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Course Criteria
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3.00 Credits
Prerequisite: NAME 3120. Review of longitudinal strength; principal stress distributions and stress trajectories; local strength analysis; panels under lateral load; columns and stanchions; panels in buckling under uniform edge compression loading and panels under shear and combination loading; rational ship section design synthesis based on stress and loading hierarchy; primary, secondary, and tertiary stresses as criteria of strength in ship structural design, including grillage aspects.
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3.00 Credits
Prerequisite: NAME 2160. Design and analysis of floating offshore platforms in general. Unsteady hydrodynamics, linear and nonlinear water waves, prediction of wave forces on large and small bodies. Fluid pressure forces on moving bodies using relative motion approach and radiation/diffraction approach. Analysis and prediction of random waves and vessel response using spectral methods. Additional topics such as mooring analysis as time permits.
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3.00 - 4.00 Credits
Prerequisite: NAME 3120. Composite materials are introduced presenting their classification, fundamental characteristics, and main advantages and disadvantages. Present and future applications within the marine industry are discussed together with the materials most commonly employed and available manufacturing methods. Elements of the mechanics of both laminate and sandwich topologies are analyzed. Additional topics cover their performance characteristics, failure, maintenance, repair, testing and regulatory aspects are. Three hours of lecture and three hours of laboratory.
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3.00 Credits
Spring and fall semesters. Prerequisite: NAME 3130. A study of ship propulsion systems, including waste heat utilization, availability, diesel engine performance, compressible pipe flow, shafting alignment, machinery vibration, and torsional vibration analysis.
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3.00 Credits
(ENMG 4131, ENME 4734, and ENEE 4131 are cross-listed) Prerequisite: MATH 2115. Review of probability and statistics; analytical stochastic models for component and system failures; strategies for inspection, maintenance, repair and replacement. Introduction to fault-tree and event-tree analysis; frequency and duration techniques; Markov models; and case studies.
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3.00 Credits
Phases of ship life cycle, the economics of costs versus benefits, qualitative and quantitative analysis of marine systems, ship life cycle cost elements and total cost of ownership, systems engineering process modeling, ship design, production, maintenance and operation processes, decision making under uncertainty, databases, dynamic programming, risk-based decision making, management of human and organization error in ship operations concurrent engineering.
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3.00 Credits
Prerequisite: Junior standing or consent of department. An examination of the shipbuilding industry and ship construction techniques is provided including analysis of the market and management theory for shipyards, product work breakdown structure, modular methodologies, manufacturing methods, outfitting and painting techniques, shipyard layout and organization, planning/ scheduling, and accuracy/quality assurance. Emphasis is placed on welding and lean six sigma practices.
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3.00 Credits
Prerequisites: MATH 2112 and CSCI 1201. Computer-aided design of curved surfaces; wire-frame outlines of surface; boundary conditions; surface patches; geometric properties of surface; and smoothness.
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3.00 Credits
Prerequisites: MATH 2112 and CSCI 1201. Computer-aided design of mechanical piece parts and assemblies of parts; a high-level language for modeling parts and assemblies; dimensioning and tolerancing; and the mathematics that underlies solid models and computer graphics.
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3.00 - 4.00 Credits
Prerequisite: Credit or registration in NAME 3120. Case study of a 60-foot motor boat design, planing theory, trim, lift and drag in planning. Use of standard series, hydrofoil vessel performance calculations, sea keeping, hull structure, hull materials, powering using supercavitating propellers or pump-jet. Team Design project required for all students. Three hours of Lecture and three hours of Laboratory.
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