Pre-Lab: The following figure is an airplane's view of a force table; a 120 gram mass hangs off of pulley at 400. A second mass of 500 grams hangs off of another pulley at 205° according to the picture in Figure 6.1. The weights pull on the ring in the center of the table via the pulleys. Picturein 33 A. Use vector components to find the combined total force (magnitude and direction) exerted on the ring by the two cables with weights hanging off of them. B. At what angle should a 3rd pulley be placed, and how much mass hanging off of it would be needed to balance the system in part A so that the central ring does not move? fieure Airplane View Force Table Pulley 1 205° 400 Side View Pulley 1 Pulley 2 Central Ring Side View Pulley 2 120 grams 500 Airplane View of Force Table grams FORCH FABLE /ould Figure 6.1: Force Table

I need help with part A and B. 

Transcribed Image Text:

Pre-Lab: The following figure is an airplane's view of a force table; a 120 gram mass hangs off of pulley at 400. A second mass of 500 grams hangs off of another pulley at 205° according to the picture in Figure 6.1. The weights pull on the ring in the center of the table via the pulleys. Picturein 33 A. Use vector components to find the combined total force (magnitude and direction) exerted on the ring by the two cables with weights hanging off of them. B. At what angle should a 3rd pulley be placed, and how much mass hanging off of it would be needed to balance the system in part A so that the central ring does not move?

Transcribed Image Text:

fieure Airplane View Force Table Pulley 1 205° 400 Side View Pulley 1 Pulley 2 Central Ring Side View Pulley 2 120 grams 500 Airplane View of Force Table grams FORCH FABLE /ould Figure 6.1: Force Table