Iowa State engineer develops laser technologies to analyze combustion, biofuels

How can an engineer find the source of the problem? It originates, after all, in the flame zone of a highly turbulent combustion chamber. That’s not exactly an easy place for an engineer to take measurements.

“It’s fairly obvious when a combustor is not running well and producing a lot of soot and other pollutants,” said Terry Meyer, an assistant professor of mechanical engineering at Iowa State University. “But then how do you solve that problem? To do that we can open up the black box and look inside the combustion chamber itself.”

The tools that Meyer is developing to do that are highly sophisticated laser-based sensors that can capture images at thousands and even millions of frames per second. Those images record all kinds of data about what’s happening in the flaming mix of fuel and air.

“The goal is to probe this harsh environment to provide the knowledge required to reduce pollutant emissions and enable the utilization of alternative fuels,” Meyer said.

By selecting lasers of different wavelengths, Meyer’s combustion sensors can record where pollutants such as soot, nitric oxide and carbon monoxide are being formed. The sensors can also look for unburned fuel and capture data about fuel sprays, fuel-air mixing and energy release.

Meyer’s lab is now working on a two-year project to develop and advance laser techniques that are expected to help engineers improve the combustion systems that move vehicles, produce power and heat buildings. An important goal of the project is to analyze and improve the performance of alternative fuels in modern combustion systems.

Meyer’s research is supported by an $87,000 grant from the Grow Iowa Values Fund, a state economic development program. This grant is supplemented by a contribution of products and engineering expertise from Goodrich Corporation’s Engine Components unit in West Des Moines, a producer of fuel system components for aircraft engines, auxiliary power units, power-generating turbines and home heating systems. ConocoPhillips, the third largest integrated energy company in the United States, is supporting similar projects in Meyer’s lab. The projects are part of ConocoPhillips’ eight-year, $22.5 million research program at Iowa State. Meyer’s research is also drawing interest and support from sources such at the National Aeronautics and Space Administration and the U.S. Air Force.

Meyer started working with laser diagnostics when he was a doctoral student in mechanical engineering at the University of Illinois at Urbana-Champaign. The work continued when he spent six years as a scientist developing and applying laser techniques for the Air Force Research Laboratory at Wright-Patterson Air Force Base in Dayton, Ohio.

He made the move to Iowa State in 2006 and is working to apply some of the military’s sophisticated laser technologies to civilian applications.

And so Meyer’s system of high-speed lasers, frequency conversion units, mirrors and cameras is being built in his Multiphase Reacting Flow Laboratory on the ground floor of Iowa State’s Black Engineering Building.

Its work that could have impacts far beyond his lab. Meyer said his research aims to reduce reliance on fossil fuels, which currently account for 85 percent of the world’s energy use.

Source: Iowa State University

Engineer works to clean and improve engine performance
The five engines in Song-Charng Kong's Iowa State University laboratory have come a long way since Karl Benz patented a two-stroke internal combustion engine in 1879. There are fuel injectors and turbochargers and electrical controls. There's more horsepower, better efficiency, cleaner burning and greater reliability.
Engineers develop a laser solution to power plants slowed by slagging
Quietly, and with little of the fanfare accompanying the relentless surge in gasoline costs, the price of coal has doubled in less than a year.
Smart Home exhibit mixes cool green design with easy high-tech living
Just inside the first floor of Chicago's Museum of Science and Industry's Smart Home, a 20-year-old re-covered Crate & Barrel sofa flanks a cool-to-the-touch, ethanol-burning fireplace that floats in the middle of the room. The flame can also be seen from any of the six thrift-store dining chairs revived in creamy white faux leather and tucked in around the high-sheen, rough-edged slab of a fallen Michigan ash tree given new life as a sculptural table.
Forward step in forecasting global warming
Arizona State University researchers have made a breakthrough in understanding the effect on climate change of a key component of urban pollution. The discovery could lead to more accurate forecasting of possible global-warming activity, say Peter Crozier and James Anderson.
Solution to high energy costs could lie underground
Sandia National Laboratories researcher Georgianne Peek thinks a possible solution to high energy costs lies underground. And it’s not coal or oil. It’s compressed air energy storage (CAES).
Special Coating Greatly Improves Solar Cell Performance
The energy from sunlight falling on only 9 percent of California’s Mojave Desert could power all of the United States’ electricity needs if the energy could be efficiently harvested, according to some estimates. Unfortunately, current-generation solar cell technologies are too expensive and inefficient for wide-scale commercial applications.
New X-ray technique may lead to better, cleaner fuel injectors for automobiles
Standard microscopy and visible light imaging techniques cannot peer into the dark and murky centers of dense-liquid jets, which has hindered scientists in their quest for a full understanding of liquid breakup in devices such as automobile fuel injectors.
NIST helps heat pumps 'go with the flow' to boost output
Air-source heat pumps typically deliver 1 1/2 to three times more heating energy to a home than the electric energy they consume. This is possible because heat pumps move heat rather than convert it from a fuel (as combustion heating systems do). National Institute for Standards and Technology researchers are working to improve the performance of these energy superstars even further by providing engineers with computer-based tools for optimizing heat exchanger designs.

Iowa State engineer develops laser technologies to analyze combustion, biofuels

Related stories:

News discussion: