https://cmapspublic3.ihmc.us/rid=1N3976C22-12M3P49-9V/Holladay%20et%20al.%20-%202009%20-%20An%20overview%20of%20hydrogen%20production%20technologies.pdf

An overview of hydrogen production technologies

Climate change and fossil fuel depletion are the main reasons leading to hydrogen technology. There are many processes for hydrogen production from both conventional and alternative energy resources such as natural gas, coal, nuclear, biomass, solar and wind. In this work, a comparative overview of the major hydrogen production methods is carried out. The process descriptions along with the technical and economic aspects of 14 different production methods are discussed. An overall comparison is carried out, and the results regarding both the conventional and renewable methods are presented. The thermochemical pyrolysis and gasification are economically viable approaches providing the highest potential to become competitive on a large scale in the near future while conventional methods retain their dominant role in H2 production with costs in the range of 1.34–2.27 $/kg. Biological methods appear to be a promising pathway but further research studies are needed to improve their production rates, while the low conversion efficiencies in combination with the high investment costs are the key restrictions for water-splitting technologies to compete with conventional methods. However, further development of these technologies along with significant innovations concerning H2 storage, transportation and utilization, implies the decrease of the national dependence on fossil fuel imports and green hydrogen will dominate over the traditional energy resources.

A comparative overview of hydrogen production processes

Solar thermochemical production of hydrogen--a review

Potential importance of hydrogen as a future solution to environmental and transportation problems

Review article covering developments in methanol steam reforming in the context of PEM fuel cell power systems. Subjects covered include methanol background, use, and production, comparison to other fuels, power system considerations, militrary requirements, competing technologies, catalyst development, and reactor and system development and demonstration.

Methanol steam reforming for hydrogen production.

Thermochemical hydrogen production: past and present

The potential for public health risks associated with intrusion of contaminants into water supply distribution systems resulting from transient low or negative pressures is assessed. It is shown that transient pressure events occur in distribution systems; that during these negative pressure events pipeline leaks provide a potential portal for entry of groundwater into treated drinking water; and that faecal indicators and culturable human viruses are present in the soil and water exterior to the distribution system. To date, all observed negative pressure events have been related to power outages or other pump shutdowns. Although there are insufficient data to indicate whether pressure transients are a substantial source of risk to water quality in the distribution system, mitigation techniques can be implemented, principally the maintenance of an effective disinfectant residual throughout the distribution system, leak control, redesign of air relief venting, and more rigorous application of existing engineering standards. Use of high-speed pressure data loggers and surge modelling may have some merit, but more research is needed.

/pdf/the-potential-for-health-risks-from-intrusion-of-3e6b52qjsm.pdf

The potential for health risks from intrusion of contaminants into the distribution system from pressure transients

Thermochemical hydrogen production

Thermochemical production of hydrogen via multistage water splitting processes

A variety of normal water distribution system operations will result in pressure fluctuations that can possibly lead to the occurrence of relatively brief (transient) low or negative pressures at various locations of the system, thus creating the potential for backsiphonage or backpressure of non-potable water from external sources into the distribution system, including contaminated water around leaking pipes Extensive pressure monitoring of a single distribution system using seven electronic data loggers for 14 years found only nine occasions when distribution system pressures were less than 138 kPa (20 psi) No negative pressures were observed Evidence showed that most low pressure events were caused by pump shutdowns Distribution system modelling suggested that negative pressures (<0 kPa) were possible when the water treatment plant pumping station lost power The model simulations suggested that protection against low pressures is possible by installing hydro-pneumatic tanks downstream of the pumping stations Modelling results suggested that air/vacuum valves did not offer reliable protection against low pressures in the system

James E. Funk

Papers

Thermochemical hydrogen production: past and present

The potential for health risks from intrusion of contaminants into the distribution system from pressure transients

Thermochemical hydrogen production

Thermochemical production of hydrogen via multistage water splitting processes

Application of pressure monitoring and modelling to detect and minimize low pressure events in distribution systems