As a result, facility operators are evaluating alternatives to legacy cooling approaches to improve energy efficiency and maintain system reliability.
Traditionally, data center cooling systems operated at fixed output levels. Newer systems use sensors and control logic to adjust cooling based on real-time workload conditions. This allows operators to respond to temperature changes more precisely and avoid overcooling or localized overheating.
In addition to temperature control, operators are focusing on improving overall system efficiency. Metrics such as Power Usage Effectiveness (PUE) and emerging concepts like Power Compute Effectiveness (PCE) are used to evaluate how efficiently energy is used within the facility.
This shift requires cooling components that can adjust airflow and power consumption based on operating conditions, rather than running at a constant output.
One of the primary methods for improving data center cooling efficiency is using variable-speed fans. Unlike legacy fixed-speed models that consume constant power regardless of load, fans using Electronically Commutated (EC) motors can adjust their speed in real time based on local heat flux. By dynamically managing airflow to match the thermal load, operators can reduce energy consumption compared to fixed-speed systems, depending on the application.
Pelonis Technologies designs EC fans and motion control systems that adjust to changing airflow and thermal conditions. These systems can include protections such as inrush current control and automatic restart functions to support consistent operation in dynamic environments.
As rack densities increase, airflow management becomes more dependent on containment and controlled air distribution. Modern facility design increasingly relies on "hot and cold" aisle containment to prevent the mixing of air streams, which can drastically reduce cooling efficiency.
Backward-curved centrifugal fans are commonly used in high-static-pressure environments. These fans generate higher pressure airflow, allowing air to move through dense server components and restricted airflow paths.
Larger-diameter axial fans are also used in external heat rejection systems. These fans move higher volumes of air at lower rotational speeds, improving energy efficiency and reducing noise levels compared to smaller, high-speed fans.
While air cooling remains widely used, liquid cooling is becoming more common in high-density data center applications. By 2026, liquid cooling is expected to become a standard design consideration for most new projects. Single-phase direct liquid cooling has consolidated its position as the dominant architecture, with liquid immersion cooling gaining traction in the highest-density environments due to its superior heat-transfer efficiency.
Hybrid portfolios are becoming the default, with high-performance fans assisting with heat dissipation for liquid-cooled components or supplementing air conditioning in Indirect Evaporative Cooling (IDEC) systems. IDEC relies on water evaporation to cool the air flowing through an external heat exchanger, effectively removing heat without introducing outside air or humidity into the data center.
This transition can reduce energy consumption and improve cooling efficiency compared to traditional systems. By working with suppliers that offer custom fan and blower solutions, operators can design cooling systems that match their specific thermal and airflow requirements.
Data center cooling systems must be designed around actual thermal loads, airflow requirements, and system constraints. As computing density increases, selecting the right cooling components becomes critical to overall system performance.
Pelonis Technologies provides custom cooling components, including EC fans and motion control systems, designed for high-efficiency thermal management in data center environments.
Contact the team to discuss your application requirements or request a quote for your next cooling system design.