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Have you ever recovered when you began to slip on ice? Your body ...
Center of Mass Lab 8
Lab Assignment 8: Center of MassInstructor’s Overview
Have you ever recovered when you began to slip on ice? Your body goes into a
type of autopilot state to maintain balance. Most people can't remember
precisely all of the movements that were executed. The human body instinctively
wants to stay upright and the seemingly wild motions that take place in a
recovery of balance are performed to keep the center of mass within the base of
the person. Other examples of the management of center-of-mass include the
following:
•
•
•
•
Bicycle riders tucking as they enter a tight corner turn
Sumo wrestlers vying for dominance in the ring by keeping low to the
ground
Squirrels using their tails as counterbalance mechanisms
Two celestial objects rotating about their mutual center-of-mass
In this lab, you will directly experiment with the concept of center-of-mass.
This activity is based on Lab 12 of the eScience Lab kit. Although you should
read all of the content in Lab 12, we will be performing a targeted subset of the
eScience experiments.
Our lab consists of two main components. These components are described in
detail in the eScience manual. Here is a quick overview:
eScience Experiment 2: In the first part of the lab, you will determine the
angle at which certain objects become unstable.
eScience Experiment 4: In the second part of the lab, you will
experimentally determine the center-of-mass of an irregularly shaped
object.
Take detailed notes as you perform the experiment and fill out the sections
below. This document serves as your lab report. Please include detailed
descriptions of your experimental methods and observations.
Experiment Tips:
eScience Experiment 2
•
•
Do not use a large mass on the string. A significant mass results in a
torque on the block system. I used a paperclip in my experiment.
You may consider setting the block-string system on a cardboard platform.
This allows you to see the location of the string relative to the base of the
blocks. A partner can help you measure the angle of the cardboard support at
the point of instability.
Make sure that your irregular shape is cut out of cardboard.
You may want to also experiment with a regular shape (e.g. square or
rectangle) as a control object to convince yourself of the validity of the
experiment.
Date:
Student:
Abstract
Introduction
From esciencelabs:
Center of mass is the point in space where all the mass of an object bal-
ances. No matter what the object’s shape or how it is moving, the center
of mass moves, as if all the mass of the object were concentrated at
that point.
Experiment 1 – stability of a tower of blocks.
In this experiment, you will test the stability of a stack of
blocks as the angle of the surface the stack rests on
gradually increases. Using a fishing sinker tied to the center of mass,
you will be able to see the position of the center of mass relative to the
base of the object as it begins to tip over.
Procedure:
1. Mark the location of the center of gravity on one side of a wooden
block with a piece of masking tape (the middle).
2. Using masking tape, attach one block above and below your original
so that your center of gravity mark is visible, making a 3-block-high
tower.
3. Use a ruler to measure and cut 30 cm. of string. Tape the string to the
mark on the middle block with 20 cm hanging downward.
4. Attach a sinker to the end of the string. Set the block stack on top of
the ramp, and line the edge of the ramp runway up with the edge of a
table so that the string can dangle.
5. Increase the incline of the ramp runway, and notice the relationship
between when the block stack starts to tip over and the location of the
string. Record your observations in Table 1.
6. Try this out with four blocks stacked. Make sure to move your center
of mass to the middle of the tower (between the second and third
blocks). Record your observations in Table 1.
Note: plumb line is
taped to side at mid-
Section.
can go
Measure
to
same as
makes to
stack
Measure angle of plumb
line to edge of base.
Tilt the blocks until the plumb line
is at the edge of the stack of blocks
This should be as far as you
Without tipping over.
The angle of the stack bottom
the table. It should be the
the angle the plump line
the center line.
Tilt a little more. Does the
fall over?
Now do the same for a stack of FOUR blocks with a plumb line again at the midsection
of the now larger stack. Compare the angle of the four-block stack with that of the
three-block stack. Which angle is smaller? What does this mean in practical terms?
Table 1 - block observations
Results
Based on your results from the experiments, please answer the following
questions:
Block experiments
Block Arrangement
Observations
Three blocks stacked
Four blocks stacked
1.
2.
3.
4.
When did the blocks typically fall over?
Which stack of blocks (3 or 4) had a lower center of mass? Which set
tipped over at the largest angle?
If you were building a skyscraper in a windy city, where would you want
most of the building’s weight to be located?
Consider the following diagram of the three-block system at the point of
instability:
This question involves a calculation, not a measurement.
When you calculate the angle of instability, consider this fact:
The angle of instability occurs when the vertical projection of the center-of-
mass (the plumb line) just meets the edge of the base of the object.
Consider using the trigonometric identity:
tan θ = side opposite / side adjacent.
Calculate the angle of instability of the system for the 3-block system using ratios
with the variable S for the length of a side.
Hint: start with the tangent of θ. You should be able to have the S variable
cancel. Then take the arctan (tan -1).
Angle of instability (θ) =
Repeat this calculation for the four-block system.
Angle of instability (θ) =
How does your result compare to the three-block system? Explain.
Experiment 2.
Center-of-mass experiments
Procedure
1. Use the scissors to cut an irregular shape out of a piece of pa-
per. Any shape will work!
2. Cut a 30-cm length of string and tie one metal washer to each
end. This will function as a “plumb-bob” that hangs down as a
vertical line.
3. Set one side of the physics kit box flush with the edge of a table and
stick a push pin in the cardboard near the top (Figure 6), page 165 of
the escience manual.
4. Punch a hole in three different spots around the edge of the shape,
but not too close together.
5. Hang the shape through one of the three holes on the push pin
making sure the shape can move freely.
6. Hook the plumb-bob to the push pin with the washer.
7. Note how the string hangs across the shape. Make a mark on the
side of the shape opposite the hole in line with the plumb-bob string.
Use this mark to draw a straight line through the shape, from the hole to
your mark.
8. Take the shape and plumb-bob off the pin, and switch to a new hole
on the shape. Repeat Steps 5 - 7 until you have three lines drawn on
the shape
1.
2.
3.
When you hang the shape from the pin, it balances around that point. How
is the mass distributed on either side of the lines you draw when it is hanging
like this?
What does the point where the three lines intersect represent? Explain
why this method works.
Is the third line necessary to find the center of mass? Why or why not?
Hint: I suggest you look up some information on radio triangulation.
Conclusions
References
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Account for the appearance of the long, jumbled, gradual slope outside the crater rim by explaining how the crater might h ...
Account for the appearance of the long, jumbled
Account for the appearance of the long, jumbled, gradual slope outside the crater rim by explaining how the crater might have been formed.
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Most Popular Content
5 pages
Lab 2 Template A
Phase transformations are something we experience every day. We place water situated in compartmentalized trays into the f ...
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Phase transformations are something we experience every day. We place water situated in compartmentalized trays into the freezer to make the ice cubes ...
20 pages
Answer To University Physics Problems Completed
The idea introduced by Max Planck to precipitate the creation of quantum physics is that the energy and the momentum can b ...
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The idea introduced by Max Planck to precipitate the creation of quantum physics is that the energy and the momentum can be quantized so as to deduce ...
2 pages
Minerals
A mineral is a naturally occurring inorganic compound. A mineral can typically be studied in two separate days, chemical c ...
Minerals
A mineral is a naturally occurring inorganic compound. A mineral can typically be studied in two separate days, chemical composition and its physical ...
Center of Mass Lab 8
Lab Assignment 8: Center of MassInstructor’s Overview
Have you ever recovered when you began to slip on ice? Your body ...
Center of Mass Lab 8
Lab Assignment 8: Center of MassInstructor’s Overview
Have you ever recovered when you began to slip on ice? Your body goes into a
type of autopilot state to maintain balance. Most people can't remember
precisely all of the movements that were executed. The human body instinctively
wants to stay upright and the seemingly wild motions that take place in a
recovery of balance are performed to keep the center of mass within the base of
the person. Other examples of the management of center-of-mass include the
following:
•
•
•
•
Bicycle riders tucking as they enter a tight corner turn
Sumo wrestlers vying for dominance in the ring by keeping low to the
ground
Squirrels using their tails as counterbalance mechanisms
Two celestial objects rotating about their mutual center-of-mass
In this lab, you will directly experiment with the concept of center-of-mass.
This activity is based on Lab 12 of the eScience Lab kit. Although you should
read all of the content in Lab 12, we will be performing a targeted subset of the
eScience experiments.
Our lab consists of two main components. These components are described in
detail in the eScience manual. Here is a quick overview:
eScience Experiment 2: In the first part of the lab, you will determine the
angle at which certain objects become unstable.
eScience Experiment 4: In the second part of the lab, you will
experimentally determine the center-of-mass of an irregularly shaped
object.
Take detailed notes as you perform the experiment and fill out the sections
below. This document serves as your lab report. Please include detailed
descriptions of your experimental methods and observations.
Experiment Tips:
eScience Experiment 2
•
•
Do not use a large mass on the string. A significant mass results in a
torque on the block system. I used a paperclip in my experiment.
You may consider setting the block-string system on a cardboard platform.
This allows you to see the location of the string relative to the base of the
blocks. A partner can help you measure the angle of the cardboard support at
the point of instability.
Make sure that your irregular shape is cut out of cardboard.
You may want to also experiment with a regular shape (e.g. square or
rectangle) as a control object to convince yourself of the validity of the
experiment.
Date:
Student:
Abstract
Introduction
From esciencelabs:
Center of mass is the point in space where all the mass of an object bal-
ances. No matter what the object’s shape or how it is moving, the center
of mass moves, as if all the mass of the object were concentrated at
that point.
Experiment 1 – stability of a tower of blocks.
In this experiment, you will test the stability of a stack of
blocks as the angle of the surface the stack rests on
gradually increases. Using a fishing sinker tied to the center of mass,
you will be able to see the position of the center of mass relative to the
base of the object as it begins to tip over.
Procedure:
1. Mark the location of the center of gravity on one side of a wooden
block with a piece of masking tape (the middle).
2. Using masking tape, attach one block above and below your original
so that your center of gravity mark is visible, making a 3-block-high
tower.
3. Use a ruler to measure and cut 30 cm. of string. Tape the string to the
mark on the middle block with 20 cm hanging downward.
4. Attach a sinker to the end of the string. Set the block stack on top of
the ramp, and line the edge of the ramp runway up with the edge of a
table so that the string can dangle.
5. Increase the incline of the ramp runway, and notice the relationship
between when the block stack starts to tip over and the location of the
string. Record your observations in Table 1.
6. Try this out with four blocks stacked. Make sure to move your center
of mass to the middle of the tower (between the second and third
blocks). Record your observations in Table 1.
Note: plumb line is
taped to side at mid-
Section.
can go
Measure
to
same as
makes to
stack
Measure angle of plumb
line to edge of base.
Tilt the blocks until the plumb line
is at the edge of the stack of blocks
This should be as far as you
Without tipping over.
The angle of the stack bottom
the table. It should be the
the angle the plump line
the center line.
Tilt a little more. Does the
fall over?
Now do the same for a stack of FOUR blocks with a plumb line again at the midsection
of the now larger stack. Compare the angle of the four-block stack with that of the
three-block stack. Which angle is smaller? What does this mean in practical terms?
Table 1 - block observations
Results
Based on your results from the experiments, please answer the following
questions:
Block experiments
Block Arrangement
Observations
Three blocks stacked
Four blocks stacked
1.
2.
3.
4.
When did the blocks typically fall over?
Which stack of blocks (3 or 4) had a lower center of mass? Which set
tipped over at the largest angle?
If you were building a skyscraper in a windy city, where would you want
most of the building’s weight to be located?
Consider the following diagram of the three-block system at the point of
instability:
This question involves a calculation, not a measurement.
When you calculate the angle of instability, consider this fact:
The angle of instability occurs when the vertical projection of the center-of-
mass (the plumb line) just meets the edge of the base of the object.
Consider using the trigonometric identity:
tan θ = side opposite / side adjacent.
Calculate the angle of instability of the system for the 3-block system using ratios
with the variable S for the length of a side.
Hint: start with the tangent of θ. You should be able to have the S variable
cancel. Then take the arctan (tan -1).
Angle of instability (θ) =
Repeat this calculation for the four-block system.
Angle of instability (θ) =
How does your result compare to the three-block system? Explain.
Experiment 2.
Center-of-mass experiments
Procedure
1. Use the scissors to cut an irregular shape out of a piece of pa-
per. Any shape will work!
2. Cut a 30-cm length of string and tie one metal washer to each
end. This will function as a “plumb-bob” that hangs down as a
vertical line.
3. Set one side of the physics kit box flush with the edge of a table and
stick a push pin in the cardboard near the top (Figure 6), page 165 of
the escience manual.
4. Punch a hole in three different spots around the edge of the shape,
but not too close together.
5. Hang the shape through one of the three holes on the push pin
making sure the shape can move freely.
6. Hook the plumb-bob to the push pin with the washer.
7. Note how the string hangs across the shape. Make a mark on the
side of the shape opposite the hole in line with the plumb-bob string.
Use this mark to draw a straight line through the shape, from the hole to
your mark.
8. Take the shape and plumb-bob off the pin, and switch to a new hole
on the shape. Repeat Steps 5 - 7 until you have three lines drawn on
the shape
1.
2.
3.
When you hang the shape from the pin, it balances around that point. How
is the mass distributed on either side of the lines you draw when it is hanging
like this?
What does the point where the three lines intersect represent? Explain
why this method works.
Is the third line necessary to find the center of mass? Why or why not?
Hint: I suggest you look up some information on radio triangulation.
Conclusions
References
Account for the appearance of the long, jumbled
Account for the appearance of the long, jumbled, gradual slope outside the crater rim by explaining how the crater might h ...
Account for the appearance of the long, jumbled
Account for the appearance of the long, jumbled, gradual slope outside the crater rim by explaining how the crater might have been formed.
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