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Author: Etienne M. Mullin
Publisher:
ISBN:
Category : Condensation
Languages : en
Pages : 88
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Book Description
The Oregon State University Multi-Application Small Light Water Reactor test facility is employed in a series tests to evaluate condensation heat transfer in small, high pressure containment vessels characteristic of small modular reactor designs under development. This integral system test facility was constructed to demonstrate the feasibility of a pioneering SMR design and features a scaled containment vessel and cooling pool heat sink. The tests performed involve supplying steam into the containment and observing the condensation rates occurring on the heat transfer surface. The test data is reduced to quantify condensation heat transfer rates and heat transfer coefficients. Particular attention is paid to the influence of system pressure and noncondensable gas inventory.
Author: Etienne M. Mullin
Publisher:
ISBN:
Category : Condensation
Languages : en
Pages : 88
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Book Description
The Oregon State University Multi-Application Small Light Water Reactor test facility is employed in a series tests to evaluate condensation heat transfer in small, high pressure containment vessels characteristic of small modular reactor designs under development. This integral system test facility was constructed to demonstrate the feasibility of a pioneering SMR design and features a scaled containment vessel and cooling pool heat sink. The tests performed involve supplying steam into the containment and observing the condensation rates occurring on the heat transfer surface. The test data is reduced to quantify condensation heat transfer rates and heat transfer coefficients. Particular attention is paid to the influence of system pressure and noncondensable gas inventory.
Author:
Publisher:
ISBN:
Category :
Languages : en
Pages : 225
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Book Description
This NEUP funded project, NEUP 12-3630, is for experimental, numerical and analytical studies on high-pressure steam condensation phenomena in a steel containment vessel connected to a water cooling tank, carried out at Oregon State University (OrSU) and the University of Wisconsin at Madison (UW-Madison). In the three years of investigation duration, following the original proposal, the planned tasks have been completed: (1) Performed a scaling study for the full pressure test facility applicable to the reference design for the condensation heat transfer process during design basis accidents (DBAs), modified the existing test facility to route the steady-state secondary steam flow into the high pressure containment for controllable condensation tests, and extended the operations at negative gage pressure conditions (OrSU). (2) Conducted a series of DBA and quasi-steady experiments using the full pressure test facility to provide a reliable high pressure condensation database (OrSU). (3) Analyzed experimental data and evaluated condensation model for the experimental conditions, and predicted the prototypic containment performance under accidental conditions (UW-Madison). A film flow model was developed for the scaling analysis, and the results suggest that the 1/3 scaled test facility covers large portion of laminar film flow, leading to a lower average heat transfer coefficient comparing to the prototypic value. Although it is conservative in reactor safety analysis, the significant reduction of heat transfer coefficient (50%) could under estimate the prototypic condensation heat transfer rate, resulting in inaccurate prediction of the decay heat removal capability. Further investigation is thus needed to quantify the scaling distortion for safety analysis code validation. Experimental investigations were performed in the existing MASLWR test facility at OrST with minor modifications. A total of 13 containment condensation tests were conducted for pressure ranging from 4 to 21 bar with three different static inventories of non-condensable gas. Condensation and heat transfer rates were evaluated employing several methods, notably from measured temperature gradients in the HTP as well as measured condensate formation rates. A detailed mass and energy accounting was used to assess the various measurement methods and to support simplifying assumptions required for the analysis. Condensation heat fluxes and heat transfer coefficients are calculated and presented as a function of pressure to satisfy the objectives of this investigation. The major conclusions for those tests are summarized below: (1) In the steam blow-down tests, the initial condensation heat transfer process involves the heating-up of the containment heat transfer plate. An inverse heat conduction model was developed to capture the rapid transient transfer characteristics, and the analysis method is applicable to SMR safety analysis. (2) The average condensation heat transfer coefficients for different pressure conditions and non-condensable gas mass fractions were obtained from the integral test facility, through the measurements of the heat conduction rate across the containment heat transfer plate, and from the water condensation rates measurement based on the total energy balance equation. 15 (3) The test results using the measured HTP wall temperatures are considerably lower than popular condensation models would predict mainly due to the side wall conduction effects in the existing MASLWR integral test facility. The data revealed the detailed heat transfer characteristics of the model containment, important to the SMR safety analysis and the validation of associated evaluation model. However this approach, unlike separate effect tests, cannot isolate the condensation heat transfer coefficient over the containment wall, and therefore is not suitable for the assessment of the condensation heat transfer coefficient against system pressure and noncondensable ...
Author: Francesco D'Auria
Publisher: Elsevier
ISBN: 0323856098
Category : Technology & Engineering
Languages : en
Pages : 818
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Book Description
Handbook on Thermal Hydraulics of Water-Cooled Nuclear Reactors, Volume 3, Procedures and Applications includes all new chapters which delve deeper into the topic, adding context and practical examples to help readers apply learnings to their own setting. Topics covered include experimental thermal-hydraulics and instrumentation, numerics, scaling and containment in thermal-hydraulics, as well as a title dedicated to good practices in verification and validation. This book will be a valuable reference for graduate and undergraduate students of nuclear or thermal engineering, as well as researchers in nuclear thermal-hydraulics and reactor technology, engineers working in simulation and modeling of nuclear reactors, and more. In addition, nuclear operators, code developers and safety engineers will also benefit from the practical guidance provided. Presents a comprehensive analysis on the connection between nuclear power and thermal hydraulics Includes end-of-chapter questions, quizzes and exercises to confirm understanding and provides solutions in an appendix Covers applicable nuclear reactor safety considerations and design technology throughout
Author: Dhongik Samuel Yoon
Publisher:
ISBN:
Category :
Languages : en
Pages : 0
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Book Description
Condensation of steam vapor is an important mode of energy removal from the reactor containment in postulated design basis accidents where high-energy steam escapes into the reactor containment. Due to its passive nature and magnitude of heat transfer associated with phase change, condensation can be used as an effective energy removal mechanism, especially for reactors with a passive containment cooling system. Therefore, there has been a great interest in modeling condensation phenomena in the reactor containment for the purpose of accident analysis. Until recently, the focus has been the presence of noncondensable gas since traditional reactor designs operate at near atmospheric pressure with substantial amount of noncondensable gas in the containment, which hinders the process of condensation heat transfer. In this case, the phase change is dominated by diffusion resistance in the gas mixture phase and the thermal resistance of condensate film layer can be neglected. Recent advanced reactor designs, on the other hand, are designed to allow very low air pressure in the containment. In this case, the heat transfer resistance due to the presence of noncondensable gas is reduced significantly and the thermal resistance of condensate film layer can no longer be neglected. Moreover, it has been reported that condensation on the micro or nano-engineered surfaces shows substantially different behavior compared to traditional untreated surfaces. Those engineered surfaces with modified wetting characteristics can affect the condensation rates by affecting the condensate film behavior on such surfaces, proposing a potential way of affecting the heat removal from reactor containment by wall surface modification. Consequently, it has become relevant and necessary to study and characterize the effect of thermal resistance and kinetic conditions of the condensate film layer on the overall condensation heat transfer in the reactor containment regarding conditions with very low noncondensable gas concentration where the presence of condensate film layer can no longer be neglected. The current condensation model in MELCOR was evaluated in order to assess its capability to predict condensation heat transfer for traditional containment conditions. By modeling sets of containment condensation experiments, satisfactory performance of MELCOR in predicting condensation phenomena was confirmed for conditions with significant noncondensable gas concentration. It has to be noted that, as a result of this assessment, few adjustments has been implemented to guarantee more accurate predictions of MELCOR in specific conditions addressed in those experiments. However, it is observed that MELCOR may be inaccurate in predicting condensation for conditions with very low noncondensable gas concentrations where the effects of condensate film layer is more prominent. However, MELCOR's correlation-based models prevent further investigations on the parameters that have not been already implemented. In an effort to better understand the effect of thermal resistance and kinetic conditions of the condensate film layer for conditions with very low noncondensable gas concentrations, a condensation model was developed in the framework of a Computation Fluid Dynamics (CFD) to include thermal and kinetic conditions of the condensate film layer. The developed condensation model includes heat transfer resistances in both phases without directly simulating the two-fluid problem and proposes that the liquid-gas interface can be represented as a free surface. Case studies were conducted to show its theoretical validity. The developed condensation model including the thermal resistance of the condensate film layer and the free surface assumption was validated against two sets of separate effects experiments, one in traditional reactor containment conditions and the other in a pure steam condition. The results indicate that a free surface assumption can greatly improve the prediction of condensation heat transfer, even for traditional reactor containment conditions where the concentration of noncondensable gas is significant. Including the thermal resistance of the condensate film layer does not provide a significant change in the results for high noncondensable gas concentration cases, as expected. For near-pure steam conditions, however, the effect of the condensate film is not only significant but also increases with decreasing noncondensable gas concentration as expected. The proposed modeling approach is also able to account for this effect.
Author: Warren M. Rohsenow
Publisher: McGraw-Hill Companies
ISBN:
Category : Science
Languages : en
Pages : 1552
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Book Description
Author: Daniel T. Ingersoll
Publisher: Woodhead Publishing
ISBN: 0128239174
Category : Technology & Engineering
Languages : en
Pages : 648
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Book Description
Handbook of Small Modular Nuclear Reactors, Second Edition is a fully updated comprehensive reference on Small Modular Reactors (SMRs), which reflects the latest research and technological advances in the field from the last five years. Editors Daniel T. Ingersoll and Mario D. Carelli, along with their team of expert contributors, combine their wealth of collective experience to update this comprehensive handbook that provides the reader with all required knowledge on SMRs, expanding on the rapidly growing interest and development of SMRs around the globe. This book begins with an introduction to SMRs for power generation, an overview of international developments, and an analysis of Integral Pressurized Water Reactors as a popular class of SMRs. The second part of the book is dedicated to SMR technologies, including physics, components, I&C, human-system interfaces and safety aspects. Part three discusses the implementation of SMRs, covering economic factors, construction methods, hybrid energy systems and licensing considerations. The fourth part of the book provides an in-depth analysis of SMR R&D and deployment of SMRs within eight countries, including the United States, Republic of Korea, Russia, China, Argentina, and Japan. This edition includes brand new content on the United Kingdom and Canada, where interests in SMRs have increased considerably since the first edition was published. The final part of the book adds a new analysis of the global SMR market and concludes with a perspective on SMR benefits to developing economies. This authoritative and practical handbook benefits engineers, designers, operators, and regulators working in nuclear energy, as well as academics and graduate students researching nuclear reactor technologies. Presents the latest research on SMR technologies and global developments Includes new case study chapters on the United Kingdom and Canada and a chapter on global SMR markets Discusses new technologies such as floating SMRs and molten salt SMRs
Author: U.S. Nuclear Regulatory Commission. Division of Systems Safety
Publisher:
ISBN:
Category : Light water reactors
Languages : en
Pages : 196
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Book Description
Author: Chʻun Li
Publisher:
ISBN:
Category :
Languages : en
Pages : 326
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Book Description
Author: Francesco D'Auria
Publisher: Woodhead Publishing
ISBN: 0081006799
Category : Technology & Engineering
Languages : en
Pages : 1200
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Book Description
Thermal Hydraulics of Water-Cooled Nuclear Reactors reviews flow and heat transfer phenomena in nuclear systems and examines the critical contribution of this analysis to nuclear technology development. With a strong focus on system thermal hydraulics (SYS TH), the book provides a detailed, yet approachable, presentation of current approaches to reactor thermal hydraulic analysis, also considering the importance of this discipline for the design and operation of safe and efficient water-cooled and moderated reactors. Part One presents the background to nuclear thermal hydraulics, starting with a historical perspective, defining key terms, and considering thermal hydraulics requirements in nuclear technology. Part Two addresses the principles of thermodynamics and relevant target phenomena in nuclear systems. Next, the book focuses on nuclear thermal hydraulics modeling, covering the key areas of heat transfer and pressure drops, then moving on to an introduction to SYS TH and computational fluid dynamics codes. The final part of the book reviews the application of thermal hydraulics in nuclear technology, with chapters on V&V and uncertainty in SYS TH codes, the BEPU approach, and applications to new reactor design, plant lifetime extension, and accident analysis. This book is a valuable resource for academics, graduate students, and professionals studying the thermal hydraulic analysis of nuclear power plants and using SYS TH to demonstrate their safety and acceptability. Contains a systematic and comprehensive review of current approaches to the thermal-hydraulic analysis of water-cooled and moderated nuclear reactors Clearly presents the relationship between system level (top-down analysis) and component level phenomenology (bottom-up analysis) Provides a strong focus on nuclear system thermal hydraulic (SYS TH) codes Presents detailed coverage of the applications of thermal-hydraulics to demonstrate the safety and acceptability of nuclear power plants
Author: NEA.
Publisher:
ISBN: 9789264266865
Category : Nuclear energy
Languages : en
Pages : 71
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Book Description
Recent interest in small modular reactors (SMRs) is being driven by a desire to reduce the total capital costs associated with nuclear power plants and to provide power to small grid systems. According to estimates available today, if all the competitive advantages of SMRs were realised, including serial production, optimised supply chains and smaller financing costs, SMRs could be expected to have lower absolute and specific (per-kWe) construction costs than large reactors. Although the economic parameters of SMRs are not yet fully determined, a potential market exists for this technology, particularly in energy mixes with large shares of renewables. This report assesses the size of the market for SMRs that are currently being developed and that have the potential to broaden the ways of deploying nuclear power in different parts of the world. The study focuses on light water SMRs that are expected to be constructed in the coming decades and that strongly rely on serial, factory-based production of reactor modules. In a high-case scenario, up to 21 GWe of SMRs could be added globally by 2035, representing approximately 3% of total installed nuclear capacity.
