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MENG 3610 Mechanical Measurements Laboratory
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
ENGR 3120 (Minimum Grade of D, May not be taken concurrently)
MTH 4270 (Minimum Grade of D, May not be taken concurrently)
An extensive set of laboratory experiences to illustrate mechanical measurements and data analysis. Experiments are designed to demonstrate the application of force, temperature, pressure and other transducers. Data acquisition and presentation of data are emphasized. | 2 | 0 | 0 | | |
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MENG 3800 Thermodynamics II
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
ENGR 3150 (Minimum Grade of D, May not be taken concurrently)
The application of the First and Second Laws of Thermodynamics to power and reversed cycles, psychometric processes, and combustion phenomena. Thermodynamic relations for simple compressible substances are developed. The design of power plants, refrigeration and climate control systems are considered. | 3 | 0 | 0 | | |
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MENG 3820 Manufacturing Processes
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
ENGR 3120 (Minimum Grade of D, May not be taken concurrently)
ENGR 3170 (Minimum Grade of D, May be taken concurrently)
Corequisites: ENGR 3170
The study of the unit processes of manufacturing: machining, forming, casting and joining. The course considers measurements, tolerances, quality control and materials as they relate to manufacturing. The design of a manufacturing process, gages and fixtures is considered. | 3 | 0 | 0 | | |
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MENG 3830 Manufacturing Processes Laboratory
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
MENG 3820 (Minimum Grade of D, May be taken concurrently)
Corequisites: MENG 3820
A set of laboratory experiences to illustrate measurements, quality control and unit processes in manufacturing. Students will use machine tools, forming, casting and welding equipment. | 1 | 0 | 0 | | |
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MENG 3900 Intermediate Mechanics of Materials
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
ENGR 3130 (Minimum Grade of D, May not be taken concurrently)
ENGR 3170 (Minimum Grade of D, May not be taken concurrently)
ENGR 3260 (Minimum Grade of C, May not be taken concurrently)
An application of engineering sciences to the design of mechanical components. The course considers theories of failure, selection and proportioning of machine elements, fatigue, stress concentration and buckling of columns. The design of machines containing power screws and fasteners is treated in depth. | 3 | 0 | 0 | | |
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MENG 3920 Machine Design
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
MENG 3900 (Minimum Grade of C, May not be taken concurrently)
The solution of problems involving systems of machine elements. The use of gears, springs, shafts and bearings is treated in depth. Static and dynamic considerations are made to system design. Design projects are used as a principal method of instruction. | 3 | 0 | 0 | | |
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MENG 4000 Adv Topics In ME
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Special Topics in mechanical engineering depending on technical relevance and/or technical currency. | 1 | 0 | 0 | | |
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MENG 4300 Metal Cutting Analysis
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
MENG 3820 (Minimum Grade of D, May not be taken concurrently)
ENGR 3130 (Minimum Grade of D, May not be taken concurrently)
An application of elastic and plastic theories is used to discuss advanced topics in metal cutting. These include machine tool operations, mechanics of cutting forces and power in cutting, tool wear and tool life. Economics of machining and cutting temperatures, current trends in machining are discussed. | 3 | 0 | 0 | | |
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MENG 4320 Metal Forming Analysis
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
MENG 3820 (Minimum Grade of D, May not be taken concurrently)
ENGR 3260 (Minimum Grade of D, May not be taken concurrently)
The analysis of extrusion, drawing, rolling and forging processes. The role of formability of materials and processing conditions are treated with engineering science. | 3 | 0 | 0 | | |
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MENG 4350 Quality Control Systems
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
MTH 4270 (Minimum Grade of D, May not be taken concurrently)
This course is specifically designed to provide students with the fundamental principles and approaches involved in analysis of data for quality control purposes. Topics covered include control charts, sampling procedures, process capability analysis, aspects of design specifications and tolerance analysis. It lays the foundation for more in-depth analysis of various quality systems and their principles by discussing the relationship between product features, manufacturing and quality control process. | 3 | 0 | 0 | | |
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MENG 4400 Adv Mechanics Of Materials & Solids
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
ENGR 3260 (Minimum Grade of D, May not be taken concurrently)
Study of mechanics of deformable bodies, including three-dimensional stress and strain tensors and their transformations. Equations of compatibility, continuity and equilibrium. Elastic constants. Failure criteria including fracture, yield and instability. Deflection relations for complex loading and shapes. indeterminate problems. Design applications and numerical methods. | 3 | 0 | 0 | | |
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MENG 4580 Internal Combustion Engines I
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
MENG 3800 (Minimum Grade of D, May not be taken concurrently)
The application of principles of chemistry and thermodynamics to the theory and design of gas power engines. The concepts of spark ignition, compression ignition, cycle analysis and combustion characteristics are treated in-depth. | 3 | 0 | 0 | | |
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MENG 4590 Internal Combustion Engines Lab
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
Corequisites: MENG 4580
A set of laboratory experiments to illustrate the principles of gas powered engines. Students use various dynamometers and specialty engines. | 1 | 0 | 0 | | |
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MENG 4720 Noise and Vibration
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
ENGR 3130 (Minimum Grade of D, May not be taken concurrently)
MTH 3720 (Minimum Grade of D, May not be taken concurrently)
An overview of problems in acoustics and vibration control. The use of single and multiple degree of freedom lumped parameter systems are used to describe systems. Methods for controlling noise and vibration sources are discussed. | 3 | 0 | 0 | | |
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MENG 4760 Vehicle Dynamics
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
ENGR 3130 (Minimum Grade of D, May not be taken concurrently)
MTH 3720 (Minimum Grade of D, May not be taken concurrently)
Modeling and analysis of the dynamics of vehicles, particularly of four wheeled motor vehicles. Topics include: fundamentals of modeling; dynamic axle loads/instability; power, traction, and stability limited acceleration; braking and stability under lockup; aerodynamics, rolling resistance, and total road load; ride excitation sources; ¼ car and full car suspension models; low speed and high speed cornering; the tire/road interface; wheel alignment effects; tractor trailer handling and stability; other topics as time and interest permit. Computer projects (simulations) required. | 3 | 0 | 0 | | |
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MENG 4780 Manufacturing Productivity
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
MENG 3820 (Minimum Grade of D, May not be taken concurrently)
A critical analysis and examination of productivity measurements. The use of time and motion studies, ergonomics and simulation are used. The technological blocks to productivity and methods of enhancing productivity are considered. | 3 | 0 | 0 | | |
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MENG 4800 Energy Systems
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
ENGR 3150 (Minimum Grade of D, May not be taken concurrently)
ENGR 3140 (Minimum Grade of D, May not be taken concurrently)
Applications of thermodynamics and fluid mechanics to energy conversion systems. Advanced modifications to basic vapor and gas power and refrigeration cycles are analyzed. Second Law (availability) analysis is applied to energy conversion processes. Other topics include: hydraulic machinery, nuclear power systems, solar energy, energy storage techniques, and wind power. Environmental issues surrounding the various types of energy systems are discussed. | 3 | 0 | 0 | | |
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MENG 4810 Alternative Energy Systems
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
ENGR 3140 (Minimum Grade of D, May not be taken concurrently)
ENGR 3150 (Minimum Grade of D, May not be taken concurrently)
Focus on alternatives to conventional energy systems for power generation, refrigeration, and transportation. Students will apply principles of thermodynamics, fluid mechanics, and other engineering disciplines to the analysis of solar, wind, nuclear, geothermal, tidal, and fuel cell power systems. An overview of global energy use and modeling will be presented. Other course topics include alternative fuels for transportation, new developments in energy storage, and the role of energy efficiency improvements in the achievement of a more equitable and sustainable global energy distribution. Environmental and economic issues surrounding the various alternatives will be addressed. | 3 | 0 | 0 | | |
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MENG 4820 Computer Integrated Manufacturing
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
MENG 3820 (Minimum Grade of D, May not be taken concurrently)
This course teaches the theory and practice of the use of computers in manufacturing engineering. Students will study in depth the use of computers during a manufacturing process, including: numerical controlled machines (CNC), programmable logic controllers (PLC), coordinate measuring machines (CMM), vision technology and systems, robotics and networks/data exchange. Projects are the principal mode of instruction. | 3 | 0 | 0 | | |
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MENG 4830 Computer Integrated Manufacturing
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
ENGR 2040 (Minimum Grade of D, May not be taken concurrently)
MENG 3820 (Minimum Grade of D, May not be taken concurrently)
This course teaches the theory and practice of the use of computers in manufacturing engineering. Students will study in depth the use of computers during a manufacturing process, including: numerical controlled machines (CNC), programmable logic controllers (PLC), coordinate measuring machines (CMM), vision technology and systems, robotics and networks/data exchange. Projects are the principal mode of instruction. | 3 | 0 | 0 | | |
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MENG 4880 Reliability in Design
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
MENG 3900 (Minimum Grade of D, May not be taken concurrently)
MTH 4270 (Minimum Grade of D, May not be taken concurrently)
A study of probabilistic models in engineering design. Topics include: reliability distribution functions, failure rate, system reliability, hazard analysis, FMEA and reliability testing. The use of the probabilistic approach to the design of mechanical components is treated in depth. | 3 | 0 | 0 | | |
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MENG 4900 Robotics
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
MTH 3720 (Minimum Grade of D, May not be taken concurrently)
ENGR 3130 (Minimum Grade of D, May not be taken concurrently)
The modeling and analysis of robotic systems. Key topics include spatial description and transformations., forward and inverse kinematics, jacobians, dynamics, an introduction to machine vision, and task planning. Students program a robot to perform a task. | 3 | 0 | 0 | | |
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MENG 4910 Manufacturing Systems
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
ENGR 3130 (Minimum Grade of D, May not be taken concurrently)
MTH 3720 (Minimum Grade of D, May not be taken concurrently)
This course is focused on modeling, analysis, and optimization of manufacturing systems. In this regard, manufacturing concepts such as dedicated, lean, flexible, agile, manufacturing cells, just-in-time, and product design considerations for manufacturing are studied. Computer aided process planning, computer aided manufacturing, and the impact of the manufacturing system on quality and on the economy will be included. | 3 | 0 | 0 | | |
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MENG 4920 Computer Aided Engineering
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
MENG 3900 (Minimum Grade of D, May not be taken concurrently)
ENGR 1050 (Minimum Grade of D, May not be taken concurrently)
ENGR 1070 (Minimum Grade of D, May not be taken concurrently)
Corequisites: MENG 3900
An introduction to the use of computer techniques to analyze mechanical components and systems. The course includes kinematic synthesis, optimal design, finite element methods and simulation. | 3 | 0 | 0 | | |
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MENG 4930 Prototype Design I
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
MENG 3900 (Minimum Grade of D, May not be taken concurrently)
The first half of a two-term sequence dealing with the solution of an industrial design problem. Students work in teams to design, analyze, construct and test a working prototype of the solution to a specified problem. The use of standard design disciplines are emphasized (failure mode and effect analysis and design verification plans). The preparation and presentation of design proposals are central to the course. | 2 | 0 | 0 | | |
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MENG 4940 Modeling of Dynamic Systems
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
MENG 3820 (Minimum Grade of D, May not be taken concurrently)
This course is focused on modeling, analysis, and optimization of manufacturing systems. In this regard, manufacturing concepts such as dedicated, lean, flexible, agile, manufacturing cells, just-in-time, and product design considerations for manufacturing are studied. Computer aided process planning, computer aided manufacturing, and the impact of the manufacturing system on quality and on the economy will be included. | 3 | 0 | 0 | | |
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MENG 4950 Prototype Design II
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
MENG 4930 (Minimum Grade of C, May not be taken concurrently)
The second half of the two-term sequence that begins with MENG 4930. This course must be taken in the same academic year as MENG 4930. The fabrication and testing of a working prototype is emphasized. The methods for the presentation of results and alternative solutions are central to the sequence. | 3 | 0 | 0 | | |
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MENG 4980 Internal Combustion Engines II
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Prerequisites:
MENG 4580 (Minimum Grade of D, May not be taken concurrently)
The continuation of the theory and design of gas power engines. Particular attention is given to detailed design considerations. The effects of changes in engine parameters on fuel economy, performance and emissions are studied. | 3 | 0 | 0 | | |
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MENG 4990 Independent Study and Research
| Credit Hours | Recitation/Lecture Hours | Studio Hours | Clinical Hours | Lab Hours |
Individualized student effort under the guidance of a faculty member. The intent of this is for students and faculty members to pursue undergraduate research topics that are not currently offered through regular coursework at the university. Prior to registration for Independent Study, the student and instructor must sign a contract that outlines course content and expectations. Culmination of the course is a graded, formal written report detailing the semester-long study. | 1 | 0 | 0 | | |
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