PAEGR112. Statics/StrengthofMatrls
A combined course of Statics and Strength of Materials covering resultants and equilibrium of force systems, trusses, frames, friction, centroids, moment of inertia, and axial stress and strain. Computer usage will be required.
PAEGR113. Statics and Dynamics
The student must have a working knowledge of college level algebra, trigonometry, and elements of calculus in addition to mechanics (physics). Primary objectives include the following: An understanding of equilibrium of particles and rigid bodies subject to concentrated and distributed forces, the mathematics of the motion of particles and rigid bodies, and of the relation of forces and motion of particles.
PAEGR114. Statics
This course deals with the principles of mechanics; force systems, coplanar and noncoplanar; concurrent, noncurrent; equilibrium; distributed forces, moments of inertia; and structures.
PAEGR115. Dynamics
Fundamental principles of dynamics as applied to particles and rigid bodies: force, mass, acceleration, work and energy, impulse and momentum and mechanical vibrations. The free body diagram approach and vector analysis methods are used throughout the course.
PAEGR201. Geology of Engineering
Investigation of the effects of geologic structure, groundwater, rock properties, and mineralogy on design and construction of highways, buildings, and tunnels. Typical solutions are discussed for problems of construction excavation and dewatering, tunneling methods, evaluating rock slope stability, and determining geologic substructure through use of maps and sub-structure through use of maps and sub-surface investigations.
PAEGR208. Applied Hydraulics
The design of water conveying and containment systems: pumps, sewers, open channels, dams, reservoirs, and water-related structures.
PAEGR209. Applied Hydraulics
Introduction to auxiliary machinery. Physical design and operational principals of pumps and hydraulic equipment, heat exchangers, distilling plants, and remote control apparatus, deck and steering machinery.
PAEGR210. Fluid Mechanics Theory
This course deals with the theory of incompressible and compressible fluid flows. Hydraulic pumps and actuators are studied with the goal of understanding fluid power systems and controls. Mathematical analysis of piping systems is covered in order to determine TDH of pumps, system resistance curve and piping sizing optimization. Topics include continuity equation, Bernoulli's Equation, series and parallel flow relative roughness, orifice calculations, pilot tubes and friction factors. A knowledge of computer programming is required.
PAEGR211. Mechanics of Materials
Examines strains that occur in elastic bodies subjected to direct and combined stresses, shear and bending moment diagrams, deflections of beams, and stresses due to torsion. An introduction to engineering materials and their mechanical proprties is also included. The laboratory includes testing of various materials such as cast iron, steel, brass, aluminum, and wood to determine their physical properties and to familiarize the student with the various material testing techniques.
PAEGR212. Strength of Materials II
A continuation of Strength of Materials to include torsion, shear and moments in beams, stresses and deflection in beams, concentric and eccentric joints, combined loading, columns and structural design of wood components. Lab experiments supplement the lecture material and include emphasis on reading instructions and report preparation. Computer programming projects will be required.
PAEGR215. Fluid Mechanics
The properties and behavior of fluids: density, pressure, fluid statics, buoyancy, hydraulic devices. Course examines fluid dynamics, continuity of flow, Bernoulli's equation, Venturi's principle, the Pitot tube, and fundamentals of dynamic lift. Orifices, nozzles, tubes, valves, and other applications of flow control devices. Discussions of viscosity and flow losses are incorporated.
PAEGR216. Hydraulics
Fundamentals of hydraulics including properties of fluids, fluid statics, principles of fluid flow, flow measurements, nozzles, orifices, weirs, open channel flow, introduction to hydraulic machinery, and including computer applications.
PAEGR217. Engineering Mechanics I
Basic concepts for the study of force systems and Newtonian mechanics, trusses and frames, torsion and bending, and friction centroids and moments of inertia. Engineering examples are stressed to develop understanding and application skills.
PAEGR218. Engineering Mechanics II
Stresses the study of bodies in motion, impulse and momentum, vibration and rotation, and work and energy. Lagrangian methods are introduced. Engineering applications are stressed.
PAEGR221. Industrial Materials
An introduction to engineering materials and their properties. Emphasis is placed on the factors that determine material properties and the process by which these properties can be changed in a controlled manner. Materials covered include steel, cast iron, non-ferrous metals and alloys, plastics, rubber and some other non-metalics.
PAEGR223. Mat'ls for Engr. Tech.
MATERIALS FOR ENGINEEREING TECHNOLOGY Materials important to manufacturing. Molecular & microscopic structures in relationship to material properties. Testing of mechanical & thermal properties with reference to ASTM standards. Equilibrium diagrams & physical metallurgy emphasizing steel & aluminum. Heat treatment of steel. Molding & forming methods for plastics.
PAEGR224. PROP. & Select of Mat'l
PROPERTIES AND SELECTION OF MATERIALS. Physical, mechanical, electrical, & chemical properties of various materials emphasizing metals & plastics. Criteria for selection of materials inlcuding cost, strength, weight, etc. Specifications including ASTM,AISI, MIL. The laboratory includes materials testing & basic metallury.
PAEGR225. Engr. Mat'ls & Processes
ENGINEERING MATERIALS AND PROCESSES> A combined lecture & laboratory course relating to the study of engineering materials. The processes of forming from liquid & particle state, plastic forming, molding deformation, & metal removal are all studied. The effects of heat treatment on material properties are discussed. Laboratory exercises are performed with basic machine tools, welding & guaging equipment.
PAEGR231. Corrosion Contr. Metals
An introduction to the characteristics and properties of metals, metal identification, and cathodic protection; theory, types, and forms of corrosion; chemical and mechanical removal of corrosion products; and steam cleaning and air spray painting equipment; includes conditioning metal surfaces and conventional air spray applications.
PAEGR232. Metallic Corros. Control
METALLIC CORROSION CONTROL. A course designed to give practical experience in the preparation of metal surfaces, corrosion inspection, and mechanical and chemical methods of corrosion removal; includes recognizing the various components, classes, functions and use of enamel, lacquer, epoxy, polyurethane, and elastomeric coating systems.
PAEGR233. Metallurgy
A study of metal structure, metallurgical examination, plastic deformation, phase diagrams, heat treatment, ferrous and non-ferrous alloys, wear, corrosion. Also includes powder, welding and foundry metallurgy.
PAEGR234. Metallurgy
Understanding of the properties of metals, methods of extracting and refining, the formulation of alloys, and the application of the appropriate metals for current technological purposes.
PAEGR235. Applied Metallurgy&HeatT
Applied Metallurgy and Heat Treating. Mechanical properties of ferrous metals through controlled cooling processes. The nature of metals, methods of microexamination, effect of alloys and principles of heat-treating metals.
PAEGR301. Geotechnical Engineering
Analysis and design of soil and soil-structure systems, geomembrances, reinforced earth, soil anchors and soil retaining structures; settlement control.
PAEGR306. Hydraulics & Pipe Flow
A study in the basic theory of the hydraulics of flow in pipes and in open channels (fluid mechanics). Presented are illustrations and examples of piping and other equipment used in buildings and factories for water supply, sewage, transfer of liquid products and wastewater disposal.
PAEGR307. Thermodynamics I
An introduction to heat and work processes that covers units, properties, energy, first and second laws, perfect gases, and compressible flow.
PAEGR308. Thermodynamics II
Power and refrigeration cycles, heat transfer, and contemporary problems in energy conversion.
PAEGR309. Fluid Flow
Elementary theory of fluid flow; hydrostatics; flow through orifices, Venturi meters, and pipes; flow in open channels; theory of the centrifugal pump.
PAEGR310. Fluid Machinery
The operations, performance, and selection of equipment and machinery for fluid power applications will be studied. Topics will include properties of fluids used in engineering applications, fluid control and protection devices, pipe flow systems and ducting design, applied measuring devices, basic fluid machinery design and selection including basic classification, operation, performance characteristics, and selection of pumps, compressors, fans, and turbines.
PAEGR312. Thermodynamics
First and second laws of thermodynamics. Properties of liquids and gases. Process and cycle analysis. Application to turbines, compressors heat engines and refrigeration units.
PAEGR313. Thermodynamics
Non-calculus discussions of law of thermodynamics; the general energy equation, properties of water; methods of heat transfer; fluid statics; fluid mechanics - Bernoulli's principle. Conceptual discussion of compressible and incompressible flow, fluid measurements, pumps, valves systems; ideal and real gases; Cycles - Carnot, Rankine, Rankine Regenerative Reheat, Refrigeration; Reactor Thermal and Hydraulic Limits.
PAEGR314. Thermodynamics
Investigates the basic properties and behavior of thermodynamic systems. Topics include termperature, pressure, work and heat, heat transfer. First Law of Thermodynamics ideal gas equation, calorimetry, thermal processes, entropy and the Second Law. Fundamental thermodynamic principles are applied to the analysis of heat engines and refrigeration cycles.
PAEGR315. SteamPowerCyc.&Thermohyd
STEAM POWER CYCLE & THERMOHYDRAULICS. Types of fluid flow; heat transfer fundamentals; boiling water reactor heat transfer and thermal-hydraulics; critical power, linear heat generation rate; reactor heat balance. Ideal gas; phase change, phase diagrams; laws of thermodynamics, heat engines; steam power cycles; Mollier diagram; elements of fluid mechanics.
PAEGR316. Applied Thermodynamics
The topics discussed in this course are the basic principles of thermodynamics and their applications to internal combustion engines, turbines, compressors, power generating, and refrigerating, and refrigeration systems.
PAEGR317. Fluid Systems
An introduction to fluid mechanics to include both hydraulic and pneumatic systems in terms of fluid statics, fluid flow, frictional and minor losses in a system, flow measurements and control, pump characteristics and selection, and pipe sizing.
PAEGR318. Fluid Mechanics
Fundamental fluid statics: manometry, forces on submerged surfaces, Archimedes' principle. Details of one-dimensional incompressible flow; conservation laws and application to flowing systems, cavitation, impulse-momentum problems, vanes. Pipe flows: laminar analyses, turbulent flows with emphasis on calculation of fluid properties. One-dimensional compressible flow; conservation laws, specialization to isentropic situation nature of speed of sound. Applications including effects of area change, converging and diverging nozzles, choking phenomena, normal shock waves.
PAEGR319. Thermodynamics
Basic laws of energy and thermodynamics and their application to heat-power machinery applied on shipboard; heat-power plants , steam generators and boilers, feed water heating, steam engines, steam and gas turbines, steam condensing equipment, internal combustion engines and vapor compression refrigeration
PAEGR320. Transport Processes
An introduction to the properties, terminology, concepts and basic laws of fluid statics and dynamics, thermodynamics and heat transfer.
PAEGR321. Properties of Materials
This course is intended for bachelor of technology students and is an introduction to the principle metallic and non-metallic engineering materials, including their physical properties, response to heat treatment, corrosion resistance, machining characteristics, surface finishing, and extrusion processes.
PAEGR322. Engineering Materials
This course introduces the student to such engineering materials as metals, viscoelastic materials, ceramics, polymers , and semi-conductors. The approach is interdisciplinary with stress upon the structure of materials. Various mechanical and thermal treatments are discussed and related to the stability of the resultant properties. The laboratory session implement and emphasize the effects of these mechanical and thermal treatments on the materials.
PAEGR323. Strength of Materials
Stresses and strains in members under the actions of axial and shearing forces, bending and twisting moments. Transformations of stress and strain; principal stresses. Combined stresses; pressure vessels. Deflection of beams. Statically indeterminate problems. Columns and structural connections.
PAEGR324. Strength of Materials
The mathematical determination of stress and deflection for materials having applied loads of normal, shear, torsional, bending, or combinations of these. The rational design of mechanical components such as fasteners, weldments, tanks, shafts, beams, and columns, to satisfy stress, deflection, and stability criteria. Mohr's circle and strain gauge techniques.
PAEGR325. Mechanics of Materials
Loads, stresses, strains, strain energy, Hook's law, temperature effects, torsion, shear, flexural stresses, beams, shear and moment diagrams, deflection - various approaches, statically indeterminate beams - various approaches combined loading, columns.
PAEGR326. Engineering Materials
Topics of materials properties with greatest emphasis on metals used in marine applications. Failure characteristics studied are mechanical, creep, fatigue, and corrosion. Heat treatment practice and theory are covered, including phase diagrams.
PAEGR330. Ferrous Metallurgy
Designed to provide the student with a comprehensive understanding of the physical properties, metallurgy and application of steels. Current commercial heat treating, joining and forming practices discussed as they relate to practical and economic uses.
PAEGR331. Metallography
Structure of pure and single phase alloys. Micro-structural changes across equilibrium diagrams of binary alloys. Effects of deformation and annealing, phase changes in solid state. Micro structures of ferrous and nonferrous alloys, metals in service.
PAEGR332. Metallography II
Micro-structures of cast irons and stainless steels. Changes in micro-structure from heat treating and joining. Surface treatments. Identification of kinds and causes of common failures of metals.
PAEGR333. Non-Ferrous Metallurgy I
Alloys of aluminum, magnesium, titanium, beryllium, and the copper base alloys, i.e., brasses and bronzes. How the alloys are won, processed, and the expected properties.
PAEGR334. NonFerrous Metallurgy II
Nickel-based alloys, low melting point alloys, noble metals, refractory metals, and heavy metals. Special materials, for example, carbides, ceramics, composites. Alloys, processing, and properties of these materials.
PAEGR335. Contemp. Metal Processes
Designed to update students with recent developments in the metals area. EDM, NC, hydraulic control, new foundry processes and advanced chip forming techniques are explored. There is opportunity for individual research and presentation of individual topics in a simulated teaching situation.
PAEGR336. Intro. to Ceramics
Engineering applications of ceramic materials and processes. Crystal structure and ionic bonding of ceramic materials; structure of glasses; point defects, point-defect chemistry and relation to nonstoichiometry; line defects and grain boundaries diffusion in stoichiometric and nonstoichiometric oxides; phase diagrams; phase transformations and the design of glassceramics; grain growth, and sintering.
PAEGR337. PlasticsMolding & Proces
Manipulative processes. Injection, compression, transfer and rotational molding. Process procedure, cycle preparation and adjustment, material selection and use, machine set-up and function, sequential operation, mold use, maintenance and safety. PLASTICS, MOLDING & PROCESS
PAEGR341. Prob Methods Engineering
Probability concepts and their engineering applications. Discrete and continuous random variables, distribution and density functions, random vectors, conditional probabilities and independence, and decision models, including the Bayesian approach. PROBABILITY METHODS ENGINEERING
PAEGR342. Physical Measurement
Physical Measurement and Analysis - Introduction to a number of experimental measuring techniques in mechanical engineering. Analysis of experimental data with special emphasis on accuracy, errors, and uncertainty in experimental measurements.
PAEGR351. Energy Conversion
Starting with basic principles of energy conversion, the vast area of modern energy technology is covered. Fossil, nuclear, solar, and geothermal energy resources and current and future methods of energy conversion are analyzed. State of the art and present research areas reviewed. Technical and economic feasibility of processes, equipment, and plants is analyzed.
PAEGR352. Energy Conversion System
Application of the principles of thermodynamics and fluid mechanics to steam and gas turbines, refrigerators, internal combustion engines, jets, and nozzles. Direct conversion. Experiments in heat transfer and thermodynamics. Calculations from data. Analysis of results.
PAEGR353. Solar Energy Application
This course is an elective course for technologists. It is concerned with the practical application and uses of solar energy. The technology of applications for domestic water heating, space heating, and low temperature water heating for industrial processes will be emphasized as well as instrumentation and controls for solar systems.
PAEGR354. Solar Thermal Energy
Solar Thermal Energy Collection and Storage - An introduction to the design and theory of systems that employ solar thermal energy as a replacement for fossil fuel energy used in buildings and homes.
PAEGR361. Adv.Fibergls.Boat&Access
Advanced Fiberglass Boat and Accesory Construction. This course will teach the student advanced methods of boat building and the manufacturing of fiberglass accessories - students will construct a fiberglass boat.
PAEGR401. Engineering Design
The design process, including decision theory, creativity concepts, human factors, optimization techniques, reliability and professional ethics. Engineering economy. Material selection and testing. Fatigue and fracture design.
PAEGR411. Advanced Fluid Mechanics
Conservation laws, viscous flow in ducts, fully developed flow, turbulent flow, pipe networks, general theory of turbomachines including pump performance and characteristics, pump cavitation and hydraulic turbines. Laminar and turbulent boundary layer flow.
PAEGR412. Heat Transfer
This course covers conduction, radiation and convection. Both steady and unsteady conduction problems are emphasized. Forced free convection heat transfer are discussed, as well as heat exchangers.
PAEGR413. Industrial Fluid Circuit
Applied fluid mechanics, applications of hydraulic and pneumatic control amplification, and power circuits. Introduction to fluidics. Project laboratory for constructing and testing of circuits demonstrating the lecture.
PAEGR421. Adv.StrengthOfMaterials
Theories of stress and strain. Energy methods. Deflections of structures using the method virtual work and Castigliano's theorem. Analysis of statically indeterminate structures. Classical and modern theories of curved beams subjected to general loading. Determination of stresses and deformations of curved beams with various boundary conditions. Thickwalled cyliners; shrink fits. Flat plates. Beams on continuous elastic support.
PAEGR422. Mech.Props. of Materials
Mechanical behavior of metals, ceramics, polymers, and composites. Elastic and plastic behavior. Theories of yielding, brittle fracture, time-dependent behavior, and fatigue. Relation of properties to structure.
PAEGR430. Phys.Metal.of Nonferrous
Physical Metallurgy of Nonferrous Metals. Nonferrous metals to include aluminum, magnesium, copper, refractory metals, titanium, and ceramics: methods of heat treatment and design applications of nonferrous metals.
PAEGR431. Electron Microscopy
This course combines the lecture and lab in introducing the field of electron microscopy. Topics include magnetic electron lenses, electron optical systems, selected area diffraction, sample preparation, thin foil techniques, and photography. (Prequisite: Chemistry and Physics)
PAEGR432. X-Ray Diffraction
This course combines the lecture and lab in introducing the methods of X-ray diffraction. Topics include directions and intensities of diffracted beams, diffractometer methods, Laue methods, power photographs, reciprocal lattice constructions, and the rotating crystal method.
PAEGR433. Proc.Glass,Ceramic Matls
PROCESSING OF GLASS, CERAMIC AND GLASS-CERAMIC MATERIALS. Conventional and unconventional techniques for processing glass, glass-ceramic, and ceramic materials. Case studies illus trate the design, engineering and scientific aspects of such processes. Vapor processes for high purity optical fibers, hotprocessing of ceramic turbine blades, photosensitive materials, and powder processing and sintering of ceramics will be discussed.
PAEGR434. Engineering Polymers
Mechanisms of polymerization reactions and practical production of polymers with desired properties. Bulk macroscopic properties of solid rubbers, glasses, and semicrystalline polymers and their relationships to chemical composition at the molecular level; pertinent physical parameters considered in detail.
PAEGR435. Polymer Processing
Starting with polymers as a raw material; covers the most common techniques of processing them. The fabrication technique with monomers, as in urethane, is discussed. Reason for and purpose of the different techniques are presented as a function of their economic importance. Processes such as laminating, injection molding, and extrusion are discussed. Effects of heat and pressure are emphasized, as well as electrical properties and the thermal and chemical degradation of polymers.
PAEGR436. Properties/Solid Polymer
Synthetic and natural polymers for engineering applications. Production and characterization of long chain molecules. Gelation and networks, rubber elasticity, design of elastomers and thermosetting resins. Amorphous and crystalline thermoplastics and their structure. Time and temperature dependent elastic properties of polymers. Plastic deformation and fracture. Design of high impact strength polymers. Fiber drawing and fiber properties.
PAEGR437. Fundamentals of Polymers
An introduction to the important fundamental aspects of polymers including preparation, structure, physical states and transitions, molecular weight distributions, viscous flow and mechanical properties.
PAEGR438. Introductory Polymer Lab
INTRODUCTORY POLYMER LABORATORY. A course in practical methods useful in the preparation and characterization of macromolecules, including addition and condensation polymerization. Various methods useful in characterizing polymers will be studied, such as solution and bulk viscosity, light scattering, osmometry, D.T.A., T.G.A., X-ray diffraction, and various chromatographic and spectroscopic techniques.
SPEGR311. Heat Transfer
Heat transfer by modes of conduction, convection and radiation. Fundamental principles of heat transfer and radiation. Heat transfer and application to the solution of industrial heat transfer problems. NAVY NUCLEAR POWER SCHOOL