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An investigation of coastal fumigation effects on nuclear accident consequences in Hong Kong /Huang, Aiping. January 1996 (has links)
Thesis (M. Phil.)--University of Hong Kong, 1996. / Includes bibliographical references (leaf 164-168).
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Local economic impact of nuclear power plantsShurcliff, Alice W. January 1975 (has links)
No description available.
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Nuclear plant reliability analysis : optimization of test intervals for standby purposes in nuclear power plantsMassachusetts Institute of Technology Energy Laboratory, Karimi, Roohollah 11 1900 (has links)
"Final report for research project sponsored by Northeast Utilities Service Company, Public Service Electric and Gas Company, Yankee Atomic Electric Company under the M.I.T. Energy Laboratory Electric Utility Program."
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Reliability methods in nuclear power plant ageing management /Simola, Kaisa. January 1999 (has links) (PDF)
Thesis (doctoral)--Helsinki University of Technology, 1999. / Includes bibliographical references. Also available on the World Wide Web.
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Pressure groups and the Daya Bay controversy /Ko, Tin-ming. January 1987 (has links)
Thesis (M. Soc. Sc.)--University of Hong Kong, 1987.
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Pressure groups and the Daya Bay controversyKo, Tin-ming. January 1987 (has links)
Thesis (M.Soc.Sc.)--University of Hong Kong, 1987. / Also available in print.
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The catalytic effect of vanadium, iron and lead on the air oxidation of pile grade A graphitePaul, Michael January 1994 (has links)
No description available.
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Organizational and institutional effects on safety and efficiency in nuclear power plants.Baker, Kathryn Anne. January 1991 (has links)
This dissertation explores the extent to which organizational and institutional factors continue to influence the economic and safety performance of nuclear power plants. Although the importance of non-technological factors during the developmental period of nuclear power has been recognized after the fact, most contemporary research fails to recognize the continued importance of organizational and institutional factors for ongoing nuclear power plant operations. Moreover, a second generation of advanced nuclear reactors is now imminent but technological advances will not suffice to prevent many of the mistakes of this first era of nuclear power. The lessons learned from our experience with the current generation of nuclear power plants must include more than technological improvements. As yet a systematic investigation of the impact of organizational and institutional factors on nuclear power plant performance has not been conducted. This dissertation progresses us much further toward accomplishing this task, although much additional research is still needed.
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CONTINUOUS-TIME OPTIMAL CONTROL OF A SIMULATED BOILING WATER NUCLEAR (BWR) POWER PLANT.BOADU, HERBERT ODAME. January 1985 (has links)
A suboptimal controller has been developed for a Boiling Water Reactor Nuclear Power Plant, using the DARE P Continuous Simulation Language, which was developed in the Electrical Engineering Department at the University of Arizona. A set of 48 nonlinear first-order differential equations and a large number of algebraic equations has been linearized about the equilibrium state. Using partitioning, the linearized equations were transformed into a block triangular form. The concept of optimal control and a square performance index reflecting the desired plant behavior have been applied on the slow subsystem to develop a suboptimal controller. The obtained feedback law is shown by simulation to be able to compensate for a variety of plant disturbances. A large variety of responses can be obtained by changing the weighting matrices. The control is basically a regulator approach to speed up response during load demand changes. Several simulations are included to demonstrate the control performance. The variables to be controlled have mainly been the average neutron density and the average coolant temperature. Simplifications have been suggested, thus obtaining considerable savings in the computations and ease in design.
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The Role of Science, Engineering, and Technology in the Public Policy Process for Infrastructure and Natural SystemsTaylor, Timothy 2009 August 1900 (has links)
Interactions between societal, natural, and infrastructure systems can be
beneficial or harmful to society. Society benefits from natural systems by being provided
with the basic necessities of life (air, water, and food). However, events such as
stratospheric ozone depletion demonstrate that society ultimately can be harmed by
societal impacts on natural systems. Domain knowledge is developed from observation
of natural, societal, and infrastructure systems. Domain knowledge is contained within
scientific knowledge and engineering knowledge. Scientific knowledge is gained
through structured observation and rigorous analysis of natural and societal systems.
Engineering knowledge is partially developed from scientific knowledge and is used to
manipulate natural and societal systems. Technology is the application of engineering
knowledge. In the past two centuries scientific and engineering knowledge have
produced technologies that affect the interaction between societal and natural systems.
Although scientists and engineers are in positions to advise on policies to address
problems involving societal/natural system interactions, their contributions are not
always fully utilized. This research examines feedback mechanisms that describe societal, natural, and
infrastructure system interaction to develop an improved understanding of the dynamic
interactions between society, natural systems, infrastructure systems, scientific and
engineering knowledge, technology, and public policy. These interactions are investing
through and opposing case study analysis performed using computer simulation
modeling. The stratospheric ozone depletion study represents a case in which domain
experts successfully influenced public policy. The U.S. civilian nuclear power study
represents a case in which domain experts were less successful in influencing public
policy. The system dynamics methodology is used to construct these two highly
integrated models of societal-natural system interaction. Individual model sectors, based
on existing theory, describe natural/infrastructure systems, knowledge and technology
development, societal risk perception, and public policy.
The work reveals that the influence of scientists and engineers in the public
policy is due in part to their ability to shift dominance between causal feedback
mechanisms that seek to minimize societal risk from natural systems and feedback
mechanisms that seek to minimize the economic risk of increased regulations. The
ability to alter feedback mechanism dominance is not solely dependent upon scientists
and engineers ability to develop knowledge but to a larger extent depends on their ability
to interact with policy makers and society when describing issues involving natural and
infrastructure systems.
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