Monday, October 13, 2014

Lab: Conservation of energy 2

Lab: Conservation of energy 2

Purpose:
Verify the conservation of energy using air track.

Equipment:
Air track, cart, ruler, air source, and motion sensor.

Experiment:
1.  Set up the apparatus as the pictures show.
2. Turn on the air source and lift up the air track with certain angel so that the cart slide down.
3. Measure the distance of two magnet, and write down the angle and the distance.
4. Repeat step two and three with different angles.
5. Calculate the force acting on the cart by the formula F=mgsin(deta).
6. Enter the data into the logPro and click curve fit with power model to get the relationship between the distance and the force.
7. Integrate the force to get the formula of the work done by the force. Take the opposite of the work as the potential energy of the cart.
8. Turn on the air source, give the cart an initial velocity, and record the motion of the cart.
9. Get a new calculated column of the Kinetic Energy of the cart, Potential Energy of the cart, and the total energy of the cart.




Result:
F=0.0003785*x^-1.792


Conclusion:
Within the a certain error, the total energy of the cart is conserved. Therefore, it verify the law of conservation of energy.

Lab: Verification of conservation of energy

Lab: Verification of Conservation of Energy

Purpose: 
Use the spring and hanging mass to verify the conservation of energy.

Equipment: Spring, Hanging Mass, motion sensor

Experiment:
1. Set up the apparatus as pictures show
2. Measure the length of the spring without hanging mass Lo.
3. Hang a known mass on the spring, measure the length of springL.
4. Calculate the spring constant k by the equation mg=k(L-Lo).
5. Derive the formula for the kinetic energy of mass, gravitational potential energy of mass, elastic potential energy of the spring, gravitational potential energy of the spring, and kinetic energy of the spring.
6. Pull down the mass with certain distance, release the mass and record the motion of the mass.
7. Add new calculated column for kinetic energy of mass, gravitational potential energy of mass, elastic potential energy of the spring, gravitational potential energy of the spring, and kinetic energy of the spring.
8. Add new calculated column named total energy as the sum of all calculated energy.
9. Graph all calculated energy and total energy in the same graph.
Apparatus

 Formulas:





Results:





Conclusion:
The total energy is around a constant, therefore the energy of the system is conserved.

Monday, October 6, 2014

Lab: Verify the integral of the force with respect to the distance is equal to kinetic energy of the block

 Lab: Verify the integral of the force with respect to the distance is equal to kinetic energy of the block

Purpose:
Through the motion of the block pulled by the spring to verify the integral of the force with respect to the distance is equal to kinetic energy of the block.

Equipment:
track, block, spring, motion sensor, force sensor.

Experiment:
1. Set up the apparatus as the pictures show.
2. Calibrate the force sensor, and zero it.
3. Stretch the block and the spring to a certain length.
4. Release the block and record the position and force.
5. Add calculated column of Kinetic Energy.
6. Do the integral of the force.
7. Click examine and move the mouse along the Kinetic Energy curve with the same portion of the integral of the force. Record the value of the integral of the force and Kinetic Energy.
8. Change the range of the integral and record the value in two other different place.






Result:




Number one: 
Integral: 0.8197m*N
Kinetic Energy: 0.636J

Number second: 
Integral: 1.203m*N
Kinetic Energy: 1.164J


Number three: 
Integral: 1.556m*N
Kinetic Energy: 1.331J


Conclusion:
 Within a certain error, the integral of the force with respect to the distance is equal to kinetic energy of the block. The work done by the force convert into the Kinetic Energy of the block.

Lab: Finding the power of the work

Lab: Finding the power of the work

Purpose:
Learn about how to calculate the work and power by measuring the force, distance and time.

Equipment:
Mass, pulley, string, timer

Experiment:
Part 1:
1. Each person walk and run up the stairs and measure both the time t to get to the second floor.
2. Count how many stairs are there.
3. Measure how high is each stair.
4. Calculate the height that the person travel.
5. Use W= mgh to calculate the work done by person against the gravity.
6. Use P=W/t to calculate the power of the work.

Part 2:
1. Set up the pulley system on the second floor.
2. One person stands on the first floor and pull the backpack with a mass, the other person stand on the second floor and record the time it takes for the backpack being pulled up to the second floor.
3. Record the weight of the mass.
4. Use W= mgh to calculate the work done by the person against the gravity.
5. Use P=W/t to calculate the power of the work.





Calculation:

Result:
Part 1: 
W=3032.12J, Pwalk=216.27W, Prun=489W

Part 2:
W=389.87J, P=97.46W

Conclusion:
We learn about how to calculate the work and power by measuring the force, distance and time.