Download e-book for kindle: Hydrogen energy and vehicle systems by Scott E. Grasman
By Scott E. Grasman
With contributions from famous laboratory scientists, professors, and engineers, Hydrogen power and motor vehicle platforms presents a brand new accomplished strategy for using hydrogen-based applied sciences to the transportation and electrical strength iteration sectors. It exhibits how those applied sciences can increase the potency and reliability of power and transportation systems.
The book’s interdisciplinary method of sustainable power structures disproves universal misconceptions concerning hydrogen applied sciences and demonstrates that hydrogen applied sciences are a potential a part of a sustainable, good, and safe power infrastructure. The e-book discusses clever power administration schemes for hydrogen strength and automobile platforms, safeguard and environmental technology with regards to hydrogen applied sciences, and the infrastructure required for secure, renewable hydrogen options.
A transparent and up to date source on hydrogen platforms, this paintings offers a balanced presentation of theoretical/technical and alertness facets of hydrogen applied sciences. It offers all stakeholder views and connects hydrogen expertise via right platforms research and integration, masking either quantitative and qualitative components.
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Additional resources for Hydrogen energy and vehicle systems
With current energy carriers, there is little opportunity to convert between various forms. In addition, the widespread use and supporting infrastructure for these dual energy carriers may provide reliability benefits for consumers. 2 presents two different views of the hydrogen reactions in a fuel cell and electrolyzer. The “electrochemical” view shows the fuel cell reaction (on the right) that produces electricity when hydrogen and oxygen combine to form water and the electrolysis reaction (on the left) where electricity is required as an input to split water into hydrogen and oxygen.
References 1. DOE. (2002). National Hydrogen Energy Roadmap. Department of Energy: Washington DC. p. 50. 2. DOE. (2005). Hydrogen, Fuel Cells & Infrastructure Technologies Program: MultiYear Research, Development and Demonstration Plan: Planned Program Activities for 2004–2015. Department of Energy: Washington DC. 3. M. (1999). Prospects for Building a Hydrogen Energy Infrastructure. Annu. Rev. Energy Environ. 24: 227–279. 4. , et al. (2005). Technical and Economic Assessment of Transition Strategies Toward Widespread Use of Hydrogen as an Energy Carrier.
2005). Energyplexes for the 21st Century: Coal Gasification for Co-producing Hydrogen, Electricity and Liquid Fuels. Energy 30: 2453–2473. 18. M. Ogden. (2007). Co-production of H2 and Electricity. UC Davis: Davis, CA. p. 22. 19. , et al. (2005). Co-production of Hydrogen, Electricity and CO2 from Coal with Commercially Ready Technology, Part A: Performance and Emissions. International Journal of Hydrogen Energy 30: 747–767. 20. , et al. (2005). Co-production of Hydrogen, Electricity and CO2 from Coal with Commercially Ready Technology.
Hydrogen energy and vehicle systems by Scott E. Grasman