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Light water

Light s vitches Light water reactors Lightwave guides Lignin... [Pg.565]

Eig. 8. Cost of electricity (COE) comparison where represents capital charges, Hoperation and maintenance charges, and D fuel charges for the reference cycles. A, steam, light water reactor (LWR), uranium B, steam, conventional furnace, scmbber coal C, gas turbine combined cycle, semiclean hquid D, gas turbine, semiclean Hquid, and advanced cycles E, steam atmospheric fluidized bed, coal E, gas turbine (water-cooled) combined low heating value (LHV) gas G, open cycle MHD coal H, steam, pressurized fluidized bed, coal I, closed cycle helium gas turbine, atmospheric fluidized bed (AEB), coal J, metal vapor topping cycle, pressurized fluidized bed (PEB), coal K, gas turbine (water-cooled) combined, semiclean Hquid L, gas turbine... [Pg.421]

The Hanford N Reactor. The Hanford N reactor was built in 1964 for purposes of plutonium production during the Cold War. It used graphite as moderator, pierced by over 1000 Zircaloy 2 tubes. These pressure tubes contained slightly enriched uranium fuel cooled by high temperature light water. The reactor also provided 800 MWe to the Washington PubHc Power Supply System. This reactor was shut down in 1992 because of age and concern for safety. The similarity to the Chemobyl-type reactors played a role in the decision. [Pg.214]

Forsberg, C. W., D. L. Moses, E. B. Lewis, R. Gibson, R. Pearson, W. J. Reich, G. A. Murphy, R. H. Staunton, and W. E. Kohn (1989). Proposed and Existing Passive and Inherent Safety-Related Structures, Systems, and Components (Building Blocks) for Advanced Light Water Reactors. Oak Ridge, TN Oak Ridge National Laboratory. [Pg.140]

Table 5.2-1 Statistical Evidence of Fires in Light Water Nuclear Power Plants ( Table 5.2-1 Statistical Evidence of Fires in Light Water Nuclear Power Plants (<May 1978) ...
The data suggest that iodine will be released, predominantly, as cesium iodide under most postulated light water reactor accident conditions. However, formation of more volatile iodine species (e.g., elemental iodine and organic iodines) is not impossible under certain accident conditions. [Pg.316]

The Canadian Deuterium Uranium reactor fissions with natural uranium, hence, no dependence on national or international fuel enrichment facilities that are needed to enrich uranium to about 3% U-235 to achieve criticality with light water moderation. [Pg.404]

Note that the only other plutonium production site in the U.S. was at Richland, Wa.shington where graphite-reflected light water cooled reactors were used. [Pg.416]

Secondary Loss ot Coolant Accident A leak rn (lie light water secondary cooling system wliidi leads to a Loss of Pumping Accident. [Pg.418]

The mean frequencies of events damaging more than 5% of the reactor core per year were found to be Internal Events 6.7E-5, Fire 1.7E-5, Seismic 1.7E-4, and total 2,5E-4. Thus, within the range of U. S. commercial light water reactors The core damage frequency itself, is only part of the story because many N-Reactor accident sequences damage only a small fraction of the core. The... [Pg.425]

Anticipated Transients without Scram for Light Water Reactors, Vol. 1-3, December 1978. Haasl, D. F, et al., Fault Tree Handbook, January 1981. [Pg.467]

Eide, S. A. et al., 1990b, Generic Component Failure Database for Light Water and Sodium... [Pg.477]

Hannerz, H., 1983, Towards Intrinsically Safe Light Water Reactors, ORAU/IEA-83-2(M)-Rev. Institute for Energy Analysis. [Pg.480]

Resources are an available supply of equipment, environment, machines, materials, processes, labor, documentation, and utilities, such as heat, light, water, power etc., which can be drawn upon when needed. This therefore requires detailed planning and logistics management and may require many lists and subplans so that the resources are available when required. Inventory management is an element of such planning. [Pg.191]

An Aging Failure Survey of LWR Safely Systems and Components Nuclear 4 Tables of component failures per years of service Light Water Reactor Safety System Components 93. [Pg.91]

Characteristics of Pipe System Failures in Light Water Reactors Nuclear Approximately 100 records of pipe failure rates in a wide variety of failure modes Nuclear Power Plant Piping 114. [Pg.92]

See other pages where Light water is mentioned: [Pg.346]    [Pg.264]    [Pg.440]    [Pg.122]    [Pg.490]    [Pg.573]    [Pg.713]    [Pg.115]    [Pg.443]    [Pg.444]    [Pg.196]    [Pg.214]    [Pg.220]    [Pg.222]    [Pg.239]    [Pg.474]    [Pg.458]    [Pg.358]    [Pg.2270]    [Pg.34]    [Pg.455]    [Pg.534]    [Pg.205]    [Pg.205]    [Pg.206]    [Pg.206]    [Pg.213]    [Pg.243]    [Pg.400]    [Pg.404]    [Pg.408]    [Pg.462]   
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See also in sourсe #XX -- [ Pg.17 , Pg.19 , Pg.21 , Pg.33 , Pg.50 , Pg.52 , Pg.54 , Pg.242 ]

See also in sourсe #XX -- [ Pg.689 , Pg.743 ]



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A Simple Model for Light-Driven Water-Splitting Reaction

Accident Experience with Light Water Reactors

Advanced Light Water Reactors

Aspects of Light-Driven Water Splitting

Coolant, light water

Cooling system, light water reactor

Dissociation light-induced water

Evidence for Slow Electron Transfer During Light-Driven Water Splitting

Fuel light-water reactor

GENERIC SAFETY ISSUES FOR LIGHT WATER REACTOR NUCLEAR POWER PLANTS

High-performance light water reactor

High-performance light water reactor HPLWR)

High-performance light water-cooled reactor

High-performance light water-cooled reactor HPLWR)

Light Water Cooled Reactor Systems

Light Water Reactor category

Light energy conversion and water-oxidation systems in photosynthesis

Light enrichment ordinary water reactor

Light scattering from water-soluble hydrophobically

Light water basic properties

Light water circuits

Light water reactors fuel cycles

Light water reactors, investment

Light water thermodynamic diagrams

Light water-cooled graphite reactors

Light water-cooled graphite-moderated

Light water-cooled graphite-moderated reactor

Light water-cooled reactors

Light, in natural waters

Light-Water Cooled

Light-water breeder reactor

Light-water reactor

Light-water reactors integrity

Light-water reactors limits

Light-water reactors pressure-temperature operating

Light-water reactors schematic diagram showing

Nuclear energy light water reactors

Nuclear light water reactors

Nuclear power reactors light water reactor

Nuclear reactor light water-cooled reactors

Operating light- and water-exposure

Operating light- and water-exposure apparatus (fluorescent UV-condensation

Phonon Relaxation of Light and Heavy Water

Photocatalysts for Water Splitting Under Visible Light

Pressure boiling light water coolant

Pressurized light-water reactor

Radionuclides in the coolants of light water reactors during normal operation

Reactor boiling light water

Reactor light water moderated

Safety aspects light water reactors

Safety in the Light-Water Reactor Fuel Cycle

Semiconductors light-driven water splitting

Shielding, light water reactor

Thermodynamic and Kinetic Criteria for Light-Driven Water Splitting

Transfer from Light to Heavy Water

Visible light, cyclic water cleavage

Water Cleavage by Visible Light

Water light absorption

Water light transmittance

Water light treatment

Water splitting visible-light-driven

Water static light scattering

Water vapor light absorption

Water, light from

White light water droplets

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