Refer to F'ig. 1, which is a schematic diagram of a frontal snapshot of the rotating laboratory a...
Refer to F'ig. 1, which is a schematic diagram of a frontal snapshot of the rotating laboratory apparatun, with the beam's cross section and the unbalancing mass respectively represented by the gray rectangie and by the black disk. g. 1: Schematic diagram of a frontal snapshot of the laboratory rotating apparatus; the gray rectangle presents the beam's cross section, and the black disk represents an unbalancing mass. (5pt) If there is one unbalancing mass of 10 g at a distance of 3 cm from the centre of the disk calculate the total downward (i.e., towards the floor) force during the experiment, exerted by the mass on the beam for a constant angular velocity w. Express this force as a function of 0 and consider both static and dynamic contributions.
Refer to F'ig. 1, which is a schematic diagram of a frontal snapshot of the rotating laboratory apparatun, with the beam's cross section and the unbalancing mass respectively represented by the gray rectangie and by the black disk. g. 1: Schematic diagram of a frontal snapshot of the laboratory rotating apparatus; the gray rectangle presents the beam's cross section, and the black disk represents an unbalancing mass. (5pt) If there is one unbalancing mass of 10 g at a distance of 3 cm from the centre of the disk calculate the total downward (i.e., towards the floor) force during the experiment, exerted by the mass on the beam for a constant angular velocity w. Express this force as a function of 0 and consider both static and dynamic contributions.