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Course Criteria
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3.00 Credits
Free and forced linear vibrations of damped and undamped mechanical and electrical systems of n degrees of freedom. Continuous system vibration. Manual and computer methods of finding natural frequencies. Self-and nonself-adjoint problems. Eigenfunction expansion. Integral transforms. Methods of approximating natural frequencies: Rayleigh, Rayleigh-Ritz, Ritz-Galerkin, Stodola, Holzer, Myklestad, matrix iteration. Perturbation techniques. Stability criteria. Prerequisites/Corequisites: Prerequisite: ENGR 2090 or equivalent. When Offered: Fall term annually. Credit Hours: 3
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3.00 Credits
The mechanics aspect of failure, fracture, and fatigue. Brittle fracture criteria. Derivation of laws of linear elastic fracture mechanics. Stress fields around cracks. Statistical aspects of fatigue. Cumulative damage. Contact fatigue. Prerequisites/Corequisites: Prerequisite: ENGR 2530. When Offered: Annually. Credit Hours: 3
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3.00 Credits
Mechanical behavior of materials and its influence on design applications. Topics include simple mechanical behavior (tension, compression, etc.), combined stress effects on deformation and fracture, ductile fracture, fracture toughness, creep behavior, fatigue, damping, and internal friction. Prerequisites/Corequisites: Prerequisite: ENGR 2530. When Offered: Fall term annually. Credit Hours: 3
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3.00 Credits
Solar irradiation, its nature, and its measurement. Insolation on tilted surfaces. Application of the principles of heat transfer and thermodynamics to the theoretical and experimental analysis of solar energy components used in the heating and cooling of buildings as well as hot water heating devices. Theoretical consideration of thermal storage devices, solar collectors, and solar-augmented heat pumps. Approximate techniques; other ongoing research topics. When Offered: Spring term annually . Credit Hours: 3
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3.00 Credits
Comprehensive treatment of conduction, convection (including boiling and condensation), and radiation heat transfer. Thermal system design and performance (including heat exchangers). Emphasis is on physical and mathematical modeling of engineering systems for application of modern analytical and computational solution methods. Prerequisites/Corequisites: Prerequisite: MANE 4010 or equivalent. When Offered: Fall term annually. Credit Hours: 3
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3.00 Credits
This course applies basic concepts of fluid mechanics and heat transfer to a wide variety of energy system components such as heat exchangers, pumps, fans, and bearings. Design and analysis techniques including modeling and simulation methods are developed for energy systems such as piping networks and refrigeration units. Prerequisites/Corequisites: Prerequisite: MANE 4010. When Offered: Spring term annually . Credit Hours: 3
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3.00 Credits
Introduction to elementary theory of combustion and applications to energy sources, fires, and explosions. Discussion of internal and external combustion piston and turbine engines, solid-and liquid-propellant rockets, fire and explosion hazards of gaseous fuels, propellant and explosive performance. Prerequisites/Corequisites: Prerequisite: MANE 4010 or equivalent. When Offered: Fall term annually. Credit Hours: 3
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3.00 Credits
Principles for the control of air properties to meet comfort and industrial requirements, load determination, psychrometry, cycles, transmission, distribution, and automatic control. Prerequisites/Corequisites: Prerequisite or Corequisite: MANE 4010. When Offered: Fall term annually. Credit Hours: 3
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3.00 Credits
The Navier-Stokes equations and the boundary layer approximation. Exact solutions and integral methods of incompressible boundary layers. Transition; turbulence. Convective heat transfer in laminar and turbulent flow. Prerequisites/Corequisites: Prerequisite: MANE 4070 or MANE 4010. When Offered: Fall term annually. Credit Hours: 3
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3.00 Credits
Solutions of acoustic wave and diffusion equations; stationary and moving monopole, dipole, quadrapole sources; geometrical acoustics; acoustical impedance, energy density, source strength, intensity flux; near and far field approximations; stationary and moving boundary interaction (viscous, dilational boundary layers, streaming, scattering). Applications include propeller, turbulent noise; total- and semi-anechoic chambers; loudspeakers; microphones, straight, tapered fluidic transmission lines; water hammer; musical instruments; room acoustics; sound absorbing, transmitting, and reflecting solid, liquid, gaseous media property determination. Prerequisites/Corequisites: Prerequisites: ENGR 2090 and MATH 2400. When Offered: Spring term alternate years. Credit Hours: 3
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