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February 22, 2011. Define: (do not create a vocab. square) Machine Input force Output force. Machines . What is a machine? A device that allows you to do work in a way that is easier for more effective.
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February 22, 2011 Define: (do not create a vocab. square) Machine Input force Output force
Machines • What is a machine? • A device that allows you to do work in a way that is easier for more effective. • What are the machines that Mrs. Bradley is holding up? Can you come up with any more machines that we use everyday?
How Machines Do Work? • Machines work by changing at least one of three things: • Change the amount of force you have to exert to do the work • Change the distance over which you exert the force • Change the direction in which you exert the force
How Do Machines Work? • Why does changing one of those 3 things make work easier? • To understand that, we have to look at input and output force. • Input force is the amount of force you have to put into a machine to get the work that you want. • Output force is the amount of force you get out of the machine.
How Machines Do Work? • Remember that force has two components, strength and direction. • When you put force into a machine you are putting in the force of a certain strength in a certain direction. • The output force of the machine will not be the same as the input force in either strength, direction, or both. • Why is changing the amount or direction of a force helpful?
How Do Machine’s Work? • Look at Mrs. Bradley’s demonstration and see if you can figure out why you might want to change the force strength or direction to do work. • When the machine that Mrs. Bradley created with the pencil and string changed the direction of her force, it actually increased the amount of force needed, so why would it still be helpful?
How Do Machines Work? • Sometimes, as in Mrs. Bradley’s machine, the most important thing is to change the direction. • Imagine trying to move a very large object. Would it be easier to pull up on the object or pull down on a string that then pulled up on the object for you? • Most of the time it is easier to pull down than up.
How Do Machines Work? • Let’s review: • A machine makes work easier or more effective. • Machines work by either changing the amount of force, the direction or the force, or the distance of the force. • For example, when you use a shovel, it takes a larger force over a short distance and changes it to a smaller force over a large distance which allows you to move the dirt. • See figure 7 on page 413.
Exit Slip – (2 people per group) • Using the magazines provided – find and cut out several pictures (3 to 5) of machines. • Glue them onto a piece of copier paper. • Label the input and the output force for each machine. • Turn in before leaving. • Make sure both of your names are on it.
February 23, 2011 • Define (no vocab. Square): • Input work • Output work • Mechanical Advantage
How Machines do work • Remember, work is the force times the distance, so: • Input work is the input force times the input distance and • Output work is the output force times the output distance.
How Machines Do Work • Remember, machines will either increase the input force, change the direction of the input force or change the distance of the input force. • Now lets look at the overhead to see the ways machines make work easier.
Mechanical Advantage • A machine’s mechanical advantage is how many times the machine increases the force exerted on it. • When we exert a force on a machine, it is very helpful when that machine is able to increase our force – it makes the work easier. • To calculate Mechanical Advantage – you have to divide the output force by the input force.
Calculate Mechanical Advantage • Mechanical Advantage = Output force Input force A machine that increases force will have a larger mechanical advantage than a machine that increases distance but not force. A machine that only changes direction should always have a mech. adv. = 1
Calculate Mechanical Advantage • Increasing force – • Output force = 30N • Input force = 10N • Mechanical Advantage = 30N/10N = 3 • Increasing Distance – • Output force = 10N • Input force = 20N • Mechanical Advantage = 10N/20N = 0.5 • Note: a mech. adv. less than one is still useful
Efficiency of Machines • Do we get out of machines everything that we put into them or is something lost along the way? • Efficiency compares the output work to the input work. • Normally, in the real world, the output work is less than the input work because some work is lost to friction. • Efficiency is always expressed as a percent
Real vs. Ideal Machines • Machines with an efficiency of 100% would be Ideal machines. • No machines exist in the real world due to friction. • A machine’s Ideal mechanical advantage would be its mechanical advantage with an efficiency of 100%. • A machine’s actual mechanical advantage is its measured mechanical advantage.
Exit Slip • In your notebooks, do the section assessment questions on page 419. Do not do the math practice square b/c we should have already done those in class. • Show me your questions before you leave today. • We will go over them if we have time.