| DCS # | DEMONSTRATION | REFERENCE | ABSTRACT |
|---|
| 4D30.00 | Kinetic Motion | | |
| 4D30.05 | on the meaning of temperature | TPT 28(7),441 | Many comments on the TPT 28(2),94 article on temperature. |
| 4D30.10 | Cenco kinetic theory apparatus | PIRA 500 | |
| 4D30.10 | Cenco kinetic theory apparatus | 4D30.10 | The Cenco apparatus with lead shot in a piston. |
| 4D30.10 | mechanical model of kinetic motion | Hh-5 | The Cenco molecular motion simulator with lead shot in a piston. |
| 4D30.10 | Cenco kinetic theory apparatus | 27-7.7 | A discussion of the Cenco kinetic theory apparatus. |
| 4D30.11 | big kinetic motion apparatus | PIRA 1000 | |
| 4D30.11 | big kinetic motion apparatus | 4D30.11 | Scale up the balls in a piston using a 16" diameter tube and 1/2" diameter balls. |
| 4D30.12 | mechanical gas model | M-22b.1 | The details are not clear from this picture of a mechanical gas model. |
| 4D30.13 | kinetic theory models | A-42 | Drive small steel balls in a small chamber with a tuning fork. |
| 4D30.20 | molecular motion simulator | PIRA 500 | |
| 4D30.20 | molecular motion simulator | 4D30.20 | Ball bearings on a vibrating plate on the overhead projector. |
| 4D30.20 | kinetic theory demonstrator | TPT 2(2),81 | A 2-D ball shaker for the overhead projector. |
| 4D30.20 | two dimensional kinetic motion | Hh-4 | Balls on a vibrating plate are used with the overhead projector for many molecular simulations. |
| 4D30.21 | equipartition of energy simulator | PIRA 1000 | |
| 4D30.21 | simple equipartition model | 27-7.8 | Jostle two different sized marbles by hand in a large tray to show different velocities. |
| 4D30.21 | kinetic theory models | A-46 | A large and small version of balls on a horizontal surface agitated by a hand frame. |
| 4D30.21 | equipartition of energy simulation | Disc 16-05 | Use different size balls in the shaker frame on the overhead. |
| 4D30.22 | pressure vs. volume simulator | PIRA 1000 | |
| 4D30.22 | pressure vs. volume simulation | Disc 16-04 | Change the size of the entrained area of the shaker frame on the overhead projector. |
| 4D30.23 | free expansion simulation | PIRA 1000 | |
| 4D30.23 | free expansion simulation | Disc 16-13 | Balls are initially constrained to one half of the shaker frame and then the bar is lifted. |
| 4D30.24 | temperature increase simulation | PIRA 1000 | |
| 4D30.24 | temperature increase simulation | Disc 16-03 | A shaker frame on the overhead projector is shown with different shaking rates. |
| 4D30.25 | mechanical shaker | 27-7.3 | Determine the distribution of velocities produced by an overhead projector shaker. Picture, Diagrams, Construction details in appendix, p.1294. |
| 4D30.26 | roller randomizer | AJP 45(11),1030 | Cylindrical rollers in a pentagon configuration produce random motion. |
| 4D30.27 | driven steel cage | 27-7.5 | A motor driven steel cage can be used horizontally or vertically to perform several models of kinetic motion. Pictures, Construction details in appendix, p.1295. |
| 4D30.30 | hard sphere model | 27-7.1 | A bouncing plate with balls. The free space ratio is varied giving models of gas through crystal behavior. Pictures, Construction details in appendix, p 1292. |
| 4D30.31 | speaker shaker | AJP 52(1),68 | Steel balls in a container on a speaker show both fluid and solid state phenomena. |
| 4D30.32 | shaking velcro balls | AJP 41(4),582 | Attach velcro to spheres and shake. "Bonding" will vary with the vigor of agitation. |
| 4D30.32 | air table molecules | AJP 38(12),1478 | Four magnets placed on the Plexiglas discs provide the attraction for many demonstrations of molecular kinetics. |
| 4D30.34 | drop formation shaker | 27-7.2 | A motorized shaker frame in a magnetic field causes steel balls to act like molecules forming drops. |
| 4D30.37 | kinetic theory models | A-41 | A fan propels several hundred small steel balls in a container. Also shows Brownian motion. |
| 4D30.38 | kinetic theory models | A-43 | Compressed air drives ping pong balls in a large container. |
| 4D30.40 | glass beads | PIRA 1000 | |
| 4D30.40 | model for kinetic theory of gases | Hh-1 | An evacuated tube containing mercury and some glass chips is heated over a Bunsen burner. |
| 4D30.40 | kinetic theory models | A-44 | Mercury heated in a evacuated glass tube causes glass beads to fly about. |
| 4D30.40 | glass beads | M-22i | Heat an evacuated tube with some mercury and glass chips. An optical projection system is shown. |
| 4D30.40 | mercury kinetic theory | Disc 16-06 | Glass chips float on a pool of mercury in an evacuated tube. Heat the mercury and the chips dance in the mercury vapor. |
| 4D30.41 | kinetic theory model | A-45 | Mercury is heated in a large evacuated tube causing pith balls to jump about. |
| 4D30.50 | model of kinetic pressure | Hh-2 | Balls drop from a funnel onto a pan balance. |
| 4D30.51 | dropping shot | M-117 | Pour lead shot onto the apex of a cone attached to a float. Vary the number and velocity of shot. |
| 4D30.55 | stream of dropping balls | AJP 28(7),666 | Apparatus 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. |
| 4D30.60 | flame tube viscosity | PIRA 1000 | |
| 4D30.60 | dependence of viscosity on temp. | Hh-9 | See Fm-4. |
| 4D30.60 | dependence of viscosity on temp. | Fm-4 | As the tube on one side of a twin burner is heated, the flame becomes smaller. |
| 4D30.60 | flame tube viscosity | 27-4.1 | One leg of a "T" tube is heated resulting in increased viscosity and a smaller flame of illuminating gas. |
| 4D30.60 | gas viscosity change with temp | Disc 14-04 | Heat the gas flowing to one of two identical burners and the flame decreases. |
| 4D30.71 | viscosity of gas independ. of press. | Fm-3 | The velocity of a precision ball falling in a precision tube is independent of pressure as the tube is partially evacuated. |
| 4D30.71 | viscosity independent of pressure | Hh-8 | See Fm-3. |
| 4D30.72 | viscosity and pressure | A-58 | Oscillations in the quartz fiber radiation pressure apparatus change frequency as it is evacuated. |
| 4D30.75 | viscosity independent of pressure | 27-4.2 | A 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. |