PIRA 4D30.00 KINETIC MOTION

DCS #DEMONSTRATIONREFERENCEABSTRACT
4D30.00Kinetic Motion
4D30.05on the meaning of temperatureTPT 28(7),441Many comments on the TPT 28(2),94 article on temperature.
4D30.10Cenco kinetic theory apparatusPIRA 500
4D30.10Cenco kinetic theory apparatus4D30.10The Cenco apparatus with lead shot in a piston.
4D30.10mechanical model of kinetic motionHh-5The Cenco molecular motion simulator with lead shot in a piston.
4D30.10Cenco kinetic theory apparatus27-7.7A discussion of the Cenco kinetic theory apparatus.
4D30.11big kinetic motion apparatusPIRA 1000
4D30.11big kinetic motion apparatus4D30.11Scale up the balls in a piston using a 16" diameter tube and 1/2" diameter balls.
4D30.12mechanical gas modelM-22b.1The details are not clear from this picture of a mechanical gas model.
4D30.13kinetic theory modelsA-42Drive small steel balls in a small chamber with a tuning fork.
4D30.20molecular motion simulatorPIRA 500
4D30.20molecular motion simulator4D30.20Ball bearings on a vibrating plate on the overhead projector.
4D30.20kinetic theory demonstratorTPT 2(2),81A 2-D ball shaker for the overhead projector.
4D30.20two dimensional kinetic motionHh-4Balls on a vibrating plate are used with the overhead projector for many molecular simulations.
4D30.21equipartition of energy simulatorPIRA 1000
4D30.21simple equipartition model27-7.8Jostle two different sized marbles by hand in a large tray to show different velocities.
4D30.21kinetic theory modelsA-46A large and small version of balls on a horizontal surface agitated by a hand frame.
4D30.21equipartition of energy simulationDisc 16-05Use different size balls in the shaker frame on the overhead.
4D30.22pressure vs. volume simulatorPIRA 1000
4D30.22pressure vs. volume simulationDisc 16-04Change the size of the entrained area of the shaker frame on the overhead projector.
4D30.23free expansion simulationPIRA 1000
4D30.23free expansion simulationDisc 16-13Balls are initially constrained to one half of the shaker frame and then the bar is lifted.
4D30.24temperature increase simulationPIRA 1000
4D30.24temperature increase simulationDisc 16-03A shaker frame on the overhead projector is shown with different shaking rates.
4D30.25mechanical shaker27-7.3Determine the distribution of velocities produced by an overhead projector shaker. Picture, Diagrams, Construction details in appendix, p.1294.
4D30.26roller randomizerAJP 45(11),1030Cylindrical rollers in a pentagon configuration produce random motion.
4D30.27driven steel cage27-7.5A motor driven steel cage can be used horizontally or vertically to perform several models of kinetic motion. Pictures, Construction details in appendix, p.1295.
4D30.30hard sphere model27-7.1A bouncing plate with balls. The free space ratio is varied giving models of gas through crystal behavior. Pictures, Construction details in appendix, p 1292.
4D30.31speaker shakerAJP 52(1),68Steel balls in a container on a speaker show both fluid and solid state phenomena.
4D30.32shaking velcro ballsAJP 41(4),582Attach velcro to spheres and shake. "Bonding" will vary with the vigor of agitation.
4D30.32air table moleculesAJP 38(12),1478Four magnets placed on the Plexiglas discs provide the attraction for many demonstrations of molecular kinetics.
4D30.34drop formation shaker27-7.2A motorized shaker frame in a magnetic field causes steel balls to act like molecules forming drops.
4D30.37kinetic theory modelsA-41A fan propels several hundred small steel balls in a container. Also shows Brownian motion.
4D30.38kinetic theory modelsA-43Compressed air drives ping pong balls in a large container.
4D30.40glass beadsPIRA 1000
4D30.40model for kinetic theory of gasesHh-1An evacuated tube containing mercury and some glass chips is heated over a Bunsen burner.
4D30.40kinetic theory modelsA-44Mercury heated in a evacuated glass tube causes glass beads to fly about.
4D30.40glass beadsM-22iHeat an evacuated tube with some mercury and glass chips. An optical projection system is shown.
4D30.40mercury kinetic theoryDisc 16-06Glass chips float on a pool of mercury in an evacuated tube. Heat the mercury and the chips dance in the mercury vapor.
4D30.41kinetic theory modelA-45Mercury is heated in a large evacuated tube causing pith balls to jump about.
4D30.50model of kinetic pressureHh-2Balls drop from a funnel onto a pan balance.
4D30.51dropping shotM-117Pour lead shot onto the apex of a cone attached to a float. Vary the number and velocity of shot.
4D30.55stream of dropping ballsAJP 28(7),666Apparatus Drawings Project No. 9: Drop 1/2" balls at a rate of 5/sec 25' onto a massive damped balance and compare deflection with static loading and theory.
4D30.60flame tube viscosityPIRA 1000
4D30.60dependence of viscosity on temp.Hh-9See Fm-4.
4D30.60dependence of viscosity on temp.Fm-4As the tube on one side of a twin burner is heated, the flame becomes smaller.
4D30.60flame tube viscosity27-4.1One leg of a "T" tube is heated resulting in increased viscosity and a smaller flame of illuminating gas.
4D30.60gas viscosity change with tempDisc 14-04Heat the gas flowing to one of two identical burners and the flame decreases.
4D30.71viscosity of gas independ. of press.Fm-3The velocity of a precision ball falling in a precision tube is independent of pressure as the tube is partially evacuated.
4D30.71viscosity independent of pressureHh-8See Fm-3.
4D30.72viscosity and pressureA-58Oscillations in the quartz fiber radiation pressure apparatus change frequency as it is evacuated.
4D30.75viscosity independent of pressure27-4.2A viscosity damped oscillator is placed into a bell jar and evacuated to various pressures to show viscosity independent of pressure. Pictures, Construction details in appendix, p. 1290.

ReferenceDescription
M-1Sutton
Ma-1Freier & Anderson
M-1dHilton
8-2.8Meiners
1A12.01University of Minnesota Handbook
AJP 52(1),85American Journal of Physics
TPT 15(5),300The Physics Teacher
Disc 01-01The Video Encyclopedia of Physics Demonstrations

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