1. Force Systems accelerate together Combination Systems – connected masses Horizontal Pulley Atwood’s Machine

2. Connected Masses What forces can you identify acting each box? What is the net force on the system?

3. A constant net force, F, accelerates the entire system’s mass. F net = m tot a for the system a = F net. m 1 + m 2 + m 3.

4. Each box has separate forces acting on it. Sketch free body diagrams for each mass ignore vertical forces. Assign 1 direction as positive (right). Write the F net equation for each, find acceleration. Isolate each masses to find T 1 & T 2. m 1 a = T 1. m 2 a = T 2 - T 1. m 3 a = F – T 2.

5. Ex 1: Connected Masses: Given a F net of 20N and masses of 4, 3, and 1 kg, find the acceleration of the system and the tension in each cord. a = F net. m 1 + m 2 + m 3

6. Find system acceleration: a = F net m 1 + m 2 + m 3. 20 N (4 + 3 + 1) kg a = 2.5 m/s 2.

7. Use the free body diagram & known acceleration to find the tension in each cord. 1 kg 4 kg F -T 2 = m 3 a or F - m 3 a = T 2. 20N - (1 kg)(2.5 m/s 2 ) = 17.5 N T 1 = m 1 a = (4 kg)(2.5 m/s 2 ) = 10 N.

8. Check the calculation using the 3 rd mass. T 2 – T 1 = m 2 a17.5 N – 10 N = 7.5 N m 2 a = (3 kg)(2.5 m/s 2 ) = 7.5 N. It is correct!!

9. T 1 = 10 N T 2 = 17.5 N m 1 a = T 1. m 2 a = T 2 - T 1.

10. Horizontal Pulley.

11. The masses accl together, the tension is uniform, accl direction is positive.

12. Sketch free body diagrams for each mass separately. Write Newton’s 2 nd Law equation for each. M1.M1. +T. Fn.Fn. m1gm1g M2.M2. -T. m2gm2g m 1 a = T m 2 a = m 2 g - T

13. Add the equations: m 1 a + m 2 a = T + m 2 g – T T cancels. m 1 a + m 2 a = m 2 g Factor a & solve

14. a = m 2 g m 1 + m 2 Solve for a, and use the acceleration to solve for the tension pulling one of the masses. m 1 a = T

15. Ex 2: Horizontal Pulley: Given a mass of 4 kg on a horizontal frictionless surface attached to a mass of 3 kg hanging vertically, calculate the acceleration, and the tension in the cord. Compare the tension to the weight of the hanging mass, are they the same?

16. a = 4.2 m/s 2 T = 16.8 N mg = 30 N, it is less than the tension.

17. Ex: Given horizontal pulley system where m 1 = 2 kg, m 2 = 5 kg, and , the coefficient of friction between m 1 and the counter is 0.35, sketch the free body diagrams for m 1 and m 2, calculate the acceleration of the system, and find T.

19. To practice problems go to: Hyperphysics site. Click Mechanics, Newton’s Laws, Standard problems, then the appropriate symbol. http:// hyperphysics.phy- astr.gsu.edu/hbase/hph.html#mechcon

20. Atwood’s Machine Use wksht.

21. Given Atwood’s machine, m 1 = 2 kg, m 2 = 4 kg. Find the acceleration and tension.

22. Sketch the free body diagram for each.

23. Boxes in Contact

24. Since F is the only force acting on the two masses, it determines the acceleration of both: The force F 2 acting on the smaller mass may now be determined.

25. Using the previously determined accl, the force F 2 acting on the smaller mass is F 2 = m 2 a By Newton’s 3rd Law, F 2 acts backward on m 1. m1m1 F2F2 F The net force, F 1, on m 1 is:

26. Given a force of 10N applied to 2 masses, m 1 =5 kg and m 2 =3kg, find the accl and find F 2 (the contact force) between the boxes. a = 1.25m/s 2 F 2 = m 2 a F 2 = 3.75 N

27. Given a force of 100 N on 100 1 kg boxes, what is the force between the 60 th and 61 st box. 100-N 1-kg

28. Find a for system. a = 1m/s 2. F 2 must push the remaining 40 boxes or 40 kg. F = 40 kg (1m/s 2.) 40 N.

29. Ignoring friction, derive an equation to solve for a and T for this system: Begin by sketching the free body diagram Write the equations for each box Add them. Solve for accl

30. Inclined Pulley

31. Given a 30 o angle, and 2 masses each 5-kg, find the acceleration of the system, and the tension in the cord. a= 2.45m/s 2. T =36.75 N

32. Derive an equation for the same inclined pulley system including friction.