001443695 000__ 04994cam\a2200553Ia\4500
001443695 001__ 1443695
001443695 003__ OCoLC
001443695 005__ 20230310003557.0
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001443695 007__ cr\un\nnnunnun
001443695 008__ 220113s2021\\\\sz\\\\\\ob\\\\001\0\eng\d
001443695 019__ $$a1292066702$$a1292144524$$a1292346624$$a1292353229$$a1292427939$$a1293249263$$a1294350280
001443695 020__ $$a9783030872816$$q(electronic bk.)
001443695 020__ $$a3030872815$$q(electronic bk.)
001443695 020__ $$z3030872807
001443695 020__ $$z9783030872809
001443695 0247_ $$a10.1007/978-3-030-87281-6$$2doi
001443695 035__ $$aSP(OCoLC)1292034235
001443695 040__ $$aYDX$$beng$$cYDX$$dGW5XE$$dDCT$$dEBLCP$$dOCLCF$$dOCLCO$$dOCLCQ$$dN$T
001443695 049__ $$aISEA
001443695 050_4 $$aTA357
001443695 08204 $$a620.1/064$$223
001443695 1001_ $$aGhajar, Afshin J.$$q(Afshin Jahanshahi),$$d1951-
001443695 24510 $$aSingle- and two-phase flow pressure drop and heat transfer in tubes /$$cAfshin J. Ghajar.
001443695 260__ $$aCham, Switzerland :$$bSpringer,$$c2021.
001443695 300__ $$a1 online resource
001443695 336__ $$atext$$btxt$$2rdacontent
001443695 337__ $$acomputer$$bc$$2rdamedia
001443695 338__ $$aonline resource$$bcr$$2rdacarrier
001443695 347__ $$atext file$$bPDF$$2rda
001443695 4901_ $$aMechanical engineering series
001443695 504__ $$aIncludes bibliographical references and index.
001443695 5050_ $$aIntroduction -- Single-Phase Flow Experimental Setup -- Friction Factor Results in Plain Tube -- Proposed Correlations for Friction Factor in Plain Tube -- Heat Transfer Results in Plain Tube -- Proposed Correlations for Heat Transfer in Plain Tube -- Simultaneous Heat Transfer and Friction Factor Analysis -- Friction Factor Results in Micro-fin Tubes -- Proposed Correlations for Friction Factor in Micro-fin Tubes -- Heat Transfer Results in Micro-fin Tubes -- Proposed Correlations for Heat Transfer in Micro-fin Tubes.
001443695 506__ $$aAccess limited to authorized users.
001443695 520__ $$aPart I of this book provides design engineers an elemental understanding of the variables that influence pressure drop and heat transfer in plain and micro-fin tubes to thermal systems using liquid single-phase flow in different industrial applications. The author and his colleagues were the first to determine experimentally the very important relationship between inlet geometry and transition. On the basis of their results, they developed practical and easy to use correlations for the isothermal and non-isothermal friction factor (pressure drop) and heat transfer coefficient (Nusselt number) in the transition region as well as the laminar and turbulent flow regions for different inlet configurations and fin geometry. The work presented in Part I of the book provides the thermal systems design engineer the necessary design tools. Part II of this book provides design engineers using gas-liquid two-phase flow in different industrial applications the necessary fundamental understanding of the two-phase flow variables. Two-phase flow literature reports a plethora of correlations for determination of flow patterns, void fraction, two- phase pressure drop and non-boiling heat transfer correlations. However, the validity of a majority of these correlations is restricted over a narrow range of two-phase flow conditions. Consequently, it is quite a challenging task for the end user to select an appropriate correlation/model for the type of two-phase flow under consideration. Selection of a correct correlation also requires some fundamental understanding of the two-phase flow physics and the underlying principles/assumptions/limitations associated with these correlations. Thus, it is of significant interest for a design engineer to have knowledge of the flow patterns and their transitions and their influence on two-phase flow variables. To address some of these issues and facilitate selection of appropriate two-phase flow models, Part II of this book presents a succinct review of the flow patterns, void fraction, pressure drop and non-boiling heat transfer phenomenon and recommend some of the well scrutinized modeling techniques. Reviews pressure drop, heat transfer coefficient, and inlet configuration effect in the transition region Includes void fraction correlations for flow patterns, pipe orientations, models for pressure drop calculations Presents non-boiling two-phase flow heat transfer correlations for different flow patterns and pipe orientations.
001443695 588__ $$aOnline resource; title from PDF title page (SpringerLink, viewed February 1, 2022).
001443695 650_0 $$aFluid dynamics.
001443695 650_0 $$aHeat$$xTransmission.
001443695 650_6 $$aDynamique des fluides.
001443695 650_6 $$aChaleur$$xTransmission.
001443695 655_0 $$aElectronic books.
001443695 77608 $$iPrint version:$$z3030872807$$z9783030872809$$w(OCoLC)1264139498
001443695 830_0 $$aMechanical engineering series (Berlin, Germany)
001443695 852__ $$bebk
001443695 85640 $$3Springer Nature$$uhttps://univsouthin.idm.oclc.org/login?url=https://link.springer.com/10.1007/978-3-030-87281-6$$zOnline Access$$91397441.1
001443695 909CO $$ooai:library.usi.edu:1443695$$pGLOBAL_SET
001443695 980__ $$aBIB
001443695 980__ $$aEBOOK
001443695 982__ $$aEbook
001443695 983__ $$aOnline
001443695 994__ $$a92$$bISE