Nuclear Engineering: An Introduction

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Upon completion, students should have an overall grasp of the radiation protection principles and practice; and most importantly the safety culture required. Experiments of health physics and radiation safety are performed and laboratory reports are written by students. Topics of experiment include 1. Geiger Muller Tube detector, 2.

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Counting Statistics, 3. Attenuation of betas in aluminium, 5. Gamma Spectroscopy, 6. Portable Instrumentation and Calibration, 7. Protective Clothing and Equipment for Respiratory Protection, 8. Protective Equipment, personnel monitoring devices, decontamination, 9. Area and effluent monitoring, Waste management.

Experiments on nuclear reactor engineering are perfomed and laboratory reports are prepared by the students. Flux distribution in a subcriticality pile, 2. RTP reactor startup and shutdown, 3. Control rod calibration by the period method, 4.

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Control rod calibration by the drop method, 5. Approach to critical with a control rod, 6. Reactor power calibration, 7. Neutron startup source, 8. Reactor kinetic and delayed neutron effects, 9. TRIGA pulsing experiment, Measurement of thermal diffusion length in graphite, Reactor flux measurement. Experiments are performed at MNA.

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This course introduces students some of the metrological terminologies used in experimental methods, concept of metrology and its application. The course will also provide understanding the concept of standardization as the management system of standards and quality. The measurement technique for electrical quantity and analysis of the result according to ISO Guide will be introduced as well.

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It will examine transducers in order to gain an awareness of what they can do. Transducer operations, characteristic and functions will be discussed. The first part of this course will familiarize students with the principles and methods used in the safety evaluation of nuclear power plants. In the second part of the course, the students will be informed regarding the safety philosophies, design criteria and regulations.

Then, the deterministic and probabilistic models, reliability analysis, nuclear and thermal-hydraulic transients, radiological consequences, and risk assessment will be described in details. Throughout the course, strong emphasis is placed on design-basis and severe accident analysis, role of engineered safety systems, siting, and licensing of the nuclear power plant. The course starts with brief discussion on neutron physics related to production, absorption and scattering of neutron, neutron cross sections and nuclear fission.

The next topics will emphasize on the principle of neutron moderation and neutron multiplication leading to steady state fission reactor core design based on diffusion theory. The principle of fusion reaction and energy production from controlled thermonuclear fusion is also briefly highlighted. In general, the course provides on the general concepts of neutron physics and it application in nuclear reactor for energy generation.

Introduction to Nuclear Engineering by John R. Lamarsh

The first part of material engineering is introductory to materials of sciences. Topics include classification of materials, atomic bonds, crystal structure, crystalline defects and solid solutions and phase diagrams. Main emphasis is on metals because metals are structurally the simplest to characterize.

The second part of the course deals with mechanics of materials. The list of the University required courses and their descriptions are presented in the introductory pages of the College of Engineering section in this bulletin.

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  • The list of the College required courses and their descriptions are presented in the introductory pages of the College of Engineering section in this bulletin. As part of the program for the Bachelor of Science in Nuclear and Science Engineering, the student is required to study 6 credit hours of technical elective courses.

    Nuclear Engineering: An Introduction

    These courses allow the student to focus on a specific area for in-depth knowledge and understanding. The student can also mix and match elective courses from the different areas to get a more general exposure to the different Nuclear and Science Engineering disciplines. The student should select, in cooperation with the academic advisor, the list of electives that best meet his or her needs and aspirations. It is highly recommended that the student register for these courses after completing the Departmental requirements.

    Students participating in Senior Design Project option must complete a 4 credits Senior Design project over two semesters. The Bachelor of Science in Nuclear Engineering encompasses credit hours that are spread over 8 semesters plus a summer training period which can normally be completed in four years. The following study plan serves as a roadmap for a smooth progression toward graduation. Various experiments covering the topics mentioned in Physics II course.

    Nuclear Engineering

    Probability concepts. Discrete random variables and probability distributions. Continuous random variables and probability distributions. Joint probability distributions.

    16. Nuclear Reactor Construction and Operation

    Introduction to parameter estimation. Computation of confidence intervals. Introduction to semiconductor materials and devices. Analysis of Diodes and. Amplifier circuits, bandwidth; feedback. Operational amplifiers and applications, filter and oscillator circuits. P re - r e qu i s i t e : - Circuit Analysis I;. Basic linear algebra: LU decomposition, normal equations and least squares solutions, eigenvalues and eigenvectors decomposition of matrices.

    Climate change and the future of energy. Free hand sketching, isometric drawing and orthographic projections. Properties of areas, second moments. Internal forces in beams. Laws of friction. Principles of particle dynamics. Mechanical systems and rigid-body dynamics. Kinematics and dynamics of plane systems.