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Library | Item Barcode | Call Number | Material Type | Item Category 1 | Status |
|---|---|---|---|---|---|
Searching... | 30000010242732 | TP359.H8 H935 2013 | Open Access Book | Book | Searching... |
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Summary
Summary
With contributions from noted laboratory scientists, professors, and engineers, Hydrogen Energy and Vehicle Systems presents a new comprehensive approach for applying hydrogen-based technologies to the transportation and electric power generation sectors. It shows how these technologies can improve the efficiency and reliability of energy and transportation systems.
The book's interdisciplinary approach to sustainable energy systems disproves common misconceptions regarding hydrogen technologies and demonstrates that hydrogen technologies are a viable part of a sustainable, stable, and secure energy infrastructure. The book discusses intelligent energy management schemes for hydrogen energy and vehicle systems, safety and environmental science related to hydrogen technologies, and the infrastructure required for safe, renewable hydrogen options.
A clear and up-to-date resource on hydrogen systems, this work provides a balanced presentation of theoretical/technical and application aspects of hydrogen technologies. It presents all stakeholder perspectives and connects hydrogen technology through proper systems analysis and integration, covering both quantitative and qualitative factors.
Author Notes
Scott E. Grasman is a professor and department head of Industrial and Systems Engineering at Rochester Institute of Technology. Dr. Grasman is the author/coauthor of over 100 technical papers and is a reviewer/editorial member of various journals and books. His primary research interests relate to the application of quantitative models, focusing on the design and development of supply chain and logistics networks.
Table of Contents
| Series Preface | p. vii |
| Foreword | p. ix |
| Preface | p. xi |
| Aknowledgments | p. xvii |
| About the Editor | p. xix |
| About the Contributors | p. xxi |
| Section I Hydrogen Energy and Fuel Cell Modeling | |
| 1 Hydrogen and Electricity: Parallels, Interactions, and Convergence | p. 1 |
| 2 Hydrogen Infrastructure: Production, Storage, and Transportation | p. 23 |
| 3 PEM Fuel Cell Basics and Computational Modeling | p. 45 |
| 4 Dynamic Modeling and Control of PEM Fuel Cell Systems | p. 79 |
| Section II Market Transformation and Applications | |
| 5 Market Transformation Lessons for Hydrogen from the Early History of the Manufactured Gas Industry | p. 123 |
| 6 Fuel Cell Technology Demonstrations and Data Analysis | p. 159 |
| 7 Producing Hydrogen for Vehicles via Fuel Cell-Based Combined Heat, Hydrogen, and Power: Factors Affecting Energy Use, Greenhouse Gas Emissions, and Cost | p. 183 |
| 8 Hybrid and Plug-In Hybrid Electric Vehicles | p. 225 |
| 9 Hydrogen as Energy Storage to Increase Wind Energy Penetration into Power Grid | p. 247 |
| 10 Hydrogen Design Case Studies | p. 273 |
| Section III Hydrogen Safety | |
| 11 Hydrogen Safety | p. 297 |
| 12 Hydrogen Fuel Cell Vehicle Regulations, Codes, and Standards | p. 311 |
| Index | p. 325 |
