Research progress of the liquid cold plate cooling technology for server electronic chips: A review

Zhou, Weinan; Dong, Kaijun; Sun, Qin; Luo, Weimin; Zhang, Bobo; Guan, Shengli; Wang, Guangwu

doi:10.1002/er.7979

Cited by 20 publications

(6 citation statements)

References 159 publications

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“…The advantage of this method is that the coolant is not in direct contact with the heating source, which can avoid problems such as electrical short circuit. Immersion liquid cooling technology is to soak the server directly in the coolant, through the coolant directly absorb the heat generated by the server and cycle out [11] . The advantage of this method is that it has high heat dissipation efficiency and is suitable for data centers with high power density.…”

Section: Concept Of Liquid Cooling Technologymentioning

confidence: 99%

Research on key technology and system application of energy management coupled with liquid cooling and intelligent control algorithm

Wang

2024

E3S Web Conf.

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With the continuous progress and innovation of science and technology, the demand and requirements for energy in modern society are getting higher and higher. The system application of liquid cooling and intelligent control algorithm coupling energy management can adapt to this demand and provide more efficient, accurate and intelligent energy management solutions. On the basis of a brief introduction to the current energy problems, the principle of liquid cooling technology and intelligent control algorithm are expounded, the design and key technologies of liquid cooling system and intelligent control algorithm are analyzed. The liquid cooling system based on fuzzy control is studied. The liquid cooling system based on fuzzy control can quickly and accurately respond to equipment temperature changes, avoid equipment damage due to overheating, and improve energy utilization efficiency and reduce energy waste. On the basis of a brief introduction to the current energy problems, this study describes the principle of liquid cooling technology and intelligent control algorithm, focuses on the design and key technologies of liquid cooling system and intelligent control algorithm, and studies the liquid cooling system based on fuzzy control. The liquid cooling system based on fuzzy control can quickly and accurately respond to equipment temperature changes, avoid equipment damage due to overheating, and can improve energy utilization efficiency and reduce energy waste.

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Section: Concept Of Liquid Cooling Technologymentioning

confidence: 99%

Research on key technology and system application of energy management coupled with liquid cooling and intelligent control algorithm

Wang

2024

E3S Web Conf.

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“…Common methods for cooling electronic devices include heat sinks, liquid cooling system, axial fans, and so on [ 1 , 2 , 3 , 4 ]. However, the high integration, miniaturization, and application situation diversity of electronic devices put forward higher requirements (such as small area heat dissipation, high penetrating capability, or low noise) for cooling system designs [ 5 , 6 , 7 ]. An effective cooling method for small heating elements can not only reduce the structural complexity of cooling systems, but also make cooling systems more energy-efficient.…”

Section: Introductionmentioning

confidence: 99%

Study on the Cooling Performance of a Focused Ultrasonic Radiator for Electrical Heating Elements

Su,

Wang,

Zheng

et al. 2024

Micromachines

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In this work, a focused ultrasonic radiator is proposed for cooling the electrical heating elements in the focal region, and its working characteristics are investigated. The analyses of the FEM computational and flow field visualization test results indicate that focused ultrasound can generate forced convective heat transfer by the acoustic streaming in the focal region, which can cool the heating elements effectively. Experiments show that when the input voltage is 30Vp-p and the ambient temperature is 25 °C, the focused ultrasonic radiator can cause the surface temperature of the heating element (high-temperature alumina ceramic heating plate with a diameter of 5 mm) in the focal region to drop from 100 °C to about 55 °C. When the diameter of the electrical heating element is changed from 5 mm to 30 mm, the cooling effect is similar in the focal region. Compared with a fan, the focused ultrasound radiator has a shorter cooling time and a more concentrated cooling area. The focused ultrasonic radiator proposed in this work is suitable for some special environments.

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“…Currently, more and more compact size results in a high power density in electronic devices. Ten years ago, the heat flux density of electronic chips had reached up to 100 W/cm 2 [1,2], and it is expected to achieve over 1000 W/cm 2 [3][4][5] in the near future. Thermal management technologies like micro-channels, heat pipes, and spray cooling have great potential, among which spray cooling technology stands out due to its high heat dissipation capacity, low surface temperatures, system stability, and cost-effectiveness, attracting widespread attention from researchers [6].…”

Section: Introductionmentioning

confidence: 99%

Numerical Investigations of the Cooling Performance of an R410A Closed-Loop Spray Cooling System

Yang,

Sang,

Chen

et al. 2024

Energies

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To investigate the spray cooling characteristics and the impact of spray parameters such as chamber pressure, spray height, and spray tilt angle on heat transfer efficiency, a mathematical model based on the Eulerian–Lagrangian frame was established for an R410A closed-loop spray cooling system. The results revealed that the spray pattern is conical, with the center velocity significantly higher than the edge velocity. The temperature distribution of the cooling surface and liquid film height both exhibit a “W” shape, and the surface temperature is lower where the liquid film is thin. There is an optimal liquid film height of approximately 5 μm, at which the cooling surface temperature is the lowest. The surface temperature increases with an increase in the spray chamber pressure. Considering average cooling surface temperature, the optimal tilt angle is 40° with an average surface temperature of 330.1 K. When considering wall temperature and wall heat transfer coefficient uniformity, however, the optimal tilt angle is 10°, leading to the average surface temperature of 332.6 K. When increasing the optimal spray height to 70 mm, the average surface temperature is 313.4 K.

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Research progress of the liquid cold plate cooling technology for server electronic chips: A review

Cited by 20 publications

References 159 publications

Research on key technology and system application of energy management coupled with liquid cooling and intelligent control algorithm

Research on key technology and system application of energy management coupled with liquid cooling and intelligent control algorithm

Study on the Cooling Performance of a Focused Ultrasonic Radiator for Electrical Heating Elements

Numerical Investigations of the Cooling Performance of an R410A Closed-Loop Spray Cooling System

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