Lab upgrade allows 山ǿ engineers to design 'resilient cities of the future'
An upgraded facility at the University of Toronto’s Faculty of Applied Science & Engineering – unlike any other in the world – will let engineers test next-generation infrastructure designed to be resilient in the face of natural disasters, from hurricanes to earthquakes.
With the support of the Canada Foundation for Innovation (CFI), a suite of new tools and equipment will be housed within 山ǿ Engineering’s existing Structural Testing Facility. It will be used to design everything from elevated highways and high-rise residential buildings to nuclear power plants, including replacements for legacy structures across North America.
“Much of our infrastructure is decades old and needs to be replaced,” says project leader Constantin Christopoulos, a professor in the department of civil and mineral engineering and Canada Research Chair in Seismic Resilience of Infrastructure.
“The scientific and engineering communities, along with governments and the private sector, are becoming increasingly aware of the inherent vulnerability of our infrastructure. We also need to design new structures to address new pressures, such as a rapidly growing Canadian population, and more frequent extreme weather scenarios due to a changing climate.”
The project is one of four at 山ǿ that are being supported by CFI, that was released March 3 and François-Philippe Champagne, the federal minister of innovation, science and industry. The other three 山ǿ projects are headed by: Professor Roberto Abraham in the David A. Dunlap department of astronomy and astrophysics in the Faculty of Arts & Science; Professors Jennifer Gommerman and Kullervo Hynynen in the Temerty Faculty of Medicine; and Charles Boone and his colleagues in the Donnelly Centre for Cellular and Biomolecular Research.
The centrepiece of the new development at 山ǿ Engineering’s Structural Testing Facility is the world’s first fully movable, adjustable, multidirectional, large-scale and large-capacity loading frame.
“This unique piece of equipment will allow structural elements and structural systems to be tested under more realistic loading conditions,” says Christopoulos. “We’ll be able to better simulate the complex effects of extreme loading events, such as earthquakes, tornadoes, hurricanes or tsunamis.”
The adjustable, multi-dimensional loading module will be capable of applying up to a total of 2,000 tonnes of force in six translational and rotational directions for specimens of up to eight metres tall and 30 metres long.
The project will also include new state-of-the-art sensing equipment and the redesign of 500 square metres of lab space. Construction is expected to begin in 2022.
Christopoulos will be working with a large team of experts from within and beyond 山ǿ Engineering. Project partners include 山ǿ Engineering faculty members Oh-Sung Kwon, Evan Bentz, Oya Mercan and Jeffrey Packer. The team is also collaborating with a team of structural engineering and large-scale testing experts at other leading North American facilities to develop, commission and use this unique equipment.
Collaborating institutions include:
- Western University’s WindEEE and Boundary Layer Wind Tunnels
- University of British Columbia
- Université de Sherbrooke
- Polytechnique Montréal
- University of Illinois
Once completed, the new facility will be used for research by 10 professors from 山ǿ and their national and international collaborators. It is also expected that it will allow for dozens of unique graduate student research projects and industry tests every year once it is fully operational.
Together, the teams will be able to carry out a technique known as “distributed hybrid simulations.” This means that full-scale portions of real structures – such as concrete pillars or steel beams – will be tested simultaneously in each of these labs across North America.
By integrating all of these physical tests into a single numerical model, the researchers can use the experimental feedback of each of the large-scale elements to more realistically simulate the response of the entire infrastructure system to extreme loading conditions. The data from the physical experiments will be integrated in real-time with models run using high-performance computers and the UT-SIM integration platform.
“This facility will enhance our capabilities not only here at 山ǿ, and across Canada, but will position Canadian engineers as global leaders in the area of structural resilience” says Christopoulos. “It is a critical step toward designing the resilient cities of the future.”