Engineering Fluid Dynamics 2019-2020 Volume 2

This book contains the successful submissions to a Special Issue of Energies entitled "Engineering Fluid Dynamics 2019-2020". The topic of engineering fluid dynamics includes both experimental and computational studies. Of special interest were submissions from the fields of mechanical, ch...

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Bibliographic Details
Other Authors: Hjertager, Bjørn (Editor)
Format: Electronic Book Chapter
Language:English
Published: Basel, Switzerland MDPI - Multidisciplinary Digital Publishing Institute 2021
Subjects:
CFD
OH
PIV
Online Access:DOAB: download the publication
DOAB: description of the publication
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100 1 |a Hjertager, Bjørn  |4 edt 
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245 1 0 |a Engineering Fluid Dynamics 2019-2020  |b Volume 2 
260 |a Basel, Switzerland  |b MDPI - Multidisciplinary Digital Publishing Institute  |c 2021 
300 |a 1 electronic resource (202 p.) 
336 |a text  |b txt  |2 rdacontent 
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506 0 |a Open Access  |2 star  |f Unrestricted online access 
520 |a This book contains the successful submissions to a Special Issue of Energies entitled "Engineering Fluid Dynamics 2019-2020". The topic of engineering fluid dynamics includes both experimental and computational studies. Of special interest were submissions from the fields of mechanical, chemical, marine, safety, and energy engineering. We welcomed original research articles and review articles. After one-and-a-half years, 59 papers were submitted and 31 were accepted for publication. The average processing time was about 41 days. The authors had the following geographical distribution: China (15); Korea (7); Japan (3); Norway (2); Sweden (2); Vietnam (2); Australia (1); Denmark (1); Germany (1); Mexico (1); Poland (1); Saudi Arabia (1); USA (1); Serbia (1). Papers covered a wide range of topics including analysis of free-surface waves, bridge girders, gear boxes, hills, radiation heat transfer, spillways, turbulent flames, pipe flow, open channels, jets, combustion chambers, welding, sprinkler, slug flow, turbines, thermoelectric power generation, airfoils, bed formation, fires in tunnels, shell-and-tube heat exchangers, and pumps. 
540 |a Creative Commons  |f https://creativecommons.org/licenses/by/4.0/  |2 cc  |4 https://creativecommons.org/licenses/by/4.0/ 
546 |a English 
650 7 |a History of engineering & technology  |2 bicssc 
653 |a CFD 
653 |a gap resonance 
653 |a hydrodynamic forces 
653 |a free surface waves 
653 |a URANS 
653 |a twin-box deck 
653 |a aerodynamics 
653 |a vortex shedding 
653 |a splash lubrication 
653 |a dynamic motion 
653 |a gearbox 
653 |a churning power losses 
653 |a non-inertial coordinate system 
653 |a ground roughness 
653 |a hill shape 
653 |a hill slope 
653 |a large-eddy simulations 
653 |a turbulent flow fields 
653 |a turbulent structure 
653 |a computational fluid dynamics (CFD) 
653 |a large eddy simulations (LES) 
653 |a 3D hill 
653 |a canopy 
653 |a flow fields 
653 |a radiation 
653 |a blocked-off-region procedure 
653 |a heat recuperation 
653 |a anisotropic scattering 
653 |a mie particles 
653 |a numerical simulation 
653 |a horizontal face angle 
653 |a energy dissipation rates 
653 |a stepped spillway 
653 |a ultra-low specific speed magnetic drive pump 
653 |a orthogonal test 
653 |a splitter blades 
653 |a optimized design 
653 |a pressure fluctuation 
653 |a radial force 
653 |a dilution 
653 |a turbulent flame 
653 |a premixed 
653 |a OH 
653 |a CH2O 
653 |a planar laser-induced fluorescence 
653 |a self-excited oscillation jet 
653 |a organ-Helmholtz nozzle 
653 |a pulse waterjet 
653 |a pressure pulsation amplitude 
653 |a WMLES 
653 |a VLSMs 
653 |a LSMs 
653 |a turbulent boundary flow 
653 |a roughness 
653 |a surrogate model 
653 |a deep neural network 
653 |a multiphase flow 
653 |a horizontal pipe 
653 |a liquid holdup 
653 |a pressure gradient 
653 |a coherent structures 
653 |a turbulent boundary layer 
653 |a stability 
653 |a pre-multiplied wind velocity spectrum 
653 |a spatial correlation coefficient field 
653 |a tunnel fires 
653 |a jet fan speed 
653 |a heat release rate 
653 |a aspect ratio 
653 |a smoke movement 
653 |a visibility 
653 |a smoke layer thickness 
653 |a smoke stratification 
653 |a orifice shape 
653 |a vertical jet 
653 |a velocity ratio 
653 |a numerical investigation 
653 |a hydraulic characteristics 
653 |a impinging water jet 
653 |a impinging height 
653 |a numerical calculation 
653 |a swirler 
653 |a optimized 
653 |a genetic algorithms 
653 |a recirculation 
653 |a combustion 
653 |a experimental validation 
653 |a welding spatter 
653 |a distribution 
653 |a shield arc metal welding 
653 |a particle heat transfer 
653 |a fire risk 
653 |a sprinkler 
653 |a fire dynamics simulator (FDS) 
653 |a fire suppression 
653 |a extinguishing coefficient 
653 |a smoke logging 
653 |a smoke spread 
653 |a pipe insulation 
653 |a fire growth rate index 
653 |a scale factor 
653 |a volume fraction 
653 |a ignition heat source 
653 |a maximum heat release rate 
653 |a time to reach maximum HRR (heat release rate) 
653 |a control 
653 |a cylinder 
653 |a energy efficiency 
653 |a clamping 
653 |a pneumatics 
653 |a unsteady RANS simulation 
653 |a two-phase flow 
653 |a riser-induced slug flow 
653 |a LedaFlow 
653 |a VOF-model 
653 |a evacuation 
653 |a interaction between smoke and evacuees 
653 |a inner smoke force 
653 |a modified BR-smoke model 
653 |a twin H-rotor vertical-axis turbines 
653 |a wake 
653 |a instability 
653 |a wavelet transform 
653 |a computational fluid dynamics (CFD), multiphysics 
653 |a heat transfer 
653 |a thermoelectricity 
653 |a automotive 
653 |a traditional market 
653 |a fire spread rate 
653 |a radiant heat flux 
653 |a separation distance 
653 |a rotor stator interaction 
653 |a boundary layer 
653 |a secondary vortex 
653 |a unsteady flow 
653 |a submerged jet 
653 |a climate change 
653 |a renewable energy 
653 |a wind power 
653 |a accelerators 
653 |a turbines 
653 |a power extraction 
653 |a Betz 
653 |a freestream theory 
653 |a hybrid simulation method 
653 |a multi-fluid model 
653 |a discrete element method, sedimentation, bed formation 
653 |a PIV 
653 |a shell-and-tube 
653 |a shell side 
653 |a tube bundle 
653 |a heat exchanger 
653 |a baffle 
653 |a maldistribution 
856 4 0 |a www.oapen.org  |u https://mdpi.com/books/pdfview/book/3425  |7 0  |z DOAB: download the publication 
856 4 0 |a www.oapen.org  |u https://directory.doabooks.org/handle/20.500.12854/68409  |7 0  |z DOAB: description of the publication