Conferences related to Heat Transfer

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2015 IEEE International Conference on Plasma Sciences (ICOPS)

Basic Processes in Fully and Partially Ionized Plasmas; Microwave Generation and Plasma Interactions; Charged Particle Beams and Sources; High Energy Density Plasmas and Applications; Industrial, Commercial, and Medical Plasma Applications; Plasma Diagnostics; Pulsed Power and other Plasma Applications.


2013 14th International Conference on Electronic Packaging Technology (ICEPT)

ICEPT 2013 is a four-day event, featuring technical sessions, invited talks, professional development courses/forums, exhibition, and social networking activities. It aims to cover the latest technological developments in electronic packaging, manufacturing and packaging equipment, and provide opportunities to explore the trends of research and development, as well as business in China.


2013 IEEE/CPMT 29th Semiconductor Thermal Measurement & Management Symposium (SemiTherm)

electronics cooling


2012 Asia-Pacific Magnetic Recording Conference (APMRC)

Hard disk drive (HDD) technologies in the areas of Magnetic Recording Physics; Future Magnetic Recording; Media Magnetics; Spintronics and Head; Mechanics, Vibro-acoustics, Heat Transfer and Airflow; Nano-Mechanics and HDI; Lube, Overcoat and Surface Protection; Micro and Nano-Actuator; Motor and Bearing; Servo and Control; Signal Processing; System Integration; Data Centre Technologies.

  • 2010 Asia-Pacific Magnetic Recording Conference (APMRC)

    Sponsored by Magnetics Society - MAG, Singapore Section A conference that focuses on the mechanical and manufacturing aspects of hard disk drive (HDD) technologies in the areas of Actuator and Microactuator; Airflow, Acoustics, Heat Transfer and Mechanics; Future Hard Disk Drive Technologies; Lube, Overcoat and Surface Protection; Motor and Bearing; Nanomechanics and Aerodynamics for Head-Disk Interface; Servo and Control.

  • 2009 Asia-Pacific Magnetic Recording Conference (APMRC)

    A conference that focuses on the mechanical and manufacturing aspects of hard disk drive (HDD) technologies in the areas of HDI dynamics; lube, overcoat and tribology; actuator and micro-actuator; motor and bearing; airflow, heat transfer, acoustics and mechanics; servo and control.

  • 2006 Asia Pacific Magnetic Recording Conference (APMRC)


2010 3rd International Conference on Thermal Issues in Emerging Technologies Theory and Applications (ThETA)

Thermal issues in emerging technologies (microelectronics, nanotechnology, smart materials,micro -electro -mechanical systems, biomedical engineering, new engergies)


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Periodicals related to Heat Transfer

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Advanced Packaging, IEEE Transactions on

The IEEE Transactions on Advanced Packaging has its focus on the modeling, design, and analysis of advanced electronic, photonic, sensors, and MEMS packaging.


Components and Packaging Technologies, IEEE Transactions on

Component parts, hybrid microelectronics, materials, packaging techniques, and manufacturing technology.


Nanotechnology, IEEE Transactions on

The proposed IEEE Transactions on Nanotechnology will be devoted to the publication of manuscripts of archival value in the general area of nanotechnology, that is rapidly emerging as one of the fastest growing and most promising new technological developments for the next generation and beyond.



Most published Xplore authors for Heat Transfer

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Xplore Articles related to Heat Transfer

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The thermal characterization of packaged semiconductor device

Shiwei Feng; Xuesong Xie; Changzhi Lu; Guangdi Shen; Guangbo Gao; Xiaoling Zhang Sixteenth Annual IEEE Semiconductor Thermal Measurement and Management Symposium (Cat. No.00CH37068), 2000

In this paper, using voltage drop of forward junction as temperature sensitive parameter (TSP) for GaAs MESFET and semiconductor laser diode, we measured temperature rise ΔT under normal operation condition. Furthermore, we composite a testing sequence in which the duration of driving pulse from several microseconds to 100 seconds. This sequence is designed actually to simulate the procedure of heat ...


Thermalhydraulic optimization of hypervapotron geometries for first wall applications

D. L. Youchison; M. A. Ulrickson; J. H. Bullock 2011 IEEE/NPSS 24th Symposium on Fusion Engineering, 2011

Plasma disruptions and Edge Localized Modes (ELMS) may result in transient heat fluxes as high as 5 MW/m2 on portions of the ITER first wall (FW). To accommodate these heat loads, roughly 50% of the first wall will have Enhanced Heat Flux (EHF) panels equipped with water-cooled hypervapotron heat sinks. Recent advances in computational fluid dynamics (CFD) enable designers to ...


Transient heat transfer and recovery behavior of superconductors

C. Schmidt IEEE Transactions on Magnetics, 1981

Transient heat transfer from bare and coated copper surfaces to saturated liquid helium was measured with a time constant of ∼ 5 μsec. In another experiment recovery of a superconducting wire after a temperature excursion was studied. The results show a large difference between bare and coated surfaces, latter recover at higher surface heat fluxes. While the recovery time of ...


Computational fluid dynamics calibration for network modelling of transformer cooling oil flows - part I heat transfer in oil ducts

W. Wu; Z. D. Wang; A. Revell; H. Iacovides; P. Jarman IET Electric Power Applications, 2012

In the context of thermal performance and thermal lifetime, it is greatly important to predict the magnitude and location of the `hot-spot` temperature inside a transformer. Various calculation approaches have been developed in the attempt to accurately predict hot-spot, including so-called `network models`. In terms of the methodology used in network modelling, the complex pattern of oil ducts and passes ...


Infrared Face Recognition Based on Blood Perfusion Using Bio-Heat Transfer Model

Zhi-hua Xie; Shi-Qian Wu; Cui-Qun He; Zhi-Jun Fang; Jucheng Yang 2010 Chinese Conference on Pattern Recognition (CCPR), 2010

To get stable biological features from the time-elapse infrared face, a new construction method of blood perfusion is proposed based on bio-heat transfer, which can be applied to face recognition. Firstly, according to the classic bio-heat transfer equation (the Pennes Equation), the blood perfusion rate in different positions can be computed based on the new blood perfusion model (PBPM). Then, ...


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Educational Resources on Heat Transfer

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eLearning

The thermal characterization of packaged semiconductor device

Shiwei Feng; Xuesong Xie; Changzhi Lu; Guangdi Shen; Guangbo Gao; Xiaoling Zhang Sixteenth Annual IEEE Semiconductor Thermal Measurement and Management Symposium (Cat. No.00CH37068), 2000

In this paper, using voltage drop of forward junction as temperature sensitive parameter (TSP) for GaAs MESFET and semiconductor laser diode, we measured temperature rise ΔT under normal operation condition. Furthermore, we composite a testing sequence in which the duration of driving pulse from several microseconds to 100 seconds. This sequence is designed actually to simulate the procedure of heat ...


Thermalhydraulic optimization of hypervapotron geometries for first wall applications

D. L. Youchison; M. A. Ulrickson; J. H. Bullock 2011 IEEE/NPSS 24th Symposium on Fusion Engineering, 2011

Plasma disruptions and Edge Localized Modes (ELMS) may result in transient heat fluxes as high as 5 MW/m2 on portions of the ITER first wall (FW). To accommodate these heat loads, roughly 50% of the first wall will have Enhanced Heat Flux (EHF) panels equipped with water-cooled hypervapotron heat sinks. Recent advances in computational fluid dynamics (CFD) enable designers to ...


Transient heat transfer and recovery behavior of superconductors

C. Schmidt IEEE Transactions on Magnetics, 1981

Transient heat transfer from bare and coated copper surfaces to saturated liquid helium was measured with a time constant of ∼ 5 μsec. In another experiment recovery of a superconducting wire after a temperature excursion was studied. The results show a large difference between bare and coated surfaces, latter recover at higher surface heat fluxes. While the recovery time of ...


Computational fluid dynamics calibration for network modelling of transformer cooling oil flows - part I heat transfer in oil ducts

W. Wu; Z. D. Wang; A. Revell; H. Iacovides; P. Jarman IET Electric Power Applications, 2012

In the context of thermal performance and thermal lifetime, it is greatly important to predict the magnitude and location of the `hot-spot` temperature inside a transformer. Various calculation approaches have been developed in the attempt to accurately predict hot-spot, including so-called `network models`. In terms of the methodology used in network modelling, the complex pattern of oil ducts and passes ...


Infrared Face Recognition Based on Blood Perfusion Using Bio-Heat Transfer Model

Zhi-hua Xie; Shi-Qian Wu; Cui-Qun He; Zhi-Jun Fang; Jucheng Yang 2010 Chinese Conference on Pattern Recognition (CCPR), 2010

To get stable biological features from the time-elapse infrared face, a new construction method of blood perfusion is proposed based on bio-heat transfer, which can be applied to face recognition. Firstly, according to the classic bio-heat transfer equation (the Pennes Equation), the blood perfusion rate in different positions can be computed based on the new blood perfusion model (PBPM). Then, ...


More eLearning Resources

IEEE-USA E-Books

  • Heat Transfer by Forced Convection between a Tube and a Fluid

    This revised edition of Taylor's classic work on the internal-combustion engine incorporates changes and additions in engine design and control that have been brought on by the world petroleum crisis, the subsequent emphasis on fuel economy, and the legal restraints on air pollution.The fundamentals and the topical organization, however, remain the same. The analytic rather than merely descriptive treatment of actual engine cycles, the exhaustive studies of air capacity, heat flow, friction, and the effects of cylinder size, and the emphasis on application have been preserved. These are the basic qualities that have made Taylor's work indispensable to more than one generation of engineers and designers of internal-combustion engines, as well as to teachers and graduate students in the fields of power, internal-combustion engineering, and general machine design.Charles Fayette Taylor is Professor of Automotive Engineering Emeritus at MIT. He directed the Sloan Automotive Laborator es at MIT from 1926 to 1960

  • Convective heat transfer in blade cooling and heat-exchanger design

    This chapter contains sections titled: 10.1 Reynolds' analogy between fluid friction and heat transfer, 10.2 The Ntu method of heat-exchanger design, 10.3 Guidelines for choice of heat-exchanger passages, 10.4 Guidelines for heat- exchanger design, 10.5 Heat-exchanger design constraints for different configurations, 10.6 Regenerator design, 10.7 Turbine-blade cooling, 10.8 Heat transfer with mass transfer, 10.9 Internal-surface heat transfer, References, Problems

  • Thermal Considerations

    This chapter contains sections titled: Introduction Heat Transfer Fundamentals Air Cooling Liquid Cooling Advanced Cooling Methods Computer-Aided Modeling Summary This chapter contains sections titled: References Appendix: Thermophysical Properties for Heat Transfer Calculations Exercises

  • How to Prevent a Power Transistor from Overheating

    This chapter contains sections titled: Electrical Model for Heat Transfer Using Manufacturer's Data for Thermal Analysis Forced-Air Cooling Dynamic Response of a Thermal System Problems

  • Thermal Design and Management of Electronics

    This chapter contains sections titled: Introduction Heat Transfer Fundamentals Air Cooling Liquid Cooling Advanced Cooling Summary This chapter contains sections titled: Exercises References Appendix 5.A: Thermophysical Properties for Heat Transfer Calculations

  • Jets in Unbounded Space

    This chapter contains sections titled: Calculation of Submerged Jet of an Incompressible Fluid, Calculation of an Open-Jet Wind Tunnel, The Jet in a Stream of Relatively High Turbulence, Concerning the Configuration of a Jet in a Deflecting Flow, The Air Curtain, Vertical Submerged Turbulent Jet of Heated Gas, Trajectories of Warm and Cold Air Jets, The Two-Phase Jet in Air, Concerning the Discharge of a Gas into a Liquid, Turbulent Heat Transfer from Steam to a Water Jet, The Fan Jet

  • General Properties of Turbulent Jets

    This chapter contains sections titled: Fundamental Concepts, Submerged Jet, Velocity Profiles in a Submerged Jet, Spread of a Turbulent Submerged Jet, Lines of Constant Velocity in a Submerged Jet, Velocity Variation Along the Axis of a Submerged Jet, Heat Transfer in a Submerged Jet, Diffusion of Constituents in a Submerged Jet, Velocity, Temperature, and Concentration Profiles in a Turbulent Jet Spreading into an External Stream of Fluid, Spread of a Turbulent Jet into a Coflowing or Counterflowing External Stream, Turbulence Characteristics in a Free Jet

  • Thermosolar Power Plants

    This chapter contains sections titled: Introduction Water Heating by Solar Energy Heat Transfer Calculation of Thermally Isolated Reservoirs Heating Domestic Water Thermosolar Energy Economical Analysis of Thermosolar Energy References

  • Air Capacity of Four-Stroke Engines

    This chapter contains sections titled: Definitions, Volumetric Efficiency, Measurements of Volumetric Efficiency in Engines, Volumetric Efficiency, Power, and Mean Effective Pressure, Ideal Induction Process, Volumetric Efficiency from the Indicator Diagram, Effect of Heat Transfer on Volumetric Efficiency, Use of Dimensional Analysis in Volumetric Efficiency Problems, Effect of Operating Conditions on Volumetric Efficiency, Effect of Design on Volumetric Efficiency, Estimating Air Capacity, Illustrative Examples

  • No title

    Transport processes represent important life-sustaining elements in all humans. These include mass transfer processes, including gas exchange in the lungs, transport across capillaries and alveoli, transport across the kidneys, and transport across cell membranes. These mass transfer processes affect how oxygen and carbon dioxide are exchanged in your bloodstream, how metabolic waste products are removed from your blood, how nutrients are transported to tissues, and how all cells function throughout the body. A discussion of kidney dialysis and gas exchange mechanisms is included. Another element in biomedical transport processes is that of momentum transport and fluid flow. This describes how blood is propelled from the heart and throughout the cardiovascular system, how blood elements affect the body, including gas exchange, infection control, clotting of blood, and blood flow resistance, which affects cardiac work. A discussion of the measurement of the blood resistance to flow (vi cosity), blood flow, and pressure is also included. A third element in transport processes in the human body is that of heat transfer, including heat transfer inside the body towards the periphery as well as heat transfer from the body to the environment. A discussion of temperature measurements and body protection in extreme heat conditions is also included. Table of Contents: Biomedical Mass Transport / Biofluid Mechanics and Momentum Transport / Biomedical Heat Transport



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