The science of walking is taking its next big step with the aid of a unique exoskeleton that allows users to walk further while using less energy. Developed by a multidisciplinary team from the Queen's Faculty of Engineering and Applied Science, the backpack-mounted prototype removes energy during a specific phase of the gait cycle, lessening the metabolic cost of walking. Details of the device's development and evaluation were published today in&苍产蝉辫;厂肠颈别苍肠别鈥one of the world's foremost academic journals.
Unlike existing exoskeleton technologies that either add energy or transfer it from one phase of the gait cycle to another, this new device assists users by removing energy which helps the knee muscles during a critical moment鈥攃alled the terminal swing phase.
鈥淩emoving energy from a person's legs during walking may sound counterintuitive, like applying the brake in a moving car,鈥 says Michael Shepertycky, a recent PhD graduate and lead author of the study, 鈥渂ut our muscles naturally remove energy while we walk, and our device helps them to do so.鈥
The team envisages the technology鈥攚hich weighs just over half a kilogram鈥攅nabling hikers to walk longer distances or helping nurses be less tired after a long shift on their feet.
鈥淚mproving walking and running economy has been an important topic of research for the past two decades, due to its scientific and practical implications,鈥 says Qingguo Li, Associate Professor of Mechanical and Materials Engineering and co-author of the study. 鈥淲alking is a delicate and highly optimized process, which makes it difficult to use exoskeletons to improve walking efficiency.鈥
In addition to assisting the user, the device converts the removed energy into electricity that can be used to power the device's control system and other portable devices. This energy harvesting capability could be particularly useful for individuals travelling on foot in remote locations, allowing them to charge cellular phones or GPS devices. Yan-Fei Liu, Professor of Electrical and Computer Engineering and co-author of the study, led the development of the device's power electronics.
The team's interdisciplinary approach included elements of walking biomechanics, physiology, human-machine interactions, and design innovation. Much of this research was conducted in the Human Mobility Research Centre, a Queen's/Kingston Health Sciences Centre facility equipped with world-class gait analysis technology.
鈥淔or the first time, we have demonstrated that removing energy can increase walking efficiency,鈥 says Dr. Shepertycky. 鈥淭his is a significant advancement in the field of exoskeleton development, and one with the potential to change the way that we approach gait assistance. The publication of this work in one of the most prestigious scientific journals highlights the research expertise and excellent facilities at Queen's, as well as the world-class multidisciplinary education that I received here.鈥
Learn more about the exoskeleton project on the .