WebFigure 1 This diagram is showing the setup of our apparatus which also includes a FBD of the stopper. The math within our lab report are based on the grounds that the stopper is exactly perpendicular to the plastic straw. The lab is done through the use of a string that has one end tied to a rubber stopper and the other tied to a number of washers. WebThe simplest case of circular motion is uniform circular motion, where an object travels a circular path at a constant speed. Note that, unlike speed, the linear velocity of an object in circular motion is constantly changing because it is always changing direction. We know from kinematics that acceleration is a change in velocity, either in ...
ROTATION PERIOD and FORCE (PART A) 1101Lab4prob3
WebNow you will find the speed of the circling stopper for various weights of circling masses. All other variables will remain constant. A. Attach one stopper to the end of the string and a 400g mass to the other. Set the radius at 0.5m. Twirl the stopper and record the time required to make 10 revolutions. B. Repeat with 2, 3, 4, and 5 stoppers. Webd. A student doing a different experiment to determine the mass of the stopper obtained the values in the data table below. Use the data table to calculate the mass of the stopper and include an explanation of your method. radius (m) hanging mass (kg) v (m/s) 0.2 0.5 3.8 simpplr company
15.5: Pendulums - Physics LibreTexts
WebCite this page as follows: "In an experiment, a 0.028 kg rubber stopper is attached to one end of a string. A student whirls the stopper overhead in a horizontal circle with a radius … Web2. Make a mark on the string at the bottom end of the tube 3. Practice whirling the stopper until you can keep the edge of the bottom tube at the marked position 4. Use a stopwatch to measure how many revolutions … WebTie the rubber stopper to the end of the string on the side of the tube with the white plug. (This is a Teflon ... Use a timing device to measure the time for 10 full oscillations, and … simpplr platform