Transcript File
Use the force! • Try to move the book in front of you by only using your mind! • Do the books obey your will? Q: What would be required to actually move the book? Force • What is force? – Push or Pull • It’s what causes “things” to accelerate 1000 kg Velocity & Acceleration Review Dis tance [m] Velocity Time [ s] D T V V AT Velocity [m] Acceleration 2 Time [ s ] V AT Force Velocity [m] Acceleration 2 Time [ s ] What is Mass? Force mass acceleration [kg m] N 2 [s ] Newton is the unit of measurement for Force Q: What is Mass? • A: Mass is the amount of Matter – or “stuff” an object has. – Stuff is made up of all of the atoms within the object. Objects with mass don’t just suddenly start moving by themselves An object with mass takes effort to move! If it’s already moving, it takes effort to stop it from moving! We call this resistance to change: “Inertia” Question • What would happen to our rate of acceleration if we increase mass? F=M*A How Mass Affects Acceleration With NO Mass Positive Acceleration Negative Acceleration With More Mass Velocity Acceleration Properties of Mass • Mass has inertia – Inertia: Resistance to the push / pull, or Change of Motion • Newton’s 1st Law of Motion: – once in motion an object stays in _______ - unless acted upon by another _______. – An object at rest stays at ______ – unless acted upon by another _______. Property of Mass F=M*A Push/Pull = Object w/ Matter * Faster/Slower Inertia is why an object with more mass resists the pushing of the force. Resistance Inertia Inertia: What does this mean? An object which is resting – or not going anywhere – doesn’t want to move, or go anywhere. It wants to stay put. It isn’t going to start moving on its own. In order to get it moving, I have to “push” it. 1000 kg An object at rest Inertia: What does this mean? An object In Motion An object which is moving doesn’t want to stop. It wants to keep moving. In order for it to stop, I have to “push” against it. (Usually, friction does a pretty good job of doing that. Imagine a large hockey puck on ice) Inertia Inertia is also resistance to the “Push”. It doesn’t want to get moving – so it resists you. The more mass you have, the more it resists you. Notice that the object is resisting motion. It wants to stay put as I push against it (force). An object Resists the “Push/Pull” 1000 kg In the next slide, you will also notice that with less mass it’s easier to start it. Inertia Notice that the object is resisting the push. It wanted to stay put as I push against it (force). Notice that with more mass, the more it resists. An object Resists the “Push/Pull” 3000 kg Mo Mass, Mo Inertia Inertia Also notice that with more mass it’s harder to stop it. Notice that when the object is in motion, it wants to stay in motion until I push against it (force) 3000 kg Mo Mass, Mo Inertia Inertia Notice that when the object is in motion, it wants to stay in motion until I push against it (force). Also notice that with less mass it’s easier to stop it. 1000 k Less Mass, Less Inertia First Law of Motion Recap: • Every object that has mass has inertia. First Law of Motion Recap: • Inertia is the objects resistance to a change in its motion, or resistance to the “Push/Pull”. – An object at rest will stay at rest unless it is acted upon by a force.” (and the opposite is also true). First Law of Motion Recap: •MO MASS MO INERTIA If the force were to stay the same, what do you think happens to our acceleration w/ different masses? Distance In other words, w/ less mass, it doesn’t take as much effort to get it moving; therefore, I can move it farther in less time (faster). ½ kg 1kg W/ Less Mass 2kg In other words, w/ more mass, it takes more effort to get it moving; therefore, it takes me more time to move it farther (slower). W/ More Mass Time Demo: Skateboard + 3 diff. people What do you think happens to our acceleration w/ different masses? Distance Which one of these lines do you think would represent a sports car, SUV & Diesel Truck? The Diesel truck would be the least steep line! Less steep = less rate of acceleration. Sports car would be the steepest line! Steeper = more rate of acceleration. The SUV would be the middle line! Steepness of line is in the middle = average acceleration rate. Time Manipulating the Force Formula • By manipulating the force formula, we can get 6 different scenarios of how an objects acceleration rate can be affected by force. F=M*A Force, Mass & Acceleration Phrases • If I Keep my “pushing” (Force) the same: – If I add more mass, I accelerate slower – If I take off mass, I accelerate faster. • If I Keep my Mass the same: – If I push hard, I accelerate faster. – If I push less, I accelerate slower. • If I want to Accelerate at the same rate: – If I increase my mass, I have to push harder. – If I decrease my mass, I don’t have to push as hard. If I Keep Force Constant: 30 N • If I have less mass, I accelerate faster. – This is because I have less inertia. 1000 kg ¤ Force = Mass * Acceleration 30 N To Keep Force Constant: 30 N • If I add more mass, I accelerate slower – This is because I have more inertia. 3000 kg ¤ Force = Mass * Acceleration 30 N If I Keep Mass Constant: 30 N • If I push hard, I accelerate faster. 30 N 1000 kg Force = Mass ¤* Acceleration If I Keep Mass Constant: 10 N • If I push less, I accelerate slower. 1000 kg Force = Mass 10 N ¤* Acceleration To Keep Acceleration Constant: 10 N • If I decrease my mass, I don’t have to push as hard. 1000 kg Force = Mass 10 N * Acceleration ¤ To Keep Acceleration Constant: 30 N • If I increase my mass, I have to push harder. 30 N 3000 kg Force = Mass * Acceleration ¤ To Keep Force Constant F Control M Manipulated A Responding If I take off mass, I accelerate faster. •20 N •20 N ½ kg 1kg 40 m/s2 20 m/s2 Control •20 N 2kg 10 m/s2 If I add more mass, I accelerate slower To Keep Mass Constant Control M F Manipulated A Responding If I push more, I accelerate more. 1kg 30 N 30 m/s2 1kg 20 N 20 m/s2 Control 1kg 10 N 10 m/s2 If I push less, I accelerate less. To Keep Acceleration Constant A Control M Manipulated F Responding If I decrease my mass, I don’t have to push as hard. 20 m/s2 20 m/s2 10 N ½ kg 20 N 1kg Control 20 m/s2 2kg 40 N If I increase my mass, I have to push harder.