MARC Record from marc_columbia

LEADER: 04289cam a2200445Mu 4500
001 13678458
005 20190216175009.0
006 m o d
007 cr |n|---|||||
008 180818s2016 enk o 000 0 eng d
019 $a1048935325
020 $a9781781831724
020 $a1781831726
020 $z9781781830178
020 $z1781830177
035 $a(OCoLC)on1048923886
035 $a(NNC)13678458
035 $a(OCoLC)1048923886$z(OCoLC)1048935325
040 $aEBLCP$beng$epn$cEBLCP$dYDX$dUAB$dSTF$dMERUC$dMERER$dIDB$dCEF$dERL$dOCLCQ$dLVT$dOCLCQ
066 $c(S
082 04 $a621.67$223
100 1 $aSrinivasan, K. M.
245 10 $aRotodynamic Pumps.
250 $a2nd ed.
260 $aLondon :$bNew Academic Science,$c2016.
300 $a1 online resource (590 pages)
336 $atext$btxt$2rdacontent
337 $acomputer$bc$2rdamedia
338 $aonline resource$bcr$2rdacarrier
588 0 $aPrint version record.
505 0 $6880-01$aCover; Preface to the Second Edition; Preface to the First Edition; Contents; Chapter 1: Introduction; 1.1 Principle and Classification of Pumps; Chapter 2: Pump Parameters; 2.1 Basic Parameters of Pump; 2.2 Pump Construction; 2.3 Losses in Pumps and Efficiency; 2.4 Suction Conditions; 2.5 Similarity Laws in Pumps; 2.6 Classification of Impeller Types According to Specific Speed (ns); 2.7 Pumping Liquids other than Water; Chapter 3: Theory of Rotodynamic Pumps; 3.1 Energy Equation using Moment of Momentum Equation for Fluid Flow through Impeller.
505 8 $a3.2 Bernoulli's Equation for the Flow through Impeller3.3 Absolute Flow of Ideal Fluid Past the Flow Passages of Pump; 3.4 Relative Flow of Ideal Fluid Past Impeller Blades; 3.5 Flow Over an Airfoil; 3.6 Two Dimensional Ideal Flow; 3.7 Axisymmetric Flow and Circulation in Impeller; 3.8 Real Fluid Flow After Impeller Blade Outlet Edge; 3.9 Secondary Flow between Blades; 3.10 Flow of a Profile in a Cascade System -- Theoretical Flow; 3.11 Fundamental Theory of Flow Over Isolated Profile; 3.12 Profile Construction as per N.E. Jowkovski and S.A. Chapligin.
505 8 $a3.13 Development of Thin Plate by Conformal Transformation3.14 Development of Profile with Thickness by Conformal Transformation; 3.15 Chapligin's Profile of Finite Thickness at Outlet Edge of the Profile; 3.16 Velocity Distribution in Space between Volute Casing and Impeller Shroud; 3.17 Pressure Distribution in the Space between Stationary Casing and Moving Impeller Shroud of Fluid Machine; Chapter 4: Theory and Calculation of Blade Systems in Centrifugal Pump; 4.1 Introduction; 4.2 One Dimensional Theory; 4.3 Velocity Triangles; 4.4 Impeller Eye and Blade Inlet Edge Conditions.
505 8 $a4.16 Determination of Outlet Dimensions of Impeller4.17 Development of Flow Passage in Meridional Plane; 4.18 Development of Single Curvature Blade-Radial Blades; 4.19 Development of Double Curvature Blade System; Chapter 5: Spiral Casings (Volute Casings); 5.1 Importance of Spiral Casings; 5.2 Volute Casing at the Outlet of the Impeller; 5.3 Method of Calculation for Spiral Casing; 5.4 Design of Spiral Casing with Cur= Constant and Trapezoidal Cross-section; 5.5 Calculation of Trapezoidal Volute Cross-section Under Constant Velocity of Flow Cv = Constant (Constant Velocity Design).
500 $a5.6 Calculation of Circular Volute Section with Cur= Constant.
655 4 $aElectronic books.
776 08 $iPrint version:$aSrinivasan, K.M.$tRotodynamic Pumps.$dLondon : New Academic Science, ©2016$z9781781830178
856 40 $uhttp://www.columbia.edu/cgi-bin/cul/resolve?clio13678458$zACADEMIC - Mechanics & Mechanical Engineering
880 8 $6505-01/(S$a4.5 Outlet Velocity Triangle : Effect Due to Blade Thickness4.6 Slip Factor as per Stodola and Meizel |109|; 4.7 Coefficient of Reaction (p); 4.8 Selection of Outlet Blade Angle (β2) and its Effect; 4.9 Effect of Number of Vanes; 4.10 Selection of Eye Diameter (D0), Eye Velocity (C0), Inlet Diameter of Impeller (D1) and Inlet Meridional Velocity (Cm1); 4.11 Selection of Outlet Diameter of Impeller (D2); 4.12 Effect of Blade Breadth (B2); 4.13 Impeller Design; 4.14 Determination of Shaft and Hub Diameters; 4.15 Determination of Inlet Dimensions for Impeller.
852 8 $blweb$hEBOOKS