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Published byBlake Simon Cain Modified over 8 years ago
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Mechanical Systems
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Topic 2.2 - Work
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So what is “work” Work is done when a force acts on an object to make the object move Work Bat hits ball Bat does work on ball
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So here is a scenario … Is work happening in this picture? Work Cont …
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So to calculate this … W = Work N.m (Newton meters) F = Force N (Newtons) D = Distance m (Meters) This is your money maker right here Calculating Work W F d
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A “Newton meter” is also referred to a Joule What is a joule? It was discovered by James Joule Work Marvel at my beard! You are welcome world!
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Energy and work are closely related Back to bikes … When you push the pedals you exert a force on them The chain ( linkage ) transfers the force to the wheels Your energy is used to provide the force that drives the pedals that move the wheels Work is being done because the force you apply to the pedals causes the bike to move Energy & Work
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Does using a machine mean less work is done? you You use the machine so you do not have to exert as much force BUT … the same amount of work is being done! Let us test this theory! Work & Machines
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Ok this picture as no point … just funny to me! Let us use this one … See Sec 2.2 Work w Machines
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The work done with a machine is the same as the work done without it This can be shown by calculating work input and work output Work & Machines
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Work input is the work needed to use, or operate, the machine Work input = Force input x d input Work output is the work done by the machine Work output = Force output x d output Efficiency = Work output x 100 Work input Work & Machines
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Topic 2.3 Hydraulics
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Most machines that move very large, very heavy objects use a hydraulic system that applies force to levers, gears or pulleys A hydraulic system uses a liquid under pressure to move loads It is able to increase the mechanical advantage of the levers in the machine Hydraulics
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Modern construction projects use hydraulic equipment because the work can be done quicker and safer There are many practical applications of hydraulic systems that perform tasks, which makes work much easier. Hydraulics
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A hydraulic lift is used to move a car above the ground, so a mechanic can work underneath it. Lifts
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Pressure is a measure of the amount of force applied to a given area p = F / A p is pressure A is Area F is Force The unit of measurement for pressure is a pascal (Pa), named after Blaise Pascal who did important research on fluids 1 Pascal is equal to the force of 1 Newton over an area of 1 m2 Pressure & Pascals
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Some Key Quick Facts … 1 Pascal or 1N over an area of 1m 2 is a very small amount of force To counter this we typically use 1 Kilopascal where kilo = 1000 Also, for smaller forces, we can also use 1 N over 1 cm 2 Pressure & Pascals
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Pascal discovered that pressure applied to an enclosed fluid is transmitted equally in all directions throughout the fluid This is known as Pascal’s Law and it makes hydraulic (liquid) and pneumatic (air) systems possible A common application of Pascal’s law is illustrated with the hydraulic jack. Pressure & Pascals
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In hydraulic systems, the pressure is created using a piston Pistons can be different sizes and hydraulic devices use pistons that are different sizes attached to each other with a flexible pipe The Input Piston is used to apply force to the fluid, which creates pressure in the fluid The fluid transfers this pressure to the output piston This pressure exerts a force on the output piston and the result is a mechanical advantage that makes the hydraulic system very useful Pistons & Pressure
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The mechanical advantage in a hydraulic system comes from the fluid pressure in the system Using the input force and the output force will give you the Mechanical Advantage of the system MA = Output force / Input force MA = 500N / 25N MA = 20 Mechanical advantages in hydraulic systems are usually quite high, showing how useful they are. MA In Hydraulics F in = 25N F out = 500N
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The reason for the large mechanical advantage in a hydraulic system is the ability of the fluid to transmit pressure equally It allows you to use a small force on the small piston to produce a larger force on the large piston p = F / A p = 20N / 4cm 2 p = 5N/cm2 MA & Pressure
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From Pascal’s law, we know that the pressure the small piston creates is the same everywhere in the fluid So the large piston has a larger area and is able to multiply the pressure because of its larger area The force and area at each piston act as ratios that have to be equal. Pressure & Pascals
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Force of the small piston Force of the large piston = Area of the small piston Area of the large piston F in = 20N F out = X? A in = 4cm 2 A out = 100cm 2
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By solving this ratio you will find that the forces created within a hydraulic system provides very large mechanical advantages - making them useful in many applications. Ratios & Pressure
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Mechanical advantage in hydraulic systems has a cost What would that cost be? That cost is the increased distance The smaller force must go through to make the large force move a small distance Need More Force?
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Imagine you had to build a robot. You decide, as the genius designers you are, that your robot will have hydraulic arms! The kicker … it needs to help around the house. Chore-Bot 5000 What could your robot accomplish with hydraulic arms vs. non-hydraulic arms? Robot Fun
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