Undergraduate Courses

Please contact the Registrar for more information.
Phone: (201)216-5555
Fax: (201)216-8030
E-mail: registrar@stevens.edu

Particle kinematics and kinetics, systems of particles, work-energy, impulse and momentum, rigid-body kinematics, relative motion, Coriolis acceleration, rigid-body kinetics, direct and oblique impact, eccentric impact.

 Concepts of energy, heat and work; thermodynamic   properties of substances and property relationships, phase change; First and Second   Laws for closed and open systems including steady and transient processes and   cycles; using entropy; representative applications including vapor and   gas power and refrigeration cycles.

This course is intended to teach modern systematic design techniques used in the practice of mechanical engineering. Methodology for the development of design objective(s), literature surveys, base case designs, and design alternatives are given. Economic analyses with an emphasis on capital investment and operating costs are introduced. Integrated product and process design concepts are emphasized with case studies. Students are encouraged to select their senior capstone design project near the end of the course, form teams, and commence preliminary work. A number of design projects are required of all students.

Applications of First and Second Laws to thermal systems including gas turbine, and internal and external combustion engines. Vapor cycles, including supercritical binary and combined cycles, regeneration and recuperation, gas compression, refrigeration and gas liquefaction. Analysis of thermal processes, including available energy and availability, irreversibility, effectiveness. Laboratory work in air compressors, internal combustion engines, furnaces, heat pumps, and gas turbines.

Properties of a fluid, basic flow analysis techniques, fluid kinematics, hydrostatics, manometry, pressure distribution in rigid body motion of a fluid, control volume analysis, conservation of mass, linear and angular momentum, Bernoulli and energy equations, dimensional analysis, viscous flow in pipes, flow metering devices, external flows, estimation of lift and drag, turbo-machinery, open channel flow.

Modeling and simulation methodologies including model-block building, logical and data modeling, validation, simulation and trade-off analysis, decision-making, and optimization. Product and assembly modeling; visual simulation; process modeling; production modeling; process plans and resource modeling, entity flow modeling including conveyors, transporters, and guided vehicles; Input and output statistical analysis. Several CAD/CAE simulation software are used.

Basic modes of heat transfer, steady heat conduction, extended surface heat transfer, transient heat conduction, computational methods, forced and free convection, boiling and condensation, thermal radiation, heat exchangers. Design projects.

The principles of dynamics as applied to the analysis of the accelerations and dynamic forces in machines such as linkages, cam systems, gears trains, belts, chains and couplings. The effect these dynamic forces have on the dynamic balance and operation of the machines and the attending stresses in the individual components of the machines. Some synthesis techniques. Students also work in teams on a semester long project associated with the design of a mechanical system from recognizing the need through a detailed conceptual design.

Application of the principles of strength of materials to the analysis and design of machine parts. Stress and deflection analysis. Curved bars, multi-support shafts, torsion, cylinders under pressure, thermal stresses, creep, and relaxation, rotating disks, fasteners, springs, bearings, gears, brakes and other machine elements are considered. Failure of structural materials under cyclic stress.

Please contact the Registrar for more information.
Phone: (201)216-5555
Fax: (201)216-8030
E-mail: registrar@stevens.edu

Technology and economics of energy sources, storage and utilization, overview of fundamental concepts of mechanical, thermal, chemical, nuclear, electrical energy conversion (practical and visionary), thermo chemical conversion, including combustion in power plants, propulsion systems, thermo mechanical conversion in nozzles and turbomachinery, "direct" energy conversion in fuel cells, etc., nuclear energy conversion.

Senior design courses. Complete design sequence with a required capstone project spanning two semesters.

Senior design courses. Complete design sequence with a required capstone project spanning two semesters.

Differential equations of fluid flow, Navier-Stokes equations, introduction to fluid turbulence, inviscid incompressible flow, introduction to airfoil theory, compressible fluid flow and applications nozzles, ducts and airfoils.

Individual investigation of a substantive character undertaken at an undergraduate level under the guidance of a faculty advisor leading to a thesis with a public defense. Thesis comitee will consist of the faculty advisor and one or more reader.

Individual investigation of a substantive character undertaken at an undergraduate level under the guidance of a faculty advisor leading to a thesis with a public defense. Thesis comitee will consist of the faculty advisor and one or more reader.

Experiments in selected mechanical engineering systems areas, including principles and applications of experimentation, data-acquisition, design of experiments, and written and oral reporting on experimental hardware and results.

Multidimensional stress, strain and transformation equations, yield conditions and theories of failure, constitutive laws including linear elasticity, viscoelasticity and temperature influences, equations of elasticity, simple applications to uniaxial stress and symmetric bending, unsymmetrical bending and shear center of beams, torsions, combined stresses with applications to beams, thin-walled cylinders and pressure tanks, shrink fits, bending beyond the elastic limit, instability and energy methods.

Static and dynamic force analysis of mechanisms, dynamics of reciprocating and rotating machinery, balancing of machinery, friction and wear, vibration and noise control in machines, manipulators and robots, computer-aided design.

Analysis and synthesis of feedback control systems to achieve specified stability and performance criteria, stability via root-locus techniques, Nyquist's criterion, Bode and Nichol's plots, effect of various control laws and pole-zero compensation on performance, applications to servomechanisms, hydraulic and pneumatic control systems, analysis of nonlinear systems.

Analysis of both bulk-forming (forging, extrusion, rolling, etc.) and sheet-forming processes, metal cutting, and other related manufacturing processes; physics and stochastic nature of manufacturing processes and their effects on quality, rate, cost and flexibility; role of computer-aided manufacturing in manufacturing system automation; methodologies used to plan and control a manufacturing system, forecasting, production scheduling, facility layout, inventory control, and project planning.

The course addresses the science underpinnings of nanotechnology to provide a hands-on experience for undergraduate students in nanofabrication and characterization. It will discuss the grand challenges of nanofabrication and will showcase examples of specific applications in electronics, photonics, chemistry, biology, medicine, defense, and energy. NANO 200 would be a pre-requisite for this course. This course will offer hands-on experiments to fabricate prototype devices/systems (e.g. relatively simple sensors or actuators) in order for students to understand the full sequence/spectrum of development of nanodevices and systems, e.g. from concept design, fabrication and characterization.Prerequisites:  NANO 200 or instructor permission