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Transcript
Simple Machines 2.notebook January 12, 2016 Work and Energy Work, Power, and Machines 1 Simple Machines 2.notebook January 12, 2016 Imagine trying to lift a car without a jack You might be exerting a lot of force, but not moving the It would feel like you have done a lot of work...but you have actually done NONE 2 Simple Machines 2.notebook January 12, 2016 In science, is done only when a force causes a change in the position or motion of an object work = force x distance So what are the units we measure work in? 3 Simple Machines 2.notebook January 12, 2016 Work is measured in a unit called 1 J = 1 Nm = 1 kgm Imagine a father playing with his daughter by lifting her repeatedly in the air. How much work does he do with each 4 Simple Machines 2.notebook January 12, 2016 Imagine walking up a flight of stairs vs. running up a Which is more exhausting? 5 Simple Machines 2.notebook January 12, 2016 The amount of time it takes to do work is an important factor measures work in relation to time power = work/time 6 Simple Machines 2.notebook January 12, 2016 So what are our units for power? Joules/second = Watt watt (W) is the amount of power required to do 1 J of This is about how much power you would need to lift an apple over your head in 1 second 746 watts = 1 horsepower 7 Simple Machines 2.notebook January 12, 2016 It takes 100kJ of work to lift an elevator 18 m. If this is done in 20 seconds, what is the average power of the elevator during this process? 8 Simple Machines 2.notebook January 12, 2016 Which is easier...lifting a car with a jack, or by yourself? 9 Simple Machines 2.notebook January 12, 2016 Compare the amount of work required to lift a fourwheeler straight up onto the bed of a pickup, with the amount of work required to push the same four- The ramp allows you to apply a larger distance, but the work done is the same 10 Simple Machines 2.notebook January 12, 2016 allow us to do the same amount of work by the distance while 11 Simple Machines 2.notebook January 12, 2016 mechanical advantage a machine describes how mechanical advantage = input distance input force 12 Simple Machines 2.notebook January 12, 2016 A machine with a mechanical advantage greater than 1 multiplies the input force force, but increases distance and speed 13 Simple Machines 2.notebook January 12, 2016 Calculate the mechanical advantage of a ramp that is 5.0 meters long and 1.5 meters high 14 Simple Machines 2.notebook January 12, 2016 Simple Machines 15 Simple Machines 2.notebook January 12, 2016 Simple Machines are the most basic machines Other machines are modifications or combinations There are two "families" of simple machines: 16 Simple Machines 2.notebook January 12, 2016 The Lever Family Levers are divided into three classes: 1st, 2nd, and 3rd Class All levers have a rigid point called the fulcrum that pivots around a 17 Simple Machines 2.notebook January 12, 2016 have a fulcrum located between the input and output forces Examples: Seesaw, hammer 18 Simple Machines 2.notebook January 12, 2016 the arm and the input force is applied at the other Examples: Wheelbarrow, two wheel cart (dolly) 19 Simple Machines 2.notebook January 12, 2016 Third-Class Levers have a fulcrum at one end with the output force on the other end. The multiply distance rather than force. Therefore have a mechanical advantage of less than 1 Examples: Forearm, Shovel 20 Simple Machines 2.notebook January 12, 2016 Pulleys are modified levers because the pulley itself is like the fulcrum of a lever A single fixed pully has a mechanical advantage of 1. All it does it change the direction of the 21 Simple Machines 2.notebook January 12, 2016 A single movable pulley has a mechanical advantage of 2 Therefore you can lift a 100 pounds with only exerting 22 Simple Machines 2.notebook January 12, 2016 Multiple pulleys can be used to get even higher mechanical advantages When multiple pulleys are put together in a single unit it is called a 23 Simple Machines 2.notebook January 12, 2016 wheel and axle is a lever or pulley connected to a shaft A small input force can be applied and the force is multiplied to become a large output force on the shaft Steering wheel, screwdrivers, cranks 24 Simple Machines 2.notebook January 12, 2016 The Inclined Plane Family In inclined plane is basically a ramp The input force is parallel to the ramp object off the ground Output Force 25 Simple Machines 2.notebook January 12, 2016 Remember, incline planes work by spreading the work out over a larger distance, which decreases the force required! 26 Simple Machines 2.notebook January 12, 2016 is a modified inclined plane A wedge is two incline planes placed back to back The wedge turns a single downward force into two forces directed out to the sides Examples: Axe, nail 27 Simple Machines 2.notebook January 12, 2016 is an inclined plane wrapped around a cylinder The steeper the threads, the ore force required to Examples: Screws, jar lids, spiral staircase 28 Simple Machines 2.notebook January 12, 2016 combines two or more simple machines A scissor: Uses two first class levers joined at a single fulcrum AND a wedge that cuts into the paper Bicycle: Wheel and axle, levers 29 Simple Machines 2.notebook January 12, 2016 What is Energy? 30 Simple Machines 2.notebook January 12, 2016 Remember, work is only done when an object experiences a change in its position or motion However, energy can be present in an object when is the ability to do work Energy and work are both expressed in units of 31 Simple Machines 2.notebook January 12, 2016 A stretched rubber band (say on a slingshot) has stored energy Potential Energy Often called "energy of position" Think of an apple hanging form a tree...the energy that could potentially do work on the apple results from its position above the ground This is called gravitational potential energy 32 Simple Machines 2.notebook January 12, 2016 The equation to calculate gravitational potential energy is: Potential energy = mass x free fall acceleration x height PE = mgh This means that potential energy is dependent on mass and height 33 Simple Machines 2.notebook January 12, 2016 A 65 kg rock climber ascends a cliff. What is the climber's gravitational potential energy at a point 35 m above the base of the cliff? 34 Simple Machines 2.notebook January 12, 2016 is the energy an object has because of its motion starts to fall it gains kinetic energy 35 Simple Machines 2.notebook January 12, 2016 The equation for calculating kinetic energy is: Kinetic energy = 1/2 x mass x speed squared kinetic energy? 36 Simple Machines 2.notebook January 12, 2016 What is the kinetic energy of a 44 kg cheetah running 37 Simple Machines 2.notebook January 12, 2016 The sum of potential energy and kinetic energy is mechanical energy Are there any other forms of energy? We eat it for energy right? 38 Simple Machines 2.notebook January 12, 2016 Energy that does not affect the motion of an object is nonmechanical energy Atoms and molecules have kinetic energy because they are moving on an atomic scale Chemical reactions involve potential energy - Chemical bonds store energy 39
