Responsibility and liability. Environmental legislation. Project and organization management. Relations between engineer and client. Technical practice - analysis, design, execution and operation. Bioresource students. Offered by: Mathematics and Statistics Faculty of Engineering. Brief review of vector geometry. Vector functions and curves.
Partial differentiation and differential calculus for vector valued functions.
Unconstrained and constrained extremal problems. Multiple integrals including surface area and change of variables. Restrictions: Open only to students in the Faculty of Engineering. Second and higher order linear ODEs. Series solutions at ordinary and regular singular points. Laplace transforms. Linear systems of differential equations with a short review of linear algebra. Differential and integral calculus of vector fields including the theorems of Gauss, Green, and Stokes.
Introduction to partial differential equations, separation of variables, Sturm-Liouville problems, and Fourier series. Linear Systems of Ordinary Differential Equations. Power Series Solutions. Partial Differential Equations. Sturm-Liouville Theory and Applications.
Fourier Transforms. Offered by: Mechanical Engineering Faculty of Engineering. Mechanical Engineering : The practice of Mechanical Engineering: its scope and context. The role of Design. Introduction to the Design process. The role of engineering analysis and socio-economic factors in Design. Introduction to the individual mechanical engineering subjects and their role in Design.
Integrated Heat Treating Solutions - Consulting and Equipment Design
Case studies. Mechanical Engineering : Static equilibrium of particles and rigid bodies. Beams, trusses, frames and machines. Concept of work and energy. Static equilibrium and stability. Mechanical Engineering : Kinematics of particles and rigid bodies. Particle dynamics: force-momentum and work-energy approaches. Kinematics and kinetics of rigid bodies. Mechanical Engineering : Thermodynamic systems and properties. First law of thermodynamics: energy, work and heat. State principle, p-v-T surfaces, phase equilibrium, ideal gas model. Second law of thermodynamics, entropy, exergy analysis.
Energy analysis applied to steady and transient engineering systems including heat engines, refrigerators and heat pumps, air compressors. Mechanical Engineering : Introduction to probability: conditional probability, binomial and Poisson distributions, random variables, laws of large numbers. Statistical analysis associated with measurements; regression and correlation.
Basic experimental laboratory techniques, including the measurement of strain, pressure, force, position, and temperature. Mechanical Engineering : The design process, including free-hand sketching; from geometry construction to manufacturing drawings; the technology and standards of engineering graphic communication; designing with CAD software. The role of visualization in the production of mechanical engineering designs.
Open only to Mechanical Engineering students. Open only to students in Year 1. Mechanical Engineering : Introduction to design. Problem formulation, idea generation, feasibility study, preliminary design, design, analysis, design evaluation, project management, and optimal design. Mechanical Engineering : Numerical techniques for problems commonly encountered in Mechanical Engineering are presented. Chebyshev interpolation, quadrature, roots of equations in one or more variables, matrices, curve fitting, splines and ordinary differential equations.
The emphasis is on the analysis and understanding of the problem rather than the details of the actual numerical program.
Optimal Control of Induction Heating Processes (Mechanical Engineering, 201)
Mechanical Engineering : First principles of analysis; motion; position; displacement; velocity; acceleration; force; inertia and its effects. Kinematic and dynamic analysis of rigid bodies in pure rotation and in pin-connected systems; dynamic balance. Rigid bodies in rolling contact; planetary gear-trains. Bodies in sliding contact; lower and higher sliding pairs. Mechanical Engineering : Single-degree-of-freedom systems; free vibrations; effect of damping; response to harmonic, periodic and arbitrary excitation.
Lagrange's equations of motion. Vibrations of multi-degree-of-freedom systems. Continuous systems. Mechanical Engineering : Modern phenomenological theories of the behaviour of engineering materials.
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- Optimal Control of Induction Heating Processes - CRC Press Book;
Stress and strain concepts and introduction to constitutive theory. Applications of theory of elasticity and thermoelasticity. Introduction to finite element stress analysis methods. Mechanical Engineering : Physical properties of fluids. Kinematics and dynamics of fluid flow: stress in a continuum, rates of strain, rotation. Control volume analysis; conservation of mass, linear momentum and energy; Euler and Bernoulli equations; Flow measurement. Dimensional analysis and dynamical similarity. Laminar and turbulent flow in pipes and boundary layers. Prerequisite: MECH Mechanical Engineering : Generalized thermodynamics relations.
Real gas effects, gas tables, dense gas equations of state and generalized compressibility, enthalpy, and entropy charts. Refrigerators and heat pumps. Psychrometry and air conditioning processes.
Thermodynamics of reactive gas mixtures. Mechanical Engineering : Basic concepts and overview. Steady and unsteady heat conduction. Fin Theory.
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