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| ||<:10%>'''PIRA #'''||<:>'''Demonstration Name'''||<:60%>'''Abstract'''|| ||1G10.10|| acceleration air glider|| Air track cart pulled by a falling weight.|| ||1G10.10|| acceleration air glider|| Accelerate a car on a track with a mass on a string over a pulley.|| ||1G10.10|| glider, mass, and pulley|| An air track cart is timed while pulled by a mass on a string over a pulley.|| ||1G10.10|| string and weight acceleration (air|| Three cases of an air glider pulled by a falling weight.|| ||1G10.11|| constant mass acceleration system|| A cart on the air track is accelerated by a mass on a string over a pulley and final velocity timed photoelectrically. Keep the mass of the system constant by transferring from the cart to the pan.|| ||1G10.11|| acceleration air glider|| Air cart with a string over a pulley to a mass. Vary mass on both cart and hanger.|| ||1G10.12|| acceleration air glider on incline|| An puck is timed as it floats up an incline pulled by a string to a weight over a pulley.|| ||1G10.13|| acceleration air glider on incline|| An air track cart is accelerated up an inclined track by the string, pulley and mass system. A newton scale is included on the cart to measure the tension in the string directly. An electromagnet release and photogate timer at a fixed distance are used to derive acceleration.|| ||1G10.14|| acceleration glider accelerometer|| An elegant pendulum accelerometer designed for the air track. Reflected laser beam is directed to a scale at one end of the track.|| ||1G10.16|| acceleration with spring (air track)|| An air track glider is pulled by a small spring hand held at constant extension.|| ||1G10.17|| constant force generators|| A note that picks some nits about the hanging mass, mentions the "Neg'ator" spring.|| ||1G10.18|| battery propeller force generator|| Plans for a battery powered air track propeller that provides a constant force.|| ||1G10.19|| constant force generator|| A constant force generator for the air track based on the induction of eddy currents. It is easy to handle and can be self-made.|| ||1G10.20|| acceleration car|| Time the acceleration of a toy truck as it is pulled across the table by a mass on a string over a pulley.|| ||1G10.21|| acceleration car and track|| Apparatus Drawings Project No. 15: Large low friction acceleration carts and track for use in the lecture demonstration.|| ||1G10.21|| acceleration car|| Three different pulley arrangements allow a cart to be accelerated across the table top.|| ||1G10.21|| acceleration car|| A car is accelerated by a descending weight.|| ||1G10.21|| acceleration car, mass & pulley|| Distance and time are measured as a toy truck is accelerated by a mass and pulley system.|| ||1G10.24|| acceleration car photo|| Take a strobed photo of a light on a car pulled by a weight on a string over a pulley.|| ||1G10.25|| acceleration block|| Accelerate a block of wood across the table by a mass on a string over a pulley.|| ||1G10.26|| acceleration car|| A complex arrangement to accelerate a car, vary parameters, and graph results is shown. Details in appendix, p.549.|| ||1G10.30|| weight of a mass|| Suspend a mass from a spring balance and then cut the string.|| ||1G10.30|| mass on a scale|| Hang a mass on a spring scale to show reaction of the scale to mg.|| ||1G10.40|| Atwood's machine|| Two equal masses are hung from a light pulley. A small percentage of one mass is moved to the other side.|| ||1G10.40|| Atwood's machine|| Place 1 kg on each side of a light pulley on good bearings. Add 2 g to one side.|| ||1G10.40|| Atwood's machine|| Three skeletonized aluminum pulleys are mounted together on good bearings. Many combinations of weights may be tried.|| ||1G10.40|| Atwood's machine|| Two equal masses are hung from a light pulley. A small percentage of one mass is moved to the other side.|| ||1G10.40|| Atwood's machine|| An Atwood's machine using an air pulley.|| ||1G10.40|| Atwood's machine|| The small weight is removed after a period of acceleration and the resulting constant velocity is measured.|| ||1G10.42|| Atwood's machine|| Hang the weights from spring balances on each side.|| ||1G10.44|| Atwood's machine|| A rotation free Atwood's machine using air bearing surface and spark timer.|| ||1G10.44|| Atwood's machine|| Atwood's machine using an air bearing and spark timer.|| ||1G10.45|| Atwood's machine problem|| One of the best nerd problems ever.|| ||1G10.45|| Morin's machine|| Morin's (French) alternative to Atwood's (English) machine.|| ||1G10.51|| auto acceleration|| On using automotive magazine test results to study kinematic relations.|| ||1G10.52|| car time trials|| Use student's cars to do time trials in the school parking lot.|| |
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| ||<:10%>'''PIRA #'''||<:>'''Demonstration Name'''||<:60%>'''Abstract'''|| |
Newton's Second Law
PIRA classification 1G
1G10. Force, Mass, and Acceleration
PIRA # |
Demonstration Name |
Abstract |
1G10.10 |
acceleration air glider |
Air track cart pulled by a falling weight. |
1G10.10 |
acceleration air glider |
Accelerate a car on a track with a mass on a string over a pulley. |
1G10.10 |
glider, mass, and pulley |
An air track cart is timed while pulled by a mass on a string over a pulley. |
1G10.10 |
string and weight acceleration (air |
Three cases of an air glider pulled by a falling weight. |
1G10.11 |
constant mass acceleration system |
A cart on the air track is accelerated by a mass on a string over a pulley and final velocity timed photoelectrically. Keep the mass of the system constant by transferring from the cart to the pan. |
1G10.11 |
acceleration air glider |
Air cart with a string over a pulley to a mass. Vary mass on both cart and hanger. |
1G10.12 |
acceleration air glider on incline |
An puck is timed as it floats up an incline pulled by a string to a weight over a pulley. |
1G10.13 |
acceleration air glider on incline |
An air track cart is accelerated up an inclined track by the string, pulley and mass system. A newton scale is included on the cart to measure the tension in the string directly. An electromagnet release and photogate timer at a fixed distance are used to derive acceleration. |
1G10.14 |
acceleration glider accelerometer |
An elegant pendulum accelerometer designed for the air track. Reflected laser beam is directed to a scale at one end of the track. |
1G10.16 |
acceleration with spring (air track) |
An air track glider is pulled by a small spring hand held at constant extension. |
1G10.17 |
constant force generators |
A note that picks some nits about the hanging mass, mentions the "Neg'ator" spring. |
1G10.18 |
battery propeller force generator |
Plans for a battery powered air track propeller that provides a constant force. |
1G10.19 |
constant force generator |
A constant force generator for the air track based on the induction of eddy currents. It is easy to handle and can be self-made. |
1G10.20 |
acceleration car |
Time the acceleration of a toy truck as it is pulled across the table by a mass on a string over a pulley. |
1G10.21 |
acceleration car and track |
Apparatus Drawings Project No. 15: Large low friction acceleration carts and track for use in the lecture demonstration. |
1G10.21 |
acceleration car |
Three different pulley arrangements allow a cart to be accelerated across the table top. |
1G10.21 |
acceleration car |
A car is accelerated by a descending weight. |
1G10.21 |
acceleration car, mass & pulley |
Distance and time are measured as a toy truck is accelerated by a mass and pulley system. |
1G10.24 |
acceleration car photo |
Take a strobed photo of a light on a car pulled by a weight on a string over a pulley. |
1G10.25 |
acceleration block |
Accelerate a block of wood across the table by a mass on a string over a pulley. |
1G10.26 |
acceleration car |
A complex arrangement to accelerate a car, vary parameters, and graph results is shown. Details in appendix, p.549. |
1G10.30 |
weight of a mass |
Suspend a mass from a spring balance and then cut the string. |
1G10.30 |
mass on a scale |
Hang a mass on a spring scale to show reaction of the scale to mg. |
1G10.40 |
Atwood's machine |
Two equal masses are hung from a light pulley. A small percentage of one mass is moved to the other side. |
1G10.40 |
Atwood's machine |
Place 1 kg on each side of a light pulley on good bearings. Add 2 g to one side. |
1G10.40 |
Atwood's machine |
Three skeletonized aluminum pulleys are mounted together on good bearings. Many combinations of weights may be tried. |
1G10.40 |
Atwood's machine |
Two equal masses are hung from a light pulley. A small percentage of one mass is moved to the other side. |
1G10.40 |
Atwood's machine |
An Atwood's machine using an air pulley. |
1G10.40 |
Atwood's machine |
The small weight is removed after a period of acceleration and the resulting constant velocity is measured. |
1G10.42 |
Atwood's machine |
Hang the weights from spring balances on each side. |
1G10.44 |
Atwood's machine |
A rotation free Atwood's machine using air bearing surface and spark timer. |
1G10.44 |
Atwood's machine |
Atwood's machine using an air bearing and spark timer. |
1G10.45 |
Atwood's machine problem |
One of the best nerd problems ever. |
1G10.45 |
Morin's machine |
Morin's (French) alternative to Atwood's (English) machine. |
1G10.51 |
auto acceleration |
On using automotive magazine test results to study kinematic relations. |
1G10.52 |
car time trials |
Use student's cars to do time trials in the school parking lot. |
1G20. Accelerated Reference Frames
PIRA # |
Demonstration Name |
Abstract |
1G30. Complex Systems
PIRA # |
Demonstration Name |
Abstract |
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