03865oam 2200553I 450 991078784130332120230807204211.00-429-16244-81-4822-3145-X10.1201/b17938 (CKB)2670000000560326(EBL)1680077(SSID)ssj0001403198(PQKBManifestationID)11852117(PQKBTitleCode)TC0001403198(PQKBWorkID)11365722(PQKB)11650748(MiAaPQ)EBC1680077(OCoLC)905554093(EXLCZ)99267000000056032620180331h20152015 uy 0engur|n|---|||||txtccrVibration analysis, instruments, and signal processing /Jyoti Kumar SinhaBoca Raton :Taylor & Francis,[2015]©20151 online resource (322 p.)Description based upon print version of record.1-322-63395-9 1-4822-3144-1 Includes bibliographical references and index.Front Cover; Contents; Preface; About the Author; Chapter 1: Introduction; Chapter 2: Single Degree of Freedom (SDOF) System; Chapter 3: Introduction to Finite Element Modeling; Chapter 4: Force Response Analysis; Chapter 5: Introduction to Vibration Instruments; Chapter 6: Basics of Signal Processing; Chapter 7: Experimental Modal Analysis; Chapter 8: Finite Element Model Updating; Chapter 9: A Simple Concept on Vibration-Based Condition Monitoring; Chapter 10: Case Studies; Back CoverPreface Over the past four decades, the technology in vibration instrumentation and measurements, signal processing, and analytical simulation using finite element (FE) methods has advanced significantly. There are several dedicated books that have recorded these advancements. However, it has been consistently observed that several persons (students, researchers, designers, and maintenance personnel in industry) involved in, say vibration- related works or research, do not fully comprehend the interrelation between theory and experiments. These individuals can be grouped as (1) good in vibration data collection but may not be aware of the applicable basic theory, and vice versa, (2) good in signal processing but may not know the basics of either the theory or vibration data collection and measurement procedures, and (3) involved in dynamic qualifications (FE analysis and modal testing) using standard commercially available software without knowing much about the basic principles and methods. It is imperative that persons involved in vibration-based analysis have at least a basic understanding of the different processes so that they can more effectively solve vibration-related problems. This book aims to communicate the fundamental principles of all three facets of vibration-based analysis (i.e., instruments and measurement, signal processing, and theoretical analysis) in a simplified tutorial manner, which is not readily available in literature. The unique content of this book will therefore be very useful for a diverse audience who are interested in vibration analysis. The target audience includes students (all levels), researchers, and engineers (involved in vibration-based condition monitoring)--Provided by publisher.VibrationMeasurementDamping (Mechanics)VibrationMeasurement.Damping (Mechanics)620.3SCI041000TEC007000TEC009070bisacshSinha Jyoti Kumar1549132FlBoTFGFlBoTFGBOOK9910787841303321Vibration analysis, instruments, and signal processing3806808UNINA04954nam 2200601 450 991082982770332120230721003723.01-282-02172-997866120217253-527-62515-13-527-62516-X(CKB)1000000000578025(EBL)482120(OCoLC)609855538(SSID)ssj0000297050(PQKBManifestationID)11227035(PQKBTitleCode)TC0000297050(PQKBWorkID)10327971(PQKB)10504207(MiAaPQ)EBC482120(EXLCZ)99100000000057802520160816h20082008 uy 0engur|n|---|||||txtccrFuel processing for fuel cells /Gunther KolbWeinheim, [Germany] :Wiley-VCH Verlag GmbH & Co. KGaA,2008.©20081 online resource (436 p.)Description based upon print version of record.3-527-31581-0 Includes bibliographical references and index.Fuel Processing; Contents; Acknowledgement; 1 Introduction and Outline; 2 Fundamentals; 2.1 Common Fossil Fuels; 2.2 Basic Definitions, Calculations and Legislation; 2.3 The Various Types of Fuel Cells and the Requirements of the Fuel Processor; 2.3.1 PEM Fuel Cells; 2.3.2 High Temperature Fuel Cells; 3 The Chemistry of Fuel Processing; 3.1 Steam Reforming; 3.2 Partial Oxidation; 3.3 Oxidative Steam Reforming or Autothermal Reforming; 3.4 Catalytic Cracking of Hydrocarbons; 3.5 Pre-Reforming of Higher Hydrocarbons; 3.6 Homogeneous Plasma Reforming of Higher Hydrocarbons3.7 Aqueous Reforming of Bio-Fuels3.8 Processing of Alternative Fuels; 3.8.1 Dimethyl Ether; 3.8.2 Methylcyclohexane; 3.8.3 Sodium Borohydride; 3.8.4 Ammonia; 3.9 Desulfurisation; 3.10 Carbon Monoxide Clean-Up; 3.10.1 Water-Gas Shift; 3.10.2 Preferential Oxidation of Carbon Monoxide; 3.10.3 Methanation; 3.11 Catalytic Combustion; 3.12 Coke Formation on Metal Surfaces; 4 Catalyst Technology for Distributed Fuel Processing Applications; 4.1 A Brief Introduction to Catalyst Technology and Evaluation; 4.1.1 Catalyst Activity; 4.1.2 Catalyst Stability; 4.1.3 Catalyst Coating Techniques4.1.4 Specific Features Required for Fuel Processing Catalysts in Smaller Scale Applications4.2 Reforming Catalysts; 4.2.1 Catalysts for Methanol Reforming; 4.2.2 Catalysts for Ethanol Reforming; 4.2.3 Overview of Catalysts for Hydrocarbon Reforming; 4.2.4 Catalysts for Natural Gas/Methane Reforming; 4.2.5 Catalysts for Reforming of LPG; 4.2.6 Catalysts for Pre-Reforming of Hydrocarbons; 4.2.7 Catalysts for Gasoline Reforming; 4.2.8 Catalysts for Diesel and Kerosene Reforming; 4.2.9 Cracking Catalysts; 4.2.10 Deactivation of Reforming Catalysts by Sintering4.2.11 Deactivation of Reforming Catalysts by Coke Formation4.2.12 Deactivation of Reforming Catalysts by Sulfur Poisoning; 4.3 Catalysts for Hydrogen Generation from Alternative Fuels; 4.3.1 Dimethyl Ether; 4.3.2 Methylcyclohexane; 4.3.3 Sodium Borohydride; 4.3.4 Ammonia; 4.4 Desulfurisation Catalysts/Adsorbents; 4.5 Carbon Monoxide Clean-Up Catalysts; 4.5.1 Catalysts for Water-Gas Shift; 4.5.2 Catalysts for the Preferential Oxidation of Carbon Monoxide; 4.5.3 Methanation Catalysts; 4.6 Combustion Catalysts; 5 Fuel Processor Design Concepts; 5.1 Design of the Reforming Process5.1.1 Steam Reforming5.1.2 Partial Oxidation; 5.1.3 Autothermal Reforming; 5.1.4 Catalytic Cracking; 5.1.5 Pre-Reforming; 5.2 Design of the Carbon Monoxide Clean-Up Devices; 5.2.1 Water-Gas Shift; 5.2.2 Preferential Oxidation of Carbon Monoxide; 5.2.3 Selective Methanation of Carbon Monoxide; 5.2.4 Membrane Separation; 5.2.5 Pressure Swing Adsorption; 5.3 Aspects of Catalytic Combustion; 5.4 Design of the Overall Fuel Processor; 5.4.1 Overall Heat Balance of the Fuel Processor; 5.4.2 Interplay of the Different Fuel Processor or Components; 5.4.3 Overall Water Balance of the Fuel Processor5.4.4 Overall Basic Engineering of the Fuel ProcessorAdopting a unique integrated engineering approach, this text covers all aspects of fuel processing: catalysts, reactors, chemical plant components and integrated system design. While providing an introduction to the subject, it also contains recent research developments, making this an invaluable handbook for chemical, power and process engineers, electrochemists, catalytic chemists, materials scientists and engineers in power technology.Fuel cellsFuel cells.621.31/2429621.312429Kolb Gunther505560MiAaPQMiAaPQMiAaPQBOOK9910829827703321Fuel Processing804567UNINA