J. D. Seader

Bio: J. D. Seader is an academic researcher from University of Utah. The author has contributed to research in topics: Process design & Homotopy. The author has an hindex of 31, co-authored 78 publications receiving 4848 citations. Previous affiliations of J. D. Seader include North American Aviation.

Separation Process Principles

Abstract: About the Authors. Preface to the Second Edition. Nomenclature. Dimensions and Units. PART ONE: FUNDAMENTAL CONCEPTS. Chapter 1. Separation Processes. Chapter 2. Thermodynamics of Separation Operations. Chapter 3. Mass Transfer and Diffusion. Chapter 4. Single Equilibrium Stages and Flash Calculations. Chapter 5. Cascades and Hybrid Systems. PART TWO: SEPARATIONS BY PHASE ADDITION OR CREATION. Chapter 6. Absorption and Stripping of Dilute Mixtures. Chapter 7. Distillation of Binary Mixtures. Chapter 8. Liquid-Liquid Extraction with Ternary Systems. Chapter 9. Approximate Methods for Multicomponent, Multistage Separations. Chapter 10. Equilibrium-Based Methods for Multicomponent Absorption, Stripping, Distillation, and Extraction. Chapter 11. Enhanced Distillation and Supercritical Extraction. Chapter 12. Rate-Based Models for Distillation. Chapter 13. Batch Distillation. PART THREE: SEPARATIONS BY BARRIERS AND SOLID AGENTS. Chapter 14. Membrane Separations. Chapter 15. Adsorption, Ion Exchange, and Chromatography. PART FOUR: SEPARATIONS THAT INVOLVE A SOLID PHASE. Chapter 16. Leaching and Washing. Chapter 17. Crystallization, Desublimation, and Evaporation. Chapter 18. Drying of Solids. Index.

Product and Process Design Principles: Synthesis, Analysis and Evaluation

Abstract: 1. Introduction to Chemical Product Design 1S Supplement to Chapter 1 2. Product-Development Process PART 1 BASIC CHEMICALS PRODUCT DESIGN 3. Materials Technology for Basic Chemicals: Molecular-Structure Design 3S Supplement to Chapter 3 4. Process Creation for Basic Chemicals 5. Simulation to Assist in Process Creation 6. Heuristics for Process Synthesis 7. Reactor Design and Synthesis of Networks Containing Reactors 7S Supplement to Chapter 7 8. Synthesis of Separation Trains 9. Heat and Power Integration 9S Suppliment to Chapter 9 Second Law Analysis 10. Mass Integration 11. Optimal Design and Scheduling of Batch Processes 12. Plantwide Controllability Assessment 12S Supplement to Chapter 12 Flowsheet Controllability Analysis 13. Basic Chemicals Product Design Case Studies PART 2 INDUSTRIAL CHEMICALS PRODUCT DESIGN 14. Materials and Process/Manufacturing Technologies for Industrial Chemical Products 15. Industrial Chemicals Product Design Case Studies PART 3 CONFIGURED CONSUMER PRODUCT DESIGN 16. Materials, Process/Manufacturing, and Product Technologies for Con"?gured Consumer Products 16S Supplement to Chapter 16 17. Con"?gured Consumer Product Design Case Studies PART 4 DETAILED DESIGN, EQUIPMENT SIZING, OPTIMIZATION, AND PRODUCT-QUALITY ANALYSIS 18. Heat Exchanger Design 19. Separation Tower Design 20. Pumps, Compressors, and Expanders 21. Polymer Compounding 22. Cost Accounting and Capital Cost Estimation 22S Supplement to Chapter 22 23. Annual Costs, Earnings, and Pro"?tability Analysis 23S Supplement to Chapter 23 24. Design Optimization 25. Six-Sigma Design Strategies PART 5 DESIGN REPORT 26. Written Reports and Oral Presentations APPENDIXES INDICES

Equilibrium-Stage Separation Operations in Chemical Engineering

Abstract: Separation Processes. Equipment for Multiphase Contracting. Thermodynamic Equilibrium Diagrams. Phase Equilibria from Equations of State. Equilibrium Properties from Activity Coefficient Correlations. Specification of Design Variables. Equilibrium Flash Vaporization and Partial Condensation. Graphical Multistage Calculations by the McCabe-Thiele Method. Batch Distillation. Graphical Multistage Calculations by the Ponchon-Savarit Method. Extraction Calculations by Triangular Diagrams. Approximate Methods for Multicomponent, Multistage Separations. Stage Capacity and Efficiency. Synthesis of Separation Sequences. Rigorous Methods for Multicomponent, Multistage Separations. Continuous Differential Contacting Operations: Gas Absorption. Energy Conservation and Thermodynamic Efficiency. Appendixes. Index.

Separation process principles : chemical and biochemical operations

Abstract: About the Authors. Preface to the Third Edition. Nomenclature. Dimensions and Units. PART 1 FUNDAMENTAL CONCEPTS. 1. Separation Processes. 1.0 Instructional Objectives. 1.1 Industrial Chemical Processes. 1.2 Basic Separation Techniques. 1.3 Separations by Phase Addition or Creation. 1.4 Separations by Barriers. 1.5 Separations by Solid Agents. 1.6 Separations by External Field or Gradient. 1.7 Component Recoveries and Product Purities. 1.8 Separation Factor. 1.9 Introduction to Bioseparations. 1.10 Selection of Feasible Separations. Summary References Study Questions Exercises. 2. Thermodynamics of Separation Operations. 2.0 Instructional Objectives. 2.1 Energy, Entropy, and Availability Balances. 2.2 Phase Equilibria. 2.3 Ideal-Gas, Ideal-Liquid-Solution Model. 2.4 Graphical Correlations of Thermodynamic Properties. 2.5 Nonideal Thermodynamic Property Models. 2.6 Liquid Activity-Coefficient Models. 2.7 Difficult Mixtures. 2.8 Selecting an Appropriate Model. 2.9 Thermodynamic Activity of Biological Species. Summary References Study Questions Exercises. 3. Mass Transfer and Diffusion. 3.0 Instructional Objectives. 3.1 Steady-State, Ordinary Molecular Diffusion. 3.2 Diffusion Coefficients (Diffusivities). 3.3 Steady- and Unsteady-State Mass Transfer Through Stationary Media. 3.4 Mass Transfer in Laminar Flow. 3.5 Mass Transfer in Turbulent Flow. 3.6 Models for Mass Transfer in Fluids with a Fluid Fluid Interface. 3.7 Two-Film Theory and Overall Mass-Transfer Coefficients. 3.8 Molecular Mass Transfer in Terms of Other Driving Forces. Summary References Study Questions Exercises. 4. Single Equilibrium Stages and Flash Calculations. 4.0 Instructional Objectives. 4.1 Gibbs Phase Rule and Degrees of Freedom. 4.2 Binary Vapor Liquid Systems. 4.3 Binary Azeotropic Systems. 4.4 Multicomponent Flash, Bubble-Point, and Dew-Point Calculations. 4.5 Ternary Liquid Liquid Systems. 4.6 Multicomponent Liquid Liquid Systems. 4.7 Solid Liquid Systems. 4.8 Gas Liquid Systems. 4.9 Gas Solid Systems. 4.10 Multiphase Systems. Summary References Study Questions Exercises. 5. Cascades and Hybrid Systems. 5.0 Instructional Objectives. 5.1 Cascade Configurations. 5.2 Solid Liquid Cascades. 5.3 Single-Section Extraction Cascades. 5.4 Multicomponent Vapor Liquid Cascades. 5.5 Membrane Cascades. 5.6 Hybrid Systems. 5.7 Degrees of Freedom and Specifications for Cascades. Summary References Study Questions Exercises. PART 2 SEPARATIONS BY PHASE ADDITION OR CREATION. 6. Absorption and Stripping of Dilute Mixtures. 6.0 Instructional Objectives. 6.1 Equipment for Vapor Liquid Separations. 6.2 General Design Considerations. 6.3 Graphical Method for Trayed Towers. 6.4 Algebraic Method for Determining N. 6.5 Stage Efficiency and Column Height for Trayed Columns. 6.6 Flooding, Column Diameter, Pressure Drop, and Mass Transfer for Trayed Columns. 6.7 Rate-Based Method for Packed Columns. 6.8 Packed-Column Liquid Holdup, Diameter, Flooding, Pressure Drop, and Mass-Transfer Efficiency. 6.9 Concentrated Solutions in Packed Columns. Summary References Study Questions Exercises. 7. Distillation of Binary Mixtures. 7.0 Instructional Objectives. 7.1 Equipment and Design Considerations. 7.2 McCabe Thiele Graphical Method for Trayed Towers. 7.3 Extensions of the McCabe Thiele Method. 7.4 Estimation of Stage Efficiency for Distillation. 7.5 Column and Reflux-Drum Diameters. 7.6 Rate-Based Method for Packed Distillation Columns. 7.7 Introduction to the Ponchon Savarit Graphical Equilibrium-Stage Method for Trayed Towers. Summary References Study Questions Exercises. 8. Liquid Liquid Extraction with Ternary Systems. 8.0 Instructional Objectives. 8.1 Equipment for Solvent Extraction. 8.2 General Design Considerations. 8.3 Hunter Nash Graphical Equilibrium-Stage Method. 8.4 Maloney Schubert Graphical Equilibrium-Stage Method. 8.5 Theory and Scale-up of Extractor Performance. 8.6 Extraction of Bioproducts. Summary References Study Questions Exercises. 9. Approximate Methods for Multicomponent, Multistage Separations. 9.0 Instructional Objectives. 9.1 Fenske Underwood Gilliland (FUG) Method. 9.2 Kremser Group Method. Summary References Study Questions Exercises. 10. Equilibrium-Based Methods for Multicomponent Absorption, Stripping, Distillation, and Extraction. 10.0 Instructional Objectives. 10.1 Theoretical Model for an Equilibrium Stage. 10.2 Strategy of Mathematical Solution. 10.3 Equation-Tearing Procedures. 10.4 Newton Raphson (NR) Method. 10.5 Inside-Out Method. Summary References Study Questions Exercises. 11. Enhanced Distillation and Supercritical Extraction. 11.0 Instructional Objectives. 11.1 Use of Triangular Graphs. 11.2 Extractive Distillation. 11.3 Salt Distillation. 11.4 Pressure-Swing Distillation. 11.5 Homogeneous Azeotropic Distillation. 11.6 Heterogeneous Azeotropic Distillation. 11.7 Reactive Distillation. 11.8 Supercritical-Fluid Extraction. Summary References Study Questions Exercises. 12. Rate-Based Models for Vapor-Liquid Separation Operations. 12.0 Instructional Objectives. 12.1 Rate-Based Model. 12.2 Thermodynamic Properties and Transport-Rate Expressions. 12.3 Methods for Estimating Transport Coefficients and Interfacial Area. 12.4 Vapor and Liquid Flow Patterns. 12.5 Method of Calculation. Summary References Study Questions Exercises. 13. Batch Distillation. 13.0 Instructional Objectives. 13.1 Differential Distillation. 13.2 Binary Batch Rectification. 13.3 Batch Stripping and Complex Batch Distillation. 13.4 Effect of Liquid Holdup. 13.5 Shortcut Method for Batch Rectification. 13.6 Stage-by-Stage Methods for Batch Rectification. 13.7 Intermediate-cut Strategy. 13.8 Optimal Control by Variation of Reflux Ratio. Summary References Study Questions Exercises. PART 3 SEPARATIONS BY BARRIERS AND SOLID AGENTS. 14. Membrane Separations. 14.0 Instructional Objectives. 14.1 Membrane Materials. 14.2 Membrane Modules. 14.3 Transport in Membranes. 14.4 Dialysis. 14.5 Electrodialysis. 14.6 Reverse Osmosis. 14.7 Gas Permeation. 14.8 Pervaporation. 14.9 Membranes in Bioprocessing. Summary References Study Questions Exercises. 15. Adsorption, Ion Exchange, Chromatography, and Electrophoresis. 15.0 Instructional Objectives. 15.1 Sorbents. 15.2 Equilibrium Considerations. 15.3- Kinetic and Transport Considerations. 15.4 Equipment for Sorption Systems. 15.5- Slurry and Fixed-Bed Adsorption Systems. 15.6 Continuous, Countercurrent Adsorption Systems. 15.7 Ion-Exchange Cycle. 15.8 Electrophoresis. Summary References Study Questions Exercises. PART 4 SEPARATIONS THAT INVOLVE A SOLID PHASE. 16. Leaching and Washing. 16.0 Instructional Objectives. 16.1 Equipment for Leaching. 16.2 Equilibrium-Stage Model for Leaching and Washing. 16.3 Rate-Based Model for Leaching. Summary References Study Questions Exercises. 17. Crystallization, Desublimation, and Evaporation. 17.0 Instructional Objectives. 17.1 Crystal Geometry. 17.2 Thermodynamic Considerations. 17.3 Kinetics and Mass Transfer. 17.4 Equipment for Solution Crystallization. 17.5 The MSMPR Crystallization Model. 17.6 Precipitation. 17.7 Melt Crystallization. 17.8 Zone Melting. 17.9 Desublimation. 17.10 Evaporation. 17.11 Bioproduct Crystallization. Summary References Study Questions Exercises 18. Drying of Solids. 18.0- Instructional Objectives. 18.1 Drying Equipment. 18.2 Psychrometry. 18.3 Equilibrium-Moisture Content of Solids. 18.4 Drying Periods. 18.5 Dryer Models. 18.6 Drying of Bioproducts. Summary References Study Questions Exercises. PART 5 MECHANICAL SEPARATION OF PHASES. 19. Mechanical Phase Separations. 19.0 Instructional Objectives. 19.1 Separation-Device Selection. 19.2 Industrial Particle-Separator Devices. 19.3 Design of Particle Separators. 19.4 Design of Solid Liquid Cake-Filtration Devices Based on Pressure Gradients. 19.5 Centrifuge Devices for Solid Liquid Separations. 19.6 Wash Cycles. 19.7 Mechanical Separations in Biotechnology. Summary References Study Questions Exercises. Answers to Selected Exercises. Index.

A Literature Survey of Benchmark Functions For Global Optimization Problems

Abstract: Test functions are important to validate and compare the performance of optimization algorithms. There have been many test or benchmark functions reported in the literature; however, there is no standard list or set of benchmark functions. Ideally, test functions should have diverse properties so that can be truly useful to test new algorithms in an unbiased way. For this purpose, we have reviewed and compiled a rich set of 175 benchmark functions for unconstrained optimization problems with diverse properties in terms of modality, separability, and valley landscape. This is by far the most complete set of functions so far in the literature, and tt can be expected this complete set of functions can be used for validation of new optimization in the future.