A review of on-chip micro-evaporation: Experimental evaluation of liquid pumping and vapor compression driven cooling systems and control

Marcinichen, Jackson B.; Olivier, Jonathan; Oliveira, Vinícius de; Thome, John R.

doi:10.1016/j.apenergy.2011.10.030

Cited by 65 publications

(20 citation statements)

References 16 publications

(19 reference statements)

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“…However, the inability to follow the Dennard supply voltage has lead to high chip heat flux dissipation densities, especially during the last decade [2]. As a consequence, electronic reliability considerations are driving a shift away from air-cooling [3] towards a number of alternative approaches including liquid cooling [4,5], two-phase cooling [6,7], phase change materials (PCM) [8,9] and nanofluids [10,11]. Single-phase liquid cooling has long been identified as an effective and feasible approach for cooling high heat flux density chips.…”

Section: Introductionmentioning

confidence: 99%

Energy efficient hotspot-targeted embedded liquid cooling of electronics

et al. 2015

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Section: Introductionmentioning

confidence: 99%

Energy efficient hotspot-targeted embedded liquid cooling of electronics

et al. 2015

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“…Using a large heat spreader [8] may not be suitable for electronics systems with size or weight constraints. Overfeeding the evaporators with refrigerant can provide a large CHF safety factor [7,[11][12][13], but the higher flow rates increase power consumption by pumps or compressors. Furthermore, there lacks systematic design approach to address the inherent nonlinearity of CHF.…”

Section: Introductionmentioning

confidence: 99%

“…Current strategies for CHF avoidance in active two-phase cooling of electronics include heat-spreaders or cold-plates to enhance heat transfer and lower heat flux [7][8][9][10][11][12][13][14], setting low evaporator outlet quality setpoints to maintain a large CHF safety factor [7,[11][12][13][14], and CHF avoidance control using wall temperature feedback proposed by our group [15][16][17][18]. Several experimental electronics cooling studies that implement these techniques are summarized in Table 1, with representative test section conditions reported.…”

Section: Introductionmentioning

confidence: 99%

Dryout avoidance control for multi-evaporator vapor compression cycle cooling

2015

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“…It avoids potential problems of mal-distribution in each ME line due to non-uniform heat load on the microprocessors and bad pipeline designs. Preliminary experimental evaluation can be found in [30]; where one SMV controlling the mixture (junction of piping) outlet vapor quality of two MEs proved to be feasible and efficient. c) Micro-evaporator (ME): transfers the heat generated by the microprocessor to the refrigerant.…”

Section: Hybrid Two-phase Cooling Cyclementioning

confidence: 99%

On-chip two-phase cooling of datacenters: Cooling system and energy recovery evaluation

Marcinichen

Olivier

Thome

2012

Applied Thermal Engineering

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131

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a b s t r a c tCooling of datacenters is estimated to have an annual electricity cost of 1.4 billion dollars in the United States and 3.6 billion dollars worldwide. Currently, refrigerated air is the most widely used means of cooling datacenter's servers, which typically represents 40e45% of the total energy consumed in a datacenter. Based on the above issues, thermal designers of datacenters and server manufacturers now seem to agree that there is an immediate need to improve the server cooling process. The goal of the present study is to propose and simulate the performance of a novel hybrid two-phase cooling cycle with micro-evaporator elements (multi-microchannel evaporators) for direct cooling of the chips and auxiliary electronics on blade server boards (savings in energy consumption of over 60% are expected). Different working fluids were considered, namely water, HFC134a and a new, more environmentally friendly, refrigerant HFO1234ze. The results so far demonstrated that the pumping power consumption is on the order of 5 times higher for the water-cooled cycle. Additionally, a case study considering the hybrid cooling cycle applied on a datacenter and exploring the application of energy recovered in the condenser on a feedwater heater of a coal power plant was also investigated (modern datacenters require the dissipation of 5e15 MW of heat). Aspects such as minimization of energy consumption and CO 2 footprint and maximization of energy recovery (exergetic efficiency) and power plant efficiency are investigated.

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A review of on-chip micro-evaporation: Experimental evaluation of liquid pumping and vapor compression driven cooling systems and control

Cited by 65 publications

References 16 publications

Energy efficient hotspot-targeted embedded liquid cooling of electronics

Energy efficient hotspot-targeted embedded liquid cooling of electronics

Dryout avoidance control for multi-evaporator vapor compression cycle cooling

On-chip two-phase cooling of datacenters: Cooling system and energy recovery evaluation

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