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CO2 Refrigeration in Ice Rinks

Ice Skater Braking hard to shoot up a ice

Understanding CO2 Refrigeration Systems in Ice Rinks

Understanding CO2 refrigeration systems in ice rinks is crucial as these systems are becoming the preferred choice for maintaining high-quality ice surfaces in a more environmentally friendly manner.

CO2, or carbon dioxide, is a natural refrigerant that offers a significant advantage over traditional synthetic refrigerants, which can be harmful to the environment. CO2 refrigeration systems operate efficiently at low temperatures, making them ideal for ice rinks where precise temperature control is essential for maintaining the perfect ice conditions. These systems are also known for their energy efficiency, which can lead to substantial cost savings for rink operators.

In addition to being eco-friendly, CO2 refrigeration systems are highly effective in reducing the carbon footprint of ice rinks. Unlike traditional refrigerants, CO2 has a global warming potential (GWP) of 1, making it a much more sustainable option. Moreover, CO2 refrigeration systems are robust and reliable, with a long lifespan and lower maintenance requirements compared to older systems. As more ice rinks around the world transition to CO2 refrigeration, understanding how these systems work and their benefits is key for operators looking to improve both their environmental impact and operational efficiency

The recently remodeled Dollard-des-Ormeaux Civic Centre in Quebec, Canada uses a carbon dioxide refrigeration system to freeze the floor of the ice rinks as well as provide building heating. The details of this project were published in a paper titled “CO2 Showcase for Ice Rinks, Pools” by Kateri Heon and Pietro Guerra from exp. Inc. in the August, 2015 ASHRAE Journal.

According to the authors, what immediately emerged from the study was that:

  • CO2 offered significant advantages for the project, compared to ammonia. This is despite ammonia compressors having an average coefficient of performance (COP) value of 3.45, which is considered excellent for the temperature requirements associated with an ice rink. Ice rink refrigeration systems typically release heat through a glycol loop that cools the compressors and can reject heat in several heating coils or through heat pumps in the building. Because CO2 refrigeration systems operate at very high pressure and, therefore, at high temperature, it is possible to reject the heat from the refrigeration system into a high-temperature water loop (160°F to 180°F [71°C to 82°C]).
  • At the Dollard-des-Ormeaux Civic Centre, the high-temperature loop heated by energy recovered from the CO2-based refrigeration system contributes to heating pool water, domestic hot water and two small glycol loops that provide heating for the players’ locker rooms, and the main pool area and changing rooms.
  • CO2 can be circulated in the building, as opposed to ammonia, which is too toxic. CO2 is not a highly viscous fluid, and the high operating pressure of the system means it can easily be moved. Given these advantages, CO2 was used to heat the stands of the Centre’s three ice rinks, with CO2 coils installed directly in the system’s air ducts. This method avoided having to provide the pumping power required for a glycol loop and optimized the efficiency of the exchange.
  • And, like ammonia, CO2 has little impact on the environment.

Over the past decade, CO2 refrigerant systems have gained growing acceptance as an alternative to traditional HCFC (hydro-chlorofluorocarbon) type R22 refrigerant or ammonia-based systems in the food and food transportation industries. However, it was not until 2010 that the world’s first 100% CO2 sub-based refrigeration system used in an ice rink was completed in Marcel Dutil Arena in Quebec.

In 2012, a Comparative Study of refrigeration systems for ice rinks in Quebec was undertaken by Natural Resources Canada’s Canmet ENERGY Research Centre. They compared 12 typical refrigeration systems currently offered for ice arenas in the market, and found that a CO2/R744 system as being the most energy efficient, while a CO2 plus brine system as the least expensive.

The Benefits of Using CO2 Refrigeration in Ice Rinks

The benefits of using CO2 refrigeration in ice rinks are significant, making it a preferred choice for modern rinks focused on sustainability and performance.

CO2 refrigeration systems offer superior efficiency and cost-effectiveness, operating at high pressures. This allows for better heat transfer and improved energy efficiency. This efficiency translates into lower operating costs, as less energy is required to maintain the ice at optimal temperatures. Furthermore, CO2 systems provide more consistent and reliable ice quality, which is essential for both recreational and professional ice sports. As a result, rinks that adopt CO2 refrigeration can expect to see both immediate and long-term benefits in terms of performance, cost savings, and environmental responsibility.

Energy Efficiency and Cost Savings with CO2 Refrigeration

CO2 refrigeration systems are revolutionizing energy efficiency in ice rinks, offering significant cost savings and environmental benefits. These systems are designed to operate at higher pressures, which enhances the heat transfer process and allows for more efficient cooling. As a result, ice rinks using CO2 refrigeration require less energy to maintain the optimal ice conditions, leading to lower energy bills. This improved efficiency not only supports the operational goals of the rink but also contributes to a reduced carbon footprint, making CO2 refrigeration an eco-friendly choice.

Key Considerations for using CO2 Refrigeration in Ice Rinks

When implementing CO2 refrigeration in an ice rink, there are several key considerations to ensure the system's success and efficiency:

  1. System Design and Installation: CO2 refrigeration systems operate at higher pressures compared to traditional systems, so it is crucial to have a well-engineered design that can handle these demands. The system must be tailored to the specific needs of the ice rink, considering factors like rink size, usage patterns, and local climate conditions. Proper installation by experienced professionals is essential to avoid leaks, ensure safety, and optimize performance.

  2. Energy Efficiency and Cost: While CO2 systems are energy-efficient, the initial setup cost can be higher due to the need for specialized equipment and materials. It's important to consider the long-term energy savings and lower operating costs that CO2 refrigeration can provide, which often offset the higher upfront investment. Analyzing the potential return on investment (ROI) is a critical step in the decision-making process.

  3. Regulatory Compliance: CO2 is a natural refrigerant with a low global warming potential (GWP), which helps ice rinks comply with environmental regulations. However, operators must still be aware of and adhere to all relevant safety standards and building codes, particularly concerning the high-pressure nature of CO2 systems.

  4. Maintenance Requirements: CO2 refrigeration systems are generally low-maintenance, but regular inspections and preventative maintenance are necessary to ensure ongoing efficiency and safety. Operators should establish a maintenance schedule that includes checking for leaks, monitoring system pressures, and servicing key components.

  5. Staff Training: Given the specific characteristics of CO2 systems, it's important to train staff on how to operate and maintain the system safely. This includes understanding the unique operational procedures, safety protocols, and emergency response plans associated with CO2 refrigeration.

  6. Environmental and Safety Considerations: While CO2 is a safer and more environmentally friendly refrigerant compared to synthetic alternatives, it still requires careful handling. Proper ventilation and gas detection systems are essential to mitigate the risks of CO2 leaks, which can be hazardous in enclosed spaces.

By addressing these key considerations, ice rink operators can effectively implement CO2 refrigeration systems that are safe, efficient, and environmentally responsible.

Gas Detection Safety for CO2 in Ice Rinks

The Fixed Multi-Gas Detector

The importance of a CO2 fixed safety system in a CO2 refrigerated ice rink cannot be overstated, as it plays a crucial role in ensuring the safety of both the facility and its occupants.

CO2 is an efficient and environmentally friendly refrigerant, but it can pose significant risks if not properly monitored and controlled.

A fixed safety system  like the MSC2 Fixed Carbon Dioxide Gas Detector is designed to continuously monitor CO2 levels within the ice rink, providing real-time alerts if there is a leak or if concentrations of CO2 reach unsafe levels.

This early detection is vital in preventing potential health hazards, such as asphyxiation, that can occur in enclosed spaces where CO2 might accumulate.

The Future of CO2 Refrigeration in Ice Sports Facilities

The future of CO2 refrigeration in ice sports facilities is poised for significant growth as the industry continues to prioritize sustainability and energy efficiency. With stricter environmental regulations and the phasing out of traditional synthetic refrigerants, CO2 refrigeration systems offer a forward-thinking solution that aligns with global efforts to reduce carbon footprints.

As more facilities adopt CO2 technology, the industry is likely to see advancements in system design and efficiency, further driving down operational costs and enhancing the quality of ice surfaces. As the industry moves forward, CO2 refrigeration is set to become the standard in ice rink technology, offering a sustainable path for the future of ice sports.

For more information on CO2 refrigeration or CO2 safety solutions, contact the CO2Meter specialists online or call  877.678.4259 to discuss the best setup for your application.


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