Charles Murray

January 8, 2013

3 Min Read
Ford Builds Metal Prototypes With 3D Printing

Ford Motor Co. is raising the stakes in rapid prototyping, making testable prototype metal parts ranging from brake rotors to transmission cases with three-dimensional (3D) printers.

Using technologies such as selective laser sintering, stereolithography, and 3D sandcasting, Ford engineers say they're able to build metal parts with the same material characteristics as those that are injection molded, and then employ them as "surrogate" parts in test vehicles prior to production. Doing so enables them to eliminate the time-consuming step of building an injection molding tool, thus cutting weeks from the process.

"With these technologies, we just build a part directly from a CAD file," Harold Sears, rapid manufacturing technology specialist for Ford, told Design News. "There's no tooling needed."


To be sure, manufacturers have used rapid prototyping techniques for more than a decade, but Ford is said to be unusual in its use of 3D printing for metal parts in test engines, transmissions, and brakes.

Prior to the advent of such techniques, manufacturers typically machined an injection mold tool before building a metal part. Doing so took time -- one to two weeks for simple tools and 10 to 12 weeks for more complex ones. By eliminating the need for those tools, they can now turn around a testable metal part in days or even hours. "In the past, we might have only been making one or two parts, but we still had to make an injection mold tool for them," Sears told us. "But with processes like laser sintering, we can now build really testable and durable parts without the tooling."

Ford has invested in what may be one of the industry's biggest rapid prototyping efforts. Three facilities near its Dearborn, Mich., headquarters contain selective laser sintering and stereolithography equipment, while another is dedicated to rapid sandcasting. The sandcasting facility enables printing of sand molds that can be used to create metal parts with the same material properties as production parts.

The giant automaker has employed those techniques in rotor supports, transmission cases, damper housings, and end covers for its C-Max and Fusion hybrids. Four-cylinder ECOBoost engines, Ford Explorer brake rotors, and F-150 exhaust manifolds have also been built with the technology.

Ford's expanded use of 3D printing has also swept across its research and development facilities. Engineers often send CAD files back and forth between the company's Silicon Valley Lab and its Dearborn facilities, then use the files to build physical prototype parts on MakerBot Thing-O-Matic 3D printers. By doing so, they can quickly tweak the designs of shift knobs, gauges, display modules, and other plastic parts.

"Now, at the press of a button, you can have the product or component at your fingertips," said K. Venkatesh Prasad, senior technical leader for Ford, in a company press release. "With a model in one hand, you can then input your changes back into the computer model."

Ford is one of many companies across numerous industries that are ratcheting up their use of rapid prototyping. Daimler AG recently funded development of an additive manufacturing system for use in automotive production, and NASA has used 3D printing for making rocket engine parts.

Ford engineers believe the trend toward rapid prototyping is still growing fast. "We're going to see more development of these materials," Sears predicts. "As the processes become more robust, they're going to allow engineers to do even more with these parts than they do today."

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About the Author(s)

Charles Murray

Charles Murray is a former Design News editor and author of the book, Long Hard Road: The Lithium-Ion Battery and the Electric Car, published by Purdue University Press. He previously served as a DN editor from 1987 to 2000, then returned to the magazine as a senior editor in 2005. A former editor with Semiconductor International and later with EE Times, he has followed the auto industry’s adoption of electric vehicle technology since 1988 and has written extensively about embedded processing and medical electronics. He was a winner of the Jesse H. Neal Award for his story, “The Making of a Medical Miracle,” about implantable defibrillators. He is also the author of the book, The Supermen: The Story of Seymour Cray and the Technical Wizards Behind the Supercomputer, published by John Wiley & Sons in 1997. Murray’s electronics coverage has frequently appeared in the Chicago Tribune and in Popular Science. He holds a BS in engineering from the University of Illinois at Chicago.

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