The Ohio University Chilled Water Plant #3, located between the main campus and the athletic fields, has been completed. The facility provides up to 7,500 tons of chilled water capacity on the Ohio University campus. It also provides the campus with electrical circuitry and switchgear for a new looped electric service and new feed point. The design of the plant also addresses the potential flooding, noise, and plume factors.
An important component of the Ohio University Chilled Water Plant's design was making sure that the actual building aligned with the college campus and other buildings surrounding the University. The building’s straightforward rectangular form and copper-colored insulated metal panel system blends with the neighborhood buildings in height, color, and alignment.
Resiliency was also something the design team was committed to. The main equipment is raised nine feet above the floodplain, which allows a ventilation system for the main floor. A ramp is provided for access to the elevated main floor, while bifold doors allow chiller maintenance. There’s also an effective acoustical sound wall with screen enclosure at the roof that provides noise protection for residential complexes.
Leers Weinzapfel Associates has also designed chiller plants on the campuses of Princeton University, the University of Pennsylvania, Tufts University, the University of Massachusetts Amherst, Harvard University’s Allston Campus, and the Ohio State University.
Related Stories
| May 1, 2014
First look: Cal State San Marcos's posh student union complex
The new 89,000-sf University Student Union at CSUSM features a massive, open-air amphitheater, student activity center with a game lounge, rooftop garden and patio, and ballroom space.
| Apr 29, 2014
USGBC launches real-time green building data dashboard
The online data visualization resource highlights green building data for each state and Washington, D.C.
Smart Buildings | Apr 28, 2014
Cities Alive: Arup report examines latest trends in urban green spaces
From vertical farming to glowing trees (yes, glowing trees), Arup engineers imagine the future of green infrastructure in cities across the world.
| Apr 16, 2014
Upgrading windows: repair, refurbish, or retrofit [AIA course]
Building Teams must focus on a number of key decisions in order to arrive at the optimal solution: repair the windows in place, remove and refurbish them, or opt for full replacement.
| Apr 9, 2014
Steel decks: 11 tips for their proper use | BD+C
Building Teams have been using steel decks with proven success for 75 years. Building Design+Construction consulted with technical experts from the Steel Deck Institute and the deck manufacturing industry for their advice on how best to use steel decking.
| Apr 8, 2014
Science, engineering find common ground on the Northeastern University campus [slideshow]
The new Interdisciplinary Science and Engineering Building is designed to maximize potential of serendipitous meetings between researchers.
| Apr 2, 2014
8 tips for avoiding thermal bridges in window applications
Aligning thermal breaks and applying air barriers are among the top design and installation tricks recommended by building enclosure experts.
| Mar 26, 2014
Callison launches sustainable design tool with 84 proven strategies
Hybrid ventilation, nighttime cooling, and fuel cell technology are among the dozens of sustainable design techniques profiled by Callison on its new website, Matrix.Callison.com.
| Mar 20, 2014
Common EIFS failures, and how to prevent them
Poor workmanship, impact damage, building movement, and incompatible or unsound substrate are among the major culprits of EIFS problems.
| Mar 12, 2014
14 new ideas for doors and door hardware
From a high-tech classroom lockdown system to an impact-resistant wide-stile door line, BD+C editors present a collection of door and door hardware innovations.
