July 19, 2022
Feature

Aluminum Alloy Manufacturing Now 50 Percent More Energy Efficient

New process eliminates the need to pre-heat materials before extrusion

A researcher stands in front of the ShAPE machine holding a piece of aluminum alloy 7075, with the words "50% Energy Savings High-Performance Aluminum Alloy" in the background.

Shear Assisted Processing and Extrusion (ShAPE™), developed by researchers at Pacific Northwest National Laboratory, improves the energy efficiency of producing extruded high-performance aluminum alloys. 

(Composite image by Cortland Johnson | Pacific Northwest National Laboratory)

Lighter vehicles can travel farther on less energy, driving demand for lighter automotive components. High-performance aluminum alloys, such as alloy 7075, are among the lightest and strongest options, but they require energy-intensive production that raises costs and therefore limits their use.

Research from the Pacific Northwest National Laboratory (PNNL) cuts that energy in half with a more efficient process to manufacture high-performance aluminum components. With support from the Department of Energy’s Advanced Manufacturing Office, researchers determined that the Shear Assisted Processing and Extrusion (ShAPE™) technology can eliminate heat treatment steps in the production process, resulting in significant energy savings and reduced emissions. ShAPE is a green, affordable manufacturing approach that enables broad use of high-performance aluminum alloys in automotive applications.

A recipe for next-generation metals manufacturing

Much like baking a cake, metals manufacturing relies on well-mixed ingredients and a lot of heat. Conventional metal production uses heat to melt individual metals and alloying elements together—like aluminum, copper, or magnesium—to create alloys that are lighter, stronger, or easier to form. If these elements aren’t well-mixed, cracks and fractures can form during processing that compromise the properties of the final product—as an undermixed, lumpy cake batter will result in a crumbling, disastrous cake. In metals production, heat is used to ensure that individual metal elements in an alloy are well-mixed during a step called homogenization.

During homogenization, large metal castings called billets are heated to nearly 500 degrees Celsius—about 900 degrees Fahrenheit—for up to 24 hours. This heat treatment step dissolves alloy aggregates—akin to lumps in the cake batter—in the billet to ensure that all metal elements are evenly distributed or homogenized. This improves the performance of the final product. After homogenization, the metal rods undergo further heating and forming in a step called extrusion.

“Homogenization is the biggest energy-consuming step in the entire metals extrusion process,” said Scott Whalen, PNNL chief materials scientist and co-developer of ShAPE.

The ShAPE machine eliminates the need for separate homogenization and extrusion steps by combining heating and deformation—the change in the shape of the metal itself. In the ShAPE machine, the metal billet is simultaneously pushed through a small opening in a die which rotates. Together, the rotational movement and deformation thoroughly mixes the metal elements as they are being extruded. Essentially, the ShAPE process homogenizes the metal billet in a few seconds, immediately before it is extruded. This eliminates the need for a day-long, pre-heating homogenization step and means that no additional energy is used to heat the billet during extrusion. Together, this results in an energy savings of up to 50 percent using ShAPE.

Have your cake and eat it too

Three panels that show microscopy images of aluminum alloy 7075 before, during, and after ShAPE processing.
Images of aluminum alloy 7075 taken with a scanning electron microscope before (A), during (B), and after (C) going through the ShAPE machine show how the microstructure of the alloy changes dramatically during extrusion. The shearing effect of the ShAPE machine breaks up particles, which are akin to lumps in cake batter, into much smaller pieces to create a more uniform microstructure. (Image by Joshua Silverstein | Pacific Northwest National Laboratory)

Not only is ShAPE a more energy efficient and quicker process, but it also improves how well the individual alloying elements are mixed, leading to a better final product. Like lumpy batter can ruin a cake, the final product in extrusion manufacturing often performs better when the elements are well-mixed. Performance testing showed that components made of aluminum alloys processed with ShAPE exceeded current American Society for Testing and Materials standards for strength and elongation.

“We took a closer look using an electron microscope and saw that ShAPE breaks apart the alloy aggregates and dissolves them into the aluminum matrix prior to extrusion, making it more extrudable,” said Tianhao Wang, PNNL materials scientist and lead author on the recent publication in Materials and Design. “This translates to better performance—our aluminum 7075 alloys are stronger and stretch farther before breaking.”  

Putting high-performance aluminum alloys in reach

Aluminum alloys are valued in the automotive and aerospace industries because they are strong and lightweight. The most high-performance aluminum alloys are time- and energy-intensive to manufacture, pricing them out of many markets, like applications in passenger vehicles. The ShAPE process removes a major hurdle in the production of high-performance aluminum alloys by dramatically reducing energy consumption and greenhouse gas emissions during manufacturing.  

“This is an important step in unlocking the potential of next-generation metals manufacturing to produce better, cheaper, greener products for the future,” said Whalen.

This research was supported by the Department of Energy’s Advanced Manufacturing Office and performed using a purpose-built ShAPE machine manufactured by BOND Technologies, Inc. The ShAPE process, tooling, and techniques are available for licensing (contact Sara Hunt, commercialization manager).

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About PNNL

Pacific Northwest National Laboratory draws on its distinguishing strengths in chemistry, Earth sciences, biology and data science to advance scientific knowledge and address challenges in sustainable energy and national security. Founded in 1965, PNNL is operated by Battelle for the Department of Energy’s Office of Science, which is the single largest supporter of basic research in the physical sciences in the United States. DOE’s Office of Science is working to address some of the most pressing challenges of our time. For more information, visit https://www.energy.gov/science/. For more information on PNNL, visit PNNL's News Center. Follow us on Twitter, Facebook, LinkedIn and Instagram.