1 / 21

Concept Check – Newton’s 1 st Law

Concept Check – Newton’s 1 st Law. A book is lying at rest on a table. The book will remain there at rest because: 1. there is a net force but the book has too much inertia 2. there are no forces acting on it at all 3. it does move, but too slowly to be seen

naida
Download Presentation

Concept Check – Newton’s 1 st Law

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Concept Check – Newton’s 1st Law A book is lying at rest on a table. The book will remain there at rest because:1. there is a net force but the book has too much inertia 2. there are no forces acting on it at all 3. it does move, but too slowly to be seen 4. there is no net force on the book 5. there is a net force, but the book is too heavy to move

  2. Concept Check – Newton’s 1st Law A book is lying at rest on a table. The book will remain there at rest because:1. there is a net force but the book has too much inertia 2. there are no forces acting on it at all 3. it does move, but too slowly to be seen 4. there is no net force on the book 5. there is a net force, but the book is too heavy to move There are forces acting on the book, but the only forces acting are in the y-direction. Gravity acts downward, but the table exerts an upward force that is equally strong, so the two forces cancel, leaving no net force.

  3. Concept Check – Newton’s 1st Law (2) A hockey puck slides on ice at constant velocity. What is the net force acting on the puck? 1. more than its weight 2. equal to its weight 3. less than its weight but more than zero 4. depends on the speed of the puck 5. zero

  4. Concept Check – Newton’s 1st Law (2) A hockey puck slides on ice at constant velocity. What is the net force acting on the puck? 1. more than its weight 2. equal to its weight 3. less than its weight but more than zero 4. depends on the speed of the puck 5. zero The puck is moving at a constant velocity, and therefore it is not accelerating. Thus, there must be no net force acting on the puck. Follow-up: Are there any forces acting on the puck? What are they?

  5. Concept Check – Newton’s 1st Law (3) You put your book on the bus seat next to you. When the bus stops suddenly, the book slides forward off the seat. Why? 1. a net force acted on it 2. no net force acted on it 3. it remained at rest 4. it did not move, but only seemed to 5. gravity briefly stopped acting on it

  6. Concept Check – Newton’s 1st Law (3) You put your book on the bus seat next to you. When the bus stops suddenly, the book slides forward off the seat. Why? 1. a net force acted on it 2. no net force acted on it 3. it remained at rest 4. it did not move, but only seemed to 5. gravity briefly stopped acting on it The book was initially moving forward (since it was on a moving bus). When the bus stopped, the book continued moving forward, which was its initial state of motion, and therefore it slid forward off the seat. Follow-up: What is the force that usually keeps the book on the seat?

  7. Concept Check – Newton’s 1st Law (4) You kick a smooth flat stone out on a frozen pond. The stone slides, slows down and eventually stops. You conclude that: 1. the force pushing the stone forward finally stopped pushing on it 2. no net force acted on the stone 3. a net force acted on it all along 4. the stone simply “ran out of steam” 5. the stone has a natural tendency to be at rest

  8. Concept Check – Newton’s 1st Law (4) You kick a smooth flat stone out on a frozen pond. The stone slides, slows down and eventually stops. You conclude that: 1. the force pushing the stone forward finally stopped pushing on it 2. no net force acted on the stone 3. a net force acted on it all along 4. the stone simply “ran out of steam” 5. the stone has a natural tendency to be at rest After the stone was kicked, no force was pushing it along! However, there must have been some force acting on the stone to slow it down and stop it. This would be friction.

  9. Newton’s First Law

  10. Inertia

  11. Mass and Inertia

  12. Inertia and the Operation of a Seat Belt

  13. Net Force Although several forces are acting on this car, the vector sum of the forces is zero. Thus, the net force is zero, and the car moves at a constant velocity.

  14. Equilibrium

  15. Sample Problem Determining Net Force Derek leaves his physics book on top of a drafting table that is inclined at a 35° angle. The free-body diagram below shows the forces acting on the book. Find the net force acting on the book.

  16. Sample Problem, continued 1. Define the problem, and identify the variables. Given: Fgravity-on-book = Fg = 22 N Ffriction = Ff = 11 N Ftable-on-book = Ft = 18 N • Unknown: • Fnet = ?

  17. Sample Problem, continued 2. Select a coordinate system, and apply it to the free-body diagram.

  18. Sample Problem, continued 3. Find the x and y components of all vectors. Draw a sketch, as shown in (b), to help find the components of the vector Fg. The angle q is equal to 180– 90 – 35 = 55.

  19. Sample Problem, continued 3. Find the x and y components of all vectors. Add both components to the free-body diagram, as shown in (c).

  20. Sample Problem, continued For the y direction: SFy = Ft – Fg,y SFy = 18 N – 18 N SFy = 0 N 4. Find the net force in both the x and y directions. Diagram (d) shows another free-body diagram of the book, now with forces acting only along the x- and y-axes. For the x direction: SFx = Fg,x – Ff SFx = 13 N – 11 N SFx = 2 N

  21. Sample Problem, continued 5. Find the net force. Add the net forces in the x and y directions together as vectors to find the total net force. In this case, Fnet = 2 N in the +x direction, as shown in (e). Thus, the book accelerates down the incline.

More Related