Download Free Materials Technology In Steam Reforming Processes Book in PDF and EPUB Free Download. You can read online Materials Technology In Steam Reforming Processes and write the review.

Materials Technology in Steam Reforming Processes is a collection of papers that covers advancement in the various areas of studies in steam reforming processes. The title presents the studies of authors who are involved in the development of a particular process. The coverage of the text includes the fundamental aspects of the creep deformation of metals; factors affecting choice of materials and design of units for pressure steam reforming; and the research background of the thermalloy grades of chromium-nickel-iron heat-resisting alloys. The selection also covers corrosion problems on finned air-cooled heat exchanger tubing; and thermal insulation for steam-reforming plants. The book will be of great use to scientists, engineers, and technicians involved in materials science.
This volume constitutes the Proceedings of the November 7-9, 1977 Conference on PROCESSING OF CRYSTALLINE CERAMICS, held at North Carolina State University in Raleigh. It was the Fourteenth in a series of "University Conferences on Ceramic Science" initiated in 1964 and still coordinated by a founding group of four ceramic related institutions, of which North Carolina State University is a charter member, along with the University of California at Berkeley, Notre Dame University, and the New York State College of Ceramics at Alfred University. In addition, two other ceramic-oriented schools, the University of Florida and Case-Western Reserve University, have also hosted Conferences in the series. These research-oriented conferences, each uniquely concerned with a timely ceramic theme, have been well attended by audiences which typically were both inter national and interdisciplinary in character; their published Proceedings have been well received and are frequently cited. This three day conference was concerned with (a) scientific aspects of all process steps which must be combined and controlled effectively and sequentially in producing crystalline ceramics (both oxides and nonoxides), and (b) utilization of these principles in developing processes for several classes of advanced ceramics critical to present and future technology.
Authored by 50 top academic, government and industry researchers, this handbook explores mature, evolving technologies for a clean, economically viable alternative to non-renewable energy. In so doing, it also discusses such broader topics as the environmental impact, education, safety and regulatory developments. The text is all-encompassing, covering a wide range that includes hydrogen as an energy carrier, hydrogen for storage of renewable energy, and incorporating hydrogen technologies into existing technologies.
Since fossil fuels suffer from dangerous side effects for the environment and their resources are limited, bioenergy attracted many attentions in various aspects as an alternative solution. Therefore, increasing number of researches are conducted every year and the processes updated frequently to make them more economic and industrially beneficial. Advances in Bioenergy and Microfluidic Applications reviews recent developments in this field and covers various advanced bio-applications, which rarely are reviewed elsewhere. The chapters are started from converting biomass to valuable products and continues with applications of biomass in water-treatment, novel sorbents and membranes, refineries, microfluidic devices and etc. The book covers various routes for gaining bioenergy from biomass. Their composition, carbon contents, heat production capacities and other important factors are reviewed in details in different chapters. Then, the processes for upgrading them directly and indirectly (using metabolic engineering and ultrasonic devices) to various fuels are explained. Each process is reviewed both technically and economically and the product analysis is given. Besides, the effect of various catalysts on increasing selectivity and productivity are taken into account. Biofuels are compared with fossil fuels and challenges in the way of bioenergy production are explained. Moreover, advanced bio-applications in membranes, adsorption, waste water treatment, microfluidic devices and etc. are introduced. This book provides a good insight about such bioprocesses and microfluidics devices for researchers, students, professors and related departments and industries that care about energy resources and curious about recent advances in related methods and technologies. Despite other books which review biomass chemistry and conversion, the current book emphasize on the application of biomass in the mentioned areas. Therefore, one can gain a better and more comprehensive insight by reading the book. - Describes energy production from biomass, biomass conversion, their advantages and limitations - Describes the application of biomass in membranes, sorbents, water-treatment, refineries, and microfluidic devices - Offers a future outlook of bioenergy production and possibility to apply in the industries
This useful, one-stop resource for understanding the most important issues in materials challenges in alternative and renewable energy. The logically organized and carefully selected articles give insight into materials challenges in alternative renewable energy and incorporate the latest developments related to materials challenges in alternative renewable energy, including hydrogen, batteries and energy storage materials, hydropower, and biomass.
Provides a comprehensive practical review of the new technologies used to obtain hydrogen more efficiently via catalytic, electrochemical, bio- and photohydrogen production. Hydrogen has been gaining more attention in both transportation and stationary power applications. Fuel cell-powered cars are on the roads and the automotive industry is demanding feasible and efficient technologies to produce hydrogen. The principles and methods described herein lead to reasonable mitigation of the great majority of problems associated with hydrogen production technologies. The chapters in this book are written by distinguished authors who have extensive experience in their fields, and readers will have a chance to compare the fundamental production techniques and learn about the pros and cons of these technologies. The book is organized into three parts. Part I shows the catalytic and electrochemical principles involved in hydrogen production technologies. Part II addresses hydrogen production from electrochemically active bacteria (EAB) by decomposing organic compound into hydrogen in microbial electrolysis cells (MECs). The final part of the book is concerned with photohydrogen generation. Recent developments in the area of semiconductor-based nanomaterials, specifically semiconductor oxides, nitrides and metal free semiconductor-based nanomaterials for photocatalytic hydrogen production are extensively discussed.
Much has been written about fundamental aspects of catalysis, yet despite their universal applications details concerning commercial catalysts and information about actual operating conditions are not readily available. This book provides up-to-date reviews and references to guide those working on industrial catalysts. It will be an invaluable guide for catalysis researchers in industry and academia, and for students.
High Temperature Vapors: Science and Technology focuses on the relationship of the basic science of high-temperature vapors to some areas of discernible practical importance in modern science and technology. The major high-temperature problem areas selected for discussion include chemical vapor transport and deposition; the vapor phase aspects of corrosion, combustion, and energy systems; and extraterrestrial high-temperature species. This book is comprised of seven chapters and begins with an introduction to the nature of the high-temperature vapor state, the scope and literature of high-temperature vapor-phase chemistry, and the role of high-temperature vapors in materials science. The discussion then turns to gas-solid reactions with vapor products; chemical vapor transport and deposition; vapor-phase aspects of corrosion at high temperature; and flames and combustion. High-temperature vapor-phase processes associated with gas turbine systems are also considered. The final chapter is devoted to the chemistry of high-temperature species in space. This monograph should serve as a valuable reference for undergraduate and graduate students, as well as scientists in fields such as chemistry, physics, materials science, and metallurgy.