The Science Of Flying A Kite

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Kites fly because of the aerodynamic forces of lift and drag. The lift is created by the difference in air pressure on the top and bottom of the kite. The drag is created by the friction of the air flowing around the kite. The weight of the kite is balanced by the lift. The thrust is created by the wind blowing on the kite.

If you’ve ever flown a kite, you would probably vouch for the fact that it’s not easy the first time. In fact, even after you’ve got yourself acquainted with flying kites, it takes a great deal of skill to keep a kite airborne in changing wind patterns and perform maneuvers like rapid climbs, quick dives and cutting others’ kites.

In this article, we will introduce you to the science of flying a kite, in the hope that the knowledge of various physical forces involved in kite-flying may give you a head start in acquiring this unique skill.

Forces Involved In Kite-flying

Anything that flies in the air with the hope of staying airborne for more than a few seconds experiences a host of physical forces, including aerodynamic lift, drag, weight and thrust, all of which are supplied by different factors. For an object to stay airborne, it must maintain a neat balance between these forces. They work on everything in the same way, irrespective of its size, from a gigantic Airbus to something as small and light as a kite.

Forces involved in flying a kite
Forces involved in flying a kite

Many of us (except physics nerds) may not have realized that, just like rockets and airplanes, there are different phases of flying a kite too. These different stages are release, launch, climb and cruise, although they aren’t as clearly defined as in the flight of airplanes or rockets.

Also Read: Why Can’t We Throw A Frisbee With Two Hands?

Release And Launch

To get the kite airborne, first of all, you need to provide it with enough lift to counteract its own weight. Although there are numerous factors (e.g.,the shape of the kite, its motion in the air, quality of air, etc.) that affect the amount of lift produced in a kite, the principal contributor is the velocity of air that goes by the kite. The design of kites helps too; if you notice, they are made of a very light (but rigid) material and have minimal accessories (in the form of thin, wooden spokes) attached to them. Their shape is also streamlined (with a pointed leading corner) to help them split the oncoming air.

structure of a kite
The aerodynamic shape of a kite helps it to fly

On a windy day, after telling your friend to hold the kite in the direction of the wind, you will give the kite some initial velocity before releasing it. Now, all you need to do is give the kite a little tug to lift it in the air. On non-windy days, though, your friend may have to move backwards a little to get the kite flying. Running with the kite also helps to create an ‘apparent wind’ that pushes the kite up. However, once released, you (and your pal) don’t necessarily need to run to impart velocity to the kite, as the velocity of wind usually increases with increasing altitude, which in turn provides enough lift to keep the kite rising in the air.

Also Read: What Physics Are Involved In The Working Of Sailboats?

Climb And Cruise

After the kite has been successfully launched, it will continue to climb into the sky with the help of well-timed, skilled tugs of the string before cruising at a general altitude. For a kite to cruise, all the forces and torque acting on it should be balanced. If by any means (like, if you hand the control of the string to an inexperienced kite-flier, such as your dog/cat) that balance is disturbed, the kite will start moving, swooshing or dipping until the forces are re-balanced. For example, when you pull the control string, the velocity of the kite increases slightly, which boosts the lift, consequently making the kite climb. Similarly, when you let go of the string a bit, the kite loses altitude due to the increased weight of the string and dips until it’s pulled back up by tugging at the string.

Kite fight

In some countries (like India), people play a game of ‘downing’ others’ kites by cutting their control strings with theirs. To do that, a person first brings his own kite in proximity to someone else’s so that both of their control strings touch, and then rapidly pull at his own control string to cut the other’s string, thereby ‘downing’ their kite. Note that the string used in such kite-contests is not ordinary kite string, but is instead made of highly abrasive materials and is therefore not safe for use by children.

Flying a kite can be really fun, I can tell you that. However, I won’t give you any false hope by saying that the skill of flying kites is an easy one to master. That being said, some knowledge of the physics involved in flying a kite will definitely give you an edge while learning how to master this pleasant pastime.

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References (click to expand)
  1. Kites - NASA. The National Aeronautics and Space Administration
  2. How Kites Fly | National Air and Space Museum. The National Air and Space Museum of the Smithsonian Institution
  3. Kite - Wikipedia. Wikipedia
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About the Author

Ashish is a Science graduate (Bachelor of Science) from Punjabi University (India). He spearheads the content and editorial wing of ScienceABC and manages its official Youtube channel. He’s a Harry Potter fan and tries, in vain, to use spells and charms (Accio! [insert object name]) in real life to get things done. He totally gets why JRR Tolkien would create, from scratch, a language spoken by elves, and tries to bring the same passion in everything he does. A big admirer of Richard Feynman and Nikola Tesla, he obsesses over how thoroughly science dictates every aspect of life… in this universe, at least.