Nuclear Engineering Division | |||
Session 393 - Hydrogen Production Process Design and Economics | |||
Water can be split to make hydrogen by using heat from a high-temperature nuclear reactor to drive various hydrogen production processes such as thermochemical and hybrid cycles, and high temperature electrolysis. Hydrogen can also be produced by reforming biomass and wastes, by photochemical, biological and solar water-splitting, and by more conventional means. This session invites papers discussing the plant design, system analysis, economics, and infrastructure issues of hydrogen production. Analysis of plant efficiency and process modeling of hydrogen production processes (with emphasis on overall plant system performance) may also be included | |||
Chair: | William A. Summers | ||
Cochairs: | Benjamin E. Russ Maximilian B. Gorensek | ||
393a | Consistent Economic Analysis of Hydrogen Production Pathways Margaret K. Mann, Johanna I. Levene, Todd G. Ramsden | ||
393b | Plant Design and Cost Analysis of a Prototype Commercial Nuclear Hydrogen Production Plant William A. Summers, Edward T. Danko, Melvin R. Buckner, Maximilian B. Gorensek | ||
393c | First Order Approximation of Hydrogen Delivery System Costs Howard B. J. Stone, Ivo J.S. Veldhuis | ||
393d | Innovative Nuclear Process Heat Applications for near-Term Hydrogen Production Charles O. Bolthrunis, Reiner W. Kuhr | ||
393e | A Low-Greenhouse-Impact Hydrogen-Based Liquid-Fuels Future Edward J. Lahoda, Charles W. Forsberg, David F. McLaughlin | ||
393f | Economic Implications of Peak Vs. Base Load Electricity Costs on Nuclear Hydrogen Systems Charles W. Forsberg |
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