The stinky, steaming air that escapes from a car's tailpipe could help us use less gas.
Researchers are competing to meet a challenge from the U.S. Department of Energy: Improve fuel economy 10 percent by converting wasted exhaust heat into energy that can help power the vehicle.
General Motors Corp. is close to reaching the goal, as is a BMW AG supplier working with Ohio State University. Their research into thermoelectrics – the science of using temperature differences to create electricity – couldn't come at a better time as high gas prices accelerate efforts to make vehicles as efficient as possible.
GM researcher Jihui Yang said a metal-plated device that surrounds an exhaust pipe could increase fuel economy in a Chevrolet Suburban by about 5 percent, a 1-mile-per-gallon improvement that would be even greater in a smaller vehicle.
Reaching the goal of a 10 percent improvement would save more than 100 million gallons of fuel per year in GM vehicles in the U.S. alone.
“The take-home message here is: It's a big deal,” Yang said.
The DOE, which is partially funding the auto industry research, helped develop a thermoelectric generator for a heavy duty diesel truck and tested it for the equivalent of 550,000 miles about 12 years ago.
John Fairbanks, the department's thermoelectrics technology development manager, said the success of that generator justified the competitive search in 2004 for a device that could augment or replace a vehicle's alternator. Three teams were selected to participate in the program, with GM and thermoelectrics manufacturer BSST separately working on cars and a team from Michigan State University focusing on heavy-duty trucks.
Fairbanks said thermoelectric generators should be on the verge of production in about three years.
“It's probably the biggest impact in the shortest time that I can think of,” he said.
The technology is similar to what NASA uses to power deep space probes, a perk being that it doesn't seem to be susceptible to wear. Probes have used a thermoelectric setup for about 30 years.
Thermoelectric devices can work in two ways – using electricity to provide heating or cooling, or using temperature differences to create electricity.
The second method is Yang's focus, and for good reason.
In an internal combustion engine, only about a quarter of the total energy from gasoline is used to actually turn the wheels, while 40 percent is lost in exhaust heat and 30 percent is lost through cooling the engine. That means about 70 percent of the available energy is wasted, according to GM.
“If I can use some of that heat energy and convert it to electricity, you can improve the overall efficiency,” Yang said.While it's not clear how much the device would add to the price of a vehicle, the whole point of the research is to make it cost-effective, Yang said.
“There are several other steps that are required to commercialize the material, but we're cautiously optimistic that these steps can be carried out successfully,” said Lon Bell, president of BSST, a subsidiary of Northville-based thermoelectrics supplier Amerigon Inc.
BSST also is working with Ford Motor Co. to develop climate control systems based on thermoelectrics.