Berlin, Heidelberg : , : Springer Berlin Heidelberg : , : Imprint : Springer, , 2017

3-662-52775-8

1 online resource (XX, 572 S.)

Springer-Lehrbuch, , 0937-7433

616.025

Emergency medicine

Emergency Medicine

Tedesco

Basis der Notfallmedizin -- Diagnostik und Überwachung in der Notfallmedizin -- Grundlegende notfallmedizinische Maßnahmen -- Atemwegssicherung, Intubation und Beatmung -- Venöser Zugang -- Notfallmedikamente und Infusionslösungen -- Kardiopulmonale Reanimation (CPR) -- Störungen der Vitalfunktionen -- Schock und Schockformen -- Herzrhythmusstörungen -- Spezielle kardiozirkulatorische und respiratorische Notfälle -- Gastrointestinale und abdominale Notfälle -- Notfälle durch Störung des Inneren Milieus -- Zerebrale Notfälle -- Notfälle im Kindesalter -- Notfälle in Zusammenhang mit Schwangerschaft und Geburt -- Spezielle Notfälle und Blutungen -- Traumatologische Notfälle -- Spezielle Unfälle und Verletzungen -- Toxikologische Notfälle -- Klinische Fälle -- Anhang.

Dieses Lehrbuch bietet Ihnen einen vollständigen Überblick über alle prüfungsrelevanten Inhalte der Notfallmedizin. Es leitet Sie leicht verständlich von den Grundlagen bis zur Praxis durch das gesamte Wissen. Profitieren Sie von der langjährigen Erfahrung des Autors, der sorgfältig das Wesentliche für Sie ausgewählt und aufbereitet hat. Der Inhalt Diese aktualisierte Neuauflage berücksichtigt die Leitlinien des European Resuscitation Council 2015. Zahlreiche Abbildungen und das bewährte didaktische Konzept ermöglichen ein effizientes Lernen: Prüfungsteil – Für eine optimale Vorbereitung auf Fallstudien Cave- und Merksätze – Bringen das Wichtigste auf den Punkt Praxistipps – Stellen einen anschaulichen Bezug zur Notfallpraxis her Der Autor Dr. Thomas

Ziegenfuß ist Chefarzt der Abteilung für Anästhesie und Intensivmedizin des St. Josef-Krankenhauses in Moers. An der Klinik für Anästhesiologie und Intensivmedizin der Universitätskliniken des Saarlandes war er Oberarzt, langjähriger Einsatzleiter für den Notarztdienst und Leitender Notarzt.

Newark : , : John Wiley & Sons, Incorporated, , 2024

©2024

9781394204564

1394204566

9781394204557

1394204558

1 online resource (272 pages)

LuqmanMohammad

621.312136

Wind power

Energy storage

Inglese

Cover -- Series Page -- Title Page -- Copyright Page -- Contents -- Preface -- Chapter 1 Wind Energy: From Past to Present Technology -- 1.1 Introduction -- 1.2 Historical Background -- 1.3 Use of Wind Energy in Specific Countries -- 1.4 Wind Technology -- 1.4.1  Wind Energy Conversion System (WECS) -- 1.4.2  Electric Generator -- 1.4.3  Evolution of Power Electronics -- 1.4.4  Energy Storage Technology -- 1.5 Horizontal-Axis Wind Turbines (HAWTs) -- 1.5.1  History -- 1.5.2  Design -- 1.5.3  Components -- 1.5.4  Working Principle -- 1.5.5  Applications -- 1.6 Vertical Axis Wind Turbine (VAWT) -- 1.6.1  Working Principle -- 1.7 Current Technologies in Wind Power Generation -- 1.7.1  Buoyant Airborne Turbine (BAT) -- 1.7.2  Offshore Floating Wind Technology -- 1.8 Advantages -- 1.9 Disadvantages of

Wind Energy -- 1.10 Conclusion -- References -- Chapter 2 Environmental Consequences of Wind Energy Technologies -- 2.1 Introduction -- 2.2 Impact of Wind Energy on the Environment -- 2.3 Key Environmental White Paper Issues Related to Wind Power -- 2.4 Individual Effects on Population Impacts -- 2.5 Comprehending the Overall Effects of Wind Power on Wildlife -- 2.6 Considerations for the Environment when Making Choices -- 2.7 Wind Power and Risk Management -- 2.8 Concerns About Using Wind Energy -- 2.9 Conclusion -- References -- Chapter 3 Important Issues and Future Opportunities for Huge Wind Turbines -- 3.1 Introduction -- 3.1.1  Visual Impact -- 3.1.2  Noise -- 3.1.3  Wildlife -- 3.1.4  Intermittent Energy Generation -- 3.2 Worldwide Wind Energy Forecast -- 3.2.1  Canada -- 3.2.2  Russia -- 3.2.3  India -- 3.2.4  United States of America -- 3.2.5  China -- 3.2.6  Germany -- 3.3 Increased Wind Penetrating Techniques -- 3.3.1  Energy Storage Systems -- 3.3.2  Advanced Forecasting Tools -- 3.3.3  Bucket Foundation.

3.3.4  Advantages of Bucket Foundation -- 3.3.5  Limitations of Bucket Foundation -- 3.3.6  Monopile Foundation -- 3.3.7  Jacket Foundation -- 3.3.8  Floating Foundation -- 3.3.9  Tripod Foundation -- 3.4 India's Perspective for Wind Energy -- 3.4.1  Intermittency and Variability -- 3.4.2  Land Acquisition -- 3.4.3  Transmission Constraints -- 3.4.4  Limited Wind Resource Data -- 3.4.5  Financing Constraints -- 3.4.6  Environmental and Social Impacts -- 3.4.7  Policy and Regulatory Uncertainty -- 3.5 Progress of Technology -- 3.5.1  Larger and More Efficient Turbines -- 3.5.2  Advancements in Turbine Design -- 3.5.3  Improvements in Manufacturing and Installation -- 3.6 Conclusion -- References -- Chapter 4 Wind Hybrid Power Technologies -- 4.1 Introduction -- 4.2 Types of Hybrid Power Systems -- 4.3 Wind Hybrid Power Technologies -- 4.3.1  Wind Diesel Hybrid Power Technology -- 4.3.2  Wind Solar Hybrid Power Technology (WSHPT) -- 4.3.3  Wind Hydrogen Hybrid Power Technology (WHHPT) -- 4.3.4  Wind-Hydro Hybrid Power Technology (WHHPT) -- 4.3.5  Wind-Photovoltaic (PV) Hybrid Power Technology -- 4.4 Summary -- References -- Chapter 5 Theories Based on Technological Advances for Wind Energy -- 5.1 Introduction -- 5.2 Theoretical Background -- 5.2.1  Basic Principles of Wind Energy Conversion -- 5.2.2  Aerodynamics of Wind Turbines -- 5.2.3  Control Systems for Wind Turbines -- 5.3 Theories Based on Technological Advances -- 5.3.1  Wind Turbine Design Theory -- 5.3.1.1 Rotor Blade Design Theory -- 5.3.1.2 Aerodynamic Design Theory -- 5.3.2  Power Control Theory -- 5.3.2.1 Maximum Power Point Tracking Theory -- 5.3.2.2 Load Control Theory -- 5.3.3  Wind Farm Layout Theory -- 5.3.3.1 Turbine Placement Theory -- 5.3.3.2 Wake Effect Theory -- 5.3.4  Grid Integration Theory -- 5.3.4.1 Power Quality Theory -- 5.3.4.2 Stability Theory.

5.4 Advancements in Wind Energy Technologies -- 5.5 Future Research Directions -- 5.6 Conclusion -- References -- Chapter 6 Wind Energy Hybrid Power Generation System with Hydrogen Storage -- 6.1 Introduction -- 6.2 Hydrogen Storage Systems -- 6.2.1  Solid-State Hydrogen Storage in Materials -- 6.3 Wind Energy Systems -- 6.4 Wind Energy Hybrid Power Generation System with Hydrogen Storage -- 6.4.1  Design and Optimization of a Wind Energy Hybrid Power Generation System with Hydrogen Storage -- 6.5 Conclusion -- References -- Chapter 7 Technologies Based on Reusable Wind Turbine Blades -- 7.1 Introduction -- 7.2 Wind Power Generation and the Importance of Wind Turbine Blades -- 7.2.1  Global Demand for Clean and Sustainable Energy -- 7.2.2  Role of Wind Turbines in Wind Power Generation -- 7.2.3  Impact of Wind Turbine Blades on Performance

and Viability -- 7.3 Conventional Wind Turbine Blade Materials and Limitations -- 7.3.1  Overview of Conventional Blade Materials -- 7.3.2  Limitations in Terms of Recyclability and Environmental Impact -- 7.4 Advancements in Materials Engineering for Reusable Wind Turbine Blades -- 7.4.1  Composite Materials in Blade Design -- 7.4.2  Bio-Based Resins for Sustainable Blades -- 7.4.3  Additive Manufacturing Techniques for Blade Production -- 7.5 Challenges in Implementing Reusable Blade Technologies -- 7.5.1  Structural Integrity of Reusable Blades -- 7.5.2  Fatigue Resistance and Durability -- 7.5.3  Manufacturing Scalability and Cost-Effectiveness -- 7.6 Implications of Reusable Wind Turbine Blades -- 7.6.1  Cost Reduction and Enhanced Energy Production -- 7.6.2  Environmental Benefits and Reduction of Carbon Emissions -- 7.6.3  Policy Frameworks and Industry Collaboration -- 7.7 Testing, Modeling, and Simulation for Reliable Reusable Blade Designs -- 7.7.1  Importance of Rigorous Testing.

7.7.2  Modeling and Simulation Techniques for Design Optimization -- 7.8 Future Prospects and Research Directions -- 7.8.1  Interdisciplinary Approaches for Sustainable Innovation -- 7.8.2  Collaboration Among Researchers, Engineers, and Stakeholders -- 7.8.3  Potential Directions for Future Research -- 7.9 Conclusion -- References -- Chapter 8 Wind Turbine Assessment: A Step-by-Step Approach -- 8.1 Introduction -- 8.2 Analytic Hierarchy Strategy -- 8.3 Results and Discussion -- 8.4 Conclusions -- References -- Chapter 9 Effect of Aerodynamics on Wind Turbine Design -- 9.1 Introduction -- 9.2 Air Properties Affecting Wind Turbines -- 9.3 Classical Blade Element Momentum Theory -- 9.4 Aerodynamic Performance Testing -- 9.4.1  Wind Tunnel Testing and Field Testing -- 9.4.2  Performance Testing of a Counter-Rotating Wind Turbine System -- 9.5 Effect of Aerodynamics on Wind Turbine Design Parameters -- 9.5.1  Solidity -- 9.5.2  Number of Blades -- 9.5.3  Different Ratios -- 9.5.3.1 Chord/Radius Ratio (c/R) -- 9.5.3.2 Height-to-Radius Ratio (H/R) -- 9.5.3.3 Blade Aspect Ratio (H/c) -- 9.5.4  Pitch -- 9.5.5  Strut Connection Point -- 9.5.6  Blade Reynolds Number (Re) -- 9.5.7  Strut Effects -- 9.5.8  Strut Arrangement -- 9.6 Wind Turbine Loads -- 9.7 Conclusions -- References -- Index -- Also of Interest -- EULA.

This comprehensive volume explores the technological advancements, environmental impacts, and future opportunities in wind energy, focusing on storage and conversion technologies. Edited by Inamuddin, Tariq Altalhi, and Mohammad Luqman, the book covers a range of topics including wind energy conversion systems, hybrid power technologies, and the integration of hydrogen storage. It addresses the environmental and social implications of wind energy, as well as the challenges of implementing reusable wind turbine blades. The book is intended for engineers, researchers, and policymakers interested in sustainable energy solutions, providing insights into the design and optimization of wind energy systems and highlighting future research directions.