t)
  • P (Fcos?)vav
  • The power delivered to a moving object equals the
    product of the component of the force in the
    direction of the motion and the speed.

39
power
  • Example
  • In 1935, R.H. Goddard, the American rocket
    pioneer, launched several S-series sounding
    rockets. Given that the engine had a constant
    thrust of 889.6 N, how much power did is transfer
    to the rocket while traveling at its maximum
    speed of 1130 km/hr?

40
power
  • This makes it clear that exerting the same force
    on an object thats moving increasingly rapidly
    requires the application of a proportionately
    greater amount of power.
  • Its easy to accelerate when jogging at 1 mph,
    but its a lot harder to attain the same
    acceleration when youre already running at 10
    mph.

41
power
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