Some assembly required: TA designs at-home lab gear, ships to students around the globe
University of Toronto students enrolled in MSE398: Materials Manufacturing and Design Laboratory received a box in the mail a few months ago that included everything they needed to build a mini-mechanical tester machine for their at-home labs.
The package included mechanical parts, electrical components, a printed circuit board and tools.
“You assemble the pieces like IKEA furniture,” says teaching assistant Crystal Liu, who is also a master's student in the Faculty of Applied Science & Engineering.
To keep remote learning engaging and hands-on during the pandemic, 鶹ֱapp Engineering instructors have gotten creative when it comes to adapting their teaching and lab exercises.
For Liu and course instructor, Scott Ramsay, an associate professor, teaching stream, in the department of materials science and engineering, it was paramount that third-year materials science engineering students still had an opportunity to gain experience performing hands-on work.
“Last spring, Professor Ramsay and I talked about the term ahead [and] we knew the pandemic was far from being over in a year’s time,” says Liu. “We both agreed that we couldn’t have students doing just simulations – it’s just not the same as a hands-on experience.
“So, we decided to send them something.”
Liu began designing a lab kit for the course and, in an effort to help others, . Through the summer, she sourced materials and components. For custom-designed parts, she worked with staff at the ’s fabrication facility to produce them with 3D printers and laser cutting equipment.
By the fall term, Liu had the materials to package 50 lab kits. And by the winter term, she had mailed them to students as far away as the United Arab Emirates, China and Turkey. For students in Toronto, Liu delivered the kits to students’ homes or arranged for them to be picked up.
Teaching assistant Crystal Liu mailed the kits to 鶹ֱapp students as far away as the UAE, China and Turkey (photo courtesy of Crystal Liu)
The course’s first assignment is to build the tester. Once fully assembled, the device is the size of a shoe box. It comes complete with a custom-designed PCB, user interface and all firmware, as well as safety features such as a shield that must be installed for the machine to run and a large emergency-stop button.
For the second assignment, students were provided with a bag of material samples to analyze.
“These include 3D-printed samples, ranging from very brittle to very stretchy, and items you can find in daily life, like tapes and plastic bags,” Liu says.
Once students insert the sample, the machine stretches it, measuring the force being applied, as well as the displacement. The user interface shows the force-versus-displacement curve while the data is saved in real time. Students can then use the information to study the material’s properties and how the data is generated.
The students’ final assignment involved finding an adhesive seam to peel – such as the ones at the top of a bag of chips – to conduct their own peel-force test using the machine.
“They go from learning how to perform a tensile test that is already designed for them, to then having to apply what they learned in order to conduct their own experiment procedure from scratch,” says Liu. “What they’re learning and how they go about it is as close as you can get to what it would be like if they were operating equipment on campus.”
Liu and Ramsay have received positive feedback from students.
“They like how hands-on it has been and really appreciated the amount of time and effort we put into the course,” she says.
Liu’s experience designing the lab kit is helping to inform her own master’s project on designing and implementing open-source hardware in engineering research. The kits were partially funded by Ramsay’s Hart Teaching Innovation Professorship.
“Crystal has worked exceptionally hard on this project and it is impressive that she was able to put this together for our students,” says Ramsay. “The hands-on experience is one of the most important aspects of this course.
“I’m so pleased that we’ve been able to give the students some of that experience in the remote environment.”
After the term wraps up in a few weeks, Liu plans to turn her research, including two mechanical testers, into a startup with the support of 鶹ֱapp Engineering’s Entrepreneurship Hatchery.
“I believe students learn better by building and playing, so this type of device could be beneficial to students at other universities, they could even be used in high school science labs,” says Liu. “However, not everyone can go from freely available design plans to components and to a product. So, through a startup, I’m hoping to make these designs even more accessible to others.”