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Mechanical Engineering

The scope of Mechanical Engineering is so wide and its services so universally needed as a basic part of all kinds of engineering work that the mechanical engineer is in demand in all industries. Mechanical engineers are required in the field of power generation, where they deal with steam, diesel or other internal combustion engines, and with hydraulic or gas turbines; in the field of heating, ventilation and refrigeration; in the design, analysis, and production of machines and equipment, for example, safety equipment, material handling equipment, automobiles, locomotives, marine vessels, furnaces, boilers, pressure vessels, heat exchangers, motors, generators and machine tools. They are employed in industries whose function is concerned with manufacturing, steel production, mining, transportation, communications, oil refining, chemical manufacture, paper, sugar, textiles, aerospace, nuclear energy, natural gas production and transmission and construction. The undergraduate program in Mechanical Engineering is designed to provide the student with a firm grasp of the fundamentals of mathematics, physics and engineering as well as to provide some opportunity for specialization in the later years. The degree of BASc in Mechanical Engineering is accredited and permits registration as a Professional Engineer in the Association of Professional Engineers in almost any Canadian province upon completion of the work experience requirement and upon passing the Association exams in law and ethics.

The Mechanical Engineering undergraduate program contains a core of basic subjects that must be taken by all students. The first year is virtually common with Civil and Electrical Engineering. The second and third years provide courses in Mechanical Engineering and Electrical Engineering with further development in mathematics and physics. Opportunities for specialization exist during the fourth year, where a choice of elective courses arranged into six different areas of specialization is available. Non-technical (complementary studies) courses are distributed throughout the program but do not appear in all years.

Each student is responsible for selecting their own program of electives, in keeping with the ultimate career objective after graduation. Each term, certain faculty members are designated to give advice to students and toJapprove their selection. It is anticipated, and indeed encouraged, that individual students should take a majorityJof their technical electives from one of the areas ofJspecialization listed below:

Fluid Mechanics and Thermal Engineering

The courses in this area of specialization deal with a broad range of applications of the principles of thermodynamics and fluid mechanics, with emphasis on topics of industrial significance, for example, combustion, energy conversion, internal flows with heat and mass transfer, turbomachinery, and external flows such as plumes in air and effluents in water.


Environmental Fluid Mechanics

This is closely linked with the above area of specialization and involves application of the principles of fluid mechanics and thermodynamics to problems in the natural environment. It is intended for students interested in careers in air and water pollution control, oceanography, and related fields.

Machine Design and Solid Mechanics

The courses offered in this area of specialization range from those which provide the mathematical and physical basis of the subject matter through to those which are largely applied in nature. Subjects treated are: mechanics (including vibrations); theories of elasticity, plasticity and fracture; machine design and design optimization.


Engineering Materials and Manufacturing

This area of specialization consists of a comprehensive series of courses in metallurgy, including heat treatment, casting, welding, cold and hot forming. Nonmetallic materials, including plastics and ceramics, and composites such as fiberglass and sandwich structures are also considered.

Production and Automation

The courses in this area of specialization are designed to provide the student with an understanding of the principles and control of production processes, the application of computers to the manufacturing activity and the organization of production. Topics treated are: automation, metal forming, numerical control of machine tools, applications of fluid power and industrial noise control.


Mechanical Engineering Core with an Option in Management Sciences

A student may acquire a BASc in Mechanical Engineering with an Option in Management Sciences by completing seven specific Management Sciences courses as electives. Students interested in this Designated Option must carefully plan their choice of complementary studies courses very early in order to ensure that the complementary studies requirements will be met.

  1. Core Program (excluding First Year)

  2. Elective Courses


The Mechanical Engineering curriculum structure is summarized in the following table:


Term Courses
1A (F) CH E 102 GEN E 163 MATH 117 MATH 115 PHYS 115 GEN E 170
1B (W,S) GEN E 121 GEN E 123 MATH 118 M E 126 PHYS 125 M SCI 261
2A (F,W) M E 200A M E 201 M E 202 M E 212 M E 219 M E 269 1 CSE
2B (S,F) M E 200B M E 203 M E 215 M E 220 M E 250 M E 262 1 CSE
3A (W,S) M E 300A M E 304 M E 305 M E 321 M E 330 M E 351 M E 354
3B (F,W) M E 300B M E 322 M E 340 M E 353 M E 360 M E 362
4A (S,F) M E 400A 4 TECH ELECT++ 2 CSE
4B (W) M E 400B 5 TECH ELECT++ 1 CSE
++ A project course, M E 482, may be taken in the 4A and 4B terms as a technical elective for each of these terms.

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