How Do We Engineer Autos for 54.5 MPG?

Lighter automotive materials and hybrid engines are two engineering approaches towards meeting the Obama administration's goal of 54.5 mpg CAFE standards for automakers by 2025.

Alexander Wolfe

July 29, 2011

3 Min Read
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The Obama administration has cut its 2025 fuel economy target for automakers from 56.2 miles per gallon to 54.5 mpg. Shaving 1.7 mpg from the goal is apparently garnering early positive response from Ford, GM, Chrysler, Honda, and Hyundai.

Nevertheless, tough technical impediments remain towards meeting such a high Corporate Average Fuel Economy (CAFE) bar.

This post isn't going to focus on the proposal. Rather, I'm posing the salient engineering question: How do we get there? We're pretty much already capable of building 40 mpg vehicles, by paring weight through use of lighter materials and using advanced hybrid power plants. I'm not going to get into the issue of the poorer crashworthiness attendant to lighter bodies. Nor do I want to debate the still-moving target of how one defines "fuel" economy for plug-in electrics. Both are important issues, but subjects for separate posts.

My point is, while 40 mpg is mostly achievable, the 50-plus mpg benchmark is, to force an analogy, a gas station too far. Still, if we attack the challenge on multiple fronts, we can get close. Listed below are the areas we'll have to attack.

The Honda CR-Z, rated 37 mpg highway, is the EPA’s highest-mileage gas-engine car.

Materials: This is probably the single most important component in making 54.5 mpg CAFE. Of course, while fiber-reinforced components could significant cut the weight of cars, they'd also send costs soaring to prohibitive levels. I'm oversimplifying, but beyond advanced plastics, many lighter materials pose the same problem. It's possible that some useful advances will come out of the Department of Energy's Vehicle Technologies Program.

Form Factor: Smart car or highway cruiser? On the design side, the question of which provides greater economy answers itself. In terms of what consumers will buy, not so much. This dichotomy is the root cause of automakers' history of fiddling around with their fleets -- e.g., some high-mileage Fiestas alongside numerous F150s -- to conform to CAFE standards.

Powertrains: What's the balance between the size of the gas engine and the electric motor? Are train-like cars (the engine drives a generator, à la the Chevy Volt) really viable, or just a way to allow manufacturers to send paperwork to the government that they're building 93 mpg(e) equivalents?

Tires: Low rolling resistance like we've never seen before, and nitrogen-fill mandatory. What else do we need to do here?

Fuel: Wikipedia has an interesting table showing gasoline gallon equivalents (GGEs). Diesel and biodiesel are roughly equivalent to gas in terms of BTU/gallon. Liquid and compressed natural gas possess far less stored energy per unit. I'd be interested to compare the BTU/unit weights of CNG versus gas. All this relates to the weight issue, which in turn effects achievable mileage.

  • IVHS: We're been talking about Intelligent Vehicle Highway Systems for over 20 years now. (More correctly, we talked about it, then stopped.) Granted, two decades ago, IVHS was blue-sky and implementation was impossible. We're much further along the path to achievability now. Truth be told, the main impediments will soon be political and financial, not technological. It's my personal belief that IVHS is the surest route to better driver and passenger safety as well as "higher mileage." I put that in quotes because by the time IVHS is full baked, fleets are likely to be electric, which offloads the issue of input-energy production to power plants. One would hope they'd be nuclear, but they'll more likely be coal-fired.

    So what do you think are the keys to higher CAFE? Please discuss below.

About the Author

Alexander Wolfe

Alex is Content Director of Design News. Previously, he was Editor-in-Chief of InformationWeek.com. In his more than two decades in the electronics and mechanical engineering sectors, he has served as Managing Editor of Mechanical Engineering magazine and written for Byte.com, McGraw-Hill's Electronics magazine, and IEEE Spectrum. He spent the 1990s at UBM's Electronic Engineering Times, where he broke the nationally known story of Intel's Pentium floating-point division bug in 1994. Alex has appeared as an industry analyst on CNN, CNBC, Fox News, and MSNBC. He's a frequent panelist and moderator at industry conferences and holds a degree in electrical engineering from Cooper Union. He can be reached at [email protected].

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