WORK LAB

 

When we are discussing work, either we, gravity, friction, or some other source provides the work that is done in a given situation. In this series of labs, an object will be moved by the application of work from a source. As a result of that work, a change in its state of energy will occur. We want to compare the results of analysis of work and energy to determine if we have the basis of a physical law.

Purpose

Procedure

  1. Conduct the experiment outlined. On the basis of visual observations, describe the nature of the work that occurs as well as the changes in energy.
     
  2. Repeat the experiment, gathering specific data for position, velocity, acceleration and force.
     
  3. Spreadsheets can be set up with Excel, or they can be set up within the interface programs themselves by making new columns and having the program do necessary calculations. For example, you could take a quantity equal to 1/2 the mass and multiply it times velocity squared to get a column of kinetic energy.

Analysis

  1. Calculate any work that occurs during your experiment. Note that this may involve finding the integral of the Force vs. Position graph.
     
  2. Calculate any change(s) in energy that occur.
     
  3. Compare the sizes of the quantities asked for above. Use percentage difference as a measure of how close they are to one another.
Group
Experiment Description
Equipment
Setup
A

B

You will release a lab cart from near the top of an inclined track. Monitor its motion along the track and set up a spreadsheet that calculates the work done and the resulting kinetic energy.

Dynamics Track
Dynamics Cart
Sonic Motion Sensor
Interface

C

D

E

You will release a rolling object (ball, cylinder or other object) from near the top of an inclined track. Monitor its motion along the track and set up a spreadsheet that calculates the work done and the resulting kinetic energy.

Rolling Object*
Track
Sonic Motion Sensor
Interface

C = Ball
D = Cylinder
E = Toy

F

G

Pull the lab cart away from the force sensor, which is attached to the cart with a long rubber band. Release the cart and calculate the work done and the kinetic energy that develops.

Lab Cart
Rubber Band
Force Sensor
Motion Sensor
Interface

H

I

Place a mass on the end of a hanging spring. The position where it no longer moves up and down is its equilibrium point. Displace it up or down from that point. Set up a spread sheet to monitor the kinetic, gravitational potential and elastic potential energies throughout a complete cycle of motion.

Spring
Mass
Motion Sensor
Interface

J

K

Place a glider on an inclined air track and attach it to a light spring. With the air flowing, the position where the glider no longer goes down the track, but sits still is its equilibrium point. Displace it up or down the track from that point. Set up a spread sheet to monitor the kinetic, gravitational potential and elastic potential energies throughout a complete cycle of motion.

Spring
Glider
Air Track
Motion Sensor
Interface

NOTES

A/B:

For this lab, you will use a roller skate cart which was state of the art 30 years ago. It should be more interesting than the almost friction-free cart that you're used to using.

C/D/E:

In groups C and D, you will be provided with two different objects with similar shapes. They are somewhat different, though, and your results from one should be compared with the results from the other. Some additional outside research may be needed.

Group E should obtain results from group C as a comparison for the results they get with their rolling object.

F/G:

Group F should conduct the experiment using a level track, while Group G should have the track inclined so the rubber band pulls the cart up the track.

The Force Sensor needs to be calibrated. Hang a mass on a string passing over a pulley. If you use 500 grams, the force will be 4.9 newtons.

You will use a long rubber band that will be provided, and should use the two extra masses in your cart to make a combined mass of around 1500 grams.

The time for this lab to unfold is relatively short. You may need to adjust the time in the program down to see the details more clearly.

H/I:

Use two to four different masses hung from the spring to establish the spring constant.

In an ideal world, the total energy in a conservative system (such as the one you have here) should remain constant. That should be your goal, and you may need to experiment in order to determine where the zero point is for UE to achieve that goal.

J/K:

Please do not stretch the spring beyond its elastic limit. A gentle movement back and forth is sufficient to gather the data in this experiment.


 

Clarence Bakken
Updated 1/13/05.