Approximately 90 percent of the world’s electricity is generated by heat energy. Unfortunately, electricity generation systems operate at around 30 to 40 percent efficiency, meaning around two thirds of the energy input is lost as waste heat. Despite this, the inefficiency of current thermoelectric materials that can convert waste heat to electricity has meant their commercial use has been limited. Now researchers have developed a thermoelectric material they claim is the best in the world at converting waste heat into electricity, potentially providing a practical way to capture some of the energy that is currently lost.
The new material, which is based on the common semiconductor telluride, is environmentally stable and is expected to convert from 15 to 20 percent of waste heat to electricity. The research team, made up of chemists, material scientists and mechanical engineers from Northwestern University and Michigan State University, say the material exhibits a thermoelectric figure of merit (or “ZT”) of 2.2, which they claim is the highest reported to date.
The higher a material’s ZT, the more efficient it is at converting heat to electricity. While there’s no theoretical upper limit to ZT, no known materials exhibit a ZT higher than 3. The researchers believe with a ZT of 2.2, the new material is efficient enough to be used in practical applications and could usher in more widespread adoption of thermoelectrics by industry.
"Our system is the top-performing thermoelectric system at any temperature," said Mercouri G. Kanatzidis, who led the research. "The material can convert heat to electricity at the highest possible efficiency. At this level, there are realistic prospects for recovering high-temperature waste heat and turning it into useful energy."
With the huge potential for thermoelectrics to recover some of the heat energy that is currently lost, they have been the focus of much research that has seen them improve significantly in recent years. So much so that the Mars rover Curiosity features lead telluride thermoelectrics, although its system only has a ZT of 1. BMW is also testing systems to harvest the heat from the exhaust systems and combustion engines of its cars.
Aside from capturing some of the wasted heat energy emitted through a vehicle’s tailpipe, the new material could be used in heavy manufacturing industries, including glass and brick making, refineries, and coal- and gas-fired power plants, and on large ships and tankers, where large combustion engines operate continuously. Such applications are seen as ideal as the waste heat temperatures in these areas can range from 400 to 600 degrees Celsius (750 to 1,100 degrees Fahrenheit),which is the sweet spot for thermoelectrics use.
The team’s paper describing the development of the new material is published in the journal Nature.
Source: Northwestern University
ought to work!
Thermoelectric would work to capture some of the energy going out the tailpipe - and hopefully even some of the convection heat. Yes, thermoelectric should eliminate the alternator, and ideally would be another energy input into a hybrid system.
You could conceive of a "limp" mode in which you've run out of gas, but you found some other kind of fuel, and you could operate off the thermoelectric and slowly work your way into a gas station. That may be pie-in-the-sky - but I remember KITT (the Knight Industries Two Thousand) could work off any combustible fuel - even blood!
If the waste heat is residue after the engine has extracted the energy that it can from it (exhaust gas) or from the engines cooling system a sterling cycle engine stands to give greater efficiency. If the engine is heating the room it is in a tall chimney and small wind turbine might give greater efficiency.
Standard Peltier junction cooling "chips" aren't very efficient, they produce much more heat on the hot side than they move away from the cold side. They're great for cooling small things quickly or larger spaces like coolers less quickly but there has to be a good method of moving the heat away.
'Course those devices are optimized for heat transfer and are horrible at converting temperature differentials into electricity.
They can be stacked and connected in series one manufacturer's specification can be run to around 200C 392F and the minimum temperature is -150C -238F.
The best location for such devices would be on the exhaust from heating systems in the Arctic and Antarctic. Stick the cold end outside and you have free electricity. (Free aside from the cost of the Peltier stacks.)
Since electric heat is 100% efficent- I'd wonder when the flip side would be true.
We have considered the viability of this application.