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200 10$aFluid catalytic cracking handbook $ean expert guide to the practical operation, design, and optimization of FCC units /$fReza Sadeghbeigi
205   $a3rd ed.
210   $aOxford, UK ;$aWaltham, MA, USA $cElsevier/Butterworth-Heinemann$d2012
215   $a1 online resource (376 p.)
300   $aDescription based upon print version of record.
311   $a0-12-386965-X 
320   $aIncludes bibliographical references and index.
327   $aFront Cover; Fluid Catalytic Cracking Handbook; Copyright Page; Contents; Preface and Acknowledgments; About the Author; 1: Process Description; Feed Preheat; Feed Nozzles-Riser; Catalyst Separation; Stripping Section; Regenerator-Heat/Catalyst Recovery; Partial Versus Complete Combustion; Regenerated Catalyst Standpipe/Slide Valve; Regenerator Catalyst Separation; Flue Gas Heat and Pressure Recovery Schemes; Catalyst Handling Facilities; Main Fractionator; Gas Plant; Primary Absorber; Sponge Oil or Secondary Absorber; Stripper or De-ethanizer; Debutanizer; Gasoline Splitter
327   $aWater Wash SystemTreating Facilities; Sour Gas Absorber; LPG Treating; Caustic Treating; Summary; References; 2: Process Control Instrumentation; Operating Variables; Process Control Instrumentation; Basic Supervisory Control; Regenerated and Spent Catalyst Slide Valve; Low Differential Pressure Override; Advanced Process Control; Advantages of Multivariable Modeling and Control; Disadvantages of Multivariable Modeling and Control; Summary; 3: FCC Feed Characterization; Hydrocarbon Classification; Paraffins; Olefins; Naphthenes; Aromatics; Feedstock Physical Properties; API Gravity
327   $aDistillationAniline Point; Refractive Index; Bromine Number and Bromine Index; Viscosity; Conradson, Ramsbottom, Microcarbon, and Heptane Insolubles; Impurities; Nitrogen; Sulfur; Metals; Nickel (Ni); Vanadium; Alkaline Earth Metals; Other Metals; Summary; Empirical Correlations; K-Factor; TOTAL; n-d-M Method; API Method; Benefits of Hydroprocessing; Summary; References; 4: FCC Catalysts; Catalyst Components; Zeolite; Zeolite Structure; Zeolite Chemistry; Zeolite Types; Zeolite Properties; Matrix; Filler and Binder; Catalyst Manufacturing Techniques; Conventional Zeolites (REY, REHY, and HY)
327   $aUSY ZeoliteBASF Process; Fresh Catalyst Properties; Particle Size Distribution; Surface Area (m2/g); Sodium (Na) (wt%); Rare Earth (wt%); E-Cat Analysis; Catalytic Properties; Conversion (activity); Coke Factor and Gas Factor; Physical Properties; Surface Area (m2/g); Apparent Bulk Density (g/cc); Pore Volume (cc/g); Pore Diameter (A?); Particle Size Distribution; Chemical Properties; Alumina (Al2O3); Sodium (Na); Nickel (Ni), Vanadium (V), Iron (Fe), and Copper (Cu); Carbon (C); Catalyst Management; Catalyst Evaluation; Summary; References; 5: Catalyst and Feed Additives
327   $aCO Combustion PromoterSOx Additive; NOx Additive; ZSM-5 Additive; Metal Passivation; Antimony; Bottoms-Cracking Additive; Summary; References; 6: Chemistry of FCC Reactions; Thermal Cracking; Catalytic Cracking; FCC Catalyst Development; Impact of Zeolites; Mechanism of Catalytic Cracking Reactions; Cracking Reactions; Isomerization Reactions; Hydrogen Transfer Reactions; Other Reactions; Thermodynamic Aspects; Summary; References; 7: Unit Monitoring and Control; Material Balance; Testing Methods; Advantages of Reaction Mix Sampling; Disadvantages of Reaction Mix Sampling
327   $aRecommended Procedures for Conducting a Test Run
330   $a This new and improved edition focuses on providing practical information and tools that engineers can use to maximize the profitability and reliability of their fluid catalytic cracking operations. The updated chapters and new content deliver expertise and know-how to an industry that faces significant cost cutting in capital expenditure and R&D, along with the retirement of technical specialists who are taking existing knowledge out of the industry with them. This FCC Handbook provides a valuable easy-to-understand resource for both experienced and inexperienced engineers and anyone else a
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200 10$aOptimisation Algorithms for Hand Posture Estimation /$fby Shahrzad Saremi, Seyedali Mirjalili
205   $a1st ed. 2020.
210  1$aSingapore :$cSpringer Nature Singapore :$cImprint: Springer,$d2020.
215   $a1 online resource (XV, 205 p. 108 illus., 99 illus. in color.) 
225 1 $aAlgorithms for Intelligent Systems,$x2524-7573
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327   $aIntroduction to Hand Posture Estimation -- Literature Review of Hand Posture Estimation Techniques and Optimisation Algorithms -- A New 3D Hand Model, Hand Shape Optimization, and Evolutionary Population Dynamics for PSO and MOPSO -- Evaluating PSO and MOPSO equipped with Evolutionary Population Dynamics -- Hand shape optimisation for geometry-based models using EPD-based Particle Swarm Optimization -- Hand recovery for geometry-based models using EPD-based Particle Swarm Optimization -- Hand model estimation considering two objectives using EPD-based Multi-Objective Particle Swarm Optimization -- Conclusion.
330   $aThis book reviews the literature on hand posture estimation using generative methods, identifying the current gaps, such as sensitivity to hand shapes, sensitivity to a good initial posture, difficult hand posture recovery in cases of loss in tracking, and lack of addressing multiple objectives to maximize accuracy and minimize computational cost. To fill these gaps, it proposes a new 3D hand model that combines the best features of the current 3D hand models in the literature. It also discusses the development of a hand shape optimization technique. To find the global optimum for the single-objective problem formulated, it improves and applies particle swarm optimization (PSO), one of the most highly regarded optimization algorithms and one that is used successfully in both science and industry. After formulating the problem, multi-objective particle swarm optimization (MOPSO) is employed to estimate the Pareto optimal front as the solution for this bi-objective problem. The book alsodemonstrates the effectiveness of the improved PSO in hand posture recovery in cases of tracking loss. Lastly, the book examines the formulation of hand posture estimation as a bi-objective problem for the first time. The case studies included feature 50 hand postures extracted from five standard datasets, and were used to benchmark the proposed 3D hand model, hand shape optimization, and hand posture recovery.
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