Optimal Flow Control and Single Split Architecture Exploration for Fluid-Based Thermal Management

High-performance cooling is often necessary for thermal management of high power density systems. Both human intuition and vast experience may not be adequate to identify optimal thermal management designs as systems increase in size and complexity. This paper presents a design framework supporting comprehensive exploration of a class of single phase fluid-based cooling architectures. The candidate cooling system architectures are represented using labeled rooted tree graphs. Dynamic models are automatically generated from these trees using a graph-based thermal modeling framework. Optimal performance is determined by solving an appropriate fluid flow control problem, handling temperature constraints in the presence of exogenous heat loads. Rigorous case studies are performed in simulation, with components having variable sets of heat loads and temperature constraints. Results include optimization of thermal endurance for an enumerated set of 4,051 architectures. In addition, cooling system architectures capable of steady-state operation under a given loading are identified.

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Optimal Flow Control and Single Split Architecture Exploration for Fluid-Based Thermal Management

Journal of Mechanical Design ◽

10.1115/1.4043203 ◽

2019 ◽

Vol 141 (8) ◽

Cited By ~ 5

Author(s):

Satya R. T. Peddada ◽

Daniel R. Herber ◽

Herschel C. Pangborn ◽

Andrew G. Alleyne ◽

James T. Allison

Keyword(s):

Thermal Management ◽

High Performance ◽

Dynamic Models ◽

Cooling System ◽

Rooted Tree ◽

Flow Distribution ◽

Modeling Framework ◽

System Architectures ◽

Architecture Exploration ◽

Heat Loads

High-performance cooling is often necessary for thermal management of high power density systems. However, human intuition and experience may not be adequate to identify optimal thermal management designs as systems increase in size and complexity. This article presents an architecture exploration framework for a class of single-phase cooling systems. This class is specified as architectures with multiple cold plates in series or parallel and a single fluid split and junction. Candidate architectures are represented using labeled rooted tree graphs. Dynamic models are automatically generated from these trees using a graph-based thermal modeling framework. Optimal performance is determined by solving an appropriate fluid flow distribution problem, handling temperature constraints in the presence of exogenous heat loads. Rigorous case studies are performed in simulation, with components subject to heterogeneous heat loads and temperature constraints. Results include optimization of thermal endurance for an enumerated set of 4051 architectures. The framework is also applied to identify cooling system architectures capable of steady-state operation under a given loading.

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A dynamically controllable evaporative cooling system for thermal management of transient heat loads

International Journal of Heat and Mass Transfer ◽

10.1016/j.ijheatmasstransfer.2019.119098 ◽

2020 ◽

Vol 148 ◽

pp. 119098 ◽

Cited By ~ 2

Author(s):

Shankar Narayanan

Keyword(s):

Thermal Management ◽

Cooling System ◽

Evaporative Cooling ◽

Evaporative Cooling System ◽

Heat Loads

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Electronics Thermal Management Using Advanced Hybrid Two-Phase Loop Technology

ASME/JSME 2007 Thermal Engineering Heat Transfer Summer Conference, Volume 2 ◽

10.1115/ht2007-32962 ◽

2007 ◽

Cited By ~ 3

Author(s):

Chanwoo Park ◽

Aparna Vallury ◽

Jon Zuo ◽

Jeffrey Perez ◽

Paul Rogers

Keyword(s):

Thermal Management ◽

High Performance ◽

Cooling System ◽

Active Flow Control ◽

Heat Pipes ◽

High Heat ◽

Heat Fluxes ◽

Significant Advance ◽

Two Phase ◽

Phase Loop

The paper discusses an advanced Hybrid Two-Phase Loop (HTPL) technology for electronics thermal management. The HTPL combined active mechanical pumping with passive capillary pumping realizing a reliable yet high performance cooling system. The evaporator developed for the HTPL used 3-dimensional metallic wick structures to enhance boiling heat transfer by passive capillary separation of liquid and vapor phases. Through the testing using various prototype hybrid loops, it was demonstrated that the hybrid loops were capable of removing high heat fluxes from multiple heat sources with large surface areas up to 135cm2 and 10kW heat load. Because of the passive capillary phase separation, the hybrid loop operation didn’t require any active flow control of the liquid in the evaporator, even at highly transient and asymmetrical heat inputs between the evaporators. These results represent the significant advance over state-of-the-art heat pipes, loop heat pipes and evaporative spray cooling devices in terms of performance, robustness and simplicity.

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Enhancement of Condensation Heat Transfer in Micro Systems

ASME 2009 InterPACK Conference, Volume 1 ◽

10.1115/interpack2009-89234 ◽

2009 ◽

Author(s):

Atsushi Tokunaga ◽

Gyoko Nagayama ◽

Takaharu Tsuruta

Keyword(s):

Heat Transfer ◽

Thermal Management ◽

High Performance ◽

Cooling System ◽

High Vacuum ◽

Condensation Heat Transfer ◽

Heat Diffusion ◽

High Heat Flux ◽

Dropwise Condensation ◽

Micro Systems

Thermal management becomes a serious concern in computer system. CPU chips are placed into small spaces with difficulty in heat diffusion. This promotes many challenges in the field of thermal management of electronics to maintain the desirable operating temperature. In order to realize the enhancement of dissipation of high heat flux from electronic components, a lot of investigations have been carried out on new cooling technology using phase change phenomena. Since the micro condenser is required in the cooling system, we are directing our attention to the enhancement of condensation heat transfer in the micro system. This study focuses on high performance of dropwise condensation heat transfer due to its small conduction resistance. In the micro systems, the interface phenomena play an important role in heat transfer. We have done dropwise condensation experiments in a high vacuum chamber system to get precise information about the vapor-liquid interface transport phenomena. Surface temperature transients are measured directly with the thin film thermocouples fabricated on the condensing surface.

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Preliminary Design and System Considerations for an Active Hybrid Laminar Flow Control System

Aerospace ◽

10.3390/aerospace6100109 ◽

2019 ◽

Vol 6 (10) ◽

pp. 109

Author(s):

Kalarikovilagam Srinivasan ◽

Bertram

Keyword(s):

Laminar Flow ◽

Flow Control ◽

Thermal Management ◽

High Speed ◽

System Development ◽

Structure Design ◽

Conceptual System ◽

Preliminary Design ◽

System Architectures ◽

Laminar Flow Control

Hybrid laminar flow control or HLFC design is a complex and multi-disciplinary process, which demands a thorough understanding of all aspects from a global systems viewpoint. The objective of the paper is to present a preliminary design of important components of an HLFC system that helps in quick assessment of conceptual system architectures. This is important to evaluate feasibility, system performance, and overall aircraft benefits at early stages of system development. This paper also discusses the various important system requirements and issues concerning the design of active HLFC systems, and the interfaces between various disciplines are presented. It can be emphasized from the study that the future compressor design for the HLFC system should consider the thermal management aspects and additional mass flow requirements from the aerodynamics-structure design optimization and also from water drain system solutions. A method to calculate the accumulated water content inside the plenum chambers is presented, and the effect of a drain hole on the power consumption is studied. A low order thermal management study of the HLFC compressor motor shows a high temperature rise in the windings for very high speed motors for long duration operation and calls for effective cooling solutions.

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Numerical Evaluation of a HVAC System Based on a High-Performance Heat Transfer Fluid

Energies ◽

10.3390/en14113298 ◽

2021 ◽

Vol 14 (11) ◽

pp. 3298

Author(s):

Gianpiero Colangelo ◽

Brenda Raho ◽

Marco Milanese ◽

Arturo de Risi

Keyword(s):

Heat Transfer ◽

High Performance ◽

Cooling System ◽

Electrical Energy ◽

Simulation Software ◽

Heat Transfer Fluid ◽

Hvac System ◽

Dynamic Simulations ◽

Heating And Cooling ◽

The University

Nanofluids have great potential to improve the heat transfer properties of liquids, as demonstrated by recent studies. This paper presents a novel idea of utilizing nanofluid. It analyzes the performance of a HVAC (Heating Ventilation Air Conditioning) system using a high-performance heat transfer fluid (water-glycol nanofluid with nanoparticles of Al2O3), in the university campus of Lecce, Italy. The work describes the dynamic model of the building and its heating and cooling system, realized through the simulation software TRNSYS 17. The use of heat transfer fluid inseminated by nanoparticles in a real HVAC system is an innovative application that is difficult to find in the scientific literature so far. This work focuses on comparing the efficiency of the system working with a traditional water-glycol mixture with the same system that uses Al2O3-nanofluid. The results obtained by means of the dynamic simulations have confirmed what theoretically assumed, indicating the working conditions of the HVAC system that lead to lower operating costs and higher COP and EER, guaranteeing the optimal conditions of thermo-hygrometric comfort inside the building. Finally, the results showed that the use of a nanofluid based on water-glycol mixture and alumina increases the efficiency about 10% and at the same time reduces the electrical energy consumption of the HVAC system.

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