Mechanical Advantage and Simple Machines

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Presentation transcript:

Mechanical Advantage and Simple Machines

Work Input and Output A machine is anything that transforms energy Work Input: the work/energy supplied to the machine Work Output: the work/energy that comes out of the machine

Law of Conservation of Energy Energy cannot be created or destroyed, just transformed from one form into another.

Work Input and Output The energy output of a process or machine can never exceed the energy input. Work In ≥ Work Out Some energy may be “lost” to friction This energy is released as heat, sound, etc.

Mechanical Advantage The ratio of output force to input force Input Force: The force you apply to the machine Output Force: The force the machine applies to the object you are trying to move

Mechanical Advantage MA > 1: The output force is greater than input MA < 1: The output force is less than input

Mechanical Advantage A machine uses an input force of 200. newtons to produce an output force of 800. newtons. What is the mechanical advantage of this machine? Another machine uses an input force of 200. newtons to produce an output force of 80.0 newtons. What is the mechanical advantage of this machine?

Mechanical Advantage A machine is required to produce an output force of 600 newtons. If the machine has a mechanical advantage of 6, what input force must be applied to the machine? A machine with a mechanical advantage of 10. is used to produce an output force of 250 newtons. What input force is applied to this machine? A machine with a mechanical advantage of 2.5 requires an input force of 120 newtons. What output force is produced by this machine?

Mechanical Advantage 200. Joules of work is put into a machine over a distance of 20. meters. The machine does 150. Joules of work as it lifts a load 10. meters high. What is the mechanical advantage of the machine?

Efficiency The ratio of output work (or energy) to input work (or energy) Similar to mechanical advantage, but with work instead of force Expressed as a percent or decimal Efficiency = work output / work input

Efficiency A car’s efficiency is only 13 percent. If the input work for the car is 200. joules, what is the output work? A simple machine produces 25 joules of output work for every 50 joules of input work. What is the efficiency of this machine?

Simple Machine An unpowered mechanical device that accomplishes a task with only one movement Simple machines are used to change the amount of force applied to an object HOW DO THEY DO THIS??????

W = Fd Simple Machine Work in = Work out When work is done over a… larger distance, there is a smaller force. smaller distance, there is a larger force.

The Lever

The Lever http://www.youtube.com/watch?v=25fW_98w-JY

The Lever a rigid bar that is free to turn about a fixed point called the fulcrum Every Lever has three (3) parts: 1. Input Arm (aka Effort Force) - The work done on the Lever. 2. Fulcrum – A fixed pivot point. 3. Output Arm (aka Resistance Force or Load) - What you are trying to move or lift.

The Lever

The Lever There are 3 classes of levers, distinguished by the location of the fulcrum with respect to the input and output forces.

1st Class Lever

1st Class Lever The Fulcrum (fixed pivot point) is located between the Effort (Input) and the Resistance (Output) Forces. The effort and the resistance move in opposite directions. The effort force pushes down in order to lift the resistance or load.

1st Class Lever When the fulcrum is closer to the effort than to the load (input arm < output arm): Output force is less than input Output speed/distance is more than input

1st Class Lever When the fulcrum is closer to the load than to the effort (input arm > output arm): Output force is greater than input Output speed/distance is less than input

1st Class Lever When the fulcrum is midway between the effort and the load (input arm = output arm): Input and output force, speed, and distance are equal

1st Class Lever Examples: Seesaw Crowbar Scissors https://www.youtube.com/watch?v=SLBdnpoKa3Y Mechanical Advantage can be less than, greater than, or equal to 1 depending on the ratio of the input and output arm length

2nd Class Levers

2nd Class Lever The load is between the effort and the fulcrum. The fulcrum is at one end of the lever. The fulcrum is usually closer to the load. Input arm is longer than output arm. Output force is greater than input force.

2nd Class Levers Examples: Wheelbarrow Bottle opener Citrus juicers Mechanical Advantage is greater than 1 since input arm is longer than output arm, so input force is less than output force

3rd Class Levers

3rd Class Levers The effort is between the load and the fulcrum. Output force is less than input force, Output speed/distance is greater than input speed/distance

3rd Class Levers Examples: Broom Shovel Fishing rod Mechanical Advantage is less than 1 since input arm is shorter than output arm, so input force is greater than output force

Types of Levers

Levers & Mechanical Advantage A lever used to lift a heavy box has an input arm of 4 meters and an output arm of 0.8 meters. What is the mechanical advantage of the lever? What is the mechanical advantage of a lever that has an input arm of 3.0 meters and an output arm of 2.0 meters?

The Inclined Plane (aka The Ramp)

The Inclined Plane a sloping surface that does not move An inclined plane provides for less effort, NOT less work. The trade off is greater distance to travel.

The Inclined Plane Used to reduce the force needed to overcome the force of gravity when lifting or lowering a heavy object.

The Inclined Plane

Ramps & Mechanical Advantage A 5.0-meter ramp lifts objects to a height of 0.75 meters. What is the mechanical advantage of the ramp? A 10.-meter long ramp has a mechanical advantage of 5.0. What is the height of the ramp? A ramp with a mechanical advantage of 8.0 lifts objects to a height of 1.5 meters. How long is the ramp?