Kooperativer Bibliotheksverbund

UID:

Umfang: 1 online resource (452 pages)

Ausgabe: 1st ed.

ISBN: 9789819744923

Anmerkung: Intro -- Preface -- Contents -- About the Authors -- 1 Energy-Saving Theory, Technology, and Double Carbon Target -- 1.1 Energy Efficiency Is the Number One Fuel -- 1.2 Energy Saving Is One of the Important Purposes of Electrical Control -- 1.3 Energy Saving Needs Are Everywhere -- 1.3.1 Single Device Energy Saving -- 1.3.2 Multi-unit System Energy Saving -- 1.4 R& -- D Overview of Energy Efficiency Optimization -- 1.5 Problems of Existing Energy Efficiency Optimization Methods -- 1.6 Quantum Optimization Method and Energy Efficiency Prediction Theory -- References -- 2 Energy Conversion and Overall Energy Efficiency -- 2.1 Energy Form of the Power Station -- 2.1.1 Convert Potential Energy to Electrical Energy -- 2.1.2 Convert Heat Energy to Electricity -- 2.1.3 Wind Power Hydrogen Production System -- 2.2 Power Dispatch and Distribution -- 2.2.1 Power Distribution -- 2.2.2 Power Dispatch -- 2.3 Energy Consumption System -- 2.3.1 Gaining Potential Energy -- 2.3.2 Provide Pressure Energy -- 2.3.3 Provide Cold and Heat Energy -- 2.3.4 Motion System -- 2.3.5 Manpower Scheduling -- 2.4 Overall Energy Efficiency and Weighted Energy Efficiency -- 2.5 Efficiency Function -- 2.6 Unification of Optimization of Power Generation and Energy Consumption -- 2.7 Not Working Is Different from Shutting Down -- 3 Overall Structure and Fieldbus of Energy Saving Control System -- 3.1 The Four Components of the Energy-Saving Control System -- 3.2 Several Structures of Energy-Saving Control System -- 3.2.1 Single Controller Structure -- 3.2.2 Multi-Controller Structure -- 3.3 The Four Key Points of Industrial Bus and Industrial Ethernet Applications -- 4 Commonly Used Energy Parameter Sensors -- 4.1 Liquid, Gas Pressure Sensor and Liquid Level Sensor -- 4.2 Temperature Sensor -- 4.3 Flow Sensor -- 4.4 Force Sensor -- 4.5 Speed Sensor. , 4.6 Torque and Speed Torque Compound Sensor -- 4.7 Voltage Transmitter -- 4.8 Current Transducer -- 4.9 Power Factor Transmitter and Supply Power Transmitter -- 5 Valves and Clutches Commonly Used in Energy-Saving Systems -- 5.1 Magnetic Powder Clutch and Magnetic Powder Brake -- 5.2 Electromagnetic Clutch and Electromagnetic Brake -- 5.3 Electro-Hydraulic Proportional Valve -- 5.4 Electro-Hydraulic Servo Valve -- 5.5 Electro-Hydraulic Digital Valve -- 5.6 Pneumatic and Hydraulic Directional Solenoid Valves -- 5.7 Solenoid Valve and Pneumatic Valve -- 5.8 Electric Regulating Valve and Pneumatic Regulating Valve -- 5.9 Electric/Pneumatic Converter -- 5.10 Self-operated Regulating Valve -- 5.11 Relays and Contactors -- 5.12 Other Electric Devices -- 6 Most Commonly Used Actuator-Motor -- 6.1 Three-Phase AC Motor -- 6.1.1 Basic Principle of Three-Phase AC Asynchronous Motor -- 6.1.2 Several External and Internal Wiring Methods of Three-Phase AC Motors -- 6.1.3 Calculation of Rated Torque of Three-Phase AC Motor -- 6.1.4 Three-Phase Permanent Magnet Synchronous AC Motor -- 6.1.5 Three-Phase AC Synchronous Motor -- 6.1.6 Three-Phase AC Asynchronous Motor with Wound Rotor -- 6.1.7 Three-Phase Frequency Conversion Speed Regulation Motor -- 6.2 Single-Phase AC Motors -- 6.3 DC Motors -- 6.4 Brushless DC Motor -- 6.5 Stepping Motors -- 6.6 Servo Motor -- 6.7 Linear Motors -- 6.8 Switched Reluctance Motors -- 6.9 Power Supply Voltage and Operating Voltage of Electrical Device -- 6.9.1 Power Supply and Structure in the United States -- 6.9.2 Design Working Voltage of Electrical Device -- 6.9.3 Power Sockets -- 6.9.4 Power Supply and Structure in China -- 7 Speed Regulation Method in Energy Saving System -- 7.1 Electromagnetic Slip Clutch -- 7.2 Hydraulic Coupling -- 7.3 Fluid Viscous Clutch -- 7.4 Mechanical Governor. , 7.5 Stepper Motor and Stepper Motor Driver -- 7.6 AC Servo Motor Driver -- 7.7 Speed Regulation Method of DC Motor -- 7.8 Rotational Speed of AC Motors -- 7.9 Efficiency of AC Motors -- 7.10 Speed Regulation Method of AC Motor -- 7.10.1 The Speed Regulation Method of Changing the Number of Pairs of Poles -- 7.10.2 Nine Speed Regulation Methods to Change the Slip S -- 7.10.3 Speed Regulation Method of Changing the Frequency -- 8 Simple Usage Method of Frequency Converter and Expanding Knowledge -- 8.1 Basic Usage of Inverter -- 8.1.1 Selection of Inverter -- 8.1.2 Main Power and Control Wiring of Inverter -- 8.1.3 Basic Parameter Setting of Frequency Converter -- 8.1.4 Outline of Frequency Converter -- 8.2 Basic Usage of ABB Inverter -- 8.2.1 Purpose -- 8.2.2 Essentials to Master -- 8.2.3 Inverter Appearance -- 8.2.4 Inverter Model -- 8.2.5 Inverter Wiring and Floating Networks -- 8.2.6 Parameter Setting -- 8.2.7 Other Notes -- 8.3 The Principle of Frequency Converter (Beginners Do not Need to Master) -- 8.3.1 Main Circuit Structure of General Frequency Converter -- 8.3.2 Sine Wave Pulse Width Modulation (SPWM) Mode and Implementation -- 8.3.3 V/F Control of Frequency Converter -- 8.3.4 Vector Control of Inverter -- 8.3.5 Direct Torque Control of Frequency Converter -- 8.4 Expansion of Inverter Application (Beginners Do Not Need to Master) -- 8.4.1 Harmonics of Frequency Converter and Countermeasures -- 8.4.2 Estimation of Input and Output Reactors -- 8.4.3 Heat Dissipation and Reactive Power Compensation of the Frequency Converter -- 8.4.4 Calculation and Estimation of Braking Resistor -- 9 Controllers Used in Energy-Saving Control Systems-PLC -- 9.1 Simple Way to Get Started with Modular PLC -- 9.2 Getting Started with PLC Programming-Ladder Diagram -- 9.2.1 "AND" -- 9.2.2 "OR" -- 9.2.3 "Output" -- 9.2.4 "Set" -- 9.2.5 "Reset". , 9.2.6 Data Transfer "MOV" -- 9.2.7 "ADD" -- 9.2.8 "SUB" -- 9.2.9 "MUL" -- 9.2.10 "DIV" -- 9.2.11 Counter C (Counter) -- 9.2.12 Timer T (Timer) -- 9.2.13 Greater Than or Equal to (≥) -- 9.2.14 Equal to (=) -- 9.2.15 Less Than (< -- ) -- 9.2.16 Greater Than (> -- ) -- 9.2.17 Less Than or Equal to (≤) -- 9.2.18 Rising Edge Action (P) -- 9.2.19 Falling Edge Action (N) -- 9.2.20 Per Second Pulse Program -- 9.2.21 PID Closed-Loop Control -- 9.3 PLC Programming Software -- 9.3.1 Module Configuration -- 9.3.2 Software Programming -- 10 Human-Machine Interface and Configuration Software -- 10.1 Basic Usage of the HMI -- 10.1.1 Main Purpose of the Human-Machine Interface -- 10.1.2 Wiring of the Man-Machine Interface -- 10.1.3 Communication Connection of HMI -- 10.1.4 Display Data -- 10.1.5 Set Data -- 10.1.6 On/off Display -- 10.1.7 On/off Control -- 10.1.8 Curve Display -- 10.1.9 Display of Bar Graph -- 10.1.10 Appearance of HMI -- 10.2 Configuration Software -- 10.2.1 Purpose of Configuration Software -- 10.2.2 General Usage of Configuration Software -- 10.2.3 Common Configuration Software -- 10.3 Quick Start of WINCC Configuration Software -- 10.3.1 Purpose -- 10.3.2 Basic Steps -- 10.3.3 Wincc Programming Software Operation and Communication Settings -- 10.3.4 Add "Variable" Connected with PLC -- 10.3.5 Adding a New Screen -- 10.3.6 Adding Static Text -- 10.3.7 Analog Value and Data Display -- 10.3.8 Output Analog and Data -- 10.3.9 Control Button -- 10.3.10 Device Run/stop Display -- 10.3.11 PC Communication Address and Running Start Screen -- 10.3.12 Techniques for Reducing the Number of Variable Tags in Configuration Software -- 11 Calculation and Selection of Motor Parameters in Automation System -- 11.1 Determination of the Rated Torque Ne of the Motor -- 11.2 Determination of Motor Speed. , 11.3 Determination of the Maximum Acceleration of the Servo Motor -- 11.4 Determination of Motor Power -- 11.5 Determination of Encoder Resolution -- 11.6 Servo Motor Inertia Ratio -- 12 Parameter Design in High-Speed High-Precision Motion Control -- 12.1 Determination of Feedforward Parameters-"Yao's Trial and Error Method" -- 12.2 A Simple Adjustment Method of PID Parameters-"Two-Four Rule" -- 12.3 "Yao's Speed up and Down Rules" of the Frequency Converter in the Speed Chain -- 12.4 The Wonderful Effect of "Virtual Axis" in Speed Synchronous Control -- 12.5 Approximate Feedforward Parameter K1 -- 13 Anti-interference and Fault Analysis of Control System -- 13.1 Anti-interference Measures -- 13.1.1 Common Mode Interference -- 13.1.2 Signal Transmission Interference by Other Means -- 13.1.3 Communication Interference -- 13.1.4 Signal Connection and Conversion Between 4-Wire Sensor and 2-Wire Sensor -- 13.1.5 Power Isolation and Sharing of Isolation Modules -- 13.1.6 Inverter Interference -- 13.1.7 Power Interference -- 13.1.8 Anti-interference of Sensor Output Signal -- 13.1.9 Digital Input of the Controller -- 13.1.10 Electrical Circuit Control Failure -- 13.2 Selection of Signal Lines and Shielding Grounding Issues -- 13.3 Failure Analysis -- 13.4 Lightning Protection Measures -- 13.5 Communication Port Crash Problem -- 14 Energy Efficiency Optimization of Multi-Unit System -- 14.1 What is a Multi-Unit System? -- 14.2 The Essence of Multi-Unit System Optimization -- 14.3 Energy Efficiency Optimization of Multi-Unit System -- 14.4 Energy Efficiency Function -- 14.5 Similar Energy Efficiency Device -- 14.6 Optimal Load Distribution Theorem of Multi-Unit System, Yao Theorem 1 -- 14.7 Optimal Switching Theorem for Multi-Unit System, Yao Theorem 2 -- 14.8 Simulation Results -- 14.9 Quantum Optimization Method and Energy Efficiency Predictive Theory. , 14.10 The Second Definition of Similar Energy Efficiency Devices.

Weitere Ausg.: Print version: Yao, Fulai Efficient Energy-Saving Control and Optimization for Multi-Unit Systems Singapore : Springer Singapore Pte. Limited,c2024 ISBN 9789819744916

Sprache: Englisch

Schlagwort(e): Electronic books. ; Electronic books.

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URL: EBSCOhost

URL: https://public.ebookcentral.proquest.com/choice/PublicFullRecord.aspx?p=31554484

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UID:

Umfang: XI, 880 p. 430 illus., 340 illus. in color. , online resource.

Ausgabe: 1st ed. 2023.

ISBN: 9789819968862

Serie: Lecture Notes in Electrical Engineering, 1091

Inhalt: This book constitutes the proceedings of the 19th Chinese Intelligent Systems Conference, CISC 2023, which was held during October 14-15, 2023, in Ningbo, Zhejiang, China. The book focuses on new theoretical results and techniques in the field of intelligent systems and control. This is achieved by providing in-depth studies of a number of important topics such as multi-agent systems, complex networks, intelligent robots, complex systems theory and swarm behavior, event-driven and data-driven control, robust and adaptive control, big data and brain science, process control, intelligent sensors and detection technology, deep learning and learning control, navigation and control of aerial vehicles, and so on. The book is particularly suitable for readers interested in learning intelligent systems and control and artificial intelligence. The book can benefit researchers, engineers and graduate students.

Anmerkung: Research on Hierarchical Mechanism of strictly metric-free model modeling and parameter optimization -- Analytical Study of the Nonlinear Characteristics of Hydraulic Servo Actuator -- Fetal Head Circumference Detection Based on Dlink-Net Model -- Circumnavigating Control of an Unmanned Aerial Vehicle Using Range-only Measurements -- Path Planning for Parafoil Airdrop System Based on TD3 Algorithm: Reward Shaping with Potential Field -- Research on Efficiency Optimization of Open Winding Permanent Magnet Synchronous Generator Considering Zero Sequence Current Suppression -- Low frequency wide bandgap of perforation local resonant meta-structure sandwich plate -- Full polarization radar target recognition based on ensemble learning algorithm -- Input-to-state Stability of Cyber-physical Systems under Denial of Service Attacks -- Research on Wing Attitude Prediction Method Based on Distributed Inertial Navigation Network -- Design and Simulation of Pneumatic Drive System for Mobile Highland Tent -- Finite-Time Stability and Stabilization of Continuous-Time Mean-Field Stochastic Systems -- Flight Control Practice of Relay Communication Service for Mars Exploration -- Research On Integration Technology of Guidance and Fuze For Air Defense Missile -- Assessment method for fine configuration of basic resource of information system -- Resilient Consensus of Heterogeneous Multi-Agent Systems Based on E-MSR Algorithms -- Target identification technology in space light environment based on improved YOLOX -- Adaptive Control of Vehicle Steering-by-wire System -- Quadcopter UAV Swarm Formation and Avoidance Collision System -- Finite-time anti-disturbance control for stochastic system with multiple disturbance -- Master-slave power battery management system based on STM32 microcontroller -- Preliminary Study on the Method of Generating Infrared Image Based on CycleGAN -- Predicting Nitrogen Oxide Concentration Based on Quadrupedal Robots -- Research on Aerofoil Distortion Angle Prediction Method Based on Prediction Model -- State Estimation and Fusion for Multisensor Systems with Non-Gaussian Noises and False Data Injection Attacks -- Key technology research of VR-based substation practice teaching system -- Experimental Research on Surface Integrity of High Strength Steel Turning by Analysis of Variance Method -- Event-triggered prescribed performance control for nonlinear servo systems with unknown disturbances -- Adaptive actor-critic neural finite time optimal control for constrained nonlinear MASs via command filter -- The Realization of Model-based Spacecraft Mission Planning and Execution of High-Level Autonomy -- Human Intention Recognition for Lower Limb Exoskeleton Robot -- Attention Based Temporal Convolutional Networks for Short-term Wind Power Forecasting -- Implementation of a receiver tracking loop adapted to intermittent network transmission -- Fusing multi-scale binary convolution with joint attention face expression recognition algorithm -- Comparison between Simulation and Experiment of Parafoil Fixed Height Flight by Adding Thrust Motor Model -- Multi-sensor Fusion Model-Free Adaptive Control for Systems with Network Attacks -- Stereovision-based Target Trajectory Tracking Control for Robotic Manipulator -- Model Predictive Control for Uncalibrated Visual Servoing Based on Broyden Estimation -- A Non-Iterative Turboshaft Engine Model with Its Neural Network Control Algorithm -- Real-time Pedestrian Tracking System Based on Depth Camera for Quadruped Robot -- Automatic Kidney Parenchyma Segmentation Based on Improved UNeXt Model -- Analysis of the problem of zero deviation characteristics exceeding the tolerance of a hydraulic servo actuator -- Design of a Multi axis Motion Control System for Smart Hands Based on SOC -- A Distributed Processing Method for Large Scale Logs -- Precession Fault Diagnosis Method Based on Butterworth Filter and Convolutional Neural Network -- Active contour model based on poisson's equation and morphology for inhomogeneous image segmentation -- Path Planning of Mobile Robot Based on Improved Artificial Potential Field Method -- Research on trajectory control of unmanned based on adaptive MPC -- Adaptive Repetitive Learning Control for Dual-motor Driving Servo Systems -- Adaptive non-backstepping output-feedback control for hydraulic servo system -- Concurrent Learning Model Reference Adaptive Control of Articulated Vehicles -- Adaptive Neural Finite-time Output Feedback Compensated Control for Stochastic Nonstrict-feedback Systems with Prescribed Performance -- Bipartite Consensus Control for Multi-Agent Systems with Privacy-Preserving under Directed Topology -- A geometric approach to design disturbance rejection controller in finite frequency domain -- Adaptive Sliding Mode Control with Disturbance Observer for Trajectory Tracking of Robotic Milling -- Research on Multi-aircraft Time Cooperative Interception Method Based on TD3 Algorithm -- Laser Intensity and Multi-Echo Information Utilization for Indoor Unmanned Aerial Vehicles (UAVs): Current Status and Future Trends -- UCB-based architecture search for remaining useful life prediction -- Simulation and experimental analysis of thermal characteristics of valve body active cooling structure -- A Method for Partitioning the Topological Structure of Groups Based on Hypergraphs -- Motion imagery classification algorithm based on multiscale convolution and transfer learning -- A Method to Enhance Data Observability for Robot Calibration in Confined Space -- Multiplayer Stackelberg-Nash Game for Discrete-Time Nonlinear System -- Adaptive Finite-Time Parameter Estimation for a Reaction Force-sensing Series Elastic Actuator -- Space Robotic Arm Joint Design and Experimental Method Research -- Multi-mobile Robots Formation Control with Prescribed Performance in Polar Coordinates -- Horizontal Trajectory Tracking Control for X Rudder AUV Adopted Sliding Mode Control with IPSO Allocation Algorithm -- A Noval Graph Convolutional Neural Network and its Application in Power Load Forecasting -- Identity Consistency Construction for Visible-infrared Person Re-identification in Cloud Environment -- Adaptive Consensus for Second-Order Uncertain Multiagent Systems with Communication Delays Using Relative Output Information -- A Multi-terrain Adaptive Feed-forward Control Walking Algorithm for Lifting Exoskeleton -- FDI Attack-Resilient Distributed Cooperative Control for Microgrids via Two-hop Communication -- Adaptive Formation Control for Uncertain Networked Wheeled Mobile Robots -- A PGK Aerodynamic Simulation Analysis and Trajectory Optimization Study -- Deep Reinforcement Learning-based Multi-objective 3D Path Planning for Vehicles.

In: Springer Nature eBook

Weitere Ausg.: Printed edition: ISBN 9789819968855

Weitere Ausg.: Printed edition: ISBN 9789819968879

Weitere Ausg.: Printed edition: ISBN 9789819968886

Sprache: Englisch

DOI: 10.1007/978-981-99-6886-2

URL: https://doi.org/10.1007/978-981-99-6886-2

URL: Volltext  (URL des Erstveröffentlichers)

UID:

Umfang: 1 online resource (0 pages)

Ausgabe: 1st ed. 2024.

ISBN: 9789819728398

Serie: Lecture Notes in Electrical Engineering, 1194

Inhalt: This book features selected papers presented at the 6th International Conference on Recent Innovations in Computing (ICRIC 2023), held on 26–27 October 2023 at the Central University of Jammu, India, and organized by the university’s Department of Computer Science and Information Technology. The book is divided into two volumes, and it includes the latest research in the areas of software engineering, cloud computing, computer networks and Internet technologies, artificial intelligence, information security, database and distributed computing, and digital India.

Anmerkung: Deep Learning Based Summarized Notes Generation from Document -- Text Summarization Techniques for the Bengali Language: Survey -- Bibliometric Analysis of Internet of Things (IoT) In Green Healthcare -- AI and patient convenience: Usage of AI based medical chatbots for medical diagnosis via smartphones -- Learning Device for Dyslexia -- Artificial Intelligence (AI) -Powered Intelligent Systems for Disease Prognosis: A Bibliometric Study -- Unleashing the Potential: Study on Artificial Intelligence Effect in Education Sector -- Analysis and Performance of Text Summarization Tools Applied on Indian Languages -- A Review of Privacy Preserving Decentralized Learning -- AI-Powered Traffic Orchestration: Reinforcement Learning at Traffic Intersections -- A Novel Melanoma Diagnosing System Using Multi-Directional Pattern Extraction Based Distributed Deep Learning Model -- An Element Gathering Optimization based Probabilistic Multi-Model Neural Network Classification Algorithm for Stock Market Prediction -- Enhancing Text Classification with Modular Deep Encoder-Decoder Networks for Multimodal Data -- Design and Development of Deep Learning Based Framework to Detect Disease in Tomato Leaf -- Leveraging Data Mining Optimization for Enhancing Safety Management in Public Security Prevention and Control Application -- A Review of Artificial Intelligence and Machine Learning for Vaccine Research -- Forecasting Criminal Activity: An Empirical Approach for Crime Rate Prediction -- Autonomous Self Driving Car Model Using Deep Learning -- Forecasting the Incidence of Neglected Tropical Diseases and Vector-Borne Diseases -- Machine Learning techniques for detection and classification of crop (Solanum lycopersicum) plant diseases due to pests: A Review -- Review and Challenges: Identify Malnutrition Among Children Under 5 Age -- A review of Crypto-ransomware pre-encryption detection -- Are We Ready To Investigate Robots? Issues and Challenges Involved in Robotic Forensics -- Unmasking the Vulnerabilities: A Deep Dive into the Security Threat Landscape of Humanoid Robots -- An Ensemble-based Extra Feature Selection Approach for predicting Heart Disease -- A Comprehensive Review on Machine Learning in Breast Cancer Analysis -- Fake News Detection using Machine Learning Algorithms -- Review of Cyber Physical System Based Security Datasets for Learning Based Intrusion Detection Systems -- Deep Learning Model based approach for DDoS Detection and Classification -- Machine Learning-Based Text Categorization with Bag of Words -- Implementation of pretrained models to classify Osteosarcoma from histopathological images -- Data Analysis on Dynamic Flow Characteristics of Variable Delivery Hydraulic Axial Piston Pump -- Impacts Of Website Design Attributes and Functional Benefits on Consumer-Instrumental Value in Electronic Commerce Apparel Websites -- Survey and Analysis of Intrusion Detection Frameworks for Cyber-Physical Systems: A Comprehensive Study -- Exploring Explainable Machine Learning in Healthcare: Closing the Predictive Accuracy and Clinical Interpretability gap -- Enhancing IoT Security through Deep Learning: A Comprehensive Study -- A Novel Distributed Tree Based One Hot Encoding (DTOHE) Technique for Intrusion Detection -- An Enhanced Neural Network Collaborative Filtering (ENNCF) for Personalized Recommender System -- MIMO Based VLC Link for Smart City Applications -- A Detailed Study of Advancements in Digital Forensics -- Diagnosis of Behavioural Disorders using Swarm Intelligent Metaheuristic Techniques -- Development of Arduino based Surveillance Drone for Enhanced Campus Security -- A Naïve Performance Metric Parameter for an Intrusion Detection System Model -- Is Artificial Intelligence based Automation for Cyber Crime Investigation the Need of the Hour? An Exploratory Study -- Traffic Sign Board Recognition and Voice Alert System using Deep Convolutional Neural Network -- Analysis of Intrusion Detection System by Applying Machine Learning using KNIME tool -- Motion-Aware Deep Feature-Based Scalable Video Summarization for Wireless Capsule Endoscopy Videos -- Empowering Smart Cities with Edge Computing-Based Iot Systems: A Focus On Data Analytics And Machine Learning Techniques -- Using Meta-LSTM to Predict Personality Traits from Blog User Behaviors -- A Review and Analysis of Privacy-Preserving Federated Learning based Applications and Services in IoT Networks.

Weitere Ausg.: Print version: Singh, Yashwant Proceedings of International Conference on Recent Innovations in Computing Singapore : Springer,c2024 ISBN 9789819728381

Sprache: Englisch

DOI: 10.1007/978-981-97-2839-8

URL: Volltext  (URL des Erstveröffentlichers)

UID:

Umfang: IX, 1870 S.

ISBN: 7-11-110942-2

Serie: CMP books

Anmerkung: Licensed ed. of: Fachwörterbuch industrielle Elektrotechnik, Energie- und Automatisierungstechnik , Hauptsacht. in chines. Schr. - Text in engl., dt. und chines.

Sprache: Englisch

Schlagwort(e): Energietechnik ; Automatisierungstechnik ; Elektrotechnik ; Englisch ; Deutsch ; Chinesisch ; Energietechnik ; Automatisierungstechnik ; Mehrsprachiges Wörterbuch

UID:

Umfang: 1 online resource (314 pages)

Ausgabe: 1st ed.

ISBN: 9780443135989

Anmerkung: Front Cover -- Making IT Sustainable -- Copyright Page -- Contents -- Endorsements -- 1. Introduction -- Why is sustainability in information technology important? -- Are the economic costs of sustainable information technology prohibitively higher than society is willing to bear? -- Sustainable information technology strategies and practices -- Why is this book on sustainable information technology needed? -- Who can benefit from reading this book? -- What differentiates this book? -- What is not included in the book? -- References -- 2. IT sustainability: definitions, terminology, standards, and metrics -- IT sustainability: definition and terminology -- IT sustainability standards -- IT sustainability metrics -- References -- 3. Technologies and innovative solutions for sustainable data centers -- Sustainable IT operations and IT service management for achieving sustainability -- Data centers and environmental concerns -- Sustainable IT operations -- Sustainable IT service management -- General solutions for optimizing energy usage effectiveness in data centers -- Carbon-aware data centers -- Carbon-aware data center software -- The carbon dependencies of data centers and net-zero status -- Data center energy efficiency: optimizing power usage effectiveness in data centers -- Energy proportionality -- Static power draw and energy proportionality -- Clock speed and energy proportionality -- Dynamic voltage and frequency scaling -- Power distribution in data centers -- Optimizing temperature in data centers: higher operating temperature -- Role of automation in improving energy efficiency in IT -- Utilizing built-in server power management features -- CPU core parking -- Server power profiles -- Role of server virtualization in improving energy efficiency in IT -- Containerized applications and energy consumption reduction -- Embodied energy. , Embodied carbon -- Green data storage -- Green networking -- Main strategies for achieving green networking -- Energy-efficient networking equipment -- Energy-efficient routing -- Carbon-aware scheduling -- Renewable energy sources -- Clean fuel for power backup: hydrogen fuel cells and biogas -- The use of wind turbines in data centers and data centers inside wind turbines -- Nuclear-powered data centers: a future frontier in sustainable computing -- Nuclear fission reactors: small modular reactors -- Nuclear fusion as an energy source for data centers -- Can direct current power make data centers more energy-efficient? -- Benefits of direct current power -- Limitations of direct current power -- Direct current-powered servers -- Incorporating sustainable materials into the design and operation of data centers -- Environmental water footprint of data centers: cooling and water consumption -- Data center cooling -- Environmental monitoring in data centers: sensors and controls -- Waterside economizers -- Data center liquid cooling -- High-density liquid cooling in data centers -- Immersion cooling -- Direct-to-chip cooling -- Evaporative cooling -- Rear door heat exchanger cooling -- Carbon dioxide removal -- "Data furnace" project -- Sustainable data center design -- High-density sustainable data centers -- Modular data centers -- Embedded data centers -- How composable disaggregated infrastructure helps in advancing to sustainable IT -- References -- 4. Green and sustainable software engineering -- Criteria for green and sustainable software development -- Green Software Foundation principles -- Sustainable application design -- Green coding practices -- Green software certifications -- Conclusion -- References -- 5. Cloud: sustainability as a driver of cloud technology innovations -- General environmental benefits and challenges of cloud computing. , Why cloud computing is more environmentally friendly than traditional on-premises computing -- Tools for measuring environmental impact of cloud computing services -- AWS customer carbon footprint tool -- Azure Sustainability Calculator and Emissions Impact Dashboard -- Google Sustainability Tools: Carbon Footprint, Active Assist, Cloud Region Picker, and Carbon Sense -- Google Cloud Carbon Footprint -- Active Assist -- Google Cloud Region Picker -- Carbon Sense -- IBM Cloud Carbon Calculator -- Sustainable software engineering for cloud computing -- Eco-friendly cloud computing architecture -- Cloud-native applications and IT sustainability -- The use of containerization and microservices to achieve sustainability in cloud-native computing -- Sustainable cloud data storage -- Sustainable cloud-based backup -- Sustainable cloud networking -- Cloud-native processors -- Cloud providers' initiatives and solutions for achieving environmental sustainability of cloud computing -- AWS's commitment to sustainability -- Sustainability initiatives of Microsoft Azure -- Sustainability initiatives of Google Cloud platform -- Sustainability solutions for Oracle Cloud -- IBM Sustainable Cloud -- References -- 6. Sustainable high-performance computing -- Green HPC in corporate sustainability initiatives -- Energy-efficient solutions for high-performance computing -- Energy-efficient high-performance processors -- Low-power processors in high-performance computing -- ARM-based processors -- Hybrid and heterogeneous high-performance computing -- Memory technologies -- Composable systems -- Intelligent packaging technologies -- Open hardware platforms -- The use of artificial intelligence for achieving sustainable high-performance computing -- Cooling technologies in green high-performance computing -- The use of renewable energy in high-performance computing. , Cloud-based green high-performance computing -- References -- Further reading -- 7. Roles of 5G/6G and the Internet of Things in advancing IT sustainability -- Sustainable cloud radio access network -- Ecological effect of moving consumers to 5G phones -- Sustainable telco cloud solutions -- Sustainable solutions for mobile cloud computing -- Sustainable edge computing -- Making multiaccess edge computing sustainable -- Sustainable 5G distributed edge architectures -- Sustainable 5G cloudlets -- Sustainable 5G micro data centers -- 5G-connected smart grids -- Sustainable Internet of Things -- Designing IoT devices for sustainability -- References -- 8. Circular economy and sustainable IT -- Circular economy concepts in sustainable IT -- Sustainable IT manufacturing -- Sustainable IT hardware -- Extending IT hardware life by using of artificial intelligence and machine learning -- Application of circular economy principles to embodied carbon in IT hardware -- The use of sustainable materials in IT -- Sustainable end-of-life strategies for IT equipment -- Cascading components across multiple lifecycles -- Waste electrical and electronic equipment reuse in the circular economy -- The Circular Economy for the Data Center Industry -- Sustainable IT equipment disposal -- IT sustainability solutions in the circular economy -- References -- 9. Remanufacturing programs in sustainable IT -- Terminology: remanufactured, refurbished, and reuse as-is -- Remanufacturing in circular economy -- EEE reverse remanufacturing and WEEE collection -- Remanufacturing operational processes for IT equipment -- Inspection -- Disassembly -- Cleaning -- Repair or replacement -- Reassembly -- Quality control -- IT OEM's remanufacturing programs -- Dell Refurbished program -- Remanufactured data center equipment -- Product design for automated remanufacturing. , Certified remanufactured IT equipment -- References -- 10. Sustainable IT supply chain management and IT procurement -- Environmental certifications and standards used in sustainable green IT supply chain management -- Sustainable IT procurement practices -- Sustainable IT procurement policies -- Renewable energy procurement in IT -- Green IT labeling schemes in sustainable IT supply chain -- References -- 11. The environmental implications of remote working -- The multifaceted role of remote working in business operations -- How remote working enabled by IT services advances environmental sustainability -- Reduced transportation emissions -- Lower energy consumption -- Less office space -- The use of renewable energy sources -- Technology advancements -- How the environmental impact of working from home can be measured -- Sustainable IT solutions used for working from home -- References -- 12. Cryptocurrency and its impact on the environment -- Energy cost of cryptocurrency -- The Cambridge Bitcoin Electricity Consumption Index -- How to reduce the energy cost of cryptocurrency mining -- The Lightning Network -- Proof-of-Stake consensus mechanisms -- Renewable energy sources and mining pools -- Using waste gas flare for cryptocurrency mining -- Energy-efficient mining hardware -- Initiatives for reducing the environmental impact of cryptocurrency mining -- The Crypto Climate Accord -- The BitGreen Project -- Sustainable infrastructure for cryptocurrency mining -- Blockware Solutions -- Greenidge Generation -- Northern Data -- Hydro66 -- Marathon Digital -- References -- 13. Adiabatic reversible computing -- Power consumption in computing: Koomey's Law and Landauer's Principle -- Reversible computing -- Adiabatic computing -- Adiabatic reversible computing -- Adiabatic quantum computing -- References. , 14. How quantum computing contributes to achieving sustainable IT.

Weitere Ausg.: Print version: Gloukhovtsev, Mikhail Making IT Sustainable San Diego : Elsevier Science & Technology,c2024 ISBN 9780443135972

Sprache: Englisch

UID:

Umfang: 1 online resource (477 p.)

Ausgabe: 2nd ed.

ISBN: 1423742435 , 1-281-00926-1 , 1-4237-4243-5 , 9786611009267 , 0-08-047969-3

Originaltitel: Newnes electrical engineer's handbook.

Inhalt: The second edition of this popular engineering reference book, previously titles Newnes Electrical Engineer's Handbook, provides a basic understanding of the underlying theory and operation of the major classes of electrical equipment.With coverage including the key principles of electrical engineering and the design and operation of electrical equipment, the book uses clear descriptions and logical presentation of data to explain electrical power and its applications. Each chapter is written by leading professionals and academics, and many sections conclude with a summary of key stand

Anmerkung: Previous ed. published as: Newnes electrical engineer's handbook. 2000. , Includes index. , Cover; Front matter; Half Title Page; Title Page; Copyright; Contents; Acknowledgements; 1. Introduction; 2. Principles of electrical engineering; 2.1 Nomenclature and units; 2.2 Electromagnetic fields; 2.3 Circuits; 2.4 Energy and power; References; 3. Materials for electrical engineering; 3.1 Introduction; 3.2 Magnetic materials; 3.3 Insulating materials; 3.4 Conducting materials; Acknowledgement; References; 4. Measurements and instrumentation; 4.1 Introduction; 4.2 Pressure; 4.3 Flow; 4.4 Temperature; 4.5 Position; 4.6 Level; 4.7 Weighing and force; 4.8 Acceleration and speed; 4.9 Current , 4.10 HART and Fieldbus 4.11 Data acquisition; 4.12 Installation notes; 5. Generators; 5.1 Introduction; 5.2 Main generator types; 5.3 Principles of operation; 5.4 The Automatic Voltage Regulator (AVR); 5.5 Brushless excitation; 5.6 Construction; 5.7 Rating and specification; 5.8 Testing; 5.9 Standards; 6. Transformers; 6.1 Principles of operation; 6.2 Main features of construction; 6.3 Main classes of transformer; 6.4 Rating principles; 6.5 Test methods; 6.6 Commissioning, maintenance and repair; 6.7 Standards; 7. Switchgear; 7.1 Introduction; 7.2 Principles of operation , 7.3 Low-voltage switchgear 7.4 Medium-voltage (distribution) switchgear; 7.5 High-voltage (transmission) switchgear; 7.6 DC switchgear; References; 8. Fuses and protection relays; 8.1 Protection and co-ordination; 8.2 Fuses; 8.3 Protection relays; References; 9. Wires and cables; 9.1 Scope; 9.2 Principles of power cable design; 9.3 Main classes of cable; 9.4 Parameters and test methods; 9.5 Optical communication cables; 9.6 Standards; References; 10. Motors, motor control and drives; 10.1 Introduction; 10.2 The direct current (DC) motor; 10.3 The cage induction motor , 10.4 The slipring induction motor 10.5 The ac synchronous motor; 10.6 The brushless servomotor; 10.7 The reluctance motor; 10.8 The switched reluctance motor; 10.9 Mechanical and duty cycle considerations; 10.10 Drive power circuits; 10.11 Effects of semiconductor power converters; 10.12 The commercial drive; 10.13 Standards; References; 11. Power electronic circuits and devices; 11.1 Introduction; 11.2 Diode converters; 11.3 Active devices; 11.4 Principles of switching circuits; 11.5 High-frequency power supplies; 11.6 Standards; References; 12. Batteries and fuel cells; 12.1 Introduction , 12.2 Primary cells 12.3 Secondary cells based upon aqueous electrolytes; 12.4 Secondary lithium ion cells; 12.5 Fuel cells; 12.6 Battery charging; 12.7 Battery monitoring; 12.8 Installation, testing and commissioning; 12.9 Operation and maintenance; 12.10 Standards; References; 13. The power system; 13.1 Introduction; 13.2 Generation; 13.3 Transmission; 13.4 Distribution; 13.5 De-regulation and privatization; 13.6 Future trends; References; 14. Power quality and electromagnetic compatibility; 14.1 Power quality; 14.2 Electromagnetic compatibility; 14.3 Standards; References , 15. Electricity and potentially explosive atmospheres , English

Weitere Ausg.: ISBN 0-7506-6268-9

Sprache: Englisch

UID:

Umfang: 1 online resource (539 p.)

Ausgabe: 1st ed.

ISBN: 3-446-43014-8 , 1-61583-752-3

Anmerkung: Bibliographic Level Mode of Issuance: Monograph , Intro -- Dedication -- Acknowledgement -- Table of Contents -- Preface -- 1 Background -- 1.1 Plastics Industry Review -- 1.1.1 Manufacturing Productivity -- 1.1.2 Manufacturing Cost Breakdown -- 1.1.3 Characteristics of Productive Plastics Manufacturers -- 1.2 Manufacturing and Strategic Planning -- 1.2.1 Manufacturing Planning -- 1.2.2 Manufacturing System Design -- 1.2.3 Strategic Planning -- 1.3 Engineering Economics -- 1.3.1 Payback Period -- 1.3.2 Net Present Value -- 1.3.3 Internal Rate of Return -- 1.4 Summary -- 2 Plastics Manufacturing Systems -- 2.1 Overview of Plastics Processing -- 2.1.1 Extrusion -- 2.1.2 Blow Molding -- 2.1.3 Injection Molding -- 2.1.4 Thermoforming -- 2.2 Characteristics -- 2.2.1 Closed Loop Control -- 2.2.2 Open Loop Control -- 2.2.3 Dynamic Control -- 2.2.4 Control Modes -- 2.2.5 Control Architectures -- 2.2.6 Automatic Control -- 2.3 Performance Measurement -- 2.3.1 Dynamic Response -- 2.3.2 Repeatability -- 2.3.3 Productivity -- 2.4 Summary -- 3 Heating and Cooling -- 3.1 Specifications -- 3.1.1 Power Output -- 3.1.2 Actuator Efficiency -- 3.1.3 Linearity -- 3.1.4 Consistency -- 3.1.5 Failure Rate and Mode -- 3.1.6 Cost -- 3.1.7 Operating Requirements -- 3.2 Heating -- 3.2.1 Conduction Heaters -- 3.2.2 Radiant Heaters -- 3.2.3 Heater Controls -- 3.3 Cooling -- 3.3.1 Coolants -- 3.3.2 Coolant Temperature Controllers -- 3.4 Transient Analysis -- 3.4.1 Lumped Thermal Capacitance -- 3.4.2 Finite Thickness Model -- 3.5 Summary -- 4 Hydraulics and Pneumatics -- 4.1 Specifications -- 4.2 Pumps and Compressors -- 4.2.1 Gear Pump -- 4.2.2 Vane Pump -- 4.2.3 Piston Pump -- 4.3 Fluid Conditioning -- 4.3.1 Filters -- 4.3.2 Heat Exchangers -- 4.3.3 Accumulators -- 4.3.4 Relief Valves -- 4.3.5 Pressure Regulators -- 4.4 Actuators -- 4.4.1 Cylinders -- 4.4.2 Motors -- 4.5 Control Valves -- 4.5.1 Directional Valves. , 4.5.2 Metering Valves -- 4.6 Dynamic Analysis -- 4.6.1 Valve Dynamics -- 4.6.2 Fluid Dynamics -- 4.6.3 Machine Dynamics -- 4.7 Summary -- 5 Electric Drives -- 5.1 Introduction -- 5.1.1 Electromagnetism -- 5.1.2 Electromotive Forces -- 5.1.3 Common Motor Types -- 5.1.4 Typical Specifications -- 5.2 Linear Solenoids -- 5.3 DC Motors -- 5.3.1 DC Brushed Motors -- 5.3.2 DC Brushless Motor -- 5.3.3 Analysis -- 5.3.4 DC Motor Controls -- 5.4 AC Induction Motors -- 5.4.1 Design -- 5.4.2 Analysis -- 5.4.3 Behavior -- 5.4.4 AC Motor Controls -- 5.5 Other Motors -- 5.5.1 Stepper Motors -- 5.5.2 Linear Motors -- 5.6 Motor Specification Guidelines -- 5.7 Summary -- 6 Process Sensors -- 6.1 Specifications -- 6.1.1 Sensitivity, Responsivity, and Resolution -- 6.1.2 Response Time -- 6.1.3 Precision and Accuracy -- 6.1.4 Linearity and Hysteresis -- 6.1.5 Range -- 6.1.6 Life Expectancy -- 6.1.7 Size -- 6.1.8 Calibration -- 6.2 Temperature Sensors -- 6.2.1 Thermocouples -- 6.2.2 Resistance Temperature Detectors -- 6.2.3 Infrared Pyrometers -- 6.3 Force and Pressure Sensors -- 6.3.1 Strain Gages -- 6.3.2 Load Cells -- 6.3.3 Pressure Transducers -- 6.4 Displacement Sensors -- 6.4.1 Resistive Sensors -- 6.4.2 Inductance Sensors -- 6.4.3 Magnetostrictive Sensors -- 6.4.4 Optical Encoders -- 6.4.5 Laser Interferometers -- 6.5 Summary -- 7 Signal Conditioning -- 7.1 Conversion -- 7.1.1 Resistance to Voltage -- 7.1.2 Bridge Circuits -- 7.1.3 Current to Voltage -- 7.2 Amplification -- 7.2.1 Operational Amplifiers -- 7.2.2 Unity Amplifier -- 7.2.3 Gain Adjustment -- 7.2.4 Bias Adjustment -- 7.3 Filtering -- 7.3.1 Passive Filters -- 7.3.2 Active Filters -- 7.4 Signal Conditioning in Software -- 7.4.1 Calibration -- 7.4.2 Software Filters -- 7.4.3 Linearization -- 7.5 Summary -- 8 Data Acquisition Systems -- 8.1 Overview -- 8.2 Analog to Digital Conversion -- 8.2.1 Resolution. , 8.2.2 Range -- 8.2.3 Sampling Frequency -- 8.2.4 Bandwidth -- 8.2.5 Buffer Size -- 8.2.6 Single-Ended and Differential Signaling -- 8.2.7 Input Impedance -- 8.2.8 Slew Rate -- 8.2.9 Thermocouple Input Modules -- 8.3 Analog Output Modules -- 8.4 Digital Input/Output Modules -- 8.5 Summary -- 9 Machine Controllers -- 9.1 System Architectures -- 9.1.1 PLC/PAC Controllers -- 9.1.2 PC/PLC Controllers -- 9.1.3 Virtual Controllers -- 9.1.4 Distributed/Embedded Microcontrollers -- 9.1.5 Summary -- 9.2 Implementation -- 9.2.1 Control Architecture -- 9.2.2 Control Cabinet -- 9.2.3 Auxiliary Modules -- 9.2.4 System Operation -- 9.3 Summary -- 10 Process Control -- 10.1 Open Loop Control -- 10.2 Thermostat Control -- 10.3 PID Control -- 10.3.1 Proportional Control -- 10.3.2 Integral Control -- 10.3.3 Proportional-Integral (PI) Control -- 10.3.4 Proportional-Integral-Derivative (PID) Control -- 10.4 Common Issues -- 10.4.1 Saturation -- 10.4.2 Electrical Noise -- 10.4.3 Filters -- 10.4.4 Delays -- 10.5 Additional Topics -- 10.5.1 Tuning Methodology -- 10.5.2 Analog Implementation -- 10.6 Summary -- 11 Process Characterization -- 11.1 Statistical Characterization -- 11.1.1 Mean and Range -- 11.1.2 Standard Deviation -- 11.1.3 Coefficient of Variation -- 11.2 Design of Experiments -- 11.2.1 Full and Fractional Factorial Designs -- 11.2.2 Advanced Designs -- 11.3 Best Practices in Experimentation -- 11.3.1 Center-Points -- 11.3.2 Population Size -- 11.3.3 Characterization Range -- 11.3.4 Grouping and Randomization -- 11.3.5 Stabilization -- 11.4 Regression -- 11.4.1 Linear Least Squares -- 11.4.2 Outlier Analysis -- 11.4.3 Correlation Coefficient -- 11.4.4 Confidence Intervals -- 11.5 Summary -- 12 Process Optimization -- 12.1 Process Capability Assessment -- 12.1.1 Yield Estimates -- 12.1.2 Process Capability Indices, CP and CPK -- 12.1.3 Six Sigma. , 12.2 Process Feasibility Analysis -- 12.2.1 Monte Carlo Analysis -- 12.2.2 Constraint Based Reasoning -- 12.3 Process Optimization -- 12.3.1 Robustness and Yield -- 12.3.2 Cost Minimization -- 12.3.3 Pareto Optimality -- 12.4 Uncertainty -- 12.5 Summary -- 13 Quality Control -- 13.1 Gage Repeatability & -- Reproducibility -- 13.2 Acceptance Sampling -- 13.3 On-Line Metrology -- 13.3.1 Rheometry -- 13.3.2 Dimensional Metrology -- 13.3.3 Machine Vision -- 13.3.4 Weight -- 13.4 Statistical Process Control -- 13.4.1 Implementation -- 13.4.2 SPC Heuristics -- 13.4.3 Multivariate Statistical Process Control -- 13.5 Summary -- 14 Automation -- 14.1 Introduction to Automation -- 14.1.1 Advantages and Disadvantages -- 14.1.2 Plastics Factory Automation Systems -- 14.2 Raw Materials Handling -- 14.2.1 Loading -- 14.2.2 Drying -- 14.2.3 Gravimetric Blending -- 14.2.4 Granulation -- 14.3 Robotics -- 14.3.1 Sprue Pickers -- 14.3.2 Traversing Robots -- 14.3.3 SCARA Robot -- 14.3.4 Fully Articulated Robots -- 14.3.5 End of Arm Tooling -- 14.4 Finished Goods Handling -- 14.4.1 Conveyors -- 14.4.2 Part Sorters -- 14.4.3 Pallet Loader -- 14.4.4 Automated Guided Vehicle -- 14.5 Integrated Systems -- 14.5.1 Strategy -- 14.5.2 Examples -- 14.6 Summary -- Appendix A: Statistical Labor Data -- A.1 United States Labor Rates -- A.2 International Labor Rates -- A.3 Trends in International Manufacturing Costs -- Appendix B: Material Properties -- Appendix C: Unit Conversions -- C.1 Length Conversions -- C.2 Mass/Force Conversions -- C.3 Pressure Conversions -- C.4 Flow Rate Conversions -- C.5 Viscosity Conversions -- C.6 Power Conversions -- C.7 Energy Conversions -- Appendix D: Matlab Primer -- D.1 Usage -- D.2 Sample Program -- D.3 Other Functions/Operators -- Bibliography -- Index -- A -- B -- C -- D -- E -- F -- G -- H -- I -- J -- K -- L -- M -- N -- O -- P -- Q -- R. , S -- T -- U -- V -- W -- X -- Y. , English

Weitere Ausg.: ISBN 3-446-42014-2

Sprache: Englisch

UID:

Umfang: 1 online resource (338 pages) : , illustrations.

ISBN: 0-08-100993-3

Serie: Woodhead Publishing series in composites science and engineering

Anmerkung: Front Cover -- Fiber Technology for Fiber-Reinforced Composites -- Copyright -- Contents -- List of contributors -- Chapter 1: Introduction -- References -- Chapter 2: Mechanics of fiber composites -- 2.1. Introduction -- 2.2. Mechanics of continuous fiber-reinforced composites -- 2.2.1. Macromechanical analysis -- 2.2.1.1. Constitutive equations -- 2.2.2. Micromechanical analysis -- 2.3. Mechanics of short fiber-reinforced composites -- 2.3.1. Law of mixtures -- 2.3.2. Shear lag model -- 2.3.3. Semi empirical models for spherical particulate systems -- 2.3.3.1. Halpin-Tsai model -- 2.3.3.2. Lewis-Nielsen model -- 2.3.3.3. S-combining rule -- 2.3.3.4. Chantler, Hu, and Boyd (CHU) model -- 2.3.3.5. Guth and Gold model -- 2.3.4. Semi empirical models for nonspherical particulate systems -- 2.3.4.1. Halpin-Tsai model -- 2.3.4.2. Modified Halpin-Tsai model -- 2.3.4.3. Guth model -- 2.3.4.4. Brodnyan model -- 2.4. Mechanics of woven fabric composites -- 2.4.1. Constitutive equations -- 2.5. Interface mechanics in fiber-reinforced composites -- 2.6. Mechanics of curved composites -- 2.7. Strength failure theories -- 2.7.1. Introduction -- 2.7.2. Constitutive equations for orthotropic materials -- 2.7.2.1. Stress-strain relations for a lamina of arbitrary orientation -- 2.7.3. Determination of strength and stiffness of an orthotropic lamina -- 2.7.3.1. Determination of stiffness and strength for a lamina -- 2.7.4. Biaxial strength criteria for an orthotropic lamina -- 2.7.4.1. Tsai-Hill failure criterion -- 2.7.4.2. Hoffman failure criterion -- 2.7.4.3. Tsai-Wu tensor failure criterion -- 2.8. Dynamic behavior of composites -- 2.8.1. Longitudinal vibrations in composite bars -- 2.8.2. Transverse vibration of composite beams -- 2.8.3. Transverse vibration of orthotropic plates -- 2.8.4. Analysis of damping in composites -- References. , Chapter 3: Fiber reinforced composites -- 3.1. Introduction -- 3.1.1. Definitions -- 3.1.2. Applications -- 3.1.3. Current and future market outlook -- 3.2. Materials (reinforcements, matrices, fiber/matrix adhesion) -- 3.2.1. Reinforcements -- 3.2.2. Matrices -- 3.2.3. Fiber/matrix adhesion -- 3.2.4. Estimation of composite properties -- 3.3. Manufacturing -- 3.3.1. Compression molding (SMC/BMC compression molding) -- 3.3.2. Hand lay-up -- 3.3.3. Spray-up -- 3.3.4. Vacuum infusion -- 3.3.5. Resin transfer molding (RTM), vacuum assisted resin transfer molding (VARTM) -- 3.3.6. Vacuum bagging -- 3.3.7. Autoclave molding -- 3.3.8. Filament winding -- 3.3.9. Centrifugal casting -- 3.3.10. Automated fiber placement (AFP), automated tape laying (ATL) -- 3.3.11. Pultrusion -- 3.3.12. Injection molding -- 3.3.13. Reaction injection molding (RIM: RRIM, SRIM) -- 3.3.14. Thermoforming -- 3.3.15. Prepregging -- 3.3.16. Sandwich construction -- 3.3.17. Machining -- 3.3.18. Joining -- 3.3.19. Recycling -- 3.4. Characterization and testing -- 3.4.1. Analyses -- 3.4.2. Testing -- 3.5. Fiber surface treatments -- 3.5.1. Oxidative -- 3.5.2. Nonoxidative -- 3.6. Conclusion -- Acknowledgments -- References -- Chapter 4: Surface modification of fibers and sizing operations -- 4.1. Introduction and historical perspective -- 4.2. Physical methods -- 4.2.1. Plasma treatment -- 4.2.2. Other physical treatments -- 4.2.2.1. UV treatment -- 4.2.2.2. Gamma radiation -- 4.2.2.3. Heat treatment -- 4.2.2.4. Ozone treatment -- 4.2.2.5. Excimer UV laser -- 4.3. Chemical treatments -- 4.3.1. Alkaline treatment -- 4.3.2. Silane treatment -- 4.3.3. Oxidative treatment -- 4.3.3.1. Permanganate treatment -- 4.3.3.2. Peroxide treatment -- 4.3.4. Graft copolymerization -- 4.3.5. Other chemical treatments -- 4.3.5.1. Esterification-based methods -- 4.3.5.2. Maleated coupling. , 4.3.5.3. Isocyanate treatment -- 4.4. Biochemical treatments -- 4.5. Sizing -- 4.5.1. Carbon fibers -- 4.5.2. Glass fibers -- 4.6. Conclusion -- References -- Chapter 5: Glass fibers -- 5.1. History of glass fiber -- 5.2. Glass fiber manufacturing -- 5.3. Types of glass fibers -- 5.4. Glass fiber products -- 5.4.1. Chopped strands -- 5.4.2. Direct draw rovings -- 5.4.3. Assembled rovings -- 5.4.4. Chopped and continuous strand mats -- 5.5. Glass fiber sizing -- 5.5.1. Film forming agents -- 5.5.2. Coupling agents (adhesion promoters) -- 5.5.3. Lubricating agents -- 5.5.4. Surface active and emulsifying agents -- 5.5.5. Antistatic agents -- 5.5.6. Antioxidizing agents -- 5.5.7. Plastifying agents -- 5.5.8. Biocides -- 5.6. Composite interphase -- 5.6.1. Thermosets -- 5.6.2. Thermoplastics -- 5.7. Conclusion -- References -- Chapter 6: Carbon fibers -- 6.1. Introduction -- 6.2. Different precursors for CF production -- 6.2.1. PAN based precursors -- 6.2.2. Pitch based precursors -- 6.2.3. Cellulose-based precursors -- 6.2.4. Other precursor materials -- 6.3. Carbonization processes -- 6.3.1. Manufacturing of CF from PAN based precursor -- 6.3.2. Manufacturing of CF from pitch based precursor -- 6.3.3. Manufacturing of CF from cellulosic precursors -- 6.4. Recent developments and trends in CF technology -- 6.5. CF in polymer-matrix composites -- 6.5.1. Types of reinforcements in CF composites -- 6.5.2. Types of polymeric matrices for CF composites -- 6.5.3. Manufacturing methods of CF composites -- 6.6. Uses of CF in other matrices -- 6.7. Conclusion -- References -- Chapter 7: Aramid fibers -- 7.1. Introduction -- 7.2. Fiber production -- 7.2.1. Synthesis of aramids -- 7.2.2. Fiber formation and spinning -- 7.3. Aramid fiber structure and properties -- 7.4. Fiber and product forms -- 7.5. Applications -- 7.5.1. Applications of meta-aramid fibers. , 7.5.2. Applications of para-aramid fibers -- 7.5.2.1. Composites -- 7.5.2.2. Protective clothing -- 7.5.2.3. Ballistic protection -- 7.6. Conclusion -- 7.7. Sources of further information -- 7.7.1. Books -- 7.7.2. Journals -- 7.7.3. Web sites -- References -- Chapter 8: Basalt fibers -- 8.1. Introduction to basalt fibers -- 8.2. Preparation of basalt fibers -- 8.3. Structural properties -- 8.4. Basalt fiber-reinforced composites -- 8.5. Surface treatments of basalt fibers -- 8.6. Applications of basalt fiber -- 8.6.1. Aerospace and automotive industry -- 8.6.2. Civil engineering -- 8.6.3. Chemical and petrochemical industry -- 8.6.4. Manufacturing engineering -- 8.6.5. Power engineering and electrical industry -- 8.7. Conclusion -- References -- Chapter 9: Ceramic fibers -- 9.1. Introduction -- 9.2. Oxide fibers -- 9.3. Nonoxide fibers -- 9.3.1. Silicon carbide based fibers -- 9.3.2. SiCN based fibers -- 9.3.3. Boron-based fibers -- 9.3.4. Other fibers -- 9.4. Production techniques of ceramic fibers -- 9.4.1. CVD technique -- 9.4.2. Melt spinning technique -- 9.4.3. Slurry spinning -- 9.4.4. Chemical conversion -- 9.4.5. Preceramic polymer processing (polymer-derived precursor method) -- 9.4.6. Sol-gel process -- 9.4.7. Single-crystal fiber growth (edge-defined film-fed growth-EFG) technique -- 9.5. Application of ceramic fibers -- References -- Chapter 10: Natural fibers -- 10.1. Introduction to natural fibers -- 10.1.1. Introduction -- 10.1.2. History -- 10.2. Plant fibers -- 10.2.1. Structure of plant fibers -- 10.2.2. Seed and fruit fibers -- 10.2.2.1. Cotton -- 10.2.2.2. Kapok -- 10.2.3. Bast and leaf fibers -- 10.2.3.1. Abaca -- 10.2.3.2. Sisal -- 10.2.3.3. Jute -- 10.2.3.4. Flax -- 10.2.3.5. Hemp -- 10.2.3.6. Henequen -- 10.2.3.7. Kenaf -- 10.3. Conclusion and future outlook -- References. , Chapter 11: The use of biotechnology for green composites -- 11.1. Introduction to green composites -- 11.1.1. Introduction -- 11.1.2. Life-cycle assessment -- 11.1.3. LCA's of composite materials -- 11.2. Natural polymer sources -- 11.2.1. Polylactic acid -- 11.2.2. Polyhydroxyalkanoates -- 11.2.3. Cellulose acetate -- 11.2.4. Thermoplastic starch -- 11.2.5. Biobased polyethylene -- 11.2.6. Polybutylenesuccinate -- 11.2.7. Others -- 11.3. Applications -- 11.3.1. Packaging applications -- 11.3.2. Automotive applications -- 11.4. Conclusion and future outlook -- References -- Chapter 12: Nanofibers for fiber-reinforced composites -- 12.1. Introduction and historical perspective -- 12.1.1. Micro- and nanofibers -- 12.1.2. Methods used to form micro- and nanofibers -- 12.2. Electrospinning -- 12.2.1. The fundamental aspects -- 12.2.2. Factors affecting fiber formation -- 12.2.3. Nanofibers containing nanoparticles -- 12.2.4. Fiber-reinforced composites -- 12.3. Carbon nanotubes/nanofibers -- 12.4. Cellulose nanofibers -- 12.4.1. Nanocellulose for fiber-reinforced composites -- 12.5. Applications -- 12.5.1. Future trends -- References -- Chapter 13: The use of nanotechnology for fibre-reinforced polymer composites -- 13.1. Introduction -- 13.1.1. Fibre-reinforced polymer composites -- 13.1.2. Nanotechnologies for fibre-reinforced polymer composites -- 13.2. Nanotechnologies for matrix modification -- 13.2.1. Matrix modification with hyperbranched polymers -- 13.2.2. Matrix modification by POSS -- 13.2.3. Nanoparticle reinforcement for matrix enhancement -- 13.3. Nanotechnologies for fibre modification -- 13.3.1. Nanomodification on natural fibres -- 13.3.1.1. Natural fibre modification with CNTs -- 13.3.1.2. Natural fibre modification with nano cellulose -- 13.3.1.3. Natural fibre modification with metal and metal oxide nanoparticles. , 13.3.2. Nanomodification on carbon fibres.

Weitere Ausg.: ISBN 0-08-101871-1

Sprache: Englisch

UID:

Umfang: 1 online resource (1,081 pages) : , illustrations (some color), graphs, charts, tables, photographs, maps.

ISBN: 0-08-100162-2 , 0-08-100149-5

Serie: Woodhead Publishing Series in Energy ; 103

Anmerkung: Front Cover -- Handbook of Generation IV Nuclear Reactors -- Related titles -- Handbook of Generation IV Nuclear Reactors -- Copyright -- Contents -- List of contributors -- Woodhead Publishing Series in Energy -- Foreword -- Preface -- Nomenclature -- Symbols -- Subscripts -- Acronyms/Abbreviations -- 1 - Introduction: a survey of the status of electricity generation in the world∗ -- 1.1 Statistics on electricity generation in the world -- 1.2 Thermal power plants3 -- 1.3 Modern nuclear power plants5 -- 1.4 Conclusions -- Abbreviations -- Acknowledgments -- References -- One - Generation IV nuclear-reactor concepts -- 2 - Introduction: Generation IV International Forum -- 2.1 Origins of the Generation IV International Forum -- 2.2 Generation IV goals -- 2.3 Selection of Generation IV systems -- 2.4 Six Generation IV nuclear energy systems -- 2.4.1 Very high temperature reactor -- 2.4.2 Gas-cooled fast reactor -- 2.4.3 Sodium-cooled fast reactor -- 2.4.4 Lead-cooled fast reactor -- 2.4.5 Molten salt reactor -- 2.4.6 Supercritical water-cooled reactors -- 2.5 Summary -- Acknowledgments -- References -- 3 - Very high-temperature reactor -- 3.1 Development history and current status -- 3.2 Technology overview -- 3.2.1 Reactor design types -- 3.2.2 Design features -- 3.2.2.1 Safety -- 3.2.2.2 Fuel cycle -- 3.2.2.3 Multipurpose -- 3.3 Detailed technical description -- 3.3.1 Fuel design -- 3.3.2 Fuel burnup -- 3.3.2.1 Uranium fuel -- 3.3.2.2 Plutonium fuel -- 3.3.3 Reactor design -- 3.3.3.1 Prismatic core reactor design -- 3.3.3.2 Pebble bed core reactor design -- 3.3.4 Reactor safety -- 3.3.5 Plant design -- 3.3.6 Plant operations -- 3.3.6.1 Startup, rated operation, and shutdown -- 3.3.6.2 Dynamic operation -- 3.4 Applications and economics -- 3.4.1 Power generation -- 3.4.2 Cogeneration -- 3.4.2.1 Hydrogen cogeneration. , 3.4.2.2 Desalination cogeneration -- 3.4.3 Industrial application -- 3.4.4 Economics -- 3.4.4.1 Cost of electricity generation -- Capital cost -- Operating cost -- Fuel cost -- Power generation cost -- 3.4.4.2 Cost of hydrogen production -- 3.4.4.3 Cost of desalination cogeneration -- 3.5 Summary -- Acronyms -- References -- 4 - Gas-cooled fast reactors -- 4.1 Rationale and generational research and development bridge -- 4.2 Gas-cooled fast reactor technology -- 4.3 Conclusions -- References -- 5 - Sodium-cooled fast reactor -- 5.1 Introduction -- 5.2 Development history -- 5.3 System characteristics -- 5.3.1 Design features with sodium properties -- 5.3.2 Core configurations -- 5.3.3 Plant system -- 5.3.4 Loop type and pool type -- 5.3.5 Consistency with fuel cycle system (fuel cycle technology) -- 5.4 Safety issues -- 5.4.1 Safety design criteria and safety design guidelines -- 5.4.2 Safety characteristics and safety design -- 5.4.2.1 Reactor shutdown -- 5.4.2.2 Decay heat removal -- 5.4.2.3 Design measure against sodium chemical reactions -- 5.4.2.4 Containment measures -- 5.5 Future trends and key challenges -- References -- 6 - Lead-cooled fast reactor -- 6.1 Overview and motivation for lead-cooled fast reactor systems -- 6.2 Basic design choices -- 6.2.1 Lead versus LBE -- 6.2.2 Design choices for reactors with lead as the coolant -- 6.2.3 Primary system concept: evolution and challenges -- 6.2.3.1 Early conceptual designs derived from sodium-cooled fast reactor concepts -- 6.2.3.2 Primary system development and current conceptual designs -- 6.3 Safety principles -- 6.4 Fuel technology and fuel cycles for the lead-cooled fast reactor -- 6.4.1 Fuel assembly characteristics -- 6.4.2 Fuel cycle for the lead-cooled fast reactor -- 6.5 Summary of advantages and key challenges of the lead-cooled fast reactor. , 6.5.1 Advantages of the lead-cooled fast reactor -- 6.5.2 Key challenges of the lead-cooled fast reactor -- 6.6 Overview of Generation IV lead-cooled fast reactor designs -- 6.6.1 Reference Generation IV systems -- 6.6.1.1 The European lead-cooled fast reactor -- 6.6.1.2 The BREST-OD-300 reactor -- 6.6.1.3 The Small Secure Transportable Autonomous Reactor -- 6.6.2 Additional Generation IV systems under study or development -- 6.6.2.1 The South Korea URANUS-40 system -- 6.6.2.2 The Chinese CLEAR-I reactor -- 6.6.2.3 The Pb-Bi-Cooled Direct Contact Boiling Water Fast Reactor -- 6.6.2.4 The SVBR-100 (Zrodnikov et al., 2009 -- Toshinsky et al., 2013) -- 6.7 Future trends -- 6.7.1 The LFR-AS-200 -- 6.7.2 Swedish Advanced Lead Reactor -- 6.7.3 Protection from lead corrosion by means of coatings -- Sources of further information -- Nomenclature -- References -- 7 - Molten salt fast reactors -- 7.1 Introduction -- 7.2 The molten salt fast reactor concept -- 7.2.1 Core and system description -- 7.2.2 Transient calculations -- 7.3 Fuel salt chemistry and material issues -- 7.3.1 Overview of the processing schemes -- 7.3.2 Impact of the salt composition on the corrosion of the structural materials -- 7.4 Molten salt fast reactor fuel cycle scenarios -- 7.5 Safety issues -- 7.5.1 Safety approach and risk analysis -- 7.5.2 Liquid-fueled reactor specificities -- 7.5.3 Decay heat removal -- 7.5.4 Preliminary accidental transient identification -- 7.6 Concept viability: issues and demonstration steps -- 7.6.1 Identified limits -- 7.6.2 Progression in safety demonstration and design optimization -- 7.6.3 Presently ongoing laboratory-scale experiments -- 7.6.4 Other research and development activities on molten salt systems -- 7.7 Conclusion and perspectives -- Nomenclature -- Abbreviations and acronyms -- Symbols -- Acknowledgments -- References. , Bibliography web sources -- 8 - Super-critical water-cooled reactors -- 8.1 Introduction -- 8.2 Types of supercritical water-cooled reactor concepts and main system parameters -- 8.3 Example of a pressure vessel concept -- 8.4 Example of a pressure tube concept -- 8.5 Fuel cycle technology -- 8.6 Fuel assembly concept -- 8.6.1 High-performance light water reactor fuel assembly concept -- 8.6.2 Fast reactor fuel assembly concept -- 8.6.3 Canadian SCWR fuel assembly concept -- 8.7 Safety system concept -- 8.7.1 Safety system in a pressure vessel-type supercritical water-cooled reactor concept -- 8.7.2 Safety system in the Canadian SCWR concept -- 8.7.2.1 Containment pool -- 8.7.2.2 Automatic depressurization system -- 8.7.2.3 Gravity-driven core flooding system -- 8.7.2.4 Isolation condensers -- 8.7.2.5 Reserve water pool -- 8.7.2.6 Atmospheric air heat exchangers -- 8.7.2.7 Passive moderator cooling system -- 8.8 Dynamics and control -- 8.9 Start-up -- 8.9.1 Start-up system in a pressure tube-type supercritical water-cooled reactor concept -- 8.10 Stability -- 8.11 Advantages and disadvantages of supercritical water-cooled reactor concepts -- 8.12 Key challenges -- 8.13 Future trends -- Acronyms -- Nomenclature -- References -- Two - Current status of Generation IV activities in selected countries -- 9 - Generation IV: USA -- 9.1 Generation IV program evolution in the United States -- 9.2 Energy market in the United States and the potential role of Generation IV systems: electricity, process heat, and waste ma ... -- 9.3 Electrical grid integration of Generation IV nuclear energy systems in the United States -- 9.4 Industry and utilities interests in Generation IV nuclear energy systems in the United States -- 9.5 Deployment perspectives for Generation IV systems in the United States and deployment schedule -- 9.6 Conclusions -- Abbreviations. , References -- 10 - Euratom research and training program in Generation-IV systems: breakthrough technologies to improve sustainability, s ... -- 10.1 Background: Euratom (nuclear fission research and training) within the Energy Union (European Union energy mix policy) -- 10.2 Generation-I, -II, -III, and -IV of nuclear fission reactors: research, development, and continuous improvement for more th ... -- Short history of Generation-IV (GIF and IAEA/INPRO/approaches) -- 10.3 "Goals for Generation-IV nuclear energy systems" and "technology roadmap" for the six GIF systems (2002 and 2013) -- 10.4 "European sustainable nuclear industrial initiative" and Euratom research and training program in fast neutron reactor systems -- NB: Historical reminder about the "European fast reactor" project (1984-93) -- 10.5 Sustainability (efficient resource utilization and minimization of radioactive waste) -- 10.6 Safety and reliability (maximum safety performance through design, technology, regulation, and culture) -- 10.7 Socioeconomics (economic advantage over other energy sources and better governance structure in energy decision-making process) -- 10.8 Proliferation resistance and physical protection (protection against all kinds of terrorism) -- 10.9 Conclusion: a new way of "developing/teaching science," closer to the end-user needs of the 21-st century (society and indu ... -- Nomenclature -- Appendix: Tentative training scheme for preconceptual Generation-IV design engineers (knowledge, skills, attitudes) -- Outline placeholder -- Abstract -- Bibliographic references: -- A1. Introduction -- A2. Trainees prerequisites -- A3. Knowledge, skills, and attitudes required for a Generation-IV engineer -- A4. Learning outcomes related to knowledge, skills, and attitudes for a Generation-IV engineer -- A4.1 Learning outcomes in the knowledge area (learning to know). , A4.1.1 General knowledge on Generation-IV systems and technology.

Sprache: Englisch

UID:

Umfang: 1 online resource (xxxii, 630 pages) : , illustrations

ISBN: 9781119994046 , 1119994047 , 9781119994053 , 1119994055 , 1119998735 , 9781119998730 , 1119998743 , 9781119998747 , 0470741333 , 9780470741337

Serie: Aerospace Series

Inhalt: "System Health Management with Aerospace Applications is the first reference text in its field. Due to the disparate nature of the technologies involved in Systems Health Management (SHM), no single person can understand all aspects of the discipline; hence this book collates together in one text the state-of-the-art in research and technology. System Health Management with Aerospace Applications is edited by a team of NASA based engineers and consultants, each heading up sections in their own areas of expertise and co-coordinating contributions from leading experts. The six sections include SHM and its Socio-Technical Context, SHM and the System Life Cycle, Analytical Methods, Operations, Subsystems and Systems. Key features: Authored and edited by experts from NASA and leading industry partners Collates together a wealth of information currently unpublished or disseminated throughout journal and conference papers Explains the fundamentals of each sub-discipline introduced, with a comprehensive list of references, enabling the reader to expand their knowledge base with no prior specialist experience required in the disparate areas Features real-life case studies"--

Inhalt: "This book collates together in one text the state-of-the-art in research and technology"--

Anmerkung: Machine generated contents note: About the Editors List of Contributors Foreword Series Editor Preface Preface AcronymsPart One The Socio-technical Context of System Health Management Charles D. Mott1 The Theory of System Health Management Stephen B. Johnson Overview 1.1 Introduction 1.2 Functions, Off-Nominal States, and Causation 1.3 Complexity and Knowledge Limitations 1.4 SHM Mitigation Strategies 1.5 Operational Fault Management Functions 1.6 Mechanisms 1.7 Summary of Principles 1.8 SHM Implementation 1.9 Some Implications 1.10 Conclusion Bibliography2 Multimodal Communication Beverly A. Sauer Overview 2.1 Multimodal Communication in SHM 2.2 Communication Channels 2.3 Learning from Disaster 2.4 Current Communication in the Aerospace Industry 2.5 The Problem of Sense-making in SHM Communication 2.6 The Costs of Faulty Communication 2.7 Implications 2.8 Conclusion Acknowledgments Bibliography3 Highly Reliable Organizations Andrew Wiedlea Overview 3.1 The Study of HROs and Design for Dependability 3.2 Lessons from the Field: HRO Patterns of Behavior 3.3 Dependable Design, Organizational Behavior, and Connections to the HRO Project Bibliography4 Knowledge Management Edward W. Rogers Overview 4.1 Systems as Embedded Knowledge 4.2 KM and Information Technology 4.3 Reliability and Sustainability of Organizational Systems 4.4 Case Study of Building a Learning Organization: Goddard Space Flight Center 4.5 Conclusion Bibliography5 The Business Case for SHM Kirby Keller and James Poblete Overview 5.1 Business Case Processes and Tools 5.2 Metrics to Support the Decision Process 5.3 Factors to Consider in Developing an Enterprise Model 5.4 Evaluation of Alternatives 5.5 Modifications in Selected Baseline Model 5.6 Modeling Risk and Uncertainty 5.7 Model Verification and Validation 5.8 Evaluation Results 5.9 Summary and Conclusions BibliographyPart Two SHM and the System Lifecycle Seth S. Kessler6 Health Management Systems Engineering and Integration Timothy J. Wilmering and Charles D. Mott Overview 6.1 Introduction 6.2 Systems Thinking 6.3 Knowledge Management 6.4 Systems Engineering 6.5 Systems Engineering Lifecycle Stages 6.6 Systems Engineering, Dependability, and Health Management 6.7 SHM Lifecycle Stages 6.8 SHM Analysis Models and Tools 6.9 Summary Acknowledgments Bibliography7 Architecture Ryan W. Deal and Seth S. Kessler Overview 7.1 Introduction 7.2 SHM System Architecture Components 7.3 Examples of Power and Data Considerations 7.4 SHM System Architecture Characteristics 7.5 SHM System Architecture Advanced Concepts 7.6 Summary Bibliography8 System Design and Analysis Methods Irem Y. Tumer Overview 8.1 Introduction 8.2 Lifecycle Considerations 8.3 Design Methods and Practices for Effective SHM 8.4 Summary Acknowledgments Bibliography9 Assessing and Maturing Technology Readiness Levels Ryan M. Mackey Overview 9.1 Introduction 9.2 Motivating Maturity Assessment 9.3 Review of Technology Readiness Levels 9.4 Special Needs of SHM 9.5 Mitigation Approaches 9.6 TRLs for SHM 9.7 A Sample Maturation Effort 9.8 Summary Bibliography10 Verification and Validation Lawrence Z. Markosian, Martin S. Feather, and David E. Brinza Overview 10.1 Introduction 10.2 Existing Software V & V 10.3 Feasibility and Sufficiency of Existing Software V & V Practices for SHM. , Note continued: 17.2.2. Trend-Based Evolutionary Approaches -- 17.2.3. Data-Driven Approaches -- 17.2.4. Particle Filtering -- 17.2.5. Physics-Based Modeling Approaches -- 17.3. Prognosis RUL Probability Density Function -- 17.4. Adaptive Prognosis -- 17.5. Performance Metrics -- 17.5.1. Accuracy -- 17.5.2. Precision -- 17.5.3. Convergence -- 17.6. Distributed Prognosis System Architecture -- 17.7. Conclusion -- Bibliography -- pt. Four OPERATIONS / Karl M. Reichard -- 18. Quality Assurance / Brian K. Hughitt -- Overview -- 18.1. NASA QA Policy Requirements -- 18.2. Quality System Criteria -- 18.3. Quality Clauses -- 18.4. Workmanship Standards -- 18.5. Government Contract Quality Assurance -- 18.6. Government Mandatory Inspection Points -- 18.7. Quality System Audit -- 18.8. Conclusion -- Bibliography -- 19. Maintainability: Theory and Practice / Gary O'Neill -- Overview -- 19.1. Definitions of Reliability and Maintainability -- 19.2. Reliability and Maintainability Engineering -- 19.3. The Practice of Maintainability -- 19.4. Improving R & M Measures -- 19.5. Conclusion -- Bibliography -- 20. Human Factors / Lilly Spirkovska -- Overview -- 20.1. Background -- 20.2. Fault Management on Next-Generation Spacecraft -- 20.3. Integrated Fault Management Automation Today -- 20.4. Human-Automation Teaming for Real-Time FM -- 20.4.1. Human-Machine Functional Allocation -- 20.4.2. Ensuring Crew Visibility in Automated Activities -- 20.4.3. Providing Crew Insight on System Summary Displays -- 20.5. Operations Concepts for Crew-Automation Teaming -- 20.6. Empirical Testing and Evaluation -- 20.7. Future Steps -- 20.8. Conclusion -- Bibliography -- 21. Launch Operations / Barbara L. Brown -- Overview -- 21.1. Introduction to Launch Site Operations -- 21.2. Human-Centered Health Management -- 21.2.1. Space Shuttle Turnaround Operations -- 21.2.2. International Space Station (ISS) Element Integrated Testing -- 21.2.3. Launch Pad Operations -- 21.2.4. Launch Countdown -- 21.2.5. Expendable Launch Vehicle Processing -- 21.3. SHM -- 21.3.1. Sensing -- 21.3.2. Integrated Data Environment -- 21.3.3. Configuration Data Automation -- 21.4. LS Abort and Emergency Egress -- 21.5. Future Trends Post Space Shuttle -- 21.6. Conclusion -- Bibliography -- 22. Fault Management Techniques in Human Spaceflight Operations / Alan Crocker -- Overview -- 22.1. The Flight Operations Team -- 22.2. System Architecture Implications -- 22.3. Operations Products, Processes and Techniques -- 22.4. Lessons Learned from Space Shuttle and ISS Experience -- 22.5. Conclusion -- Bibliography -- 23. Military Logistics / Karl M. Reichard -- Overview -- 23.1. Focused Logistics -- 23.2. USMC AL -- 23.3. Benefits and Impact of SHM on Military Operations and Logistics -- 23.4. Demonstrating the Value of SHM in Military Operations and Logistics -- 23.5. Conclusion -- Bibliography -- pt. Five Subsystem Health Management / Philip A. Scandura, Jr. -- 24. Aircraft Propulsion Health Management / Bruce Wood -- Overview -- 24.1. Introduction -- 24.2. Basic Principles -- 24.2.1. Module Performance Analysis -- 24.2.2. Engine Health Tracking -- 24.3. Engine-Hosted Health Management -- 24.3.1. Sensors -- 24.3.2. Engine Gas Path -- 24.4. Operating Conditions -- 24.4.1. Actuation -- 24.4.2. Mechanical Components -- 24.4.3. Vibration -- 24.4.4. Lubrication System -- 24.4.5. Turbo-machinery -- 24.4.6. Direct Blade Measures -- 24.4.7. Future -- 24.5.Computing Host -- 24.6. Software -- 24.6.1. FADEC Codes -- 24.6.2. Anomaly Detection -- 24.6.3. Information Fusion -- 24.6.4. Fault Isolation -- 24.7. On-Board Models -- 24.8.Component Life Usage Estimation -- 24.8.1. Traditional Component Lifing Methods -- 24.8.2. Advanced Component Life Usage Tracking -- 24.9. Design of an Engine Health Management System -- 24.9.1. Safety -- 24.9.2. Lifecycle Cost -- 24.10. Supporting a Layered Approach -- 24.11. Conclusion -- Bibliography -- 25. Intelligent Sensors for Health Management / Todd Hong -- Overview -- 25.1. Introduction -- 25.2. Sensor Technology Approaches -- 25.2.1. Ease of Application -- 25.2.2. Reliability -- 25.2.3. Redundancy and Cross-correlation -- 25.2.4. Orthogonality -- 25.3. Sensor System Development -- 25.3.1. Smart Sensors -- 25.3.2."Lick and Stick" Leak Sensor Technology -- 25.4. Supporting Technologies: High-Temperature Applications Example -- 25.5. Test Instrumentation and Non-destructive Evaluation (NDE) -- 25.6. Transition of Sensor Systems to Flight -- 25.6.1. Performance Considerations -- 25.6.2. Physical Considerations -- 25.6.3. Environmental Considerations -- 25.6.4. Safety and Reliability Considerations -- 25.7. Supporting a Layered Approach -- 25.8. Conclusion -- Acknowledgments -- Bibliography -- 26. Structural Health Monitoring / Yujun Kim -- Overview -- 26.1. Introduction -- 26.2. Proposed Framework -- 26.2.1. Impact Monitoring -- 26.2.2. Detection of Bolt Loosening in the TPS -- 26.2.3. Design of Built-In Structural Health Monitoring System -- 26.3. Supporting a Layered Approach -- 26.4. Conclusion -- Acknowledgments -- Bibliography -- 27. Electrical Power Health Management / Amy Chicatelli -- Overview -- 27.1. Introduction -- 27.2. Summary of Major EPS Components and their Failure Modes -- 27.2.1. Solar Arrays -- 27.2.2. Fuel Cells -- 27.2.3. Batteries -- 27.2.4. Flywheel Energy Storage -- 27.2.5. PMAD -- 27.3. Review of Current Power System HM -- 27.3.1. Hubble Space Telescope (HST) -- 27.3.2. International Space Station (ISS) -- 27.3.3. Space Shuttle -- 27.3.4. Aeronautics -- 27.4. Future Power SHM -- 27.4.1. Design Considerations -- 27.5. Supporting a Layered Approach -- 27.6. Conclusion -- Bibliography -- 28. Avionics Health Management / Edmund C. Baroth -- Overview -- 28.1. Avionics Description -- 28.1.1. Avionics Components -- 28.1.2. Avionics Architectures -- 28.1.3. Avionics Technology -- 28.2. Electrical, Electronic and Electromechanical (EEE) Parts Qualification -- 28.2.1.Commercial Grade -- 28.2.2. Industrial Grade -- 28.2.3. Military Grade -- 28.2.4. Space Grade -- 28.3. Environments -- 28.3.1. Environmental Parameters -- 28.4. Failure Sources -- 28.4.1. Design Faults -- 28.4.2. Material Defects -- 28.4.3. Fabrication Faults -- 28.5. Current Avionics Health Management Techniques -- 28.5.1. Scan Design/Built-In Self-test (BIST) -- 28.5.2. Error Detection and Correction (EDAC) -- 28.5.3. Boundary Scan -- 28.5.4. Voting -- 28.5.5. Idle Data Pattern Diagnosis -- 28.5.6. Input Protection -- 28.5.7. Module Test and Maintenance (MTM) Bus -- 28.5.8. Intelligent Sensors and Actuators -- 28.5.9. Avionics Systems -- 28.6. Avionics Health Management Requirements -- 28.6.1. Prognostic Health Management and Recovery -- 28.6.2. Anomaly and Failure Detection -- 28.6.3. Recovery -- 28.7. Supporting a Layered Approach -- 28.8. Conclusion -- Bibliography -- 29. Failure-Tolerant Architectures for Health Management / Priya Narasimhan -- Overview -- 29.1. Introduction -- 29.2. System Failure Response Stages -- 29.3. System-Level Approaches to Reliability -- 29.4. Failure-Tolerant Software Architectures for Space Missions -- 29.4.1. Generic Spacecraft -- 29.4.2. Defense Meteorological Satellite Program (DMSP) -- 29.4.3. Mars Pathfinder -- 29.5. Failure-Tolerant Software Architectures for Commercial Aviation Systems -- 29.5.1. Generic Aviation System -- 29.5.2. Airbus A330/A340/A380 -- 29.5.3. Boeing 777 -- 29.6. Observations and Trends -- 29.6.1.Commercial Off-the-Shelf Components -- 29.6.2."By-Wire" Software Control and Autonomy -- 29.6.3. Escalating Fault Sources and Evolving Redundancy -- 29.6.4. Domain-Specific Observations -- 29.7. Supporting a Layered Approach -- 29.8. Conclusion -- Acknowledgments -- Bibliography -- 30. Flight Control Health Management / Douglas J. Zimpfer -- Overview -- 30.1.A FC Perspective on System Health Management -- 30.1.1.Commercial Passenger Aircraft -- 30.1.2. Unmanned Aerial Vehicle -- 30.1.3. Spacecraft -- 30.1.4. Reusable Space Exploration Vehicle -- 30.2. , Elements of the FC System -- 30.3. FC Sensor and Actuator HM -- 30.3.1. Sensor HM -- 30.3.2. Actuator HM -- 30.4. FC/Flight Dynamics HM -- 30.4.1. Navigation HM -- 30.4.2. Guidance HM -- 30.4.3. Control HM -- 30.5. FC HM Benefits -- 30.6. Supporting a Layered Approach -- 30.7. Conclusion -- Bibliography -- 31. Life Support Health Management / Eric-Jan Manders -- Overview -- 31.1. Introduction -- 31.1.1. Life Support Systems -- 31.2. Modeling -- 31.2.1. Physics-Based Modeling -- 31.2.2. Resource-Based Modeling -- 31.3. System Architecture -- 31.3.1. Behavior Monitors and Diagnoser -- 31.3.2. Failure-Adaptive Controller -- 31.3.3. Supervisory Controller -- 31.3.4. Resource Monitors -- 31.3.5. Planner and Scheduler -- 31.4. Future NASA Life Support Applications -- 31.4.1. Crew Exploration Vehicle -- 31.4.2. Lunar Habitats -- 31.4.3. Martian Habitats -- 31.5. Supporting a Layered Approach -- 31.6. Conclusion -- Bibliography -- 32. Software / Philip A. Scandura, Jr. -- Overview -- 32.1. Sampling of Accidents Attributed to Software Failures -- 32.2. Current Practice -- 32.2.1. Multi-Version Software -- 32.2.2. Recovery Block -- 32.2.3. Exception Handling -- 32.2.4. Data Capture Methods -- 32.3. Challenges -- 32.4. Supporting a Layered Approach -- 32.5. Conclusion -- Bibliography -- pt. Six SYSTEM APPLICATIONS / Thomas J. Gormley. , Note continued: 33. Launch Vehicle Health Management / Thomas J. Gormley -- Overview -- 33.1. Introduction -- 33.2. LVSHM Functionality and Scope -- 33.3. LV Terminology and Operations -- 33.4. LV Reliability Lessons Learned -- 33.5. LV Segment Requirements and Architecture -- 33.6. LVSHM Analysis and Design -- 33.6.1. LVSHM Analysis Process Overview -- 33.6.2. On-Vehicle LVSHM Design -- 33.6.3. On-Ground LVSHM Design -- 33.7. LV LVSHM System Descriptions -- 33.7.1. Evolved Expendable Launch Vehicle LVSHM -- 33.7.2. NASA Space Transportation System LVSHM -- 33.7.3. Advanced Reusable Launch Vehicle LVSHM Test Programs -- 33.8. LVSHM Future System Requirements -- 33.8.1. RLVs and Operationally Responsive Spacelift -- 33.8.2. Human-Rated Launch Vehicles -- 33.8.3. Allocation of LVSHM Functionality -- 33.8.4. Redundancy, Fault Tolerance, and Human Rating -- 33.9. Conclusion -- Bibliography. 34. Robotic Spacecraft Health Management / Paula S. Morgan -- Overview -- 34.1. Introduction -- 34.2. Spacecraft Health and Integrity Concerns for Deep-Space Missions -- 34.3. Spacecraft SHM Implementation Approaches -- 34.4. Standard FP Implementation -- 34.5. Robotic Spacecraft SHM Allocations -- 34.6. Spacecraft SHM Ground Rules and Requirements -- 34.7. SFP and SIFP Architectures -- 34.7.1. FP Monitor Structure -- 34.7.2. Example of Standard FP Application: Command Loss -- 34.7.3. Example of Standard FP Application: Under-voltage Trip -- 34.8. Conclusion -- Bibliography -- 35. Tactical Missile Health Management / Stephen A. Marotta -- Overview -- 35.1. Introduction -- 35.2. Stockpile Surveillance Findings -- 35.3. Probabilistic Prognostics Modeling -- 35.3.1. Stress and Strength Interference Method -- 35.3.2. Cumulative Damage Function Method -- 35.3.3. Weibull Service Life Prediction Method -- 35.4. Conclusion -- Bibliography -- 36. Strategic Missile Health Management / Gregory A. Ruderman -- Overview -- 36.1. Introduction -- 36.2. Fundamentals of Solid Rocket Motors -- 36.3. Motor Components -- 36.3.1. Cases -- 36.3.2. Propellant-Liner-Insulator System -- 36.4. Challenges for Strategic Rocket Health Management -- 36.4.1. Material Property Variation -- 36.4.2. Material Aging -- 36.4.3. Defects -- 36.5. State of the Art for Solid Rocket System Health Management (SHM) -- 36.5.1. State of the Art for Deployed SHM Systems -- 36.5.2. State of the Art in Laboratory SHM Demonstrations -- 36.6. Current Challenges Facing SRM SHM -- 36.6.1. SRM SHM Data Acquisition, Storage and Analysis -- 36.6.2. System Longevity and Reliability -- 36.6.3. Lack of Service Life Sensors -- 36.6.4. Business Case -- 36.7. Conclusion -- Bibliography -- 37. Rotorcraft Health Management / James J. Zakrajsek -- Overview -- 37.1. Introduction -- 37.2. Rotorcraft System Health Management Standard Practices -- 37.3. New Practices -- 37.4. Lessons Learned -- 37.5. Future Challenges -- 37.6. Conclusion -- Bibliography -- 38.Commercial Aviation Health Management / Gary Bird -- Overview -- 38.1.Commercial Aviation Challenge -- 38.2. Layered Approach to SHM -- 38.3. Evolution of Commercial Aviation SHM -- 38.3.1. First-Generation Systems -- 38.3.2. Second-Generation Systems -- 38.3.3. Third-Generation Systems -- 38.3.4. Fourth-Generation Systems -- 38.4.Commercial State of the Art -- 38.4.1. Primus Epic CMC -- 38.4.2. Boeing 787 Crew Information System/Maintenance System -- 38.5. The Next Generation: Intelligent Vehicles/Sense and Respond -- 38.5.1. Enabling the Shift to Sense and Respond Network-centric Operations -- 38.5.2. Barriers to Adoption -- 38.5.3. Next Steps -- 38.6. Conclusion -- Bibliography.

Weitere Ausg.: Print version: System health management. Hoboken, N.J. : Wiley, 2011 ISBN 9780470741337

Sprache: Englisch

Schlagwort(e): Electronic books. ; Electronic books. ; Electronic books.

URL: https://onlinelibrary.wiley.com/doi/book/10.1002/9781119994053

URL: https://onlinelibrary.wiley.com/doi/book/10.1002/9781119994053

URL: https://onlinelibrary.wiley.com/doi/book/10.1002/9781119994053