Sunday, November 24, 2019

Ultra Sound essays

Ultra Sound essays We looked at the mass-spring system and determined the spring constant by two different methods. We took measurements of T at 25 oscillations at 6 different masses. We graphed X vs. Mass (added) in grams. We determined the spring constant by using the formula K=1/slope x 9.8m/s. The graph was in agreement with Hookes Law because it was a straight line. We then squared T and graphed T vs. Mass (added) in grams, and determined the spring constant using 4II/ K=Slope. We also calculated the mass of the spring which was calculated to be 1/3 of the mass of the spring. 100g 61.5cm 26.09sec 1.0436sec 1.089sec 150g 68.0cm 28.99sec 1.1596sec 1.345sec 200g 74.5cm 31.66sec 1.2664sec 1.604sec 250g 81.0cm 34.07sec 1.3628sec 1.857sec 100g 61.5cm 26.01sec 1.0404sec 1.082sec 150g 68.0cm 28.97sec 1.1588sec 1.3428sec 200g 74.5cm 29.61sec 1.2644sec 1.5987sec 250g 81.0cm 32.61sec 1.3044sec 1.7014sec 50g 55.5cm 22.70sec .908sec .8245sec 100g 61.5cm 26.09sec 1.0436sec 1.089sec 150g 68.0cm 28.97sec 1.156sec 1.336sec 200g 74.5cm 31.61sec 1.2644sec 1.599sec 250g 81.0cm 33.97sec 1.3588sec 1.846sec We used two methods to obtain spring constants. We have also determined the effective mass. We used the static method where a force was exerted on the spring by hanging weight on it. We graphed the x (cm) ...

No comments:

Post a Comment

Note: Only a member of this blog may post a comment.