Influence of Complex Fluid Flow on Temperature Distribution in the Rotor Region of Large Hydrogenerator under the Rotor Rotation

A three-dimensional (3D) numerical model is developed by using control volume method to analyze the effects of the electron beam scanning speed on the temperature distribution and fluid flow of the liquid phase in the electron beam melting® (EBM) of Ti-6Al-4V powder. The numerical calculations are performed by Fluent codes, in which thermal analyses with and without considering fluid flow in the molten pool are compared. A series of experiments are performed with an Electron Beam Melting® machine to verify the numerical accuracy. Compared to thermal analysis without considering convection in the molten pool, a closer numerical prediction of geometrical size of molten pool to the experimental data can be achieved by using thermal and fluid flow modeling. The difference between the melt pool geometry in the two models is due to the consideration of the effects of the outward flow in the fluid flow model caused by surface tension.

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Fluid Flow and Temperature Distribution Around a Surface-Mounted Module Cooled by Forced Air Flow in a Portable Personal Computers

Transactions of the Korean Society of Mechanical Engineers B ◽

10.3795/ksme-b.2004.28.2.238 ◽

2004 ◽

Vol 28 (2) ◽

pp. 238-246

Keyword(s):

Fluid Flow ◽

Temperature Distribution ◽

Air Flow ◽

Personal Computers ◽

Forced Air

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Algorithm Scheme to Simulate the Distortions during Gas Quenching in a Single-Piece Flow Technology

Coatings ◽

10.3390/coatings10070694 ◽

2020 ◽

Vol 10 (7) ◽

pp. 694 ◽

Cited By ~ 1

Author(s):

Jacek Sawicki ◽

Krzysztof Krupanek ◽

Wojciech Stachurski ◽

Victoria Buzalski

Keyword(s):

Heat Transfer ◽

Experimental Data ◽

High Pressure ◽

Heat Transfer Coefficient ◽

Fluid Flow ◽

Transfer Coefficient ◽

Single Piece ◽

Gas Quenching ◽

Complex Fluid ◽

Algorithm Scheme

Low-pressure carburizing followed by high-pressure quenching in single-piece flow technology has shown good results in avoiding distortions. For better control of specimen quality in these processes, developing numerical simulations can be beneficial. However, there is no commercial software able to simulate distortion formation during gas quenching that considers the complex fluid flow field and heat transfer coefficient as a function of space and time. For this reason, this paper proposes an algorithm scheme that aims for more refined results. Based on the physical phenomena involved, a numerical scheme was divided into five modules: diffusion module, fluid module, thermal module, phase transformation module, and mechanical module. In order to validate the simulation, the results were compared with the experimental data. The outcomes showed that the average difference between the numerical and experimental data for distortions was 1.7% for the outer diameter and 12% for the inner diameter of the steel element. Numerical simulation also showed the differences between deformations in the inner and outer diameters as they appear in the experimental data. Therefore, a numerical model capable of simulating distortions in the steel elements during high-pressure gas quenching after low-pressure carburizing using a single-piece flow technology was obtained, whereupon the complex fluid flow and variation of the heat transfer coefficient was considered.

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The fluid mechanics of poohsticks

Philosophical Transactions of The Royal Society A Mathematical Physical and Engineering Sciences ◽

10.1098/rsta.2019.0522 ◽

2020 ◽

Vol 378 (2179) ◽

pp. 20190522 ◽

Cited By ~ 1

Author(s):

Julyan H. E. Cartwright ◽

Oreste Piro

Keyword(s):

Fluid Flow ◽

Fluid Mechanics ◽

Solid Body ◽

State Of The Art ◽

The State ◽

Theme Issue ◽

Two Fluids ◽

Stokes Drag ◽

Complex Fluid

The year 2019 marked the bicentenary of George Gabriel Stokes, who in 1851 described the drag—Stokes drag—on a body moving immersed in a fluid, and 2020 is the centenary of Christopher Robin Milne, for whom the game of poohsticks was invented; his father A. A. Milne’s The House at Pooh Corner , in which it was first described in print, appeared in 1928. So this is an apt moment to review the state of the art of the fluid mechanics of a solid body in a complex fluid flow, and one floating at the interface between two fluids in motion. Poohsticks pertains to the latter category, when the two fluids are water and air. This article is part of the theme issue ‘Stokes at 200 (part 2)’.

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Accurate cars measurement and fluid-flow modelling of the temperature distribution around a linear incandescent filament

Chemical Physics Letters ◽

10.1016/0009-2614(86)80195-6 ◽

1986 ◽

Vol 129 (2) ◽

pp. 191-196 ◽

Cited By ~ 7

Author(s):

R. Devonshire ◽

I.S. Bring ◽

G. Hoey ◽

F.M. Porter ◽

D.R. Williams ◽

...

Keyword(s):

Fluid Flow ◽

Temperature Distribution ◽

Flow Modelling

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The Application of a Unique Flow Modeling Technique to Complex Combustion Systems

Volume 3: Coal, Biomass and Alternative Fuels; Combustion and Fuels; Oil and Gas Applications; Cycle Innovations ◽

10.1115/86-gt-264 ◽

1986 ◽

Author(s):

J. Waslo ◽

T. Hasegawa ◽

M. B. Hilt

Keyword(s):

Image Processing ◽

Fluid Flow ◽

Light Scattering ◽

Three Dimensional ◽

Modeling Technique ◽

Flow Modeling ◽

Visualization Technique ◽

Gas Turbine Combustor ◽

Complex Fluid ◽

Additional Image

This paper describes the application of a unique three-dimensional water flow modeling technique to the study of complex fluid flow patterns within an advanced gas turbine combustor. The visualization technique uses light scattering, coupled with realtime image processing, to determine flow fields. Additional image processing is used to make concentration measurements within the combustor.

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Temperature Distribution in a Turbulent Flow in the Heat Pollution Phenomena

ASME 2020 Heat Transfer Summer Conference ◽

10.1115/ht2020-8969 ◽

2020 ◽

Author(s):

Victorita Radulescu

Keyword(s):

Mathematical Model ◽

Mass Transfer ◽

Fluid Flow ◽

Temperature Distribution ◽

Prandtl Number ◽

Experimental Results ◽

Turbulent Heat ◽

Fluid Viscosity ◽

Solid Walls ◽

Good Agreement

Abstract The thermal pollution, with major effects on the water quality degradation by any process involving the temperature transfer, represents nowadays a major concern for the entire scientific world. The turbulent heat and the mass transfer have an essential role in the processes of thermal pollution, mainly in problems associated with the transport of hot fluids in long heating pipes, thermal flows associated with big thermo-electric power plants, etc. In the last decades, the problems of the turbulent heat and mass transfer were analyzed for different dedicated applications. The present paper, in the first part, estimates the universal law of the velocity distribution near a solid wall, with a specific interpretation of the fluid viscosity, valid for all types of flows. Most of the scientific researches associate nowadays both the turbulent heat and the mass transfer with the Prandtl number. In the turbulent fluid flow near a solid and rigid surface, there are three flowing domains, laminar, transient, and fully turbulent, each one with its characteristics. In this paper, it is assumed that the friction effort at the wall remains valid at any distance from the wall, but with different forms associated with the dynamic viscosity. By using the superposition of the molecular and turbulent viscosity and by creating the interdependence between the molecular and turbulent transfer coefficients is estimated the mathematical model of the velocity profile for the fluid flow and temperature distribution. Three supplementary hypotheses have been assumed to estimate the dependence between the laminar and thermal sub-layer and the hydrodynamic sub-layer. The theoretical obtained distribution was compared with some experimental results from the literature and it was observed there is a good agreement between them; the differences are smaller than 3%. In the second part of the paper is determined the temperature field for a fluid flowing also in presence of the solid surfaces with different temperatures, associated not only with the Prandtl number but also with the fluid viscosity and its dependence with the temperature, correlated with the Grashoff number. In the next paragraph is used the concept of the laminar substrate with different thicknesses for the hydrodynamic flows with thermal transfer to the solid walls, and also the inverse transfer from the solid walls affecting the fluid flow and the mass transfer. The obtained mathematical model is correlated with the semi-empirical data from the literature. By numerical modeling, the obtained results were compared with the experimental measurements and it was determined the dependence between the Stanton number and the Prandtl number. The numerical results demonstrate a good agreement with the experimental results in a wide range of the Prandtl numbers from 0.5 to 3000. Finally, are mentioned some conclusions and references.

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Heat transfer modeling within the microclimate between 3D human body and clothing: effects of ventilation openings and fire intensity

International Journal of Clothing Science and Technology ◽

10.1108/ijcst-12-2019-0191 ◽

2020 ◽

Vol ahead-of-print (ahead-of-print) ◽

Author(s):

Miao Tian ◽

Jun Li

Keyword(s):

Heat Transfer ◽

Fluid Flow ◽

Temperature Distribution ◽

Convective Heat Transfer ◽

Convective Heat ◽

Human Body ◽

Thermal Environment ◽

Heat Transfer Process ◽

Fire Intensity ◽

Content Type

PurposeThe purpose of this study is to determine the effect of ventilation openings and fire intensity on heat transfer and fluid flow within the microclimate between 3D human body and clothing.Design/methodology/approachOn account of interaction effects of fire and ventilation openings on heat transfer process, a 3D transient computational fluid dynamics model considering the real shape of human body and clothing was developed. The model was validated by comparing heat flux history and distribution with experimental results. Heat transfer modes and fluid flow were investigated under three levels of fire intensity for the microclimate with ventilation openings and closures.FindingsTemperature distribution on skin surface with open microclimate was heavily depended on the heat transfer through ventilation openings. Higher temperature for the clothing with confined microclimate was affected by the position and direction of flames injection. The presence of openings contributed to the greater velocity at forearms, shanks and around neck, which enhanced the convective heat transfer within microclimate. Thermal radiation was the dominant heat transfer mode within the microclimate for garment with closures. On the contrary, convective heat transfer within microclimate for clothing with openings cannot be neglected.Practical implicationsThe findings provided fundamental supports for the ease and pattern design of the improved thermal protective systems, so as to realize the optimal thermal insulation of the microclimate on the garment level in the future.Originality/valueThe outcomes broaden the insights of results obtained from the mesoscale models. Different high skin temperature distribution and heat transfer modes caused by thermal environment and clothing structure provide basis for advanced thermal protective clothing design.

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