| 000 | 06107naaaa2201777uu 4500 | ||
|---|---|---|---|
| 001 | https://directory.doabooks.org/handle/20.500.12854/59163 | ||
| 005 | 20220714175408.0 | ||
| 020 | _abooks978-3-03921-428-0 | ||
| 020 | _a9783039214280 | ||
| 020 | _a9783039214273 | ||
| 024 | 7 |
_a10.3390/books978-3-03921-428-0 _cdoi |
|
| 041 | 0 | _aEnglish | |
| 042 | _adc | ||
| 100 | 1 |
_aJaworski, Artur J. _4auth _91594079 |
|
| 245 | 1 | 0 | _aSelected Problems in Fluid Flow and Heat Transfer |
| 260 |
_bMDPI - Multidisciplinary Digital Publishing Institute _c2019 |
||
| 300 | _a1 electronic resource (460 p.) | ||
| 506 | 0 |
_aOpen Access _2star _fUnrestricted online access |
|
| 520 | _aFluid flow and heat transfer processes play an important role in many areas of science and engineering, from the planetary scale (e.g., influencing weather and climate) to the microscopic scales of enhancing heat transfer by the use of nanofluids; understood in the broadest possible sense, they also underpin the performance of many energy systems. This topical Special Issue of Energies is dedicated to the recent advances in this very broad field. This book will be of interest to readers not only in the fields of mechanical, aerospace, chemical, process and petroleum, energy, earth, civil ,and flow instrumentation engineering but, equally, biological and medical sciences, as well as physics and mathematics; that is, anywhere that "fluid flow and heat transfer" phenomena may play an important role or be a subject of worthy research pursuits. | ||
| 540 |
_aCreative Commons _fhttps://creativecommons.org/licenses/by-nc-nd/4.0/ _2cc _4https://creativecommons.org/licenses/by-nc-nd/4.0/ |
||
| 546 | _aEnglish | ||
| 653 | _an/a | ||
| 653 | _athermal performance | ||
| 653 | _amicrobubble pump | ||
| 653 | _aparticle deposition | ||
| 653 | _aflow oscillation | ||
| 653 | _aorthogonal jet | ||
| 653 | _aflat plate | ||
| 653 | _agas turbine engine | ||
| 653 | _aair heater | ||
| 653 | _aflow behavior | ||
| 653 | _atransonic compressor | ||
| 653 | _afriction factor | ||
| 653 | _anonlinear thermal radiation | ||
| 653 | _aoscillators | ||
| 653 | _aporous cavity | ||
| 653 | _aPOD | ||
| 653 | _aturbulent flow | ||
| 653 | _athermosyphon | ||
| 653 | _aturbulence | ||
| 653 | _amass transfer | ||
| 653 | _atip leakage flow | ||
| 653 | _acapture efficiency | ||
| 653 | _apipe flow | ||
| 653 | _acorrelation | ||
| 653 | _adecomposition dimensionalities | ||
| 653 | _aheat transfer | ||
| 653 | _apressure loss | ||
| 653 | _aCANDU-6 | ||
| 653 | _anumerical modeling | ||
| 653 | _aCFD | ||
| 653 | _amagnetic field | ||
| 653 | _aboundary layer | ||
| 653 | _atwo-phase flow | ||
| 653 | _aheat transfer performance | ||
| 653 | _aColebrook-White | ||
| 653 | _acomputational burden | ||
| 653 | _aphase change | ||
| 653 | _asurrogate model | ||
| 653 | _aPadé polynomials | ||
| 653 | _atraveling-wave heat engine | ||
| 653 | _aflow regime | ||
| 653 | _anumerical simulation | ||
| 653 | _aenergetics | ||
| 653 | _a( A g ? F e 3 O 4 / H 2 O ) hybrid nanofluid | ||
| 653 | _apumps | ||
| 653 | _aBEM | ||
| 653 | _aSPIV | ||
| 653 | _aacoustic streaming | ||
| 653 | _amicrobubbles | ||
| 653 | _aAspen® | ||
| 653 | _apush-pull | ||
| 653 | _aPositive Temperature Coefficient (PTC) elements | ||
| 653 | _aiterative procedure | ||
| 653 | _atransient analysis | ||
| 653 | _aspiral fin-tube | ||
| 653 | _atoxic gases | ||
| 653 | _aunsteady heat release rate | ||
| 653 | _awater hammer | ||
| 653 | _amethod of moment | ||
| 653 | _avisualization | ||
| 653 | _asuperheated steam | ||
| 653 | _aimpingement heat transfer enhancement | ||
| 653 | _aX-ray microtomography | ||
| 653 | _amoderator | ||
| 653 | _awind turbine | ||
| 653 | _aflow rate | ||
| 653 | _afin-tube | ||
| 653 | _aflue gas | ||
| 653 | _aactuator disc | ||
| 653 | _atemperature distributions | ||
| 653 | _asupercritical LNG | ||
| 653 | _asharp sections | ||
| 653 | _amoment of inertia | ||
| 653 | _aColebrook equation | ||
| 653 | _apump efficiency | ||
| 653 | _atower | ||
| 653 | _aOpenFOAM | ||
| 653 | _acomputational fluid dynamics | ||
| 653 | _achemical reaction | ||
| 653 | _apump performance | ||
| 653 | _alogarithms | ||
| 653 | _anumerical results | ||
| 653 | _adownwind | ||
| 653 | _athermodynamic | ||
| 653 | _atriaxial stress | ||
| 653 | _aflow friction | ||
| 653 | _aenergy conversion | ||
| 653 | _aentropy generation | ||
| 653 | _azigzag type | ||
| 653 | _ainertance-compliance | ||
| 653 | _asection aspect ratios | ||
| 653 | _alaminar separation bubble | ||
| 653 | _aaxial piston pumps | ||
| 653 | _athermogravimetry | ||
| 653 | _apressure drop | ||
| 653 | _aload resistances | ||
| 653 | _avortex breakdown | ||
| 653 | _aT-section prism | ||
| 653 | _aflow-induced motion | ||
| 653 | _acentrifugal pump | ||
| 653 | _aload | ||
| 653 | _avortex identification | ||
| 653 | _adecomposition region | ||
| 653 | _acondensation | ||
| 653 | _aperformance characteristics | ||
| 653 | _apipes | ||
| 653 | _adetached-eddy simulation | ||
| 653 | _aComputational Fluid Dynamics (CFD) simulation | ||
| 653 | _athermal cracking | ||
| 653 | _areal vehicle experiments | ||
| 653 | _abubble size | ||
| 653 | _athermal energy recovery | ||
| 653 | _ahydraulic resistances | ||
| 653 | _aconcentration | ||
| 653 | _atower shadow | ||
| 653 | _afire-spreading characteristics | ||
| 653 | _athermoacoustic electricity generator | ||
| 653 | _abubble generation | ||
| 653 | _amulti-stage | ||
| 653 | _athermal effect | ||
| 653 | _aferrofluid | ||
| 653 | _aPHWR | ||
| 653 | _afluidics | ||
| 653 | _amultiphase flow | ||
| 653 | _aprinted circuit heat exchanger | ||
| 653 | _aparticle counter | ||
| 653 | _adew point temperature | ||
| 856 | 4 | 0 |
_awww.oapen.org _uhttps://mdpi.com/books/pdfview/book/1559 _70 _zDOAB: download the publication |
| 856 | 4 | 0 |
_awww.oapen.org _uhttps://directory.doabooks.org/handle/20.500.12854/59163 _70 _zDOAB: description of the publication |
| 999 |
_c2997532 _d2997532 |
||