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Work and Power Work is done if (1) an object moves, and (2) if a force acts in the same direction that the object moves. Work = Force times distance W = (F)(d) Work is measured in units called Joules (J). Time is not important when you’re measuring work. The same amount of work is done whether you do it slowly or quickly. Power measures how fast you can do work. Power = Work divided by time P = W / t Another formula used to calculate power is: P = (F)(d) / t
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Work, Machines, and Energy
Work and PowerWork is done if (1) an object
moves, and (2) if a force acts in the same direction that the object moves.
Work = Force times distance W = (F)(d)
Work is measured in units called Joules (J).
Time is not important when you’re measuring work. The same amount of work is done whether you do it slowly or quickly.
Power measures how fast you can do work.
Power = Work divided by time P = W / t
Another formula used to calculate power is:
P = (F)(d) / t
Simple Machines
• A machine is a device that helps make work easier to perform by accomplishing one or more of the following functions:
• Increase the size of the force; OR• Change the direction of the force; OR• Change the distance over which the force is exerted.
3
Work and MachinesA machine is a device that makes
work easier. It does not let you do less work.
When you use a machine, two works are done! The work you do to the machine is called input work, and the work the machine does to the resistance is called output work.
The force you use on the machine is the effort force, and the distance you move is the effort distance.
The weight of the object being moved is the resistance force, and the distance the object moves is the resistance distance.
Work input = effort force times effort distance. Wi = (Fe)(de)
Work output = resistance force times resistance distance.
Wo= (Fr)(dr)
Mechanical EfficiencyMachines make it easier to do
work, but you always put more work into a machine than you get out of it!
This is because some work is used to overcome friction!
Mechanical efficiency of a machine is always less than 100% because of friction.
Even though it’s easier to cut the wood with the saw than without it, the worker does more work using the saw than he would have done without it.
M.E. = work output x 100% work input
Mechanical AdvantageMechanical advantage tells how many times a machine
multiplies your effort force.Mechanical advantage can also change the direction of your
effort force.You can find the mechanical advantage of any simple machine
by dividing the resistance force by the effort force.Some simple machines have other formulas that can also be
used to find M.A.
M.A. = resistance force
effort force
Simple Machines: Inclined PlaneSimple machines do work
with one movement. There are six kinds of
simple machines: inclined plane, wedge, screw, lever, wheel and axle, and pulley.
An inclined plane is a ramp. You use less force to pull
something heavy up a ramp than you would use if you tried to lift it.
An inclined plane does not make you do less work. It lets you use less effort force, but you have to move a greater distance!
Simple Machines: Wedge and ScrewA wedge is an inclined plane
that can move. An axe is a wedge, and so is a
chisel, a knife, or a wood plane. The effort force used to split wood is great. When you use a wedge, you use less effort force, but move a greater distance.
A screw is an inclined plane that is turned in a circle. Car jacks are screws.
You turn a jack handle many times to lift the car a small amount, but the force you need to turn the handle is much less than would be needed to lift the car yourself!
Simple Machines - Levers IMachines that do work by
moving around a fixed point are called levers.
There are three classes of levers, depending on the location of the fulcrum, effort force, and resistance force.
The balance point of a lever is called the fulcrum.
The mechanical advantage of a lever = __effort arm length__
resistance arm length
Resistance Arm
Fulcrum
Effort Arm
Simple Machines - Levers IIThe fulcrum is between the effort
force and the resistance force in a first class lever.
The effort force is between the fulcrum and the resistance force in a third class lever.
The resistance force is between the effort force and the fulcrum in a second class lever.
First Class LeverFulcrum
Resistance
Effort
Second Class Lever
Fulcrum
ResistanceEffort
Third Class Lever
Resistance
Effort Fulcrum
Simple Machines - Wheel and AxleA wheel and axle
consists of two circular objects that share the same center.
The larger circle is the wheel and the smaller circle is the axle.
A wheel and axle is conceded to be a modified lever. (see pulleys)
The mechanical advantage of a wheel and axle is the radius of the wheel divided by the radius of the axle.
M.A. = radius of wheel radius of axle
Wheel
Axle
Simple Machines - PulleysA pulley is a rope wrapped
around a grooved wheel.
The two main types of pulleys are fixed pulleys and moveable pulleys. Together they make a system called a block and tackle.
To find the mechanical advantage of a pulley system, count the ropes that support the resistance!
Pulleys and Levers
• Pulleys actually act as modified first class levers because the wheel and axle act as a fulcrum. Below is a block and tackle
Energy and Its FormsEnergy can be converted from one form to another.The five main forms of energy are:
Heat
Chemical
Nuclear
Electromagnetic (electrical, magnetic, light)
Mechanical
Transferring Heat Energy
• 3 Ways:• Conduction – Through touch• Convection – mixing fluids (liquids or gases) at different
temperatures • Radiation – can transfer heat through empty space (doesn’t need a
medium like air)
Conductors and Insulators
• Conductors permit the transfer of heat or electricity (metal is an example)
• Insulators prevent the transfer of heat or electricity (glass is an example)