Big Chemical Encyclopedia

Chemical substances, components, reactions, process design ...

Articles Figures Tables About

Thermal generating systems

The isotope plutonium-238 [13981 -16-3] Pu, is of technical importance because of the high heat that accompanies its radioactive decay. This isotope has been and is being used as fuel in small terrestrial and space nuclear-powered sources (3,4). Tu-based radioisotope thermal generator systems dehvered 7 W/kg and cost 120,000/W in 1991 (3). For some time, %Pu was considered to be the most promising power source for the radioisotope-powered artificial heart and for cardiovascular pacemakers. Usage of plutonium was discontinued, however, after it was determined that adequate elimination of penetrating radiation was uncertain (5) (see PROSTHETIC AND BIOMEDICAL devices). [Pg.191]

Water-soluble peroxide salts, such as ammonium or sodium persulfate, are the usual initiators. The initiating species is the sulfate radical anion generated from either the thermal or redox cleavage of the persulfate anion. The thermal dissociation of the persulfate anion, which is a first-order process at constant temperature (106), can be greatly accelerated by the addition of certain reducing agents or small amounts of polyvalent metal salts, or both (87). By using redox initiator systems, rapid polymerizations are possible at much lower temperatures (25—60°C) than are practical with a thermally initiated system (75—90°C). [Pg.168]

Heat Recovery and Seed Recovery System. Although much technology developed for conventional steam plants is appHcable to heat recovery and seed recovery (HRSR) design, the HRSRhas several differences arising from MHD-specific requirements (135,136). First, the MHD diffuser, which has no counterpart ia a conventional steam plant, is iacluded as part of the steam generation system. The diffuser experiences high 30 50 W/cm heat transfer rates. Thus, it is necessary to allow for thermal expansion of the order of 10 cm (137) ia both the horizontal and vertical directions at the connection between the diffuser and the radiant furnace section of the HRSR. [Pg.435]

Additionally, a thermal wave is generated in the bed in a similar fashion to that of the thermal wave system. However it is more similar to existing gas... [Pg.329]

Sulphuric acid at 93% was added to p-nitrotoluene. The temperature reached 160°C due to a failure of the thermal control system. The sulphonic acid formed decomposed violently at this temperature. The post-accident investigation showed that the decomposition started between 160 and 190 C. In fourteen minutes the temperature rose to 190-224°C and in one minute and thirty seconds to 224-270°C. A large volume of gas was then released during the eruption. The phenomena caused by the decomposition of nitrated derivatives in the presence of sulphuric acid will be addressed several times. What these incidents have in common is the formation of large carbonised volumes. This phenomenon is common with sulphonic acids. The nitro group role is to destabilise intermediate compounds and final compounds and to generate... [Pg.301]

Y. S. Tang. Ph.D has more than 35 years of experience in the field of thermal and fluid flow. His research interests have covered aspects of thermal hydraulics that are related to conventional and nonconventional power generation systems, with an emphasis on nuclear reactor design and analysis that focuses on liquld-meta -cooled reactors. Dr. Tang is co-author of Radioactive Waste Management published by Taylor 8 Francis, and Thermal Analysis of Liquid Metal Fast Breeder Reactors, He received a B5. from National Central University In China and an MS. in mechanical engineering from the University of Wisconsin. He earned his Ph.D. [Pg.572]

Nuclear and magneto-hydrodynamic electric power generation systems have been produced on a scale which could lead to industrial production, but to-date technical problems, mainly connected with corrosion of the containing materials, has hampered full-scale development. In the case of nuclear power, the proposed fast reactor, which uses fast neutron fission in a small nuclear fuel element, by comparison with fuel rods in thermal neutron reactors, requires a more rapid heat removal than is possible by water cooling, and a liquid sodium-potassium alloy has been used in the development of a near-industrial generator. The fuel container is a vanadium sheath with a niobium outer cladding, since this has a low fast neutron capture cross-section and a low rate of corrosion by the liquid metal coolant. The liquid metal coolant is transported from the fuel to the turbine generating the electric power in stainless steel... [Pg.300]

Linear programming Boiler/turbo generator system (11.4) Thermal cracker (14.1) >. i Planning and scheduling (16.1)... [Pg.416]

Physical separation of the chlor-alkali/EDC plant from the cracking/oxyhydro-chlorination plant does create some complications regarding the necessary duplication of feedstocks and services. In particular, there will be the need for two ethylene supplies and for two independent thermal oxidation systems. Approximately half of the total ethylene must be provided as the feed to the EDC unit with the remainder fed to the oxyhydrochlorination unit. The EDC unit as well as the cracking and oxyhydrochlorination units will generate off-gases that require emission control,... [Pg.283]

It can be shownthat asymptotically (i.e. in the limit where the number M of generated configurations tends to infinity) this procedure generates system configurations x, with a probability proportional to the Boltzmann weight, P,(x) = exp [— Jf(x)//cBr]/Z. Thus thermal averages are just calculated as simple arithmetic averages ... [Pg.104]


See other pages where Thermal generating systems is mentioned: [Pg.272]    [Pg.272]    [Pg.510]    [Pg.880]    [Pg.272]    [Pg.272]    [Pg.510]    [Pg.880]    [Pg.421]    [Pg.428]    [Pg.179]    [Pg.350]    [Pg.423]    [Pg.235]    [Pg.235]    [Pg.237]    [Pg.502]    [Pg.2232]    [Pg.2371]    [Pg.300]    [Pg.164]    [Pg.320]    [Pg.1056]    [Pg.1056]    [Pg.1102]    [Pg.375]    [Pg.245]    [Pg.175]    [Pg.21]    [Pg.239]    [Pg.401]    [Pg.136]    [Pg.33]    [Pg.242]    [Pg.82]    [Pg.382]    [Pg.1200]    [Pg.245]    [Pg.216]    [Pg.1200]   
See also in sourсe #XX -- [ Pg.880 ]




SEARCH



Generator systems

Thermal generation

Thermal systems

© 2024 chempedia.info