For release: March 6, 2000
Contacts:
David Jiles, Metallurgy and Ceramics, (515) 294-9685
Bill McCallum, Metallurgy and Ceramics, (515) 294-4736
Susan Dieterle, Public Affairs, (515) 294-1405
Material for automotive sensor under development at Ames Lab
Technology could be lightweight alternative to hydraulic power-steering
systems
AMES, Iowa -- A material developed at the U.S. Department of Energy's Ames Laboratory may
steer automotive companies toward their goal of lighter, more fuel-efficient vehicles.
Researchers say a ΒΌ-inch-thick ring of the material could be used in an electronic torque
sensor to regulate the steering power provided to a car's wheels by an electric motor.
This would enable automakers to eliminate the heavy, energy-draining hydraulic pumps
currently used in power-steering systems.
"Replacing the hydraulic power-steering system with an electrical system that uses
this type of sensor should improve the fuel efficiency of a car by about 5 percent,"
said David Jiles, a senior physicist at Ames Lab and a professor of materials science and
engineering at Iowa State University. Lighter, more energy-efficient vehicles would use
less gasoline, conserving fossil fuels and reducing transportation costs, he added.
Jiles and Bill McCallum, a senior Ames Lab materials scientist and an ISU adjunct
professor of materials science and engineering, looked at a number of options during the
past five years as they searched for an inexpensive sensor material that met the
specifications of the auto industry. They said only one viable option emerged: a composite
consisting of cobalt ferrite (a compound of cobalt oxide and iron oxide) and small amounts
of nickel and silver to hold the material together.
"I think we've looked into all of the possibilities and it's difficult to conceive of
a better material at this time," Jiles said. "The fact that it's also a
relatively low-priced material makes it very attractive."
He said current power-steering systems use a hydraulic assist that requires the continuous
circulation of hydraulic oil in order to sense and respond to steering changes. This
produces a constant drain on the car's engine, even when the steering wheel isn't being
turned. "The hydraulic system has to be pressurized in order to work and the car uses
up energy to do that," Jiles said. "Also, the hydraulic system weighs a lot, so
there's a significant weight reduction if you can replace it with an electrical
system."
A sensor using a small ring of the cobalt-ferrite composite would be strategically placed
on the steering column. As a driver turned the wheel, the magnetization of the
cobalt-ferrite ring would change in proportion to the amount of force applied by the
driver. The change would be detected by a nearby field sensor that would interpret how
much force should be applied to turn the wheels and then relay the information to an
electrical power-assist motor. Unlike the hydraulic system, the electrical system would
consume minimal energy when the steering wheel was not being turned.
What makes the cobalt-ferrite composite ideal for this application is a property known as
magnetostriction, Jiles said. Magnetostrictive materials undergo slight length changes
when magnetized. Jiles and McCallum take advantage of that property, but in reverse. In
their approach, the turn of the steering wheel would apply stress to the cobalt-ferrite
ring, producing a change in the magnetic field it emits.
Cobalt ferrite maintains its magnetostrictive abilities throughout the temperature range
specified by the auto industry, from minus 40 degrees C (minus 40 F) to 150 C (302 F).
Jiles said that's necessary because automakers don't agree on the best location on the
steering column for the torque sensor. Some want it in the passenger compartment while
others want it in the engine compartment, where it would be subjected to engine heat as
well as winter conditions.
McCallum added that cobalt ferrite also meets the strength and corrosion-resistance
requirements for the sensor material. "This ceramic-metallic composite is similar in
concept to materials used in high-strength tool bits where excellent mechanical properties
are needed," he said. "And cobalt ferrite is basically high-class rust, so it's
hard to corrode any further."
Jiles said the composite is also a cost-effective choice. While other materials may rank
higher in terms of magnetostriction, they're too costly to be used in wide-scale
production. For example, Terfenol-D is a rare-earth, magnetostrictive compound that Ames
Lab helped develop in the 1980s, exploring the compound's phase equilibria and
single-crystal growth anisotropy. It possesses a much higher degree of
magnetostriction, especially as a single crystal, but can cost up to 100 times more than
the cobalt-ferrite composite.
"If you normalize the measurements based on the cost of the different materials,
you can see that our cobalt-ferrite material is far and away the best performer,"
Jiles said.
Electronic torque sensors would also allow steering systems to be fine-tuned with the
addition of software and other controls. "With a hydraulic power-steering assist,
there's not much that you can do," Jiles said.
The sensors may also be part of the development of "smart" cars that are capable
of adapting to an individual's driving style. "You may eventually have something like
a neural network in your car that learns about your driving characteristics as you
drive," Jiles said.
Jiles and McCallum have applied for a patent on the cobalt-ferrite compound and plan to
continue working with automotive manufacturers interested in using the material in an
electronic torque sensor.
Much of the research on the sensor material was funded through an $820,000 grant they
received in 1996 from the Department of Energy's Advanced Energy Projects Division. One of
the DOE's primary missions is to engage in research that leads to the development of
materials that improve the efficiency, economy, environmental acceptability and safety of
energy sources.
Ames Laboratory is operated for the DOE by ISU. The Lab conducts research into various
areas of national concern, including energy resources, high-speed computer design,
environmental cleanup and restoration, and the synthesis and study of new materials.
To view a graphic representation of the sensor, click here.
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