1 / 21

1.5 m/s (2) 2.0 m/s (3) 2.5 m/s (4) 4 m/s (5) 5 m/s (6) 6 m/s (7) 8 m/s (8) 10 m/s

Momentum is a vector. Suppose the mass of a block is 2kg. If the x-component of the momentum of a block is +4 kg ·m/s and the y-component of the momentum of the block is -3 kg·m/s, what is the speed of the block? . 1.5 m/s (2) 2.0 m/s (3) 2.5 m/s (4) 4 m/s

kelii
Télécharger la présentation

1.5 m/s (2) 2.0 m/s (3) 2.5 m/s (4) 4 m/s (5) 5 m/s (6) 6 m/s (7) 8 m/s (8) 10 m/s

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. Momentum is a vector. Suppose the mass of a block is 2kg. If the x-component of the momentum of a block is +4 kg·m/s and the y-component of the momentum of the block is -3 kg·m/s, what is the speed of the block? • 1.5 m/s (2) 2.0 m/s (3) 2.5 m/s (4) 4 m/s • (5) 5 m/s (6) 6 m/s (7) 8 m/s (8) 10 m/s

  2. If m=2 kg, px = +4 kg·m/s, py = -3 kg·m/s.What is the magnitude of the momentum of the block? Find speed: p = mv 5 kg·m/s = 2kg * v v = 2.5 m/s +4 kg·m/s -3 kg·m/s Could also calculate velocity components directly, then find magnitude (speed): px = m·vxpy = m·vy 4kg·m/s = 2kg *vx -3kg·m/s = 2kg *vy vx = 2 m/s vy = -1.5 m/s

  3. F versus t graph Impulse equal to area under F vs t graph Vector quantity: need to account for direction Impulse in x direction will only affect momentum in x will not change momentum in y

  4. Two balls of equal mass are dropped on the table from the same height. Ball A bounces back up to roughly the same height from which it was dropped. Ball B does not bounce back up at all. Which ball receives the greater impulse from the table? Ball A Ball B Both feel the same impulse Greater change in momentum (not only stopped, but reversed direction) Careful with signs! VECTORS! Suppose initial velocity is -5m/s and final velocity is + 5m/s (presume +y is up)

  5. A 2kg puck is traveling along at 3m/s. An impulse of 10Ns is exerted on the puck at an angle perpendicular to its motion. Which path best describes the motion of the puck after the impulse? (1) q = 90° (2) 45° < q < 90° (3) q = 45° (4) 0° < q < 45° (5) q = 0° After impulse, px = 6 kg m/s (same as before) py = 10 kg m/s Greater momentum in y than in x 10 kg·m/s 6 kg·m/s

  6. Collisions During collision: F12 = - F21 during whole time J12 = J21 (Sum ext forces + sum int forces)Δt = pf – p0 Sum int forces always zero If sum of average external forces = 0 Momentum stays same – Conserved! System – object/group of objects considering Total momentum of system – add momenta from each object.

  7. Two small railroad cars are traveling at each other with the masses and speeds shown below. If you take the two cars as the system, what is the initial total momentum of the system? (1) 11000 kgm/s to the left (2) 1000 kgm/s to the left (3) 0 kgm/s (4) 1000 kgm/s to the right (5) 11000 kgm/s to the right 6000 kg m/s to right; 5000 kg m/s to left

  8. After the two cars collide, they stick together. Which direction will they be traveling? (How fast will they be traveling?) (1) to the left (2) they will be stationary (3) to the right Collision with momentum conserved. pinitialto right, pfinal to right vfinal = 0.14 m/s to the right

  9. Two cars collide and stick together. How fast will they be traveling after the collision? +x 2m/s 3m/s 4000kg 2000kg pinitial = pfinal p1,i + p2,i = p12,f m1v1,i + m2v2,i = (m1+ m2)vf 4000kg·2m/s + 2000kg·(-3m/s) = (6000kg)vf 2000kg·m/s =(6000kg) vf Vf =+0.33 m/s

  10. A 1kg bullet has a horizontal velocity of 200 m/s. It strikes to a wooden block of 10 kg initially at rest and becomes embedded. What is the velocity of the bullet and the block after the event?

  11. A 1kg bullet has a horizontal velocity of 200 m/s. It strikes to a wooden block of 10 kg initially at rest. If the bullet pass through the block and its final speed is 100 m/s, what will be the velocity of the bullet?

  12. Three railroad cars of equal mass are on a track. The one on the left is approaching at 6m/s. Ignoring friction, when they have all linked up as one, what is their speed? Clicker! (1) 1 m/s (2) 2 m/s (3) 3 m/s (4) 4 m/s (5) 5 m/s (6) 6 m/s (7) 12 m/s (8) 18 m/s (9) 0 m/s pinitial = pfinal m*6 = (3m) * v v = 2 m/s

  13. Three railroad cars of equal mass are on a track. The one on the left is approaching at 6m/s. Ignore friction. At the end the two left cars are linked and traveling at 1m/s, but the rightmost car didn’t connect properly and is free. Was is the speed of the separate unlinked car? Clicker! (1) 1 m/s (2) 2 m/s (3) 3 m/s (4) 4 m/s (5) 5 m/s (6) 6 m/s (7) 12 m/s (8) 18 m/s (9) 0 m/s pinitial = pfinal m*6 = (2m) * 1m/s + m*v v = 4 m/s

  14. Collisions • All collisions conserve momentum • ELASTIC: KE conserves. • INELASTIC: KE does not conserve. • perfectly inelastic – stick together (final v same)

  15. Elastic Collisions KE: KE0,1 + KE0,2 = KEf,1 + KEf,2 p: p0,1 + p0,2 = pf,1 + pf,2

  16. Example A bullet of 0.1 kg is fired to a wooden block of mass 5 kg hanged by a rope as shown. After the bullet hits the block, it is embedded in the block. If the block swings (bullet is embedded) to a height of 0.5 m due to the impact, what is the Initial speed of the bullet?

  17. Clicker! A ball is attached to a wire, held horizontally, and dropped. It strikes a block that is sitting on a horizontal, frictionless surface. Air resistance is negligible and the collision is elastic. During the collision, which of the following are conserved? • horizontal component of total momentum of ball/block system (2) Total KE of ball/block system (3) Both

  18. Problem 65 – Cutnell and Johnson A 4.00-g bullet is moving horizontally with a velocity of +355 m/s, where the + sign indicates that it is moving to the right. The mass of the first block is 1150 g, and its velocity is +0.550 m/s after the bullet passes through it. The mass of the second block is 1530 g. (a) What is the velocity of the second block after the bullet imbeds itself? (b) Find the ratio of the total kinetic energy after the collision to that before the collision. 0.513m/s KEAfter /KEBefore = 1.49e-3

  19. Problem 65 – Cutnell and Johnson - extended A 4.00-g bullet is moving horizontally with a velocity of +355 m/s, where the + sign indicates that it is moving to the right. The mass of the first block is 1150 g, and its velocity is +0.550 m/s after the bullet passes through it. The mass of the second block is 1530 g. (c) What is the speed of the bullet after the collision with Block 1 and before the collision with Block 2? (d) What is the average force of the bullet on the block if it takes 0.400ms to go through block 1?

  20. Three pucks collide and stick together. Initial speeds and masses are given. What is the direction of the 3 pucks after the collision? (choose an axis only if exactly on that axis) Clicker! 9 if stationary Initial momentum of system: up and to the right Final momentum: same – up and to the right px,i = +(2kg)(3m/s) + (1kg)(0m/s) – (1kg)(3m/s) = + 6 kg·m/s - 3 kg·m/s = + 3 kg·m/s pyi = (2kg)(0m/s) + (1kg)(3m/s) + (1kg)(0m/s) = + 3 kg·m/s

  21. Example Find the center of mass of the objects shown. 0.5 m 1 m 4 kg 2 kg 1 kg

More Related