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Course Criteria
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3.00 Credits
- 3 credits This course is a continuation of EGR260 Aerodynamics I and includes basic compressible flow theory. The subject matter includes inviscid compressible flow, shock and expansion waves, onedimensional flow theory, wing theory, principles of stability and control, and aircraft propulsion. Prerequisites: EGR210, EGR215 and EGR260
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3.00 Credits
- 3 credits This introductory course utilizes the principles of statics, dynamics and strength of materials in the design of machine elements such as gears, shafts, bearings, springs, clutches and brakes. Topics covered include fatigue, theory of failure, dynamic loading conditions, fasteners and the kinematic motion and control of machine parts and linkages by use of graphical, analytical and computer methods. Prerequisites: EGR215, EGR220; fall offering only
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3.00 Credits
- 3 credits In this course students will be introduced to the numerical solution of many physical problems, such as, vibration, heat transfer and structural problems. The numerical solution for the governing equation of a physical system will be conducted by finite element techniques. In this course students will be introduced to the finite element methods and their implementation to the engineering problems. Prerequisite: EGR220; corequisite: EGR340
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3.00 Credits
- 3 credits Fundamental process of cycle energy analysis of ideal and real systems, thermodynamics of fluid flow, properties and processes of gas and vapor mixtures, thermodynamics of reactive systems, modern gas and vapor power cycles and refrigeration cycles are covered. Prerequisite: EGR210; fall offering only
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3.00 Credits
R- 3 credits This course discusses the principles of heat transfer. Included is a discussion of conduction, convection, radiation and heat exchangers. Computer applications are also covered. Prerequisites: MAT220, EGR210
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4.00 Credits
- 4 credits Given a specification for a small, twoengine turbofan-type airplane, the student develops its overall configuration. Characteristics include fuselage, propulsion system, wing and high-lift devices, tail surfaces, landing gear arrangements, and weight and balance limitations. This is then adapted to a specified mission profile, all in conformance with the appropriate regulatory airworthiness and operational criteria. Lectures are supplemented with laboratory work. Prerequisites: EGR260, EGR225, EGR235. Corequisite: EGR360
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3.00 Credits
- 3 credits In this course an attempt is made to emphasize basic structural theory related to the aircraft design. Heavy emphasis is placed on the application of the elementary principles of mechanics to the analysis of aircraft structures. This course will cover topics on shear and bending stresses, spanwise air-load distribution, external load on the airplane, joints and fittings, design of members in tension, bending and torsion, design of webs in shear and deflections of structures. Prerequisite: EGR225, EGR340
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3.00 Credits
- 3 credits Economic aspects of engineering design, construction and operation are covered. Selection among several alternatives, including annual cost, present worth and rate of return, are some of the methods of analysis discussed. Economic life and replacement are covered. Prerequisite: MAT120; fall offering only
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3.00 Credits
- 3 credits A basic course in industrial inspection methods, the use of gauges, electronic and optical comparators, statistical analysis of mass produced items and the use of control charts to detect changes in process. Other topics covered are the setting of control limits and lot sizes for sampling, sampling by variables and attributes, percent prediction of probable defects in a monitored process, production control and production reliability. Prerequisite: MAT356
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3.00 Credits
- 3 credits This course is presented as an introductory course for new Patran users. Students will master the basic skills required to use Patran in mechanical engineering applications. The course emphasizes practical skills development through comprehensive, hands-on laboratory sessions. Students will learn to build analysis models using Patran, define material properties, create boundary conditions, apply loads, and submit their job for analysis and postprocessor results using Nastran.
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