A University-wide pledge, led by President Jeffrey P. von Arx, S.J., who signed the American College & University Presidents Climate Commitment (ACUPCC) in 2007, has been made to reduce the University's carbon footprint. Fairfield joined 500 other universities who agreed to harness the influence of their respective institutions to address global warming and achieve climate neutrality for their campuses.
Go Stags! Go Green! Read the Plan
Fairfield University’s first Campus Sustainability Plan is the collaborative work of faculty, students and staff. The plan provides guidance and clarity of focus for the myriad of sustainability initiatives and activities that are currently underway, or have been planned for the future of our campus environment.
Please direct all comments to Professor Jim Biardi at firstname.lastname@example.org.
2016-17 Grants Competition
The Campus Sustainability Committee is pleased to announce the grants competition for the 2015-16 Academic Year.
1. email to Jim Fitzpatrick email@example.com
2. hard copy to Box A in the Barone Campus Center or
3. fax, ext 4217
Fairfield's Campus Sustainability Committee (CSC)
Fairfield's Campus Sustainability Committee (CSC), comprised of administrators, faculty, staff, and students, is charged with helping set the University's goals and evaluating its progress with regards to sustainability. Born out of the Climate Commitment, the CSC meets monthly to discuss University projects and policies related to sustainability. In addition, the CSC helps to facilitate and communicate individual efforts to all for interdepartmental collaboration.
The results for Fairfield have led to a number of awards and recognitions and press releases. A strong green movement on campus is taking shap, with an array of recent campus green projects, including:
For more information, read the meeting minutes below.
Combined Heat and Power Plant (CHP)
In 2007, Fairfield built its cost-effective, energy producing combined heat and power plant (CHP) on campus that provides power to the majority of buildings. The CHP system requires approximately 22% less fuel than typical onsite thermal generation and purchased electricity, according to the EPA. Based on this comparison, the CHP system effectively reduces CO2 emissions by an estimated 7,400 tons per year. This reduction is equivalent to the annual emissions from more than 1,200 passenger vehicles.
Fairfield's CHP generates nearly 95% of the power needed by the campus and produces up to 66% of the school's high temperature hot water heating and cooling supply, according to the EPA. The recovery and utilization of otherwise wasted heat from the 4.6 MW Solar Turbine has led to an estimated annual savings of $2.2 million.
The $9.5 million project was done in collaboration with United Technologies Carrier. The United Illuminating Company gave Fairfield a $2.3 million grant for the project, stemming from the State of Connecticut's Capital Grant for Customer-Side Distributed Generation Resources program.
The United States Environmental Protection Agency honored the University with a 2010 Energy Star CHP Award for the energy smart CHP, which is helping to considerably reduce emissions and demand on the region's electric grid.
Jesuit Community Center
In 2009, Fairfield completed construction on an environmentally friendly home for the Jesuit community and a gathering place for spiritual direction, retreats, meetings and entertaining. The Jesuit Community Center boasts many energy-saving features, including a sod roof, with grass over the main portion of the house, that filters storm water, reduces heat loss, and keeps the building cool in the summer. The large windows in the house direct sunlight onto the dark concrete floors, using solar energy to radiate warmth through the interior. In addition, many recycled materials were used for the building's surfaces. Interior and exterior walls are also well insulated, saving energy, but also preserving a quiet atmosphere appropriate for contemplation.
The most dramatic energy-saving dimension to the new Center is the "closed loop" geothermal heating system, which provides heat in winter and cools the building in the summer based on the naturally stable temperature of the earth 400 feet below the surface. 15 "wells" have been drilled around the building, and in each well are pipes - interconnected through a closed loop network - filled with a combination of water and a non-toxic anti-freeze solution. Pumps in the house push the liquid out of the building and down into the pipes in the wells before the liquid is circulated back into the house.
In New England, the earth at a depth of 400 feet remains at a stable temperature between 50 and 60 degrees Fahrenheit. The heat pump in the building uses the temperature differential between the liquid in the loop and the ambient exterior air temperature to create heat in the winter and cooling in the summer.
The "close loop" geothermal system could save as much as half of the energy that the building would otherwise consume.
OVF 30 Regenerative Converter
Fairfield University recently installed an OVF 30 Regenerative Converter in a residence hall elevator that will produce 'clean energy.' Part of a pilot project, it is the first campus elevator to be retrofitted with the device. Upon completion, the revamped elevator, located in Loyola Hall, will generate about 20% to 30% of its own electricity through mechanical braking energy. Better yet, elevator energy consumption is decreased by 20% using the regenerated energy that was previously wasted and dissipated as heat.
The OVF 30 Regenerative Converter, which has a small footprint, can lead to heat emissions from elevator machine rooms being reduced by as much as 40%. By placing the created energy back into the building, heating, ventilating, and air conditioning demands are also reduced. The University also received a rebate in the amount of $4,125 from a UI rebate program for installing the environmentally-friendly technology.
Fairfield University has adopted energy efficient LED lighting as the standard fixture for replacing exterior lighting. The first application of LED lighting was the expansion and upgrades to the Quick Center Lot. The existing 250 Watt High Pressure Sodium (HPS) fixtures were replaced with 94 Watt "cut off" fixtures. The "cutoff" feature directs the light to the ground surface to achieve approximately one foot candle per square foot. This feature greatly reduces night sky glare commonly referred to as light pollution. In addition to saving significant electrical consumption, the LED fixtures have a life span of 70,000 hours compared to 25,000 hours for conventional fixtures. Fairfield has also replaced HPS wall sconces with LED lights at all of the quad residences.
The Quick Center Lot also included the green feature of pervious pavement in lieu of the standard impervious pavement. Pervious pavement allows storm-water to percolate into the water table as opposed to going into catch-basins which increase point flows and flooding.
LEED the Way
Fairfield now builds facilities with an eye to energy efficiency, recycling, and high marks from Leadership in Energy & Environmental Design (LEED), a rating system of the U.S. Green Building Council that promotes responsible building practices. The Kelley Center, for instance, features carpet tiles, access flooring, structural steel, and ceiling tiles made from recycled materials. The windows, up-lighting, and under-floor air system ensure lower energy use and healthy breathing.
As part of the President's climate commitment, Fairfield University has been designing and building new facilities to the LEED silver standard. This is the case with the $60 million residential program which has incorporated additional green roofs, energy efficient design, and building dashboards.
Laundry Equipment Replacement
All washers and dryers for student use were replaced in September, 2010 with Energy Star products. Since the beginning of the fall semester 2010, it is estimated that over 449K gallons of water have been saved. For more information, go to laundryview.com.