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Transcript of Seeing biology through an engineer’s eyes - Green & Gold News
(http://greenandgold.uaa.alaska.edu/wp-content/uploads/2015/08/080615VortexRings04.jpg)
Light from a laser illuminates vortex rings made by acomputer-controlled piston and actuator. UAA Assistant
Professor Jifeng Peng and mechanical engineering graduatestudent Zachary Garcia are analyzing vortex rings as part oftheir National Science Foundation-funded research. (Photo by
Philip Hall/UAA)
Seeing biology through an engineer’s eyesAugust 12, 2015
(http://greenandgold.uaa.alaska.edu/wp-content/uploads/2015/08/080615VortexRings08.jpg)
UAA Assistant Professor Jifeng Peng, left, and Zachary Garcia, a UAA mechanical engineering graduate student, areconducting National Science Foundation-funded research into vortex rings. (Photo by Philip Hall/UAA)
Rhythmic contractions jellyfish use to propel themselves through water inspired a UAA engineering assistant professor to apply for—and win—a $174,957 National Science Foundation grant that’s helping him and a graduate student learn more about propulsionefficiency.
Dr. Jifeng Peng (https://sites.google.com/site/jfpengweb/home) and Zachary Garcia, a mechanical engineering graduate student,have, since receiving that 2013-2015 NSF grant, spent their days studying vortex rings—also called vortices—doughnut-shapedrings formed when fluid flows back on itself and spins, looking like a watery version of smoke rings.
Jellyfish drift. They can also move, however, gathering water into their bells and releasing it in pulsing movements forming aseries of these vortices. Peng and Garcia have been creating similar vortices with a tank and computer-controlled piston, andstudying them using a laser and digital particle image velocimetry (DPIV).
“This is a novel propulsion technique,” said Peng, who uses this project asan instructional demonstration and outreach for summer engineering campsessions and high school students’ tours. “If you think about engineering apropulsion system in water, propellers are pretty much the only way. Propellersgenerate a large amount of thrust, but their relative energy efficiency is not ashigh as [the use of vortices]. That’s why we see in nature a lot of animals use thistechnique.”
Squid accelerate by quickly ejecting a pulse of fluid at high velocity. Frenchscientists in 1938 succeeded in photographing “tourbillons(https://books.google.com/books?
id=4GY4AAAAIAAJ&pg=PA190&lpg=PA190&dq=vortex+ring+animal&source=bl&ots=cvr_DxnYqj&sig=lzARnw8GuABeVOFc7K9CZ25YOlM&hl=en&sa=X&ved=0CB8Q6AEwAGoVChMI88qWhpufxwIVRZmICh35fgTB#v=onepage&q=vortex%20ring%20animal&f=false)
(http://greenandgold.uaa.alaska.edu/wp-content/uploads/2015/08/Zach-Garcia-
notes.jpg)Zachary Garcia, a UAA mechanical engineering graduatestudent, is collaborating with UAA’s Dr. Jifeng Peng on
creating and studying varying sizes and frequencies of vortexrings, to see which combinations are optimal for propulsion.
what appear to be vortex rings—behind a pigeon in slow flight, using tobacco smoke to make them visible. Other researchersused talcum powder to highlight and photograph vortex rings in the wakes of hovering insects, and scientists have also claimed toobserve vortex elements in the wakes of flying finches.
‘Like making bubble rings in a pool’
Peng and Garcia use a laser to spotlight particles that follow the pulses of water from the piston. They photograph the pulses anduse DPIV to track the movement of each particle, which measures 14 microns—about the length of three red blood cells laid endto end, in a row.
“It’s like making bubble rings in a pool,” Garcia said, “but what we’re doing, instead of air in the water, we’re making a vortex ringof water in water.”
The piston moves inside the cylinder, generating a vortex ring at the end which, when the piston stops moving, separates andmoves out into the tank.
“It’s kind of hard to see in the water and we want to be able to record the vortex ring so we can analyze it, so what we’ve done isadd silver-covered glass particles,” Garcia said. “They’re hollow so they don’t sink; they just kind of stay buoyant. They’re silvercoated so we can reflect a laser off of them and see them a lot better.”
When Peng and Garcia first started their experiments, they used a raised tank of water and a valve—the valve opened, waterflowed down and they used that rush of water to create a pulse. Then, they used a pump and a valve. The pump pressurized thewater behind the valve, so opening and closing the valve created a pulse of water.
“Mostly what we’ve been trying to do is generate pressure, refine the method,” Garcia said. “It’s been trial and error.” Then, joking,“That’s what grad students are for!”
One of the valves they were using opened and closed quickly, but Peng andGarcia found a computer-controlled actuator could accomplish that task evenfaster—a computer regulates up to 12 volts of electricity that can be supplied tothe actuator—like adjusting a valve on a hose to affect flow.
“At the end is the piston,” Garcia said. “You can turn the valve a little or open it upto allow the maximum amount of power.”
They shine a laser through a lens that splits it into a sheet of light. That sheetbisects the tank and also bisects the vortex rings, allowing the researchers to seetheir cross sections, the swirling rings, and record them with a camera at 30frames per second.
“We can control the pulse length, which then corresponds to the size of the vortexring, and we can also do multiple vortex rings with gaps in between them,” Garciasaid.
That’s key to what they’re studying—the interaction between the vortex rings aswell as keeping an eye on how they interact with the surrounding fluid.
“We look at how the particles change, how their positions change between eachframe,” Garcia said. “We don’t do it by hand; computer programs look at that. Wecan look at the velocity, how it’s moving. You would expect the center to bespinning faster than the outside, things like that.”
Opening new vistas in science
Peng’s bioengineering project is important—figuring out the optimal combination of consecutive vortex size and frequency couldsomeday help engineers devise more efficient submarines and other watercraft, wind turbines and eventually advance researchinto Lilliputian vehicles that could be employed in microsurgery.
“The NSF wanted to cultivate interdisciplinary research,” Peng said. “As a researcher, you’re always looking for a new field ofstudy.”
Written by Tracy Kalytiak, UAA Office of University Advancement.
(//creativecommons.org/licenses/by-nc/4.0/) "Seeing biology through an engineer’s eyes" is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License (//creativecommons.org/licenses/by-nc/4.0/).
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