Industrial chemistry and manufacturing technologies Books

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Book Synopsis

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Book Synopsis

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Book SynopsisWood as an engineering material can be technically defined “as a hygroscopic, orthotropic, biological, and permeable material having extreme chemical diversity and physical complexity with structures, that vary extensively in their shape, size, properties and function”. Therefore, using wood to its best advantage and most efficiency in engineering applications, specific characteristics or chemical, physical and mechanical properties must be considered. The products are divided into two classes, solid wood and composite wood products. Solid wood includes shipbuilding, bridges, flooring, mine timbers, etc. Composite wood products include insulation board, plywood, oriented strand board, hardboard and particle board. In recent years, the machining of wood products has acquired great importance due the short supply of wood and increasing environmental awareness among users and manufacturers. The optimization of the machining process centers around the mechanism of chip formation, tool wear, workpiece surface quality, crack initiation and propagation of different types of wood. Other factors are also humidity, temperature, static preloads, and vibrations that can affect the wood during the machining process. The book provides some fundamentals and recent research advances on machining wood and wood products.Trade Review"This book should be valuable in advanced courses for undergraduate engineering students in courses dealing with wood machining. It might also serve as a reference for researchers inside the field of wood mechanics and wood manufacturing." (International Wood Products Journal, 1 April 2011) Table of ContentsPreface xi Chapter 1. Machining of Wood and Wood Composites 1 Grzegorz KOWALUK 1.1. Introduction 1 1.2. Wood and wood-based composites 2 1.3. Approach to cutting 7 1.4. Main techniques of machining 11 1.5. Problems of machining wood and wood composites – a review 19 1.6. Into the future – further scenarios of wood and wood composites machining 21 1.7. Acknowledgement 23 1.8. Bibliography 24 Chapter 2. Wood and Wood-based Panel Machining Quality 27 Cristina COELHO, Nuno GARRIDO, Jorge MARTINS, Luisa CARVALHO and Carlos COSTA 2.1. Solid wood machining 27 2.2. Wood-based panels machining 39 2.3. Surface quality 50 2.4. Case study: solid wood machining and surface quality evaluation 65 2.5. Case study: particleboard machining and edge quality evaluation 73 2.6. Bibliography 75 Chapter 3. Reducing Tool Wear by Cryogenic Treatment and Cooling with Refrigerated Air when Processing Medium Density Fiberboard 83 Rado GAZO, Judith GISIP and Harold A. STEWART 3.1. Introduction 83 3.2. Effects of refrigerated air 85 3.3. Effects of cryogenic treatment and refrigerated air 98 3.4. Acknowledgements 111 3.5. Bibliography 111 Chapter 4. Wearing Mechanisms Contributing to Reduced Tool Life after Wood and Secondary Wood Products Machining 115 Boles³aw PORANKIEWICZ 4.1. Introduction 116 4.2. Cutting edge-material cut interface 116 4.3. TGA indirect evidence of HTTR 119 4.4. Theoretical QC analysis of HTTR 134 4.5. Investigations of direct evidence of HTTR 140 4.6. Cutting edge SEM image examinations 143 4.7. Synergistic effect of high temperature reactions and mechanical wear 146 4.8. Final remarks 150 4.9. Conclusions 154 4.10. Acknowledgements 155 4.11. Bibliography 155 Chapter 5. Monitoring Surface Quality on Molding and Sawing Processes for Solid Wood and Wood Panels 159 Alfredo AGUILERA 5.1. Introduction 159 5.2. General concepts 160 5.3. Monitoring the cutting process 176 5.4. Surface roughness and quality for solid wood and panels 190 5.5. Concluding remarks 210 5.6. Acknowledgements 211 5.7. Bibliography 211 Chapter 6. Evaluating the Roughness of Sanded Wood Surfaces 217 Lidia GURAU, Hugh MANSFIELD-WILLIAMS and Mark IRLE 6.1. Introduction 217 6.2. Profile filtering applied to wood surfaces 228 6.3. A proposed method for separating processing roughness from anatomical roughness 246 6.4. A case study: the processing roughness of oak surfaces sanded with various grit sizes 250 6.5. Concluding remarks 259 6.6. Perspectives 260 6.7. Acknowledgements 261 6.8. Bibliography 261 List of Authors 269 Index 273

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Book SynopsisFault tree analysis is an important technique in determining the safety and dependability of complex systems. Fault trees are used as a major tool in the study of system safety as well as in reliability and availability studies. The basic methods – construction, logical analysis, probability evaluation and influence study – are described in this book. The following extensions of fault trees, non-coherent fault trees, fault trees with delay and multi-performance fault trees, are also explained. Traditional algorithms for fault tree analysis are presented, as well as more recent algorithms based on binary decision diagrams (BDD).Table of ContentsIntroduction 11 Chapter 1 Single-Component Systems 17 1.1 Distribution of failure and reliability 17 1.1.1 Function of distribution and density of failure 17 1.1.2 Survival function: reliability 18 1.1.3 Hazard rate 19 1.1.4 Maintainability 19 1.1.5 Mean times 20 1.1.6 Mean residual lifetime 21 1.1.7 Fundamental relationships 21 1.1.8 Some probability distributions 22 1.2 Availability of the repairable systems 25 1.2.1 Instantaneous availability 25 1.2.2 Asymptotic availability 26 1.2.3 Mean availability 26 1.2.4 Asymptotic mean availability 27 1.3 Reliability in discrete time 27 1.3.1 Discrete distributions 28 1.3.2 Reliability 28 1.4 Reliability and maintenance 29 1.4.1 Periodic test: repair time is negligible 29 1.4.2 Periodic test: repair time is not negligible 30 1.4.3 Mean duration of a hidden failure 30 1.5 Reliability data 31 Chapter 2 Multi-Component Systems 33 2.1 Structure function 33 2.2 Modules andmodular decomposition 36 2.3 Elementary structure systems 37 2.3.1 Series system 37 2.3.2 Parallel system 38 2.3.3 System k-out-of-n 38 2.3.4 Parallel-series system 39 2.3.5 Series-parallel system 39 2.4 Systems with complex structure 40 2.5 Probabilistic study of the systems 42 2.5.1 Introduction 42 2.5.2 Inclusion-exclusion method 43 2.5.3 Disjoint products 44 2.5.4 Factorization 46 2.5.5 Reliability bounds 46 Chapter 3 Construction of Fault Trees 49 3.1 Basic ideas and definitions 49 3.1.1 Graphic symbols 52 3.1.2 Use of the operators 53 3.2 Formal definition and graphs 56 3.3 Stages of construction 57 3.3.1 Preliminary analysis 58 3.3.2 Specifications 59 3.3.3 Construction 59 3.4 Example of construction 60 3.4.1 Preliminary analysis 60 3.4.2 Specifications 62 3.4.3 Construction 62 3.5 Automatic construction 63 Chapter 4 Minimal Sets 67 4.1 Introduction 67 4.2 Methods of study 68 4.2.1 Direct methods 68 4.2.2 Descending methods 71 4.2.3 Ascending methods 73 4.3 Reduction 74 4.4 Other algorithms for searching the cut sets 75 4.5 Inversion of minimal cut sets 76 4.6 Complexity of the search for minimal cut sets 78 Chapter 5 Probabilistic Assessment 79 5.1 The problem of assessment 79 5.2 Direct methods 80 5.2.1 AND operator 81 5.2.2 OR operator 81 5.2.3 Exclusive OR operator 82 5.2.4 k-out-of-n operator 83 5.2.5 Priority-AND operator 83 5.2.6 IF operator 83 5.3 Methods of minimal sets 84 5.3.1 Inclusion-exclusion development 84 5.3.2 Disjoint products 85 5.3.3 Kitt method 86 5.4 Method of factorization 88 5.5 Direct recursive methods 90 5.5.1 Recursive inclusion-exclusion method 90 5.5.2 Method of recursive disjoint products 91 5.6 Other methods for calculating the fault trees 92 5.7 Large fault trees 93 5.7.1 Method of Modarres and Dezfuli [MOD 84] 93 5.7.2 Method of Hughes [HUG 87] 94 5.7.3 Schneeweiss method [SCH 87] 95 5.7.4 Brown method [BRO 90] 95 Chapter 6 Influence Assessment 97 6.1 Uncertainty 97 6.1.1 Introduction 97 6.1.2 Methods for evaluating the uncertainty 98 6.1.3 Evaluation of the moments 99 6.2 Importance 103 6.2.1 Introduction 103 6.2.2 Structural importance factors 105 6.2.3 Probabilistic importance factors 106 6.2.4 Importance factors over the uncertainty 109 Chapter 7 Modules – Phases – Common Modes 111 7.1 Introduction 111 7.2 Modular decomposition of an FT 111 7.2.1 Module and better modular representation 111 7.2.2 Modularization of a fault tree 114 7.3 Multiphase fault trees 116 7.3.1 Example 117 7.3.2 Transformation of a multiphase system 118 7.3.3 Method of eliminating the minimal cut sets 118 7.4 Common mode failures 119 Chapter 8 Extensions: Non-Coherent, Delay and Multistate Fault Trees 123 8.1 Non-coherent fault trees 123 8.1.1 Introduction 123 8.1.2 An example of a non-coherent FT 126 8.1.3 Prime implicants and implicates 126 8.1.4 Probabilistic study 128 8.2 Delay fault trees 129 8.2.1 Introduction 129 8.2.2 Treatment 129 8.3 FTs and multistate systems 131 8.3.1 Multistate systems 131 8.3.2 Structure function 132 8.3.3 Stochastic description and function of reliability 135 8.3.4 Fault trees with restrictions 136 8.3.5 Multistate fault trees 138 Chapter 9 Binary Decision Diagrams 143 9.1 Introduction 143 9.2 Reduction of the Shannon tree 143 9.2.1 Graphical representation of a BDD 143 9.2.2 Formal BDD 145 9.2.3 Probabilistic calculation 147 9.3 Probabilistic assessment of the FTs based on the BDD 148 9.4 Research about the prime implicants 151 9.5 Algorithmic complexity 153 Chapter 10 Stochastic Simulation of Fault Trees 155 10.1 Introduction 155 10.2 Generation of random variables 155 10.2.1 Generation of a uniform variable 155 10.2.2 Generation of discrete random variables 157 10.2.3 Generation of real random variables 158 10.3 Implementation and evaluation of the method 159 10.3.1 The Monte Carlo method 159 10.3.2 Estimating the probability of the top event 160 10.3.3 Precision of the estimation 161 10.3.4 Acceleration of the convergence 164 10.3.5 Rare events 165 Exercises 167 Appendices 177 A BDD Algorithms in FT Analysis 179 A1 Introduction 179 A2 Obtaining the BDD 180 A3 Algorithm of probabilistic assessment 182 A4 Importance factors 183 A5 Prime implicants 184 B European Benchmark Fault Trees 187 B1 Description of the data 187 B2 Fault tree: Europe-1 188 B2.1 Structure of the fault tree (structural data) 188 B2.2 Probabilistic data 190 B2.3 Results 190 B3 Fault tree: Europe-2 191 B3.1 Structure of the fault tree 191 B3.2 Probabilistic data 192 B3.3 Results 192 B4 Fault tree: Europe-3 193 B4.1 Structure of the FT 193 B4.2 Probabilistic data 195 B4.3 Results 195 C Some Results of Probabilities 197 Main Notations 201 Bibliography 205 Index 221

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Book Synopsis

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