Instead of reinventing the wheel, the goal of one UBC researcher is to make wheels, and other manufactured materials, lighter, stronger, and safer.
Once the domain of science fiction, the recently installed 3-D X-ray computed tomography (CT) microscope at UBC’s Okanagan campus is allowing experts to peer inside the internal structure of materials and explore a 3-D image, magnified 1,000 times. It’s the first step towards lighter and stronger resources that can be used in most industries including aerospace, energy, and manufacturing, says UBC School of Engineering Assist. Prof. André Phillion.
The leading-edge technology—this is B.C.’s first high-resolution CT scanner, and one of only five in Canada—provides highly-magnified, internal pictures that can be examined in great detail. For those in the manufacturing industry, this opens the window to determine how defects can form and how they can lead to failure. Phillion uses the basic aluminum alloy automobile wheel as an example.
“We know that stress causes fatigue and we know how metals respond to stress,” Phillion says. “What we’re asking is, ‘Can we predict a potential flaw in the wheel and then eliminate potential danger?’ ”
Phillion says UBC’s machine is different than the CT scanners found in most hospitals, since the magnification is much greater. He is not aware of anyone in Canada using this technique to study manufacturing. In UBC’s lab, investigators can take a sample about the size of a pinkie finger and magnify it more than 1,000 times its original size to reveal the internal structure of the material. Defects then become visible.
While André Phillion’s 3-D X-ray computed tomography (CT) microscope at UBC’s Okanagan campus is working to improve manufacturing materials of the future, it has caught the attention of health researchers. Phillion is currently working with Vancouver’s Jim Hogg Research Centre to study Chronic Obstructive Pulmonary Disease (COPD). By placing small fragments, perhaps 10 mm in diameter, of a diseased lung into the 3-D X-ray machine, experts can examine highly magnified images of the tissue.
“We are able to look at the structure of lung tissue in 3-D,” says Phillion. “We hope to learn what’s happening to the lung at the very early stages of the disease to suggest treatment before it causes more damage.”
This is exciting news for Assoc. Prof. Neil Eves, co-director at the Centre for Heart, Lung and Vascular Health at UBC’s Okanagan campus. COPD is not just a smoker’s disease, Eves says, as it is caused by exposure to any noxious particles or gases, which can damage airways and lung tissue.
“COPD is a disease that is rapidly growing around the world, and there is considerable need for research to allow us to better understand how the disease first presents and then progresses,” Eves says. “Better understanding of the early processes and early detection are paramount to slowing the progression of this devastating disease and reducing its impact on society.”