Handbook of Mathematical Relations in Particulate Materials Processing

Read more

Informationen zum Autor Randall M. German, PhD , is the CAVS Chair Professor of Mechanical Engineering and Director of the Center for Advanced Vehicular Systems at Mississippi State University. He holds an Honorary Doctorate from the Universidad Carlos III de Madrid in Spain, is a Fellow of APMI and ASM, holds the Tesla Medal, and is listed in various issues of Who's Who. His accomplishments comprise 850 published articles, twenty-three issued patents, nineteen edited proceedings, and fourteen books, including Sintering Theory and Practice (Wiley). Seong Jin Park, PhD , is Associate Research Professor in the Center for Advanced Vehicular Systems at Mississippi State University. He is the recipient of numerous awards and honors, including Leading Scientists of the World and Outstanding Scientists Worldwide, both awarded by the International Biographical Centre in 2007. Dr. Park is the author of over 190 published articles and three books, holds four patents, and created four commercialized software programs. His areas of specialization and interest include materials processing technology, numerical technology, and physics. Klappentext The only handbook of mathematical relations with a focus on particulate materials processingThe National Science Foundation estimates that over 35% of materials-related funding is now directed toward modeling. In part, this reflects the increased knowledge and the high cost of experimental work. However, currently there is no organized reference book to help the particulate materials community with sorting out various relations. This book fills that important need, providing readers with a quick-reference handbook for easy consultation.This one-of-a-kind handbook gives readers the relevant mathematical relations needed to model behavior, generate computer simulations, analyze experiment data, and quantify physical and chemical phenomena commonly found in particulate materials processing. It goes beyond the traditional barriers of only one material class by covering the major areas in ceramics, cemented carbides, powder metallurgy, and particulate materials. In many cases, the governing equations are the same but the terms are material-specific. To rise above these differences, the authors have assembled the basic mathematics around the following topical structure:* Powder technology relations, such as those encountered in atomization, milling, powder production, powder characterization, mixing, particle packing, and powder testing* Powder processing, such as uniaxial compaction, injection molding, slurry and paste shaping techniques, polymer pyrolysis, sintering, hot isostatic pressing, and forging, with accompanying relations associated with microstructure development and microstructure coarsening* Finishing operations, such as surface treatments, heat treatments, microstructure analysis, material testing, data analysis, and structure-property relationsHandbook of Mathematical Relations in Particulate Materials Processing is suited for quick reference with stand-alone definitions, making it the perfect complement to existing resources used by academic researchers, corporate product and process developers, and various scientists, engineers, and technicians working in materials processing. Zusammenfassung The only handbook of mathematical relations with a focus on particulate materials processing The National Science Foundation estimates that over 35% of materials-related funding is now directed toward modeling. In part, this reflects the increased knowledge and the high cost of experimental work. Inhaltsverzeichnis Foreword. About the Authors. A Abnormal Grain Growth. Abrasive Wearâ??See Friction and Wear Testing. Acceleration of Free-settling Particles. Activated Sintering, Early-stage Shrinkage. Activation Energyâ??See Arrhenius Relation. Ad...

List of contents

PARTIAL TABLE OF CONTENTS Foreword. About the Authors. A Abnormal Grain Growth. Abrasive Wearâ See Friction and Wear Testing. Acceleration of Free settling Particles. Activated Sintering, Early stage Shrinkage. Activation Energyâ See Arrhenius Relation. Adsorptionâ See BET Specific Surface Area. Agglomerate Strength. Agglomeration Force. Agglomeration of Nanoscale Particlesâ See Nanoparticle Agglomeration. Andreasen Size Distribution. B Ball Millingâ See Jar Milling. Bearing Strength. Bell Curveâ See Gaussian Distribution. Bending beam Viscosity. Bending Test. BET Equivalent Spherical particle Diameter. BET Specific Surface Area. Bimodal Powder Packing. Bimodal Powder Sintering. Binder Burnoutâ See Polymer Pyrolysis. C Cantilever beam Testâ See Bending beam Viscosity. Capillarity. Capillarity induced Sinteringâ See Surface Curvature Driven Mass Flow in Sintering. Capillary Pressure during Liquid phase Sinteringâ See Mean Capillary Pressure. Capillary Riseâ See Washburn Equation. Capillary Stressâ See Laplace Equation. Case Carburization. Casson Model. Cemented carbide Hardness. Centrifugal Atomization Droplet Size. D Darcyâ s Law. Debindingâ See Polymer Pyrolysis, Solvent Debinding Time, Thermal Debinding Time, Vacuum Thermal Debinding Time , and Wicking. Debinding Master Curveâ See Master Decomposition Curve. Debinding Temperature. Debinding Timeâ See Solvent Debinding Time, Thermal Debinding Time, Vacuum Thermal Debinding Time , and Wicking . Debinding by Solvent Immersionâ See Solvent Debinding Time. Debinding Weight Loss. Delubricationâ See Polymer Pyrolysis. Densification. Densification in Liquid phase Sinteringâ See Dissolution induced Densification. E Effective Pressure. Ejection Stressâ See Maximum Ejection Stress. Elastic Behaviorâ See Hookeâ s Law . Elastic deformation Neck size Ratio. Elastic modulus Variation with Density. Elastic property Variation with Porosity. Electrical conductivity Variation with Porosity. Electromigration Contributions to Spark Sintering. Elongation. Elongation Variation with Densityâ See Sintered Ductility. F Feedstock Formulation. Feedstock Viscosityâ See Suspension Viscosity and Viscosity Model for Infection molding Feedstock . Feedstock Viscosity as a Function of Shear Rateâ See Cross Model . Feedstock Yield Strengthâ See Yield Strength of Particle Polymer Feedstock. Fiber fracture from Buckling. Fiber fracture Probability. Fiber Packing Density. Fickâ s First Law. Fickâ s Second Law. Field activated Sintering. G Gas absorption Surface Areaâ See BET Specific Surface Area. Gas atomization Cooling Rate. Gas atomization Melt Flow Rate. Gas atomization Particle Size. Gas generated Final Pores. Gas Permeabilityâ See Kozeny Carman Equation. Gate Strain Rate in Injection Molding. Gaudin Schuhmann distribution. Gaussian Distribution. Gel densification Model. H Hall Petch Relation. Hardenability Factor. Hardness. Hardness Variation with Grain Size in Cemented Carbides. Heating rate Effect in Transient Liquid phase Sintering. Heat Transfer in Sintered Materials. Heat transfer Rate in Modelingâ See Cooling Rate in Molding. Herring Scaling Law. Hertzian stressâ See Elastic Deformation Neck size Ratio. Heterodiffusionâ See Mixed powder Sintering Shrinkage. I Impregnationâ See Infiltration Pressure. Inertial flow Equation. Infiltration Depth. Infiltration Pressure. Infiltration Rate. Inhibited Grain Growthâ See Zener Relation. Initial stage Liquid phase Sintering Stressâ See Sintering Stress in Initial stage Liquid phase Sintering. Initial stage Neck Growth. Initial stage Sinteringâ See Surface Diffusion Controlled Neck Growth . Initial stage Sintering Modelâ See Kuczynski Neck growth Model. J Jar Milling. Jet Mixing Time. K Kawakita Equation. Kelvin Equation. Kelvin Modelâ See Viscoelastic Model for Powder Polymer Mixtures. K Factor. Kingery Intermediate stage Liquid phase Sintering Modelâ See Intermediateâ stage Liquid phase Sintering Model. Kingery Model for

Report

"Suited for quick reference with stand alone definitions. It is the perfect complement to existing textbooks since it will simply cut to the key relations. " (Alamogordo Daily News, 16 March 2011)