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204 results on '"Poh Seng Lee"'

1. Addressing the quantitative conversion bottleneck in single-atom catalysis

Author

Zhongxin Chen, Jingting Song, Rongrong Zhang, Runlai Li, Qikun Hu, Pingping Wei, Shibo Xi, Xin Zhou, Phuc T. T. Nguyen, Hai M. Duong, Poh Seng Lee, Xiaoxu Zhao, Ming Joo Koh, Ning Yan, and Kian Ping Loh

Subjects
Science
Abstract

The practical application of single atom catalyst (SAC) in liquid-phase heterogeneous catalysis is hampered by the productivity bottleneck as well as catalyst leaching. Here, a bench-top, fast-flow reactor integrated with Pt1-MoS2 SAC was fabricated for continuous production of multifunctional anilines (28 examples) at a record productivity of 5.8 g h-1.

Published
2022
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2. Methods and techniques of improving experimental testing for microfluidic heat sinks

Author

Samuel D. Marshall, Lakshmi Balasubramaniam, Rerngchai Arayanarakool, Bing Li, Poh Seng Lee, and Peter C.Y. Chen

Subjects
Heat sink, Experimental techniques, Liquid heat transfer, Microfluidic channels, Engineering (General). Civil engineering (General), TA1-2040
Abstract

There exist numerous methods of experimentally testing designs for heat sinks in the laboratory, especially for microscale fluidic devices, which can lead to a problem for comparison between new studies and those in the literature. To explore this issue, laboratory-based experiments on the heat transfer and flow impedance properties of a sample microchannel heat sink were repeated over a varying range of equipment. Three types of heat source (hot plate, film heater and copper block with cartridge heaters), two types of piping (polymer and metal), and the presence or absence of manifolds were investigated and the differences in heat sink performance were noted. Overall, especially in terms of achieving consistent, repeatable results, it was found that the arrangement of copper block heater, metal piping and the inclusion of manifolds was superior for this particular microchannel device. Hence, it is suggested that future testing of heat sinks and heat exchanger devices employ a similar arrangement of equipment for greater accuracy and comparability. In particular, the plastic tubing and hot plate configurations were found to have relatively poor consistency when testing the heat sink, and the film heater produced non-uniform heating, even over a small surface area.

Published
2017
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3. Direct Analytical Modeling for Optimal, On-Design Performance of Ejector for Simulating Heat-Driven Systems

Author

Fahid Riaz, Fu Zhi Yam, Muhammad Abdul Qyyum, Muhammad Wakil Shahzad, Muhammad Farooq, Poh Seng Lee, and Moonyong Lee

Subjects
ejector, low-grade heat, R245fa, simulation, CFD, heat recovery, Technology
Abstract

This paper describes an ejector model for the prediction of on-design performance under available conditions. This is a direct method of calculating the optimal ejector performance (entrainment ratio or ER) without the need for iterative methods, which have been conventionally used. The values of three ejector efficiencies used to account for losses in the ejector are calculated by using a systematic approach (by employing CFD analysis) rather than the hit and trial method. Both experimental and analytical data from literature are used to validate the presented analytical model with good agreement for on-design performance. R245fa working fluid has been used for low-grade heat applications, and Engineering Equation Solver (EES) has been employed for simulating the proposed model. The presented model is suitable for integration with any thermal system model and its optimization because of its direct, non-iterative methodology. This model is a non-dimensional model and therefore requires no geometrical dimensions to be able to calculate ejector performance. The model has been validated against various experimental results, and the model is employed to generate the ejector performance curves for R245fa working fluid. In addition, system simulation results of the ejector refrigeration system (ERS) and combined cooling and power (CCP) system have been produced by using the proposed analytical model.

Published
2021
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4. Rapid Prototyping of Polymer-Based Rolled-Up Microfluidic Devices

Author

Rerngchai Arayanarakool, Hian Hian See, Samuel David Marshall, Niven Singh Virik, Heng Wang, Poh Seng Lee, and Peter Chao Yu Chen

Subjects
prototype fabrication, roll-to-roll (R2R) processing, polymeric thin film, microfluidic heat transfer, curved channels, Mechanical engineering and machinery, TJ1-1570
Abstract

This work presents the simple and rapid fabrication of a polymer-based microfluidic prototype manufactured by rolling up thin films of polymer. The thin films were fabricated via a casting method and rolled up around a center core with the aid of plasma activation to create a three-dimensional (3D) spiral microchannel, hence reducing the time and cost of manufacture. In this work, rolled-up devices with single or dual fluidic networks fabricated from a single or two films were demonstrated for heat sink or heat exchanger applications, respectively. The experimental results show good heat transfer in the rolled-up system at various flow rates for both heat sink and heat exchanger devices, without any leakages. The rolled-up microfluidic system creates multiple curved channels, allowing for the generation of Dean vortices, which in turn lead to an enhancement of heat and mass transfer and prevention of fouling formation. These benefits enable the devices to be employed for many diverse applications, such as heat-transfer devices, micromixers, and sorters. To our knowledge, this work would be the first report on a microfluidic prototype of 3D spiral microchannel made from rolled-up polymeric thin film. This novel fabrication approach may represent the first step towards the development of a pioneering prototype for roll-to-roll processing, permitting the mass production of polymer-based microchannels from single or multiple thin films.

Published
2018
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8. Heat transfer enhancement using double taper microchannel

Author

Karthik Balasubramanian, Poh Seng Lee, Kupireddi Kiran Kumar, Chui Chee Kong, Pallikonda Mahesh, and Vivek Chandramohan

Subjects
Microchannel, Materials science, business.industry, Mechanical Engineering, Heat transfer enhancement, Optoelectronics, business, Industrial and Manufacturing Engineering
Abstract

A three-dimensional numerical study on the combined effect of height as well as width tapering on the thermal performance of double taper microchannel is presented in this paper. The channel inlet width is considered as 300 µm, taper ratio on sidewalls and bottom wall are varied from 0 to 1 and 1 to 3.9, respectively. The thermal resistance ratio, average bottom wall temperature, temperature difference ratio, and pumping power ratio of the channel are evaluated for various flow rates, height, and width tapering. Results showed higher reduction of wall temperature with combined effect height as well as width tapering compared with straight channel. The optimal size of the micro channel to minimize the pumping power and average wall temperature on the constraint of heat flux and footprint area is found. The reduction in average bottom wall temperature is 17.34%, and pumping power ratio is 0.44 (56% power reduction) noted, respectively, at Reynolds number 340. Finally, optimal dimension of double taper microchannel is evaluated for better thermo-hydraulic performance.

Published
2021
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14. Residual Physics and Post-Posed Shielding for Safe Deep Reinforcement Learning Method

Author

Qingang Zhang, Muhammad Haiqal Bin Mahbod, Chin-Boon Chng, Poh-Seng Lee, and Chee-Kong Chui

Subjects
Human-Computer Interaction, Control and Systems Engineering, Electrical and Electronic Engineering, Software, Computer Science Applications, Information Systems
Abstract

Deep reinforcement learning (DRL) has been researched for computer room air conditioning unit control problems in data centers (DCs). However, two main issues limit the deployment of DRL in actual systems. First, a large amount of data is needed. Next, as a mission-critical system, safe control needs to be guaranteed, and temperatures in DCs should be kept within a certain operating range. To mitigate these issues, this article proposes a novel control method RP-SDRL. First, Residual Physics, built using the first law of thermodynamics, is integrated with the DRL algorithm and a Prediction Model. Subsequently, a Correction Model adapted from gradient descent is combined with the Prediction Model as Post-Posed Shielding to enforce safe actions. The RP-SDRL method was validated using simulation. Noise is added to the states of the model to further test its performance under state uncertainty. Experimental results show that the combination of Residual Physics and DRL can significantly improve the initial policy, sample efficiency, and robustness. Residual Physics can also improve the sample efficiency and the accuracy of the prediction model. While DRL alone cannot avoid constraint violations, RP-SDRL can detect unsafe actions and significantly reduce violations. Compared to the baseline controller, about 13% of electricity usage can be saved.

Published
2022

20. Numerical investigation of thermal and hydraulic performance in novel oblique geometry using nanofluid

Author

Ritesh Kumar, Poh Seng Lee, Badyanath Tiwary, and Pawan Singh

Subjects
Numerical Analysis, Nanofluid, Materials science, Thermal, Oblique case, Computational analysis, Mechanics, Heat sink, Condensed Matter Physics, Fin (extended surface)
Abstract

To capitalize the advantage of oblique fin heat sink (OFHS) with Al2O3–water nanofluids of different volumetric concentration (1, 2, and 4%), a comprehensive computational analysis has been...

Published
2019
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21. Numerical investigation of thermal and hydraulic performances of a condenser coil with oblique-shaped tubes

Author

Poh Seng Lee, Kent Loong Khoo, Nuttawut Lewpiriyawong, and Chuan Sun

Subjects
Pressure drop, Materials science, 020209 energy, Mechanical Engineering, 02 engineering and technology, Building and Construction, Mechanics, 01 natural sciences, 010305 fluids & plasmas, Fin (extended surface), Flow separation, Electromagnetic coil, 0103 physical sciences, Heat transfer, Thermal, Heat exchanger, 0202 electrical engineering, electronic engineering, information engineering, Tube (fluid conveyance)
Abstract

High efficiency condenser coil providing higher heat removal capacity with lower air-side pressure drop is desirable. However, coil designs with different fin patterns for higher heat transfer incur large air-side pressure drop and thus consume more energy. In this study, the thermal and hydraulic performances of the condenser coil design with plain fin, corrugated fin, and novel oblique-shaped tube are evaluated numerically with a 3-fin and 3-tube model in comparison with a conventional circular tube coil. This novel oblique-shaped tube design features smaller air recirculation zone behind the tube so as to increase effective heat transfer area and to lower air-side pressure drop. The numerical results show that, for the plain fin configuration, the shape of the oblique tube is important in reducing the recirculation zone on the fin, thus increasing effective heat transfer area and heat transfer amount up to 14% and reducing the air-side pressure drop up to 14% at the same inlet air velocity as compared with the circular tube coil. With corrugated fin guiding and promoting air speed, causing more flow separation zones, it is detrimental to the thermal-hydraulic performance of the oblique tube coil. The discussion of choice of materials for tube and fin, such as copper, brass, and aluminium, is provided with possible manufacturing processes required for realizing potential high performance coil design. Parametric optimisation on the best performing plain fin oblique tube design shows that, for the design of condenser coil with oblique tube, there is no optimal FPI, but it is recommended to keep the ratio of tube pitch to tube frontal length/diameter to about 3 to 3.5.

Published
2019
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22. Experimental study of flow boiling in a hybrid microchannel-microgap heat sink

Author

John Mathew, Poh Seng Lee, Christopher Yap, and Tianqing Wu

Subjects
Fluid Flow and Transfer Processes, Mass flux, Pressure drop, Microchannel, Materials science, Mechanical Engineering, 02 engineering and technology, Mechanics, Heat transfer coefficient, Heat sink, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Heat flux, Boiling, 0103 physical sciences, Heat transfer, 0210 nano-technology
Abstract

A stable flow boiling operation is key to enhancing the two-phase cooling performance of microchannel heat sinks. To this end, a novel heat sink is developed which integrates a 300 μm × 600 μm straight microchannel array in the upstream region with a 25 mm × 600 μm microgap channel in the downstream region of a 25 mm × 25 mm copper heat sink. Flow boiling experiments are conducted using de-ionized water at 5 different mass fluxes in the range of 100–399 kg/m2 s, supplied at a fixed inlet temperature of 85.5 °C. The downstream heat transfer coefficient in the microgap section shows an M-shaped profile with increasing heat flux and vapor quality. Stable boiling conditions are prevalent across a large span of operating heat flux. Instabilities are experienced only for a short range of low heat flux following ONB. The stabilizing effect is attributed to the larger flow cross-section area offered by the downstream microgap section that allows expanding vapor bubbles to evacuate with lesser hindrance. Flow visualization reveals that a stable annular flow regime is established at moderate to high heat flux during which the stable boiling operation is observed. Thin film evaporation taking place during annular flow conditions results in an increasing trend in the downstream heat transfer coefficient from moderate to high heat flux. Pressure drop associated with the hybrid heat sink is found to be modest and reaches a maximum of 6 kPa at the highest mass flux of 399 kg/m2 s. A brief comparison of this heat sink is made with its straight microchannel and microgap heat sink counterparts. The hybrid heat sink shows a heat transfer performance that is superior to the microgap heat sink while poorer than the straight microchannel heat sink although it offers a better boiling stability than the straight microchannel heat sink. It however lowers the pressure drop compared to the straight microchannel heat sink.

Published
2019
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23. Thermal and hydraulic analysis of aluminium oblique-tube condenser coils with plain fins manufactured by controlled atmosphere brazing

Author

Nuttawut Lewpiriyawong, Chuan Sun, Poh Seng Lee, and Kent Loong Khoo

Subjects
Materials science, Atmospheric pressure, 020209 energy, Mechanical Engineering, Drop (liquid), chemistry.chemical_element, Thermal contact, 02 engineering and technology, Building and Construction, 020401 chemical engineering, chemistry, Aluminium, Electromagnetic coil, Heat transfer, Thermal, 0202 electrical engineering, electronic engineering, information engineering, Brazing, 0204 chemical engineering, Composite material
Abstract

This paper presents new development of aluminium oblique-tube condenser coils with plain fins manufactured by controlled atmospheric brazing (CAB) for air-conditioning applications. The CAB technique provides good quality joints and thermal contact between oblique tubes and fins for more effective heat transfer. Performances of seven oblique-tube coils with different numbers of tubes per pass (i.e. 1, 2, 3, 4, 5, 7 and 14) were assessed against those of a commercial circular-tube coil with corrugated fins. The contribution of the slender oblique tubes with plain fins reduced air pressure drop penalties by 20.9–30.9% for 1–3 m/s air velocity. Thermal performance of the 1-tube-per-pass coil surpassed that of the commercial coil albeit not energy-saving. On the other hand, the 4-tube pass coil when matching with the heat transfer performance of the 3- and 2-tube-per-pass coils and the circular-tube coil saved water-side pump energy as high as 27.9%, 36.3% and 38.7%, respectively.

Published
2019
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24. Study of thermal and hydraulic performance of air cooled minichannel heatsink with novel geometries

Author

Poh Seng Lee, Pawan Singh, Mithun Sarkar, and Sanjeev Kumar

Subjects
Convection, Materials science, 020209 energy, General Chemical Engineering, Airflow, Reynolds number, Laminar flow, 02 engineering and technology, Mechanics, Heat sink, Condensed Matter Physics, Thermal conduction, 01 natural sciences, Atomic and Molecular Physics, and Optics, 010406 physical chemistry, 0104 chemical sciences, symbols.namesake, Heat transfer, 0202 electrical engineering, electronic engineering, information engineering, symbols, Junction temperature
Abstract

Numerical and experimental study of minichannel heat sinks (MCHS), with air as a cooling medium, has been performed for straight channel heatsink (SC HS), wavy channel heatsink (WC HS) and branch wavy channel heatsink (BWC HS) to investigate thermal and hydraulic performances. After considering both the conduction and the convection as a mode of heat transfer, numerical computation of three-dimensional conjugated heat transfer between the heat sink and air flow has been performed by using full domain simulation in ANSYS Fluent. Laminar model is selected for the study of air flow and heat transfer as the Reynolds number varied from 300 to 1900 for a different range of air flow rates. Heating powers of 20 watt and 30 watt are applied at the base of the heat sink. Followed by detailed experimentation, the numerical results are also examined to get acquainted with the flow fields and their roles in the thermal performance of individual heat sinks. It has been found that the thermal-hydraulic performance factor of BWC HS exhibited superiority over SC HS and WC HS. It is also noticed that significant improvements in the junction temperature of BWC HS have been achieved. Experimental results have been validated with numerical results.

Published
2019
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27. Direct Analytical Modeling for Optimal, On-Design Performance of Ejector for Simulating Heat-Driven Systems

Author

Muhammad Farooq, Poh Seng Lee, Moonyong Lee, Muhammad Wakil Shahzad, Fahid Riaz, Fu Zhi Yam, and Muhammad Abdul Qyyum

Subjects
Technology, Control and Optimization, Iterative method, Computer science, 020209 energy, H300, Energy Engineering and Power Technology, Mechanical engineering, 02 engineering and technology, Computational fluid dynamics, ejector, law.invention, System model, 020401 chemical engineering, law, 0202 electrical engineering, electronic engineering, information engineering, 0204 chemical engineering, Electrical and Electronic Engineering, Engineering (miscellaneous), Renewable Energy, Sustainability and the Environment, business.industry, Direct method, Refrigeration, Injector, Solver, simulation, low-grade heat, R245fa, CFD, heat recovery, energy, thermal, system, Working fluid, business, Energy (miscellaneous)
Abstract

This paper describes an ejector model for the prediction of on-design performance under available conditions. This is a direct method of calculating the optimal ejector performance (entrainment ratio or ER) without the need for iterative methods, which have been conventionally used. The values of three ejector efficiencies used to account for losses in the ejector are calculated by using a systematic approach (by employing CFD analysis) rather than the hit and trial method. Both experimental and analytical data from literature are used to validate the presented analytical model with good agreement for on-design performance. R245fa working fluid has been used for low-grade heat applications, and Engineering Equation Solver (EES) has been employed for simulating the proposed model. The presented model is suitable for integration with any thermal system model and its optimization because of its direct, non-iterative methodology. This model is a non-dimensional model and therefore requires no geometrical dimensions to be able to calculate ejector performance. The model has been validated against various experimental results, and the model is employed to generate the ejector performance curves for R245fa working fluid. In addition, system simulation results of the ejector refrigeration system (ERS) and combined cooling and power (CCP) system have been produced by using the proposed analytical model.

Published
2021

29. Energy Analysis of a Novel Ejector-Compressor Cooling Cycle Driven by Electricity and Heat (Waste Heat or Solar Energy)

Author

Muhammad Imran, Fahid Riaz, Muhammad Farooq, Poh Seng Lee, and Kah Hoe Tan

Subjects
Materials science, 020209 energy, Nuclear engineering, Geography, Planning and Development, TJ807-830, 02 engineering and technology, Management, Monitoring, Policy and Law, ejector, TD194-195, Renewable energy sources, law.invention, 020401 chemical engineering, refrigeration, law, Waste heat, 0202 electrical engineering, electronic engineering, information engineering, Astrophysics::Solar and Stellar Astrophysics, vapour compression, GE1-350, 0204 chemical engineering, Condenser (heat transfer), Evaporator, CCP, Environmental effects of industries and plants, Renewable Energy, Sustainability and the Environment, business.industry, Refrigeration, VCC, Injector, Coefficient of performance, Solar energy, Environmental sciences, efficiency, low-grade heat, Physics::Space Physics, Astrophysics::Earth and Planetary Astrophysics, business, Gas compressor, energy
Abstract

Low-grade heat is abundantly available as solar thermal energy and as industrial waste heat. Non concentrating solar collectors can provide heat with temperatures 75&ndash, 100 &deg, C. In this paper, a new system is proposed and analyzed which enhances the electrical coefficient of performance (COP) of vapour compression cycle (VCC) by incorporating low-temperature heat-driven ejectors. This novel system, ejector enhanced vapour compression refrigeration cycle (EEVCRC), significantly increases the electrical COP of the system while utilizing abundantly available low-temperature solar or waste heat (below 100 &deg, C). This system uses two ejectors in an innovative way such that the higher-pressure ejector is used at the downstream of the electrically driven compressor to help reduce the delivery pressure for the electrical compressor. The lower pressure ejector is used to reduce the quality of wet vapour at the entrance of the evaporator. This system has been modelled in Engineering Equation Solver (EES) and its performance is theoretically compared with conventional VCC, enhanced ejector refrigeration system (EERS), and ejection-compression system (ECS). The proposed EEVCRC gives better electrical COP as compared to all the three systems. The parametric study has been conducted and it is found that the COP of the proposed system increases exponentially at lower condensation temperature and higher evaporator temperature. At 50 &deg, C condenser temperature, the electrical COP of EEVCRC is 50% higher than conventional VCC while at 35 &deg, C, the electrical COP of EEVCRC is 90% higher than conventional VCC. For the higher temperature heat source, and hence the higher generator temperatures, the electrical COP of EEVCRC increases linearly while there is no increase in the electrical COP for ECS. The better global COP indicates that a small solar collector will be needed if this system is driven by solar thermal energy. It is found that by using the second ejector at the upstream of the electrical compressor, the electrical COP is increased by 49.2% as compared to a single ejector system.

Published
2020

30. Energy Analysis of a New Combined Cooling and Power System for Low-Temperature Heat Utilization

Author

Poh Seng Lee, Siaw Kiang Chou, Fahid Riaz, Muhammad Imran, and Muhammad Farooq

Subjects
Electric power system, Nuclear engineering, Waste heat, Environmental science, Refrigeration, Compression (physics), Energy analysis
Abstract

In this paper, a new combined cooling and power (CCP) system has been proposed which enables harnessing of very low-grade heat (< 100 °C) in an effective way. The novel system configuration uses two vapour generators to extract more heat from heating stream and employs ejector in a unique way to serve two purposes; (i) to reduce pressure at the expander outlet for more power output (ii) vapour compression for refrigeration. The system is modelled in EBSILON which is a commercial thermal design and optimization tool. For ejector performance prediction, a new on-design optimal performance analytical model is used which is developed in EES (Engineering Equation Solver). The parametric study shows that when the evaporator pressure is changed from 0.8 bar (9.4 °C) to 1.2 bar (19.5 °C) the output of the system is increased by 58 % and when the condenser pressure is changed from 1.8 bar (30.5 °C) to 2.2 bar (36.2 °C) the system output is dropped by 56.4 %.

Published
2020
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31. Thermal enhancement of fin and tube heat exchanger with guiding channels and topology optimisation

Author

Nuttawut Lewpiriyawong, Chuan Sun, Poh Seng Lee, Kent Loong Khoo, and Shi Zeng

Subjects
Fluid Flow and Transfer Processes, Optimal design, Pressure drop, Materials science, 020209 energy, Mechanical Engineering, Airflow, Topology (electrical circuits), 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Topology, Fin (extended surface), Heat exchanger, Heat transfer, 0202 electrical engineering, electronic engineering, information engineering, 0210 nano-technology, Wind tunnel
Abstract

As the air-side heat transfer is controlling the efficiency of fin and tube heat exchangers (FTHX), the thermal enhancement of FTHX relies more on the air-side. A theoretical model of the baseline FTHX is built using ANSYS Fluent which is then validated by wind tunnel experiments. After analysing the simulation results of the baseline FTHX, two novel air-side fin configurations are proposed. The first design can guide more airflow to the back of the tubes to mitigate wake zones. For the second design, topology optimisation is used to significantly increase the heat transfer area at the air-side with minimised pressure drop penalty. To further improve the two designs, parametric studies are conducted through which optimal design parameters are obtained. Comparing with the baseline FTHX, the optimal guiding channel fin design and topology optimisation fin design can dissipate 8.5% and 7.0% more heat respectively, or consume 41.4% and 33.3% less fan power respectively. As such, the proposed enhanced air-side fin designs are promising candidates for improving the efficiency of FTHXs.

Published
2018
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32. Optimization of a Fluid Distribution Manifold : Mechanical Design, Numerical Studies, Fabrication, and Experimental Verification

Author

Poh Seng Lee, Lakshmi Balasubramaniam, Xin Jin, Rerngchai Arayanarakool, Heng Wang, Peter C. Y. Chen, and Samuel D. Marshall

Subjects
Fabrication, Materials science, Computer simulation, 020209 energy, Mechanical Engineering, Mechanical engineering, 02 engineering and technology, Industrial and Manufacturing Engineering, law.invention, Conical cavity, law, 0202 electrical engineering, electronic engineering, information engineering, Mechanical design, Manifold (fluid mechanics), Distribution (differential geometry)
Published
2018
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33. Experimental and numerical investigation of a mini channel forced air heat sink designed by topology optimization

Author

Shi Zeng, Bugra Kanargi, and Poh Seng Lee

Subjects
Fluid Flow and Transfer Processes, Materials science, Fin, 020209 energy, Mechanical Engineering, Multiphysics, Heat transfer enhancement, Topology optimization, 02 engineering and technology, Mechanics, Heat sink, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Forced convection, Heat transfer, 0202 electrical engineering, electronic engineering, information engineering, Junction temperature, 0210 nano-technology
Abstract

This work presents a method of designing an air heat sink with forced convection by topology optimization. Both pressure drop and heat transfer performances are evaluated. To reduce computational cost, a 2D two-layer model is first developed and implemented in COMSOL Multiphysics to represent three-dimension fully conjugate heat transfer modeling. It has been shown to be accurate in temperature field prediction and able to capture trends of pressure drop variation. Through a multi-stage optimization process, a non-conventional fin structure is created. The optimized structure is then manufactured and experimentally validated. Compared to a conventional straight channel heat sink, the topology optimized heat sink can achieve lower junction temperatures with the same pumping power or requires lower pumping powers for maintaining the same junction temperature. Furthermore, full 3D numerical analysis by ANSYS Fluent is performed to study the detailed characteristics of the topology optimized heat sink. It shows that the non-conventional layout of the fins introduces strong mixing effect, continuous boundary layer interruption and local high speeds, which all contribute to heat transfer enhancement.

Published
2018
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34. Mathematical modeling and performance evaluation of a desiccant coated fin-tube heat exchanger

Author

Poh Seng Lee and Mrinal Jagirdar

Subjects
Desiccant, Materials science, business.industry, 020209 energy, Mechanical Engineering, 02 engineering and technology, Building and Construction, Management, Monitoring, Policy and Law, Isothermal process, Fin (extended surface), General Energy, 020401 chemical engineering, Air conditioning, Waste heat, Heat exchanger, HVAC, 0202 electrical engineering, electronic engineering, information engineering, Mass flow rate, 0204 chemical engineering, Process engineering, business
Abstract

A solid-desiccant system that utilizes low grade heat is potentially a viable add-on to conventional HVAC systems since it can help reduce power consumption significantly, for achieving indoor thermal comfort conditions. In contrast to desiccant wheels which carry out adiabatic dehumidification, isothermal dehumidification process that may be realized by a cross-flow heat exchanger is much more efficient. In this paper, a novel mathematical model is developed to simulate heat and mass exchange phenomena of a desiccant coated fin tube heat exchanger (DCFTHX). This model takes solid side mass transfer resistance as well as fin efficiency into consideration. The model is validated using experimental results in the literature. It is also compared against simplified models to establish its utility. A parametric study is then conducted to investigate the effects of geometrical parameters as well as mass flow rate of water and air velocity on dehumidification and adsorption heat removal performance of the DCFTHX as well as the performance of the augmented air-conditioning system under warm and humid ambient conditions. Under the range of parameters and conditions simulated, if low grade waste heat (50 °C hot water) is available for regeneration, integration of DCFTHX sub-system with a conventional air conditioning system can yield as high as 31% energy savings (even when the additional power consumed by pumps and blower fans is accounted for).

Published
2018
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35. Vortex-enhanced thermal environment for air-cooled data center: An experimental and numerical study

Author

Xin Xiong and Poh Seng Lee

Subjects
business.industry, Mechanical Engineering, Nuclear engineering, Flow (psychology), Airflow, Enclosure, Building and Construction, Computational fluid dynamics, Aisle, Vortex, Containment, Water cooling, Environmental science, Electrical and Electronic Engineering, business, Civil and Structural Engineering
Abstract

Poor airflow management attributed to hot air recirculation and cold air by-pass adds massive thermal inefficiencies to air-cooled data center’s cooling system. The containment system usually was adopted to mitigate such drawbacks by isolating the space using a physical partition wall, such as hot aisle containment. Although the recirculation and by-pass can be effectively suppressed, the consequent high backpressure built up in the containment reducing the server air flowrate and possibly increasing the server temperature beyond the acceptable limit. This study presents a new enclosure mechanism for air-cooled data center using a vortex flow as an alternative to the conventional hot aisle containment to reduce the hot recirculation and, at the same time to retain the server air flowrate. The experiments conducted in a half-scale test cell (2-times smaller than a typical data center hall in length scale) examined vortex containment's effectiveness. The experiment results revealed that the average Supply Heat Index (SHI) in vortex hot aisle containment could be reduced to 0.11. Although vortex hot aisle containment did not enclose all hot recirculation compared to the full containment deployed in the benchmark layout, the relieved backpressure (the high pressure in the hot aisle) retains the rack flowrate by 42% (2.1 m/s in the vortex hot aisle containment with a diameter 1.2 m (VFL1200) layout compared to 1.2 m/s in full containment) and results in a 4.3% lower normalized server temperature (1.03 in VFL1200 layout compared to 1.076 in full containment CL). In the end, the validated CFD model provides more insights on vortex containment characteristics, such as the vortex strength and pressure distribution.

Published
2021
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36. A numerical investigation of fan wall cooling system for modular air-cooled data center

Author

Yogesh Fulpagare, Poh Seng Lee, and Xin Xiong

Subjects
Environmental Engineering, business.industry, Geography, Planning and Development, Airflow, Mechanical engineering, Building and Construction, Computational fluid dynamics, Plenum space, Rack, Raised floor, Water cooling, Environmental science, Overhead (computing), Data center, business, Civil and Structural Engineering
Abstract

Airflow management in the data center is one of the most researched topics to achieve uniform airflow for effective thermal management. Recently, the Fan Wall Cooling (FWC) system is popular in air-cooled data centers due to the advantage of no raised floor plenum. In this research, a validated CFD model is used to study the FWC performance with different configurations to gain insights for the optimum design. Five new configurations are proposed to optimize the FWC performance along with ordinary FWC. Each of them has a different rack-tilted and row-tilted angle. The results show that tilting the rack by 15° towards the supply air direction can increase the rack air flowrate by 2.5% (800 CFM), and reduce the maximum normalized server temperature ( T s e r , m a x ∗ ) by 7% from 1.30 to 1.21. The CFD simulations also reveal that all new configurations can effectively mitigate the airflow maldistribution. Lastly, the FWC exhibits superior thermal performance compared to the conventional Underfloor Air Delivery (UFAD) and the Overhead Air Supply (OHAS) methods.

Published
2021
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37. A numerical and experimental investigation of heat transfer and fluid flow characteristics of an air-cooled oblique-finned heat sink

Author

Christopher Yap, Poh Seng Lee, and Bugra Kanargi

Subjects
Fluid Flow and Transfer Processes, Dynamic scraped surface heat exchanger, Materials science, Convective heat transfer, Critical heat flux, 020209 energy, Mechanical Engineering, Heat transfer enhancement, Thermodynamics, 02 engineering and technology, Mechanics, Heat transfer coefficient, Heat sink, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Fin (extended surface), Heat transfer, 0202 electrical engineering, electronic engineering, information engineering, 0210 nano-technology
Abstract

The thermal and hydraulic performances of an air-cooled, planar, oblique-finned heat sink (OF HS) were investigated for two oblique angles: 30° and 45°. The conjugate heat transfer between the heat sink and the air flow were computed numerically in ANSYS Fluent for a range of air flow rates for the smallest periodically repeating portion of the heat sink. The RNG k-e turbulence model with enhanced wall treatment was used to solve the fluid flow and heat transfer. Followed by the experimental validation, the numerical results were scrutinized further to understand the effects of the flow field on the measured heat transfer performances. Apart from boundary layer disruption, vortices generated within the secondary channels due to flow separation particularly improved the advection component of the convective heat transfer, resulting in a heat transfer enhancement, exceeding the pressure drop penalty. The strong flow mixing, showing chaotic behavior, enabled a more uniform increase in the air temperature in the streamwise direction, utilizing the cooling potential of the air flow more effectively. 30° oblique-finned heat sink was observed to induce higher rates of secondary flow rates and improve the heat transfer performance more than its 45° counterpart. Due to the migration of the flow in the direction of the secondary channels, the heat transfer enhancement was compromised at high Reynolds numbers, the pressure drop penalty exceeded the heat transfer enhancement, causing a reduction in the thermal-hydraulic performance factor. The effects of flow migration on the flow and temperature fields were investigated with full domain numerical simulations. Experimental investigations showed significant improvements in the junction temperatures.

Published
2018
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38. Heat transfer augmentation in a radial curved microchannel

Author

Poh Seng Lee, Kiran Kumar Kupireddi, Vivek Chandramohan, Chui Chee Kong, Nitin Kumar Mamidi, and Karthik Balasubramanian

Subjects
Physics::Fluid Dynamics, Microchannel, Materials science, Mechanical Engineering, Physics::Medical Physics, Heat transfer, Miniaturization, Thermal management of electronic devices and systems, Mechanics, Industrial and Manufacturing Engineering
Abstract

Rapid advancement toward miniaturization has emerged with confront for superior heat dissipation techniques. Of all the available cooling systems, microchannel-based cooling systems stand out to provide better cooling performance through superior heat removal abilities. In the present study, the cooling performance and hydraulic flow characteristics of a radial curved microchannel with three curvature ratios were numerically investigated and compared with a radial straight microchannel. Unlike the conventional straight microchannels, curved channels possess better fluid mixing as a result of the centrifugal force caused due to curvature. This phenomenon has a significant effect on heat transfer and fluid flow characteristics. Work on radial curved microchannels has been scarce and there is a lot of potential to augment the heat transfer with lower pumping power particularly with a central inlet. A three-dimensional conjugate heat transfer analysis was carried out for three radial curved microchannels and a radial straight microchannel using the ANSYS Fluent commercial software with the Reynolds number range of 125–275. The results showed a Nusselt number increment of 36.38% for radial curved microchannels when compared to the radial straight microchannel. Further, the lowest average wall temperature was noted for the radial curved microchannel with a curvature ratio of 0.17 which was 15.63 °C lower when compared to that in a radial straight microchannel for the same Reynolds number. Contours of velocity and temperature are presented at various locations along the stream to aid the results. The overall performance of all three radial curved microchannels was found to be higher than that of the radial straight microchannel in the Reynolds number range considered, out of which the maximum performance factor of 1.245 was obtained for the radial curved microchannel with a curvature ratio of 0.17 as compared to the radial straight microchannel.

Published
2021
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39. Analysis of Low-Grade Waste Heat Driven Systems for Cooling and Power for Tropical Climate

Author

Ravi Ranjan, Fahid Riaz, Thazin Soe, Cher Seng Tay, Poh Seng Lee, and Siaw Kiang Chou

Subjects
business.industry, 020209 energy, Environmental engineering, Biomass, 02 engineering and technology, Renewable energy, Power (physics), Conference of the parties, 020401 chemical engineering, Waste heat, Tropical climate, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, 0204 chemical engineering, business, Geothermal gradient, Efficient energy use
Abstract

In the 21st conference of the parties (COP21) of United Nations, both renewable energy and energy efficiency were recognized as essential means for low-carbon future. It is estimated that around 20-50 % of energy input to industries is lost as waste heat. Low-grade heat is abundantly available from renewable sources like solar, biomass and geothermal. There is a need to develop technologies which can utilize very low-grade heat (

Published
2017
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40. Methods and techniques of improving experimental testing for microfluidic heat sinks

Author

Peter C. Y. Chen, Poh Seng Lee, Lakshmi Balasubramaniam, Samuel D. Marshall, Rerngchai Arayanarakool, and Bing Li

Subjects
Fluid Flow and Transfer Processes, Microchannel, Materials science, 020209 energy, Experimental techniques, Plate heat exchanger, Mechanical engineering, 02 engineering and technology, Heat sink, 021001 nanoscience & nanotechnology, lcsh:TA1-2040, Heat spreader, Heat transfer, Heat exchanger, 0202 electrical engineering, electronic engineering, information engineering, Micro heat exchanger, Microfluidic channels, Plate fin heat exchanger, Liquid heat transfer, 0210 nano-technology, lcsh:Engineering (General). Civil engineering (General), Engineering (miscellaneous)
Abstract

There exist numerous methods of experimentally testing designs for heat sinks in the laboratory, especially for microscale fluidic devices, which can lead to a problem for comparison between new studies and those in the literature. To explore this issue, laboratory-based experiments on the heat transfer and flow impedance properties of a sample microchannel heat sink were repeated over a varying range of equipment. Three types of heat source (hot plate, film heater and copper block with cartridge heaters), two types of piping (polymer and metal), and the presence or absence of manifolds were investigated and the differences in heat sink performance were noted. Overall, especially in terms of achieving consistent, repeatable results, it was found that the arrangement of copper block heater, metal piping and the inclusion of manifolds was superior for this particular microchannel device. Hence, it is suggested that future testing of heat sinks and heat exchanger devices employ a similar arrangement of equipment for greater accuracy and comparability. In particular, the plastic tubing and hot plate configurations were found to have relatively poor consistency when testing the heat sink, and the film heater produced non-uniform heating, even over a small surface area.

Published
2017

41. A pump-free microfluidic 3D perfusion platform for the efficient differentiation of human hepatocyte-like cells

Author

Hwa Liang Leo, Lin Jin, Poh Seng Lee, Pawan Singh, Louis Jun Ye Ong, Hanry Yu, Yi-Chin Toh, Lor Huai Chong, and Abhishek Ananthanarayanan

Subjects
0301 basic medicine, Hepatocyte differentiation, Cellular differentiation, Liver cell, Hydrostatic pressure, Bioengineering, Nanotechnology, Biology, Applied Microbiology and Biotechnology, Cell biology, 03 medical and health sciences, 030104 developmental biology, Tissue engineering, Cell culture, Progenitor cell, Stem cell, Biotechnology
Abstract

The practical application of microfluidic liver models for in vitro drug testing is partly hampered by their reliance on human primary hepatocytes, which are limited in number and have batch-to-batch variation. Human stem cell-derived hepatocytes offer an attractive alternative cell source, although their 3D differentiation and maturation in a microfluidic platform have not yet been demonstrated. We develop a pump-free microfluidic 3D perfusion platform to achieve long-term and efficient differentiation of human liver progenitor cells into hepatocyte-like cells (HLCs). The device contains a micropillar array to immobilize cells three-dimensionally in a central cell culture compartment flanked by two side perfusion channels. Constant pump-free medium perfusion is accomplished by controlling the differential heights of horizontally orientated inlet and outlet media reservoirs. Computational fluid dynamic simulation is used to estimate the hydrostatic pressure heads required to achieve different perfusion flow rates, which are experimentally validated by micro-particle image velocimetry, as well as viability and functional assessments in a primary rat hepatocyte model. We perform on-chip differentiation of HepaRG, a human bipotent progenitor cell, and discover that 3D microperfusion greatly enhances the hepatocyte differentiation efficiency over static 2D and 3D cultures. However, HepaRG progenitor cells are highly sensitive to the time-point at which microperfusion is applied. Isolated HepaRG cells that are primed as static 3D spheroids before being subjected to microperfusion yield a significantly higher proportion of HLCs (92%) than direct microperfusion of isolated HepaRG cells (62%). This platform potentially offers a simple and efficient means to develop highly functional microfluidic liver models incorporating human stem cell-derived HLCs. Biotechnol. Bioeng. 2017;114: 2360-2370. © 2017 Wiley Periodicals, Inc.

Published
2017
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42. A numerical and experimental investigation of heat transfer and fluid flow characteristics of a cross-connected alternating converging–diverging channel heat sink

Author

Poh Seng Lee, Christopher Yap, and Omer Bugra Kanargi

Subjects
Fluid Flow and Transfer Processes, Materials science, Convective heat transfer, Critical heat flux, 020209 energy, Mechanical Engineering, Heat transfer enhancement, Thermodynamics, 02 engineering and technology, Heat transfer coefficient, Mechanics, Heat sink, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Fin (extended surface), Physics::Fluid Dynamics, Heat transfer, 0202 electrical engineering, electronic engineering, information engineering, Micro heat exchanger, 0210 nano-technology
Abstract

In this study, the conjugate heat transfer performance of an enhanced planar heat sink design, comprising cross-connected alternating converging–diverging channels, was analyzed for forced air convection conditions. Numerical simulations were performed in ANSYS Fluent 15.0 using the RNG k–e turbulence model accompanied by the enhanced wall treatment option to resolve the air flow and evaluate the heat transfer. Numerical results, which were validated experimentally, were utilized to investigate the flow and the temperature fields. The converging–diverging channel sections induced secondary flows through the cross connections, repeatedly disturbing the thermal and hydraulic boundary layers over the leading edges of the fin sections. The performance of the proposed heat sink design was benchmarked against the conventional straight channel heat sink of equivalent dimensions. Significant heat transfer enhancement was observed. However, the vortices, generated as a result of the separation of the secondary flows, were observed to prevent the heat transfer performance from being further improved and cause an excessive increase in the pressure drop penalty.

Published
2017
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43. An Experimental Study of the Vortex-Enhanced Hot Aisle Containment (VEHAC) using a Scale Model

Author

Poh Seng Lee, Yogesh Fulpagare, and Xin Xiong

Subjects
geography, geography.geographical_feature_category, business.industry, Nuclear engineering, Inlet, Aisle, Temperature measurement, Vortex, Containment, Thermal, Environmental science, Data center, business, Scale model
Abstract

Raised-floor data center supplying the cold air to servers through the perforated tiles encounters the thermal inefficiency from the cold air by-pass and the hot air recirculation. Although the containment solutions solve the problem, studies [1]–[4] have emphasized the potential rise of the energy cost if extensive leakages are presented or poorly maintained. In this study, an experiment was conducted to evaluate a new approach to minimize the recirculation and by-pass other than the conventional containment system, i.e. Vortex-Enhanced Hot Aisle Containment (VEHAC) using a scale model with scale ratio 11.25. The formation of a vortex observed in the experiment built a “virtual wall” at special oriented hot aisle preventing the hot air recirculating back to cold aisle. Server inlet air temperature was improved by 0.4 °C in the scale model measured during the experiment.

Published
2019
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44. Thermal Characterization of Vortex Flow Layout for Data Center

Author

Xin Xiong, Poh Seng Lee, and Yogesh Fulpagare

Subjects
Rack, business.industry, Raised floor, Thermal engineering, Airflow, Environmental science, Data center, business, Aisle, Plenum space, Marine engineering, Vortex
Abstract

Data center thermal management is one of the focused research areas worldwide to optimize system performance to reduce electric power consumption [1]. One of the ways is effective airflow management by aisle containment. To achieve this, in this study we proposed vortex hot aisle containment first time in data center research community. The rack arrangement is designed in such a way that the hot aisle airflow can create the vortex due to pressure gradients. To characterize this airflow, we performed initial CFD simulations [2] and started the experimentation. This paper focuses on the experimental details of this study. Four 32U racks with 6U server simulators were tested in raised floor plenum data center facility at School of Commuting in the National University of Singapore. Initial steady-state experiments were performed for vortex hot aisle containment to monitor the rack inlet and outlet air temperature for varying heat load and server fan speed. Results show the favorable pressure variations to generate the vortex airflow inside the vortex hot ails containment and expect to give more insights with some more experiments.

Published
2019
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45. Heat Transfer Investigation of an Additively Manufactured Minichannel Heat Exchanger

Author

Poh Seng Lee, Bejan Hamawandi, Hamidreza Rastan, Björn Palm, Amir Abdi, and Monika Ignatowicz

Subjects
Materials science, Distilled water, Thermal, Heat exchanger, Heat transfer, Flow (psychology), Laminar flow, Composite material, Energy engineering
Abstract

This study investigates the thermal performance of laminar single-phase flow in an additively manufactured minichannel heat exchanger both experimentally and numerically. Distilled water was employed as the working fluid, and the minichannel heat exchanger was made from aluminum alloy (AlSi10Mg) through direct metal laser sintering (DMLS). The minichannel was designed with a hydraulic diameter of 2.86 mm. The Reynolds number ranged from 175 to 1360, and the heat exchanger was tested under two different heat fluxes of 1.5 kWm−2 and 3 kWm−2. A detailed experiment was conducted to obtain the thermal properties of AlSi10Mg. Furthermore, the heat transfer characteristics of the minichannel heat exchanger was analyzed numerically by solving a three-dimensional conjugate heat transfer using the COMSOL Multiphysics® to verify the experimental results. The experimental results were also compared to widely accepted correlations in literature. It is found that 95% and 79% of the experimental data are within ±10% range of both the simulation results and the values from the existing correlations, respectively. Hence, the good agreement found between the experimental and simulation results highlights the possibility of the DMLS technique as a promising method for manufacturing future multiport minichannel heat exchangers.

Published
2019
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46. Numerical Study of a New Rack Layout for Better Cold Air Distribution and Reduced Fan Power

Author

Xin Xiong, Poh Seng Lee, Chuan Sun, and Yogesh Fulpagare

Subjects
Rack, Steady state, Containment, business.industry, Flow (psychology), Environmental science, Data center, Mechanics, Computational fluid dynamics, business, Vortex, Power (physics)
Abstract

Cold air by-pass and hot air recirculation are two primary sources of inefficiencies in data center thermal management. Although some studies have been conducted to investigate the cause of such issues [1] [2], few attempts were reported to improve the situation by changing the rack layout configuration. A new rack layout, called Vortex Flow Layout (VFL) configuration is proposed in this study. The configuration is simulated under fully, partial and no containment cases to evaluate its performance. Studied from a steady state CFD model utilizing the vortex flow effect, the hot air recirculation is found to be suppressed by 3 °C and 5.3 °C in partial containment and open configuration respectively. It is found that the formation of a vortex traps the hot server-outlet air in the vortex core that helps to restrict the recirculation. The VFL partial containment shows the best performance with high recirculation suppression effect and reduced fan power.

Published
2019
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47. Pool Boiling Heat Transfer Enhancement with Porous Fin Arrays Manufactured by Selective Laser Melting

Author

John Mathew, Poh Seng Lee, Tianqing Wu, Chen-Nan Sun, and Beng Loon Aw

Subjects
Materials science, Critical heat flux, 020209 energy, Thermal resistance, 02 engineering and technology, Heat transfer coefficient, Heat sink, 021001 nanoscience & nanotechnology, Boiling, Heat transfer, 0202 electrical engineering, electronic engineering, information engineering, Selective laser melting, Composite material, 0210 nano-technology, Porosity
Abstract

Advanced cooling solutions are crucial for the further development of modern technologies. Additive manufacturing (AM) helps to remove many of the conventional design constraints and thereby enables the realization of novel heat sink topologies and geometries that lead to enhanced thermal performance. In this study, porous fin arrays with minimum cavity and channel size of 0.3mm are designed and manufactured using Selective Laser Melting (SLM) technology. AlSi12 alloy powders are adopted to print directly on the copper base. Stable connection is achieved between two materials and thermal resistance is reduced to minimum. The heat transfer performance of heat sinks with different porous layers are evaluated through pool boiling experiments with deionized water. The benchmark test involves a plain copper surface with a footprint of $10\times 10\mathrm{mm}$ , same as the base used for additive manufacturing. High speed visualization results are combined with the measured boiling data to assess the two-phase heat transfer performance of heat sinks. Superior heat removal performance is achieved with SLM manufactured porous fin arrays with the highest heat transfer coefficient (HTC) enhancement of 80% and critical heat flux (CHF) enhancement of more than 170%. The performance boost is mainly attributed to the larger number of nucleation sites, increased heat transfer area, capillary-assisted suction, and separated liquid-vapor pathways associated with the porous fin array designs. The present study showcases the combination of complex structure design with SLM technology and would provide useful insight for the development of future high performance heat sink designs and the optimization of AM process.

Published
2019
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48. Performance of an internally cooled and heated desiccant-coated heat and mass exchanger: Effectiveness criteria and design methodology

Author

Mrinal Jagirdar, JT Johan Padding, and Poh Seng Lee

Subjects
Desiccant, Moisture, business.industry, 020209 energy, Modeling, Mixing (process engineering), Energy Engineering and Power Technology, Humidity, 02 engineering and technology, Coefficient of performance, Desiccant dehumidification, HVAC, Industrial and Manufacturing Engineering, Air conditioning, Fluid power, 020401 chemical engineering, Desiccant coated heat exchanger, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Fin tube heat exchanger, 0204 chemical engineering, business, Process engineering
Abstract

Internally cooled and heated desiccant-coated heat and mass exchangers (ICHDHMX) driven by low-grade heat are very attractive owing to their energy-saving potential, especially for applications where substantial moisture removal (such as air-conditioning) is a necessity. In this paper, we derive equations for the performance of an ideal ICHDHMX, allowing us to define humidity-ratio effectiveness (εY) and relative-humidity effectiveness (εRH) such that their values approach 1 as the performance approaches that of an ideal ICHDHMX. Besides an equation-based approach, an easy-to-use psychrometric-chart based approach is presented to determine the performance of an ideal ICHDHMX. We invoke conservation principles to ascertain whether or not it is feasible to use the ICHDHMX for a given set of inlet conditions of air and water streams for dehumidification and regeneration. The dimensions of the ICHDHMX can be determined using this methodology, not even requiring knowledge of a tuning parameter unless a precise outlet specific humidity is required. Simulations are conducted for cases involving three incoming hot water temperatures (38, 44 and 50 °C) and several mixing ratios of room return air (25 °C at 0.011 kg/kg dry air) and outdoor air (32 °C at 0.02 kg/kg dry air), typical of warm and humid weather conditions. For all cases, the cool-water inlet is fixed at 30 °C. The results show that even when the dehumidification air-stream humidity is high, if the regeneration air-stream humidity is low (typical of room-exhaust air), the operation of an ICHDHMX is feasible using a low regeneration temperature of only 38 °C. When the regeneration temperature is 50 °C, the exchanger can operate under the complete range of humidity conditions tested. A cooling coefficient of performance up to 9.8 and effectiveness value up to 0.88 is realized, while the fluid power required is generally very low. These findings substantiate the case for commercial adoption of this technology for air-conditioning.

Published
2021
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49. A diagnostic tool for detection of flow-regimes in a microchannel using transient wall temperature signal

Author

Mrinal Jagirdar and Poh Seng Lee

Subjects
Flow visualization, Materials science, Microchannel, 020209 energy, Mechanical Engineering, Flow (psychology), 02 engineering and technology, Building and Construction, Mechanics, Management, Monitoring, Policy and Law, 021001 nanoscience & nanotechnology, Volumetric flow rate, General Energy, Frequency domain, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Working fluid, Transient (oscillation), Current (fluid), 0210 nano-technology
Abstract

Flow boiling in microchannels has been receiving a lot of attention in recent years because of its high heat flux removal capabilities at low flow rates and low pumping power. An important aspect of flow-boiling experiments is prediction or detection of the prevalent flow-regime. Currently, most researchers use high-speed camera for flow visualization for regime detection. However, in some cases due to limitations of the experimental setup and test-piece, such as multi-layer cooling of 3D IC stack, this may not be feasible. In this paper, the influence of flow-regime on frequency domain of local temperature data of the wetted surface is studied. Experiments have been performed synchronously with high speed flow visualization on a single microchannel with width and length of 2.54 mm and 25.4 mm respectively. The microchannel heights tested were 0.14 , 0.28 and 0.42 mm . De-gassed, de-ionized water was used as the working fluid. Mass fluxes tested ranged from 200 to 1000 kg / ( m 2 s ) . Depending on the prevalent flow regime, some of the highest of peak amplitudes in the frequency domain were quite distinct. Within the bounds of current experimental parameters, it is concluded that local transient temperature data can be a potential diagnostic tool for detection of flow-regimes. (A shorter version of this paper was presented at the 7th International Conference on Applied Energy (ICAE2015), March 28–31, 2015, Abu Dhabi, UAE (Original paper title: “Temperature transients for detection of flow-regimes in a mini/microchannel” and Paper No.: 430).)

Published
2017
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50. Coupled equivalent circuit models for fluid flow and heat transfer in large connected microchannel networks – The case of oblique fin heat exchangers

Author

Poh Seng Lee, Saif A. Khan, and Nasi Mou

Subjects
Fluid Flow and Transfer Processes, Physics, 020209 energy, Mechanical Engineering, Heat transfer enhancement, Mass flow, Enhanced heat transfer, Thermodynamics, 02 engineering and technology, Mechanics, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Annular fin, Nusselt number, Fin (extended surface), Physics::Fluid Dynamics, 0202 electrical engineering, electronic engineering, information engineering, Micro heat exchanger, Trailing edge, 0210 nano-technology
Abstract

This paper presents a simplified equivalent circuit model, which exploits the electric–hydraulic analogy and electric–thermal analogy, to predict the mass flow distribution and temperature distribution in an oblique fin array used in enhanced heat transfer applications. Methods to obtain accurate correlations for calculation of flow-dependent hydraulic ‘resistances’ are outlined and developed for both primary and secondary channels in the oblique fin array. Appropriate Nusselt number correlations and thermal resistance models are also employed to predict the temperature distribution associated with the mass flow distribution. Detailed full-domain numerical (CFD) simulations are performed to obtain parameters for the hydraulic resistance correlations, and also to serve as benchmarks for the proposed equivalent circuit model. Detailed comparisons between the results of simplified model and numerical simulation showed that the simplified model can accurately predict the mass flow distribution and temperature distribution, within ±5%, for varying fin number, aspect ratio, fin pitch, fin length, oblique angle and inlet velocity. Slightly higher deviations of mass flow prediction are observed for high inlet velocities as a result of the presence of vortices close to the trailing edge of the oblique fin region.

Published
2016
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