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Assessing Design and Energy Efficiency of Liquid-based Cooling Systems for Data Centers

액체냉매기반 데이터센터 냉각시스템의 설계기준 및 에너지 효율평가에 관한 연구

  • Cho, Jinkyun (Dept. of Building and Plant Engineering, National Hanbat University)
  • 조진균 (국립한밭대학교 설비공학과 )
  • Received : 2024.03.17
  • Accepted : 2024.04.23
  • Published : 2024.05.30

Abstract

This study explores the design and energy assessment of liquid-based cooling systems to meet the growing demands and high power densities of IT equipment in data centers. It creates a baseline model for cooling systems to handle a 200 kW ITE equipment load and sets objective criteria for evaluating cooling energy efficiency. This study identified seven distinct data center workloads and points out the limitations of traditional air-cooling methods for IT power densities exceeding 50 kW/rack, suggesting a shift to liquid-based alternatives. Liquid-based cooling systems were classified into three main types: RDEX, plate cooling, and immersion cooling, with specific operational characteristics depending on the system configuration. To gauge system efficiency, this study introduces the TUE metric, correlating the total energy input to the data center with the energy used by computing components. An analysis of energy efficiency showed a significant reduction in the Power Usage Effectiveness (PUE), with immersion cooling achieving an outstanding PUE of 1.05. The TUE metric also revealed considerable efficiency gains across all liquid-based cooling systems compared to traditional air cooling. This study anticipates a rise in the adoption of liquid-based cooling systems and stresses the need for universal design criteria, taking into account ITE power density and energy efficiency.

Keywords

Acknowledgement

이 연구는 2024년도 한국연구재단 연구비 지원에 의한 결과의 일부임. 과제번호: 2022R1F1A1068262

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