Modeling with Differential Equations in Chemical Engineering'Modelling with Differential Equations in Chemical Engineering' covers the modelling of rate processes of engineering in terms of differential equations. While it includes the purely mathematical aspects of the solution of differential equations, the main emphasis is on the derivation and solution of major equations of engineering and applied science. Methods of solving differential equations by analytical and numerical means are presented in detail with many solved examples, and problems for solution by the reader. Emphasis is placed on numerical and computer methods of solution. A key chapter in the book is devoted to the principles of mathematical modelling. These principles are applied to the equations in important engineering areas. The major disciplines covered are thermodynamics, diffusion and mass transfer, heat transfer, fluid dynamics, chemical reactions, and automatic control. These topics are of particular value to chemical engineers, but also are of interest to mechanical, civil, and environmental engineers, as well as applied scientists. The material is also suitable for undergraduate and beginning graduate students, as well as for review by practising engineers. |
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Page 341
... lines connecting the two streamlines , for instance , lines ac or bd . This is true also of flows across the differential lines , dx and dy , connecting the differentially separated streamlines of Figure 13.2 . This fact leads to ...
... lines connecting the two streamlines , for instance , lines ac or bd . This is true also of flows across the differential lines , dx and dy , connecting the differentially separated streamlines of Figure 13.2 . This fact leads to ...
Page 367
... lines , such as gas transmission lines , is essentially isothermal . Moreover , isothermal flow may be an adequate approximation for many process lines in a plant . In insulated lines , the flow naturally is essentially adiabatic . A ...
... lines , such as gas transmission lines , is essentially isothermal . Moreover , isothermal flow may be an adequate approximation for many process lines in a plant . In insulated lines , the flow naturally is essentially adiabatic . A ...
Page 448
... Line integral 221-222 Lines , method of , 192 , see also Method of lines LMTD , 314 Lorentz equation , 182 , 206 P7.12 Lumping approximation , 210 , 417 multipass heat exchanger , 418-419 Mach number , 366 Mapping , complex variable ...
... Line integral 221-222 Lines , method of , 192 , see also Method of lines LMTD , 314 Lorentz equation , 182 , 206 P7.12 Lumping approximation , 210 , 417 multipass heat exchanger , 418-419 Mach number , 366 Mapping , complex variable ...
Common terms and phrases
a₁ a²u applied arctan auxiliary conditions ax² ay² b₁ becomes Bessel equation Bessel functions boundary conditions C₁ C₂ chemical coefficients convergence coordinates curve d²y derivative diffusion diskette dx dy dx/dt dx² dy/dx eigenvalues equa Example Figure finite first-order flow fluid formulas Gaussian elimination heat equation heat transfer homogeneous independent variables initial conditions input integral equation inverse k₁ Laplace equation Laplace transform linear differential equations linear equations mathematical method nodes nonhomogeneous nonlinear numerical ODEs orthogonal parameters Partial Differential Equations phase plane plane polynomials problem reaction reactor region result roots second-order separation of variables sinh solution solved substitution T₁ Table temperature tion u₁ V₁ values vector velocity x₁ x²y y₁ zero ди др ду дх