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11	Computer model of a nuclear reactor primary coolant pump Wong, Kean January 1982 (has links) Thesis (M.S.)--Massachusetts Institute of Technology, Dept. of Nuclear Engineering, 1982. / MICROFICHE COPY AVAILABLE IN ARCHIVES AND SCIENCE / Includes bibliographical references. / by Kean Wong. / M.S. Nuclear Engineering. Pumping machinery
12	Experimental investigation of heat transfer characteristics of MITR-II fuel plates, in-channel thermocouple response and calibration. Szymczak, William Joseph January 1976 (has links) Thesis. 1976. M.S.--Massachusetts Institute of Technology. Dept. of Nuclear Engineering. / Microfiche copy available in Archives and Science. / Includes bibliographical references. / M.S. Nuclear Engineering Nuclear fuel elements Nuclear reactors Cooling Heat Transmission
13	Natural convection analysis of the MITR-II during loss of flow accident Bamdad Haghighi, Farid January 1977 (has links) Thesis. 1977. Nucl.E.--Massachusetts Institute of Technology. Dept. of Nuclear Engineering. / MÌ²iÌ²cÌ²á¹ŸoÌ²fÌ²iÌ²cÌ²áº–eÌ² cÌ²oÌ²pÌ²yÌ² aÌ²vÌ²aÌ²iÌ²á¸»aÌ²á¸‡á¸»eÌ² iÌ²á¹‰ AÌ²á¹ŸcÌ²áº–iÌ²vÌ²eÌ²sÌ² aÌ²á¹‰á¸ SÌ²cÌ²iÌ²eÌ²á¹‰cÌ²eÌ². / Includes bibliographical references. / by Farid Bamdad-Haghighi. / Nucl.E. Nuclear Engineering Nuclear reactor accidents Nuclear reactors Cooling
14	Flooding limits in a simulated nuclear reactor hot leg Krolewski, Susan M January 1980 (has links) Thesis (B.S.)--Massachusetts Institute of Technology, Dept. of Mechanical Engineering, 1980. / MICROFICHE COPY AVAILABLE IN ARCHIVES AND ENGINEERING. / Bibliography: leaf 31. / by Susan M. Krolewski. / B.S. Mechanical Engineering. Nuclear reactors Cooling Nuclear reactor accidents Nuclear reactors Models
15	Feasibility study of a controllable mechanical seal for reactor coolant pumps Payne, John Wilson 03 April 2013 (has links) In a nuclear power plant, one of the most important systems for both safety and performance is the reactor cooling system. The cooling system is generally driven by one or more very large centrifugal pumps. Most reactor coolant pumps utilize a multi-stage mechanical face seal system for fluid containment. As a result, these seal systems are critical to safe, continued operation of a nuclear reactor. Without adequate sealing, loss of coolant volume can occur, and a reactor may be forced to shut down, costing the operating utility significantly until it can be brought online again. The main advantage of mechanical face seals is their self-adjusting properties. These seals are tuned so that they automatically adjust to varying fluid conditions to provide adequate leakage control. Because of the enormous pressures, complicated water chemistry, and possible large temperature transients, the mechanical seals inside a reactor coolant pump must be some of the most robust seals available. In addition, their long service life and continuous operation demand durability and the capability to adjust to a wide range of conditions. However, over time, wear, chemical deposition, or changing operating conditions can alter the face gap, which is the critical geometry between the sealing faces of a seal. An altered face gap can lead to undesirable conditions of too much or not enough leakage, which must be maintained within a certain range to provide lubrication and cooling to the seal faces without resulting in uncontrolled coolant volume loss. Nuclear power plants operate within strict leakage ranges, and long-term effects causing undesirable leakage can eventually necessitate a reactor shutdown if the seal cannot self-adjust to control the leakage. This document will examine possible causes of undesirable leakage rates in a commonly-used reactor coolant pump assembly. These causes will be examined to determine the conditions which promote them, the physical explanation for their effect on the operation of a mechanical seal, and possible methods of mitigation of both the cause and its effect. These findings are based on previous publications by utilities and technical and incident reports from reactor stations which detail actual incidents of abnormal seal performance and their root causes as determined by the utilities. Next, a method of increasing the ability of a mechanical seal to adapt to a wider range of conditions will be proposed. This method involves modifying an existing seal face to include a method of active control. This active control focuses on deliberately deforming one face of the mechanical sealing face pair. This deformation alters the face gap in order to make the fluid conditions inside the face gap more preferable, generating more or less leakage as desired. Two methods of actuation, hydraulic pressure and piezoelectric deformation, will be proposed. Finally, a model of the actively controlled seal faces will be introduced. This model includes a method of numerically solving the Reynolds equation to determine the fluid mechanics that drive the lubrication problem in the seal face and coupling the solution with a deformation analysis in a finite element model of a seal face. The model solves iteratively until a converged solution of a sealed pressure distribution, a resulting face deformation, and a calculated leakage rate is reached. The model includes a study of the effects of induced deformation in the seal via both hydraulic and piezoelectric actuation and the ability of this deformation to control the leakage rate. Mechanical face seals Hydraulic controllable seal Seals (Closures) Nuclear reactors Cooling
16	Simulation of sodium pumps for nuclear power plants Boadu, Herbert Odame January 1981 (has links) No description available. Sodium cooled reactors. Nuclear reactors -- Cooling. Digital computer simulation.
17	Quantified PIRT and uncertainty quantification for computer code validation Luo, Hu 05 December 2013 (has links) This study is intended to investigate and propose a systematic method for uncertainty quantification for the computer code validation application. Uncertainty quantification has gained more and more attentions in recent years. U.S. Nuclear Regulatory Commission (NRC) requires the use of realistic best estimate (BE) computer code to follow the rigorous Code Scaling, Application and Uncertainty (CSAU) methodology. In CSAU, the Phenomena Identification and Ranking Table (PIRT) was developed to identify important code uncertainty contributors. To support and examine the traditional PIRT with quantified judgments, this study proposes a novel approach, the Quantified PIRT (QPIRT), to identify important code models and parameters for uncertainty quantification. Dimensionless analysis to code field equations to generate dimensionless groups (�� groups) using code simulation results serves as the foundation for QPIRT. Uncertainty quantification using DAKOTA code is proposed in this study based on the sampling approach. Nonparametric statistical theory identifies the fixed number of code run to assure the 95 percent probability and 95 percent confidence in the code uncertainty intervals. / Graduation date: 2013 / Access restricted to the OSU Community, at author's request, from Dec. 5, 2012 - Dec. 5, 2013 Code Validation Uncertainty Quantification Sensitivity Analysis Quantified PIRT Nuclear Computer Code Uncertainty (Information theory) Computer programs -- Validation

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