Teams of recent Purdue University graduates have honed a patent-pending, dynamically adjustable wheelchair prototype designed to help users more efficiently and safely navigate airports, board aircraft and move through narrow aisleways to their seats.
A nine-minute video about the work is online.
Peter Ponticello, a recent alumnus of Purdue University’s Polytechnic Institute and a team member who worked to fine-tune the design, said navigating an airport requires addressing various floor surfaces and narrow aircraft aisles.
“It is extremely difficult for a passenger to board an airplane without requiring constant assistance from a dedicated usher throughout the process,” Ponticello said.
The current standard for wheelchair users is to transfer between multiple devices: wheelchairs, airport buggies and aisle chairs when boarding and deplaning a commercial aircraft. This requires airport personnel to lift and move passengers from one device to another, which could lead to physical harm.
Brad Duerstock is a power wheelchair user and professor of practice in the Weldon School of Biomedical Engineering and School of Industrial Engineering; he is unrelated to the wheelchair prototype design project.
“The requirement to transfer to a normal airline seat is fraught with many hazards that have led to personal injury to the wheelchair user and/or the airline attendant,” Duerstock said.
Typical transfers of wheelchair users between their wheelchair and an aisle chair occurs in the jetway.
“It always delays the boarding of passengers who must wait for the wheelchair user to be physically transferred into the aisle chair and then enter into the airplane and then transfer again into airplane seat,” Duerstock said. “This is not only dangerous but very inefficient.”
Ponticello, Connor Edwards, Logan Gardocki and Cole Mulzer are recent Purdue graduates, and Jack Moran is scheduled to graduate this year. They worked on a remote-operated and battery-powered base for the wheelchair that functions as all three traditionally employed devices.
“It travels omnidirectionally and features an improved turn radius compared to currently available wheelchairs,” Ponticello said.
The base also dynamically contracts from 18-by-18-by-22-inch to 18-by-10-by-22 to pass through narrow aisles.
The original design won the 2020 FAA Challenge: Smart Connected Aviation Student Competition. Team members were Austin Barrow, Eric Eagon, Quinn Joyce, Dylan Kerr, James Pannullo and Xingmei Zhu from the School of Aeronautics and Astronautics, and Brendan Kerr from the Department of Computer Science. Eagon and Joyce were co-leaders; Dengfeng Sun, a professor in the School of Aeronautics and Astronautics, served as the team’s academic mentor. Another Polytechnic team of Tyler Affolder, Allana Brown, Brandon Mair, Caleb Phillips, Wade Ridge and Joseph Warren also worked on design. James Condron, assistant professor of practice, advised both Purdue Polytechnic Institute teams.
“After we studied previous versions of the design, we updated the software, redid the electrical setup and redesigned the mechanical features,” Ponticello said.
Along with being safer than traditional methods to transport passengers to planes, Ponticello said the device is cost-efficient for airports.
“This wheelchair allows for those who need to utilize a wheelchair in an airport to do so without the constant assistance of an usher,” Ponticello said. “This greatly reduces the amount that airports spend on ushers who assist those with limited mobility.”
The first team that worked on the design disclosed it to the Purdue Research Foundation Office of Technology Commercialization, which has applied for a patent on the intellectual property. Industry partners interested in further developing the design should contact Matt Halladay, [email protected], about track code 2020-JOYC-68976.
The Purdue teams have validated the concept of the design by testing it on a variety of flooring surfaces and through spaces that replicate the dimensions of aircraft aisleways. Commercial partners are being sought to advance the design further, including enabling it to transport a passenger from an airport entrance and then take them to a designated gate and exact aisle seat on an aircraft.
