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Mimicking humpback whale flippers may improve airplane wing design
EurekAlert! ^ | 5/11/04 | Deborah Hill

Posted on 05/12/2004 7:56:37 PM PDT by FlyVet

Mimicking humpback whale flippers may improve airplane wing design DURHAM, N.C. -- Wind tunnel tests of scale-model humpback whale flippers have revealed that the scalloped, bumpy flipper is a more efficient wing design than is currently used by the aeronautics industry on airplanes. The tests show that bump-ridged flippers do not stall as quickly and produce more lift and less drag than comparably sized sleek flippers.

The tests were reported by biomechanicist Frank Fish of West Chester University, Penn., fluid dynamics engineer Laurens Howle of the Pratt School of Engineering at Duke University and David Miklosovic and Mark Murray at the U.S. Naval Academy. They reported their findings in the May 2004 issue of Physics of Fluids , published in advance online on March 15, 2004.

In their study, the team first created two approximately 22-inch-tall scale models of humpback pectoral flippers -- one with the characteristic bumps, called tubercles, and one without. The models were machined from thick, clear polycarbonate at Duke University. Testing was conducted in a low speed closed-circuit wind tunnel at the U.S. Naval Academy in Annapolis, Md.

The sleek flipper performance was similar to a typical airplane wing. But the tubercle flipper exhibited nearly 8 percent better lift properties, and withstood stall at a 40 percent steeper wind angle. The team was particularly surprised to discover that the flipper with tubercles produced as much as 32 percent lower drag than the sleek flipper.

"The simultaneous achievement of increased lift and reduced drag results in an increase in aerodynamic efficiency," Howle explains.

This new understanding of humpback whale flipper aerodynamics has implications for airplane wing and underwater vehicle design. Increased lift (the upward force on an airplane wing) at higher wind angles affects how easily airplanes take off, and helps pilots slow down during landing.

Improved resistance to stall would add a new margin of safety to aircraft flight and also make planes more maneuverable. Drag -- the rearward force on an airplane wing -- affects how much fuel the airplane must consume during flight. Stall occurs when the air no longer flows smoothly over the top of the wing but separates from the top of the wing before reaching the trailing edge. When an airplane wing stalls, it dramatically loses lift while incurring an increase in drag.

As whales move through the water, the tubercles disrupt the line of pressure against the leading edge of the flippers. The row of tubercles sheers the flow of water and redirects it into the scalloped valley between each tubercle, causing swirling vortices that roll up and over the flipper to actually enhance lift properties.

"The swirling vortices inject momentum into the flow," said Howle. "This injection of momentum keeps the flow attached to the upper surface of the wing and delays stall to higher wind angles."

"This discovery has potential applications not only to airplane wings but also on the tips of helicopter rotors, airplane propellers and ship rudders," said Howle.

The purpose of the tubercles on the leading edge of humpback whale flippers has been the source of speculation for some time, said Fish. "The idea they improved flipper aerodynamics was so counter to our current doctrine of fluid dynamics, no one had ever analyzed them," he said.

Humpback whales maneuver in the water with surprising agility for 44-foot animals, particularly when they are hunting for food. By exhaling air underwater as they turn in a circle, the whales create a cylindrical wall of bubbles that herd small fish inside. Then they barrel up through the middle of the "bubble net," mouth open wide, to scoop up their prey.

According to Fish, the scalloped hammerhead shark is the only other marine animal with a similar aerodynamic design. The expanded hammerhead shark head may act like a wing.

The trick now is to figure out how to incorporate the advantage of the tubercle flipper into manmade designs, said Fish.

The research team now plans to perform a systematic engineering investigation of the role of scalloped leading edges on lift increase, drag reduction and stall delay.


TOPICS: Business/Economy; Miscellaneous; News/Current Events; Technical
KEYWORDS: aerodynamics; aerospace; biomechanics; drag; engineering; fluiddynamics; lift; science; stall; whale
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"The tests were reported by biomechanicist Frank Fish..."

You just can't make this stuff up. Paul Harvey mentioned this today. I'm looking forward to seeing strange-looking wings on future aircraft.

1 posted on 05/12/2004 7:56:39 PM PDT by FlyVet
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To: FlyVet
This is just dying for some of the computer geniouses on this site to create an appropriate image.
2 posted on 05/12/2004 7:58:37 PM PDT by Rokke
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To: FlyVet
I'm not sure why this is such a big suprise, and I've wondered about it in the past...

It's long been known that long, smooth surfaces cause additional drag in laminar fluid flow.

That's why golfballs have the dimples. The balls fly farther than smooth ones.

Mark
3 posted on 05/12/2004 8:00:37 PM PDT by MarkL (The meek shall inherit the earth... But usually in plots 6' x 3' x 6' deep...)
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To: FlyVet
Hae a good friend that was an F-4U pilot that shot down 2 Migs in Korea named Frank Fisch. It's not Fish, but close!

Along the lines of improving lift, drag, etc., i've had in the back of my mind for over 20 years that props should have winglets facing forward. The "Q" tip props weren't successful (facing backward) just as the droop tip Cessna wing wasn't successful, they turned it the wrong direction!
4 posted on 05/12/2004 8:18:48 PM PDT by dalereed (,)
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To: FlyVet
I would venture a guess that these tubercles would not work so good at higher speeds. They might work well for Pipers, slower aircraft but probably not so good on airliners or fighters.
5 posted on 05/12/2004 8:19:27 PM PDT by El Gran Salseron (It translates as the Great, Big Salsa Dancer, nothing more. :-))
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To: FlyVet
I don't like this for one reason, whales don't fly.
6 posted on 05/12/2004 8:23:57 PM PDT by Pylon (NSD 7-4-69 12-24-87)
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To: Pylon
I don't like this for one reason, whales don't fly.

You no doubt base that wild assertion on the fact that you have probably never seen them fly, right?

7 posted on 05/12/2004 8:26:48 PM PDT by Hank Rearden (Is Fallujah gone yet?)
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To: FlyVet
Southwest's on the case.

<|:)~

8 posted on 05/12/2004 8:27:03 PM PDT by martin_fierro (Action figure sold separately)
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To: FlyVet

9 posted on 05/12/2004 8:38:45 PM PDT by Reeses
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To: FlyVet
1. We already know about tripping boundary layer turbulence to prevent on the onset of separation which both lowers lift and increases drag.

2. A wing designed to function like a whale may be good for very low speed incompressible flow wings. Unfortunately all commercial aircraft fly in a faster flow regime.

3. Why are we surprised that a creature that lives in the water has a body designed for swimming in water?
10 posted on 05/12/2004 8:39:29 PM PDT by miner89 (Wherever you go, there you are)
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To: FlyVet

11 posted on 05/12/2004 8:41:06 PM PDT by Reeses
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To: FlyVet
All our lives we were told the most important invention was the wheel; yet had we a knife first and the fruit of a citrus tree we would, through trial and error, have disclosed a wheel replete with spokes - but whence came the axle?
12 posted on 05/12/2004 8:42:19 PM PDT by Old Professer
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To: Pylon
Tell that to a hapless fish.
13 posted on 05/12/2004 8:43:43 PM PDT by Old Professer
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To: Reeses
I always thought they had bad eyesight or were poor navigators and those protuberances were but the evidence of hard-won victories.
14 posted on 05/12/2004 8:46:26 PM PDT by Old Professer
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To: Hank Rearden
You no doubt base that wild assertion on the fact that you have probably never seen them fly, right?

That depends, are we talking sober?

15 posted on 05/12/2004 8:53:14 PM PDT by Pylon (NSD 7-4-69 12-24-87)
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To: FlyVet
If they build it, I promise to try to fly it............FRegards
16 posted on 05/12/2004 8:53:30 PM PDT by gonzo (Hey, it's tough dealing with Tourettes Syndrome! So %$#@(*&+#$ and &$*&@# yer cat!)
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To: MarkL; Pylon; El Gran Salseron
Given the relative viscosity of the two fluids, a whale compares to a fairly fast moving aircraft. Penguins "fly" on pretty stubby wings, as do supersonic aircraft.

FYI, 1,519 10E-6 (m2/s) is the kinematic viscosity of water at 5 degC, compared to 17.2 10E-6 (m2/s) for air at 1 bar and 40 degC, courtesy of www.engineeringtoolbox.com.

I'm not an aeronautical engineer, so I can't tell you quickly what T/P conditions prevail at various Mach levels and altitudes at a leading edge. Apply a 25 fold velocity difference, though, and whales begin to look like jets, operating in similar viscosities.

17 posted on 05/12/2004 9:13:20 PM PDT by yatros from flatwater
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To: miner89
Plagiarizing old stuff for grant money

This is old stuff. My father, an old time aerodynamist was one of the 2 original founders of the American Helicopter Society with 80 patents, (He worked with Igor Sikorsky, Stan hiller, frank paisecki and even spent time with Charles Lindbergh) sat next to a guy at Aerojet in the 50's who invented Vortex generators, those little tabs you see on the leading edge on the wings of commercial aircraft. Does the same thing.

I do like the bumps on the whales nose, should try that one on a sub
18 posted on 05/12/2004 9:15:04 PM PDT by underbyte (Arrogance will drop your IQ 50 points)
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To: Reeses

Name that Senator.

19 posted on 05/12/2004 9:25:02 PM PDT by Jeff Chandler (Why the long face, John?)
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To: underbyte
Plagiarizing old stuff for grant money
 
Hey that guy with the suit covered with question marks (Lesco?) is responsible, but on the series side, the first thing that came to mind was Golf Balls have dimples that make them more aerodynamic.
 
(Just  a laymans Opinion)

20 posted on 05/12/2004 9:41:04 PM PDT by TexasTransplant (The Democrats would rather win the WH than the War against Islamic Extremists)
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