Air is Strong!

Posted on May 15, 2012 by


Figure 1.  The vacuum “lift”

This is a photo of a science fair project that sought to test how much weight a canister vacuum cleaner could ”lift.”  It started with a demonstration that can be done with any vacuum cleaner: we tried picking up balls of various sizes.  No ordinary shop vac with a normal-sized hose can lift a bowling ball, but with a simple modification, any vacuum cleaner can easily lift a bowling ball.  The key to the whole experiment is surface area.

Before getting into the details, I should point out there really is no such thing as suction as most people (myself included) think of it.  The common thought is that vacuums exert a force that pulls objects into them.  Hence the terms “lift” “suck” and “pick up” which are often used to describe vacuuming.  That is not the case.  In actuality, objects entering the hose of a vacuum cleaner are being pushed into it.

Most people recognize that vacuum cleaners work by blowing air out of the canister, which creates a vacuum inside which in turn, “draws” air in on the suction side (figure 2).  However, many people don’t realize that the low-pressure vacuum inside the canister isn’t actually pulling air into the vac.  Instead air near the inlet hose is getting pushed in by the surrounding atmosphere because there is greater pressure outside the canister than in.


Figure 2.  How a canister vacuum works.

Another way to think about it is to consider what happens to a dust bunny when it is vacuumed.
The figure below shows how my mind thinks a vacuum cleaner works: that is, when the hose is placed above a dust bunny, the air rushing into the hose pulls the bunny into the hose.  My mind wants to think of suction as a pulling force.

Figure 3.  Wrong concept of suction (it is not a pulling force)

However, what is actually happening when a dust bunny gets “sucked” into or “picked up by” a hose.  The object isn’t pulled in at all.  Instead, atmospheric air is pushing the object into the hose from underneath.

Figure 4. Correct concept of suction (a pushing force):

For practical purposes, it may not matter to most people whether the dust bunny is pushed or pulled, only that it comes out from under the end table.  However knowing that it is the air pushing objects toward the hose takes on a new level of impressiveness when one observes air holding up a 409 pound box!

This is how the original experiment went:  there was a collection of balls of different mass, each having a diameter larger than the mouth of the hose, that I would ask the students which ones they think a vacuum cleaner could “lift”  They all make their votes, then we try them one at a time.  With the vacuum running, the hose is lowered  down onto a ball until it forms a seal, then I attempt to rase the hose with the ball and hose in tact.

I use a 5 gallon shop style vacuum cleaner, so it easily lifts a racket ball, baseball and softball.  It even lifts a 5 pound sand-filled workout ball.  But when we get to the bowling ball, the hose forms a good tight seal, but as soon as I try to lift, the seal is broken, end the hose separates from the ball.  I then introduce the concept of pressure, and see if we can devise a way to lift the ball.

P=F/A

This formula states that pressure is equal to force divided by area.  On earth, we have a very dense atmosphere; it exerts a force of 15 pounds per square inch.  If you don’t think that is very much, try to remove a glass-carrying suction cup that has been sealed to a smooth floor.  It has a surface area of about 7 inches.  So when it forms a seal to a smooth surface with the air underneath removed, it takes 100 pounds of force to overcome the air pressure pushing down on it!

The vacuum cleaner experiments illustrates the force of the air pushing on an object as well.  When the seal forms between the object and the hose, air pressure pushes on the object to keep the object pressed against the mouth of the hose.  And it takes several pounds of force to counter act the pushing force of the atmosphere to break the seal.  So if the object is heavy enough, its weight will exert enough force to break the seal.

Notice from the equation above, however that pressure has to do with both force and area.  So, for a given pressure if the area is increased, so is force.  So in our experiment, we secure a funnel to the end of the hose to increase the area (figure 6).  In so doing, the same air pressure can “lift” more weight.


Figure 5.  A funnel increases area to create a larger area of low pressure.

This is an experiment you can try at home.  Just make sure the funnel is securely taped to the end of the vacuum cleaner hose, and try lifting up something heavy.  Pretty impressive!

The homeschooler who performed the experiment shown in figure 1 wanted to try an even larger surface area.  So he built a disk having a diameter of 18 inches.  This created an area over 80 times greater than the hose, and therefore a force over 80 times greater.  The picture (figure 1) shows the device being held PUSHED against the disk on top by air pressure.  We loaded over 409 pounds in the box before the seal finally broke!

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Magnifying weight: It’s all about acceleration

Posted on May 10, 2012 by


Periodically, I use bathroom scales for experiments.  (However instead of calling them scales, I prefer the term forceometer, because they are very good at measuring the gravitational force of attraction between the earth and an object).

I’ve found that I cannot leave forceometers lying around in the workshop when kids (particularly boys) are present.  They cannot avoid the temptation to jump on them to see if they can “peg” the needle.  I can’t fault them too much though, because they are doing good empirical research.  And what they find is that it really is not all that hard to have a “weight” over 300 pounds for a very brief time.  It’s all in the acceleration.

Another place to see this phenomenon is with the stomp rocket.  Students learn very quickly that there is a direct correlation between force of stomp and distance the rocket travels.  What they may not realize that they are simply following Newton’s first law to generate a large force by maximizing acceleration.

F = ma

The above formula tells us that force is proportional to acceleration.  Acceleration is change in speed, therefore the faster an object’s (or boy’s) speed changes, the larger the force.

In the picture below, the boy is going to be accelerated by gravity as he free-falls over the entire distance that he falls. Then he is going to lose all his speed over a very short distance, so his acceleration will be much higher than gravity.  (we’ll talk more about g force in a separate post)

If the student were to simply stand on the stop rocket pad, he would exert a force equal to his own weight.  With a few calculations, we can estimate how much extra force he will generate by falling from a height of 40 cm.

Knowing that gravity will accelerate him downward at a rate of 9.8m/s per second, it is possible to determine that his velocity just before he hits the stomp rocket pad will be about 2.8 m/sec.  When he hits the stomp rocket pad, he will lose all that velocity while traveling only about 7.5 cm, which would take about 6/100 of a second.  So his stopping acceleration would be 21.23 m/sec per second, which is a little more than twice normal gravity, so he would exert a force of twice his weight by simply free-falling 40cm.

Everyone knows that stomp-rocketers won’t just free-fall; at the last moment, they’ll forcefully extend their legs to stomp, which cuts the acceleration time in half or a third so that the total force exerted would be four or even six times his own weight.  For a 50 lb kid, that could mean a total impact force of 300 pounds, which is enough to peg the needle on my forceometers (bathroom scales).  And that is why I’ve learned not to leave the forceometers lying around in the workshop, and instead make sure I have plenty of stomp rockets on hand!

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Babies that don’t look anything like their parents

Posted on December 30, 2011 by


One axis that is helpful in the life-cycle arena is comparing organisms that exhibit different types of development.  That may include:

  • Complete and incomplete metamorphosis in insects
  • Metamorphosis in amphibians
  • Alternation of generations in plants

This article discusses investigations of invertebrates that undergo complete metamorphosis.

Step 1) Find insects.  In Fairbanks Alaska during the winter, this can be a bit difficult.  However, it is fortunate that we have a largish pet store here in town.  A great organism for hands-on insect investigation is the Darkling beetle (Zophobas morio) larva, otherwise known as the superworm.  Note that the term “worm” is a misnomer, because they are in fact insect larva with 3 pairs of fully-arthropodic legs. Second, the “super” part is a takeoff from the more common meal worms.  Meal worms are also beetle larva.  For hands-on insect explorations, however, I highly recommend the superworms over the meal worms for several reasons:

1) superworms are much larger
2) superworms are far more active
3) superworms are really tough, and hold up well to handling (and the occasional drop)

The one downside with these organisms is that the adults are reported to put off a fairly offensive odor.  So, if you purchase a tub of darkling beetle larva, you’ll want to have thought through an exit strategy to employ after you have finished experimenting with these organisms.  Fortunately for me, I know several families who raise chickens and ducks, who are glad to take these tasty snacks home for their pets.

Step 2) Experiment.  Here are a few investigations kids can do with superowrms, as usual, the list of the ideas goes in increasing difficulty, but as usual older kids are not discouraged from doing any of the projects.  It continues to be my experience that many kids like to revisit certain activities they’ve done before, and I am sure they learn something new in the process.

  • Count legs (if child hasn’t seen one before, begin the investigation by not telling them what the organism is), then let them guess.
  • Measure length
  • Measure burrowing rate – how fast will a darkling beetle dig into the food medium
  • Observe burrowing behavior (notice that often darkling beetle larva travel in reverse!)
  • Observe larva’s behavior when placed on a table top
  • Observe the larva’s behavior when placed in a small pile of food medium on a table top (generally, they will venture out, in a few directions, recognize where the boundary is, then burrown into the pile and stay there)
  • Build a track and place potential food items along the path observe the insect’s behavior
  • Build a track and place piles of potential burrowing stuff
  • Build a maze and place potential food items at regular intervals
  • Build a maze and place piles of potential habitat (wood shavings, grains, etc)


Math ideas

  • Count legs
  • Measure lengths of larva
  • Calculate the animal’s rate of travel.
    • Measure how far the insect travels in a given time (say 10 seconds)
    • Measure how long it takes for the insect to travel a given distance (say 100 cm)
  • Calculate average length of 3 or more larva
  • Calculate average rate of travel of 3 or more larva

Take it further.

1) Look up the following vocabulary words:

  • Egg
  • Larva
  • Pupa
  • Adult
  • Metamorphosis

2) Study darkling beetle life cycles.  How long, on average do they spend as larva, pupa and adults.

3) Find photographs of adult darkling beetles online.

Please let me know how you enjoy working with these interesting organisms.

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Welcome Mad Scientists

Posted on December 1, 2011 by

This is the place for all things Mad Science.  My goal is to share my favorite science and math projects, activities and experiments that can be performed using every-day materials found around the house.  I also provide detailed instructions, links and background information in addition to datasheets and tips for making accurate measurements.  My hope is that classroom teachers, homeschool parents, and mentors of all types will find the resources they need to help inspire and engage the next generation of scientists.

Of course, I’m just one person.  If you would like to become a contributor, sharing science and math activities and experiments for which you’ve had good success, please go to the join page.

I hope you enjoy the pages of activities, ideas and resources that help make learning fun!

Dr. D

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