Fundamental concepts of thermodynamics. Thermal properties of substances and state equations. Conservation of mass, first and second laws. Examples of applications to different engineering systems.

Prerequisites:

PHYS 221

This course is an introduction to numerical analysis. The primary objective of the course is to develop a basic understanding of numerical algorithms and skills to implement algorithms to solve mathematical problems on the computer.

Prerequisites:

MATH 122, ME 201

Probability and statistics. Uncertainty, distributions. Numerical solution of algebraic, transcendental and differential equations. Numerical integration and differentiation. Structured programming language required.

Prerequisites:

MATH 122, PHYS 221. Select one from EE 107, CIVE 201, ME 201

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Basic principles of thermodynamics, fluid mechanics, and heat transfer. First and second laws of thermodynamics and application to engineering systems and their design. Not for mechanical engineering major.

Prerequisites:

PHYS 221 with "C-" (1.67) or better

Physical principles of elastic and plastic deformation of materials. Dislocation theory. Fatigue, creep, fracture, hardness, phase diagrams and other mechanical phenomena in materials. Ceramics and composite materials. Residual stresses. Lecture and lab demonstrations.

Prerequisites:

ME 223

Introduction to fluid properties, fluid statics, buoyancy, fluid kinematics, Bernoulli's equation, control volume and differential approach to flow conservation equations, dimensional analysis, similitude, viscous flow in pipes, flow over immersed bodies, and pumps. Includes significant design component. Prerequisite: MATH 223, ME 214 Co-requisite: ME 241

Prerequisites:

MATH 223, ME 214

Steady and unsteady conduction. Free and forced convection. Heat transfer by radiation. Combined modes of heat transfer. Elements of heat exchangers design. Includes significant design component.

Prerequisites:

ME 241, ME 321

Energy analysis and design of thermodynamic systems including power and refrigeration cycles. Thermodynamic relations. Application of thermodynamics to mixtures and solutions. Psychometrics. Introduction to chemical thermodynamics. Third law of thermodynamics. Includes significant design component.

Prerequisites:

CHEM 191, ME 241

Introduction to manufacturing, tribology, casting, bulk deformation, sheet metal forming, material removal, joining, polymers, powder metals, ceramics, automation, integrated systems. Design for manufacture. Includes significant design component.

Prerequisites:

ME 206, ME 223

Experiments in Mechanical Engineering, load-deformation, load-failure, fatigue, impact, hardness. Introduction to traditional machining and material processing. This course includes laboratory.

Prerequisites:

ME 306

Analysis of linear systems in the time and frequency domains. Physical systems modeled and analyzed using time domain techniques. Fourier and Laplace Transforms.

Prerequisites:

ME 201, ME 214, PHYS 222, EE 230, PHYS 232, EE 240, ME 281, MATH 321

Probability and statistics and its application to mechanical measurements. Principles of operation of devices and systems to measure various quantities that arise in mechanical engineering. Conditioning and digitization of signals during the measurement process is also discussed.

Prerequisites:

ME 203, ME 214, EE 230, EE 240

Curricular Practical Training: Co-Operative Experience is a zero-credit full-time practical training experience for one summer and an adjacent fall or spring term. Special rules apply to preserve full-time student status. Please contact an advisor in your program for complete information.

Prerequisites:

ME 201. At least 60 credits earned; in good standing; instructor permission; co-op contract; other Prerequisites may also apply.

Minimum design loads for buildings using ASCE 7 guidelines and load distribution. Analysis of determinate structural systems including the case of moving loads. Analysis of indeterminate structures using the flexibility and moment distribution methods. Use of software to enhance the analysis.

Prerequisites:

ME 223

The application of the principles of thermodynamics, fluid mechanics, and heat transfer to the design and analysis of selected energy systems of current interest, such as nuclear, solar, geothermal, and also conventional systems. Lecture and design projects.

Prerequisites:

ME 324, ME 329

Application of principles of mechanics to the design of various machine elements such as gears, bearings, springs, rivets, welding. Stresses in mechanical elements. Design factors, fatigue, manufacturability. Lectures and design projects. Includes significant design content.

Prerequisites:

ME 214, ME 223

The application of mechanics to the design and analysis of motion and force transmitting systems. Optimum design. Includes significant design component.

Prerequisites:

ME 417

This course provides the students with sound understanding of both solid modeling techniques and finite element analysis. It covers the major features as well as feature manipulation techniques. It also provides a background in deriving, understanding and applying the stiffness matrices and finite element equations for various types of finite elements and systems. Static stress analyses, sensitivity studies and optimization studies are covered. Includes significant design component. Prerequisite: ME 203, ME 324, ME 417 Fall

Prerequisites:

ME 203, ME 324, ME 417

Introduce anisotropic mechanics theories, engineering application of various composite materials, mechanical behaviors and fabrication of composites, experimental and theoretical approach for composite designs, contemporary issues such as nano/microcomposites. Includes significant design component.

Prerequisites:

ME 223

Analysis of heat and mass flow, design of heat exchangers and accompanying piping system. Methods of heat transfer enhancement, heat pipes. Includes significant design component.

Prerequisites:

ME 324

Introduction to the theory of aerosols and particulate systems. Properties, behavior, and physical principles of aerosols; including particle size statistics. Brownian motion and diffusion, and coagulation. Application in areas such as environmental systems, respiratory deposition, bioterrorism, and materials processing.

The first course in a two semester sequence that provides a complete design experience under professional guidance. The course covers: the product realization process, financial analysis, quality, patents, ethics and case studies. The students initiate a design project early in the semester to be completed in ME 438. Prereq: senior standing in ME

Prerequisites:

ME 324, ME 329, ME 333, ME 336, ME 341, ME 417

Methods of energy conversion. Topics may include hydroelectric, geothermal, wind and solar power generation, as well as unconventional methods of energy conversion. Term design problems.

Prerequisites:

ME 324, ME 329

Exploration of the principles and application of Building Information Modeling (BIM) in the HVAC&R industry. Course will include a practice project in the HVAC field using Autodesk Revit.

Prerequisites:

Instructor Permission