Centre College Champions Hall

Achieving Sustainability & Wellness in Olympic-Sized Natatorium

Centre College’s Champions Hall sets a new standard for athletic and wellness facilities, seamlessly blending functionality, sustainability, and innovation. Designed for both athletic and academic use, the 117,536 ft² complex includes an Olympic-sized swimming pool, a fieldhouse with a 6-lane, 200-meter track and turf infield, as well as locker rooms, strength and wellness areas, nutrition spaces, and multi-purpose event space. Sustainability was a core focus throughout the design and construction process, reflecting the college’s commitment to environmental stewardship. CMTA provided MEP engineering for the LEED Gold-targeted facility, ensuring it achieved ambitious operational efficiency and indoor air quality goals.

Project At A Glance

Size: 117,536 Square Feet
Cost: $60,000,000
Completed: 2024
Baseline Energy Use: 330 EUI
Performed Energy Use: 188 EUI
Carbon Reduction: 1,458 MTCO2e Annually
Renewable Energy: 248.3 kw
LEED: Gold Targeted

The Challenges

Pursue sustainability goals while remaining within budget
Optimize energy efficiency while heating the 750,000-gallon indoor pool
Maintain effective climate control and optimized indoor air quality in the natatorium's unique thermal environment

Countless hours were dedicated to making the largest building on campus the most sustainable one. The features we incorporated will pay dividends in terms of energy savings and benefit the environment in direct, tangible ways that help make the future brighter for our students and entire community.

Milton C. Moreland

Centre College President

The Solutions

Sustainability was a top priority for the owner from the beginning of the design phase. However, the facility’s expansive fieldhouse and natatorium, which includes heating a 750,000-gallon pool, posed significant climate control and energy efficiency challenges. To address these, CMTA explored three solutions for the facility’s HVAC system: a 4-pipe fan coil system with a chiller and boiler, air-source heat pumps, and geothermal with water-source heat pumps. Although the geothermal option had the highest initial cost—$5.2M compared to $4.1M for the air-cooled chiller and boiler—it provided greater operational efficiency, lower annual utility costs, and a longer lifespan. Ultimately, these advantages translated into a projected 7-year return on investment for the geothermal system, which also proved to be approximately 30% less expensive over a 30-year life cycle compared to the traditional systems.

As a result, CMTA implemented a geothermal HVAC system, with wells drilled beneath the adjacent football stadium to supply energy for the building and meet most of the pool’s heating demands. Projections indicate that only a few days each year will require supplemental natural gas heating to augment geothermal production. To further maximize energy efficiency, the team installed LED lighting with occupancy sensors, demand control ventilation, and progressive scheduling. The pool dehumidification units are also connected to the geothermal wellfield, enhancing system efficiency by cooling and dehumidifying air while using the warm, humid return air to precondition incoming airflow. This process reduces energy consumption, with pool water circulating through the unit to improve air conditioning efficiency. Additionally, sensors monitoring VOC levels, building pressure, and humidity/temperature continuously optimize air quality and natatorium pressure through variable frequency drives (VFD) that regulate exhaust and purge fans as needed. Primary heating is supplied by hot gas reheat from the condenser coil, with auxiliary heat provided by natural gas.

For the field house, Air Rotation Units handle conditioning and ventilation. These units feature dual-temperature coils connected to water-to-water heat pumps that tie directly to the geothermal wellfield for heat absorption and rejection. The wellfield is decoupled from the building’s heat pump loop, allowing independent operation. This thoughtful design enables geothermal pumps to shut down during low-load periods, with the building's loop maintaining temperature without fully engaging the system.

The project team also had to overcome budgetary challenges to install photovoltaic (PV) panels on the natatorium roof. Through creative problem-solving and collaboration with their alumni network, the owner secured a repurposed 248.3 kW solar array that had been removed from a failed installation at another university. After thorough inspection by the design team, the panels were determined to be suitable for reuse and were sold to the college at cost. This innovative solution not only diverted the solar panels from the waste stream but also reduced the college’s energy demand from the grid, offering a significant carbon emissions reduction. Due to these high-performance design strategies, the building is operating at an Energy Use Intensity (EUI) of 188 kBtu/ft²/yr—a 57% improvement over the baseline EUI.

Enhancing Occupant Comfort & Wellness

The team effectively addressed the unique thermal environments of the indoor pool natatorium and fieldhouse through thoughtful design, positively impacting both space conditions and occupant comfort and wellness. A key feature of the design was the installation of a Chloramine Evacuator system, which captures and exhausts harmful chloramines directly from the pool surface into the gutter system, significantly improving air quality by preventing their circulation throughout the natatorium. Additionally, space temperature was maintained slightly above the pool water temperature, with the relative humidity maintained between 50% and 60% to ensure optimal performance and comfort. Ventilation rates were maintained at 0.48 cfm/ft², contributing to a well-regulated environment.

Thermal comfort in the adjacent fieldhouse was enhanced by strategically directing air high against the roof and returning it low and slow, ensuring proper mixing and a comfortable breathing zone. Meanwhile, office spaces, lounges, and multi-purpose rooms are conditioned using efficient water source heat pumps connected to a geothermal wellfield, with thermostats dynamically modulating temperatures to maintain setpoints effectively. This comprehensive and targeted approach demonstrates a commitment to balancing thermal comfort, air quality, and energy efficiency.

Simplified Operation & Maintenance

Geothermal water-source heat pumps offer an efficient and practical solution for operation and maintenance. Designed for reliability and maintainability, the residential-style geothermal heat pumps require minimal upkeep, requiring only filter replacements. If needed, fans or compressors can be replaced in the water source heat pumps with relative ease. Additionally, the pool dehumidification units are controlled through the BAS and scheduled for pool events, modulating airflow based on VOC sensors, building pressure, and humidity/temperature sensors. Adequate space in the mechanical room ensures easy access for maintaining equipment, ensuring efficient servicing and minimizing operational disruptions.

The Results

By implementing a highly efficient system, the college achieved its sustainability goals and significantly reduced its long-term carbon footprint. Within the first year alone, the building avoided 1,458 metric tons of CO₂ emissions—a remarkable 36% reduction compared to the baseline energy systems.

Complementing this achievement, sustainable design choices prioritized both environmental safety and indoor air quality. For instance, the elimination of glycol from the geothermal system reduced the presence of harmful chemicals, promoting a safer indoor environment. Additionally, the pool dehumidification unit incorporates an innovative purge mode, which replaces 50% of the return air with fresh outdoor air. This capability allows for a rapid exchange of the natatorium’s air, effectively minimizing chloramines and delivering a healthier, more comfortable indoor atmosphere. Together, these advanced systems demonstrate the college’s commitment to environmental stewardship and the cost-effective creation of spaces that prioritize sustainability and occupant well-being.

Champions Hall Energy Use

[{"x":"JAN","Baseline":"27.5","Actual":"15.7"},{"x":"FEB","Baseline":"55.0","Actual":"31.3"},{"x":"MAR","Baseline":"82.5","Actual":"47.0"},{"x":"APR","Baseline":"110.0","Actual":"62.7"},{"x":"MAY","Baseline":"137.5","Actual":"78.4"},{"x":"JUN","Baseline":"165.0","Actual":"94.0"},{"x":"JUL","Baseline":"192.5","Actual":"109.7"},{"x":"AUG","Baseline":"220.0","Actual":"125.4"},{"x":"SEP","Baseline":"247.5","Actual":"141.0"},{"x":"OCT","Baseline":"275.0","Actual":"156.7"},{"x":"NOV","Baseline":"302.5","Actual":"172.4"},{"x":"DEC","Baseline":"330.0","Actual":"188.0"}]

What does this data mean?

Baseline: AIA 2030 Annual Energy Use Goal

Actual: The measured energy use of this project

Renovations That Pay For Themselves, Guaranteed

[This project is] a testament to the Park Authority’s commitment to sustainability. As stewards of public spaces, we prioritize energy efficiency not only to reduce environmental impact but also to ensure long-term operational savings.

Jai Cole

FCPA Executive Director