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St. John’s College Santa Fe and Ameresco's Comprehensive Solar and Energy Efficiency Project
Technology Category
- Functional Applications - Enterprise Asset Management Systems (EAM)
- Sensors - Utility Meters
Applicable Industries
- Buildings
- Renewable Energy
Applicable Functions
- Procurement
- Product Research & Development
Use Cases
- Construction Management
- Infrastructure Inspection
The Challenge
St. John’s College Santa Fe campus was in need of a comprehensive, multi-phase solar and energy efficiency project to renovate its facility infrastructure and recognize energy savings opportunities. The college was looking to reduce its carbon footprint and save on energy costs. The challenge was to implement a solution that would not only be environmentally friendly but also cost-effective. The college needed to upgrade its facilities with renewable energy sources and energy-efficient technologies. The project was to include the addition of solar panels, electric vehicle charging stations, LED lighting retrofits, re-roofing and rooftop HVAC retrofits, boiler and air handling unit replacements, and water infrastructure upgrades in the dormitories.
About The Customer
St. John’s College is a distinctive educational institution with campuses in Annapolis, Maryland, and Santa Fe, New Mexico. The college is known for its all-required, interdisciplinary Great Books curriculum. Undergraduate and graduate students at St. John’s read more than 200 of the West’s most influential books across disciplines and discuss those books with faculty in small, seminar-style classes. The college has been hailed as the “most contrarian college in America” by The New York Times, the “most rigorous college in America” by Forbes, and the “most forward-thinking, future-proof college in America” by Quartz.
The Solution
Ameresco, Inc., a leading cleantech integrator specializing in energy efficiency and renewable energy, partnered with St. John’s College Santa Fe campus to implement a comprehensive, multi-phase solar and energy efficiency project. The project included the addition of 1,670 solar panels and 20 electric vehicle charging stations across four campus parking lots. The solar installation used an innovative grid-connected photovoltaic design, which linked the energy generated to the local utility grid and enabled St. John’s College to store and utilize power as needed. Other updates included campus-wide interior and exterior LED lighting retrofits, re-roofing and rooftop HVAC retrofits on three buildings, boiler and air handling unit replacements, and water infrastructure upgrades in the dormitories.
Operational Impact
Quantitative Benefit
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