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Course Criteria
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3.00 Credits
Spring and fall semesters. Prerequisite: NAME 3150. A study of ship hydrodynamic problems in the areas of viscous fluid motion, ideal fluid flow, two-dimensional hydrofoils, three-dimensional foils as well as propeller theory.
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3.00 - 4.00 Credits
Prerequisites: NAME 3150 NAME 3160 and MATH 2115. Linear oscillatory motion of floating bodies (Ships and Offshore Structures) due to water waves. Vibration theory, unsteady ideal flow theory, water wave theory, and linear ship motions theory. Prediction of ship platform motion in regular and irregular waves. Developments in hydroelasticity, maneuvering, and nonlinear ship motion. In addition a laboratory experience will allow the students to compare theoretical and computer predicted motions with measured motions in the wave/tow tank. A laboratory component is also included in the course.
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3.00 Credits
Prerequisites: ENGL 2152, NAME 3130, NAME 3171, either NAME 3150 or NAME 4154, and credit or registration in NAME 3120. Preliminary ship and offshore structures design to meet owner's general, environmental, and economical requirements; principal dimensions, form, power requirements and stability; outfitting; structural design; preparation of preliminary design drawings. Two hours of lecture and one three-hour laboratory per week. Not for graduate credit.
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2.00 - 3.00 Credits
Prerequisites: consent of department and Senior standing in engineering or equivalent. An introduction to legal problems which confront engineers in marine design, construction, and operation. Applies to river and ocean transport and offshore production.
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3.00 Credits
Prerequisite: Credit or registration in NAME 3160, NAME 4170. Completion of the project started in the prerequisite course; the preliminary design of a ship or other marine system component: hull, machinery, or an off-shore platform. Six hours of laboratory per week.
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3.00 Credits
Prerequisite: Credit or registration in NAME 3150. A study of advanced marine vehicle design for high-speed transport; transport factor evaluation of high-speed craft, design of high multi-hull crafts, surface effect ships, hybrid vessels, and wing in ground craft.
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3.00 Credits
Prerequisite: CHEM 1017 and PHYS 1061. Elements of materials science and of the corrosion of metals; effects of marine environments on construction materials; and methods for selecting materials in the design of marine structures and marine equipment.
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3.00 Credits
Prerequisite: NAME 4120 or consent of department. Energy methods applied to elements of ship structure; principles of virtual work; plasticity: static collapse of beams and plates; application of plasticity to various ship structural topics: slamming ice strengthening collision protection transverse web frame; ultimate strength of ship girder; probabilistic aspects; distribution curves of capability and demand; combination of varying stresses of different frequencies - quasistatic and vibratory stresses; probabilistic design of the hull girder to an acceptable risk of failure.
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3.00 Credits
(ENCE 4723, ENME 4723, and NAME 4723 are cross-listed). Prerequisite: ENME 3720 or ENCE 3318 or consent of the department. Elements of wind and wave generation and forecasting, tidal phenomena, hurricanes, storm surge, tsunamis, interaction of waves and wind with coastal and offshore structures, coastal and estuary processes. Design aspects of various topics are discussed and analyzed: e.g., offshore structures, spar buoys, underwater pipelines, oil production risers, coastal protection, mooring cables, vortex shedding, gas flares, beach formation, harbor resonance, structure resonance, etc. A design project is required.
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3.00 Credits
(NAME 4728 and ENME 4728 are cross-listed.) Prerequisites: Mechanical Engineering 3720. Classification of partial differential equations, mathematical description of fluid flow phenomena. Survey of various discretizaiton methods for the equations of fluid mechanics, including finite difference, finite volume and weighted residual methods. Basic algorithms for solving fluid mechanics problems. Introduction to grid generation. Application of existing CFD codes to practical engineering problems.
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