ACTIVITIES TO ESTABLISH TECHNICAL CONFIDENCE FOR HTGR FUEL PROCESSING

Fuel particles for the High-Temperature Gas-Cooled Reactor (HTGR) contain a layer of pyrolytic silicon carbide to act as a miniature pressure vessel and primary fission product barrier. Optimization of the SiC with respect to fuel performance involves four areas of study: (a) characterization of as-deposited SiC coatings; (b) thermodynamics and kinetics of chemical reactions between SiC and fission products; (c) irradiation behavior of SiC in the absence of fission products; and (d) combined effects of irradiation and fission products. This paper reports the behavior of SiC deposited on inert microspheres and irradiated to fast neutron fluences typical of HTGR fuel at end-of-life.

HYDROGEN FROM HYDROGEN SULPHIDE IN BLACK SEA

Alternative Energy and Ecology (ISJAEE) ◽

10.15518/isjaee.2019.01-03.049-055 ◽

2019 ◽

pp. 49-55

Author(s):

S. Z. Baykara ◽

E. H. Figen ◽

A. Kale ◽

T. N. Veziroglu

Keyword(s):

Hydrogen Production ◽

Black Sea ◽

Hydrogen Sulphide ◽

Sea Water ◽

Economic Value ◽

Environmental Pollutant ◽

The Black Sea ◽

Fuel Processing ◽

Acid Gas ◽

Reducing Bacteria

Hydrogen sulphide, an acid gas, is generally considered an environmental pollutant. As an industrial byproduct, it is produced mostly during fuel processing. Hydrogen sulphide occurs naturally in many gas wells and also in gas hydrates and gas-saturated sediments especially at the bottom of the Black Sea where 90% of the sea water is anaerobic.The anoxic conditions exist in the deepest parts of the basin since nearly 7300 years, caused by the density stratification following the significant influx of the Mediterranean water through the Bosphorous nearly 9000 years ago. Here, H2S is believed to be produced by sulphur reducing bacteria at an approximate rate of 10 000 tons per day, and it poses a serious threat since it keeps reducing the life in the Black Sea. An oxygen–hydrogen sulphide interface is established at 150–200 m below the surface after which H2S concentration starts increasing regularly until 1000 m, and finally reaches a nearly constant value of 9.5 mg/l around 1500 m depth.Hydrogen sulphide potentially has economic value if both sulphur and hydrogen can be recovered. Several methods are studied for H2S decomposition, including thermal, thermochemical, electrochemical, photochemical and plasmochemical methods.In the present work, H2S potential in the Black Sea is investigated as a source of hydrogen, an evaluation of the developing prominent techniques for hydrogen production from H2S is made, and an engineering assessment is carried out regarding hydrogen production from H2S in the Black Sea using a process design based on the catalytic solar thermolysis approach. Possibility of a modular plant is considered for production at larger scale.

Hydrogen generators using fuel processing technologies

10.3403/30140640 ◽

2007 ◽

Keyword(s):

Fuel Processing ◽

Processing Technologies

Microchemical Systems for Fuel Processing and Conversion to Electrical Power

10.21236/ada469898 ◽

2007 ◽

Author(s):

Klavs F. Jensen

Keyword(s):

Electrical Power ◽

Fuel Processing

HTGR Fuel Recycle Development Program (189a OHO45). Fuel refabrication, Task 500. Rate-controlling factors in the carbothermic preparation of UO/sub 2/--UC/sub 2/--C microspheres

10.2172/6394979 ◽

1979 ◽

Author(s):

D. P. Stinton ◽

S. M. Tiegs ◽

W. J. Lackey ◽

T. B. Lindemer

Keyword(s):

Development Program ◽

Controlling Factors ◽

Htgr Fuel

Corrigendum to “Reaction mechanisms for H2O-enhanced dolomite calcination at high pressure” [Fuel Processing Technology 217 (2021) 106830]

Fuel Processing Technology ◽

10.1016/j.fuproc.2021.106865 ◽

2021 ◽

pp. 106865

Author(s):

Chunguang Zhou ◽

Patrik Yrjas ◽

Klas Engvall

Keyword(s):

High Pressure ◽

Reaction Mechanisms ◽

Processing Technology ◽

Fuel Processing

Exergy analysis of a biomass-based multi-energy system

E3S Web of Conferences ◽

10.1051/e3sconf/201911302017 ◽

2019 ◽

Vol 113 ◽

pp. 02017

Author(s):

Mariagiovanna Minutillo ◽

Alessandra Perna ◽

Alessandro Sorce

Keyword(s):

Exergy Analysis ◽

Energy System ◽

H2 Production ◽

Operating Conditions ◽

Processing Unit ◽

Storage Unit ◽

Fuel Processing ◽

Fuel Processor ◽

Energy Processes ◽

And Storage

This paper focuses on a biofuel-based Multi-Energy System generating electricity, heat and hydrogen. The proposed system, that is conceived as refit option for an existing anaerobic digester plant in which the biomass is converted to biogas, consists of: i) a fuel processing unit, ii) a power production unit based on the SOFC (Solid Oxide Fuel Cell) technology, iii) a hydrogen separation, compression and storage unit. The aim of this study is to define the operating conditions that allow optimizing the plant performances by applying the exergy analysis that is an appropriate technique to assess and rank the irreversibility sources in energy processes. Thus, the exergy analysis has been performed for both the overall plant and main plant components and the main contributors to the overall losses have been evaluated. Moreover, the first principle efficiency and the second principle efficiency have been estimated. Results have highlighted that the fuel processor (the Auto-Thermal Reforming reactor) is the main contributor to the global exergy destruction (9.74% of the input biogas exergy). In terms of overall system performance the plant has an exergetic efficiency of 53.1% (it is equal to 37.7% for the H2 production).

Irradiation performance of HTGR fuel rods with diluted thermosetting matrices

Nuclear Engineering and Design ◽

10.1016/0029-5493(77)90128-5 ◽

1977 ◽

Vol 44 (1) ◽

pp. 109-123 ◽

Cited By ~ 3

Author(s):

R.E. Bullock ◽

S.A. Sterling

Keyword(s):

Fuel Rods ◽

Irradiation Performance ◽

Htgr Fuel