Mechanical Engineering (BME)
Description
The objectives of the undergraduate program in Mechanical Engineering are:
- To produce engineers who understand the performance of engineered products and systems in terms of the relevant fundamental principles of math, science and the humanities, whether they are practicing engineers or students in graduate Engineering programs.
- To produce engineers who excel in the professional practice of mechanical engineering. Professional practice includes the ability to identify, design, and implement solutions to technical problems through a multiplicity of laboratory, analytical and communication methods within a business climate.
- To produce engineers who are aware of how their roles as technical professionals and leaders affect the wider human community, who serve not only as employees or employers, but as socially-conscious citizens, and who are motivated by moral principles in their professional and personal lives.
The Bachelor of Mechanical Engineering curriculum prepares graduates to solve problems related to:
- design and manufacture of products
- reliability of components and systems
- conversion of energy from one form to another
- utilization of energy in efficient and productive ways
- instrumentation and control of physical processes
Mechanical engineers design systems that range from vehicles to consumer products, climate control systems, power generation, aircraft, and production systems. Mechanical engineers are prepared to draw on technical knowledge and insight involving materials, mechanics, controls, structures and manufacturing processes.
A mechanical engineer deals with the physical reality of things such as engines, vehicle bodies, electric generators, cranes, air conditioners, airplane wings, pumps, and robots. He or she is faced with the challenges and uncertainties that come with complex products and systems, which often transcend multiple disciplines. In addition to using the classical and modern principles of engineering science, the mechanical engineer must be able to devise economically viable, environmentally friendly, and socially acceptable solutions to problems. The analytical problem solving skills combined with sound technical fundamentals of the mechanical engineering degree can also form the basis for successful careers in fields such as business, law and medicine.
This program is accredited by the Engineering Accreditation Commission of .
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Program Learning Outcomes
Graduates from the Bachelor of Mechanical Engineering program at University of Ó£ÌÒÊÓƵ will have:
- an ability to identify, formulate, and solve complex engineering problems by applying principles of engineering, science, and mathematics.
- an ability to apply engineering design to produce solutions that meet specified needs with consideration of public health, safety, and welfare, as well as global, cultural, social, environmental, and economic factors.
- an ability to communicate effectively with a range of audiences.
- an ability to recognize ethical and professional responsibilities in engineering situations and make informed judgments, which must consider the impact of engineering solutions in global, economic, environmental, and societal contexts.
- an ability to function effectively on a team whose members together provide leadership, create a collaborative and inclusive environment, establish goals, plan tasks, and meet objectives.
- an ability to develop and conduct appropriate experimentation, analyze and interpret data, and use engineering judgment to draw conclusions.
- an ability to acquire and apply new knowledge as needed, using appropriate learning strategies.
- an ability to apply principles of mathematics (including multivariate calculus and differential equation).
- an ability to model, analyze, design, and realize physical systems, components or processes.
- an ability to work professionally in either thermal or mechanical systems while requiring topics in each area.
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Degree Requirements - Bachelor of Mechanical Engineering Program (139 credit hours)
The Bachelor of Mechanical Engineering curriculum provides students with an in-depth knowledge of engineering science and design methodology. These insights are reinforced by intensive laboratory experiences in virtually every area of study and three semester-long industrial co-op assignments. Students also have team-oriented design experiences integrated throughout their curriculum. A capstone design project, conducted in the senior year, challenges students with a project that involves solving a real product or process-related problem that draws on knowledge of engineering science and design.
Combined Five-Year Bachelor/Master Program
The Five-Year Bachelor/Master Degree program is designed to enable completion of both the Bachelor of Mechanical Engineering and the Master of Mechanical Engineering degrees in five calendar years. The program allows qualified Bachelor of Mechanical Engineering students to take up to three graduate level courses during their final three academic semesters that will meet undergraduate degree requirements while also accruing course credits toward their graduate degree. Click here for more information.
Curriculum
The BME curriculum includes University Core Curriculum courses, Engineering core courses for Mechanical Engineering, Mechanical Engineering major courses, including two Technical Electives, and a cooperative education (co-op) sequence consisting of a co-op preparation course and three summer work experiences.
Engineering Foundation Courses for Mechanical Engineering
- ENGR 1000 Engineering Ethics (2 credits)
- ENGR 1234 Introductory Mathematics for Engineering Applications (3 credits)
- MTH 1410 Analytic Geometry and Calculus I (4 credits)
- MTH 1420 Analytic Geometry and Calculus II (4 credits)
- MTH 2410 Analytic Geometry and Calculus III (4 credits)
- MTH 3720 Differential Equations with Linear Algebra (4 credits)
- MTH 4270 Applied Probability and Statistics (3 credits)
- PHY 1600 General Physics I (3 credits)
- PHY 1610 General Physics Laboratory I (1 credits)
- PHY 1620 General Physics II (3 credits)
- PHY 1630 General Physics Laboratory II (1 credits)
- CHM 1050 Introduction to General Chemistry (4 credits) or
- CHM 1070 General Chemistry I (3 credits) and CHM 1100 Chemistry Laboratory I (1 credits)
- ENGR 1020 Basic Engineering Graphics and CAD (1 credit)
- ENGR 1021 Intermediate Engineering Graphics and CAD (1 credit)
- ENGR 1023 Engineering Computing & Problem Solving (1 credit)
- ENGR 1080 Fundamentals of Engineering Design (2 credits)
- CSSE 1710 Introduction to Programming I (see Note) 3 credits
- CSSE 1711 Intro to Programming I Lab (1 credits)
- ENGR 3000 Introduction to Cooperative Education (1 credit)
- ENGR 3110 Professional Practice of Engineering (2 credits)
- ENGR 3112 Fundamentals of Engineering Practice (1 credit)
- CTA 3010 Engineering Co-Op I (2 credits)
- CTA 3020 Engineering Co-Op II (2 credits)
- CTA 3030 Engineering Co-Op III (2 credits)
Note: If a student's schedule would exceed 18 credits in a semester, student may take CSSE 1712 for three credits, which combines CSSE 1710 and CSSE 1711.
Total: 55 credits
Mechanical Engineering Major Courses
- ENGR 3120 Statics (3 credits)
- ENGR 3130 Dynamics (3 credits)
- ENGR 3140 Fluid Mechanics (3 credits)
- ENGR 3150 Thermodynamics I (3 credits)
- ENGR 3170 Science of Materials (3 credits)
- ENGR 3190 Fluid Mechanics Laboratory (1 credits)
- ENGR 3200 Principles of Electrical Engineering (3 credits)
- ENGR 3210 Principles of Electrical Engineering Laboratory (1 credits)
- ENGR 3260 Mechanics of Materials (3 credits)
- ENGR 3270 Mechanics of Materials Lab (1 credits)
- ENGR 3400 Heat Transfer (3 credits)
- ENGR 3410 Heat Transfer Lab (1 credits)
- ENGR 4220 Control Systems (3 credits)
- MENG 3610 Mechanical Measurements Lab (2 credits)
- MENG 3800 Thermodynamics II (3 credits)
- MENG 3820 Manufacturing Processes (3 credits)
- MENG 3830 Manufacturing Processes Lab (1 credits)
- MENG 3900 Intermediate Mechanics of Materials (3 credits)
- MENG 3920 Machine Design (3 credits)
- MENG 4920 Computer Aided Engineering (3 credits)
- MENG 4930 Prototype Design I (2 credits)
- MENG 4950 Prototype Design II (3 credits)
- 3000 or 4000 level engineering, math, or science course - 2 technical electives (6 credits)
Total: 60 credits
Technical Electives - flexibility and focus
The Mechanical Engineering program is supplemented by six credit hours of Technical Electives. Technical Electives are upper division (3000 or 4000 level) courses in engineering, mathematics or science. An integrated concentration of courses is recommended to strengthen the background of students in their area of specialization. The Technical Electives are included in the major GPA calculation.
Accepted Technical Electives listed by area of specialization include:
Engineering Mechanics and Energy Conversion
- ENGR 4140 Intermediate Fluid Mechanics (3 credits)
- ENGR 4420 Finite Elements Methods (3 credits)
- ENGR 4440 Vibrations (3 credits)
- MENG 4810 Alternative Energy Systems (3 credits)
- ENGR 4820 Heating, Ventilating, and Air Conditioning of Buildings (3 credits)
Manufacturing Processes and Systems
- MENG 4350 Quality Control Systems (3 credits)
- MENG 4820 Computer Integrated Manufacturing (3 credits)
- MENG 4880 Reliability in Design (3 credits)
- MENG 4900 Robotics (3 credits)
- MENG 4940 Manufacturing Systems (3 credits)
Mechatronics
- ENGR 4520 Sensors and Actuators (3 credits)
- ELEE 4680 Computer Networking (3 credits)
- ELEE 4780 Embedded Systems (3 credits)
- ENGR 4780 Mechatronics (3 credits)
- ENGR 4790 Mechatronics Modeling and Simulation (3 credits)
- MENG 4900 Robotics (3 credits)
Vehicle Systems
- MENG 4580 Internal Combustion Engines I (3 credits)
- MENG 4720 Noise and Vibration (3 credits)
- MENG 4760 Vehicle Dynamics (3 credits)
- MENG 4980 Internal Combustion Engines II (3 credits)
Innovation and Entrepreneurship
- ENT 3000 Interdisciplinary Design, Entrepreneurship, and Service (3 credits)
- ENGR/ENT 4500 Innovation and Creativity (3 credits)
- ENGR/ENT 4700 Front and Back Ends of Innovation (3 credits)
Other Technical Electives in electrical engineering, software engineering, mathematics, business, advanced electric vehicle, and entrepreneurship are permissible with the department's approval.
University Core Curriculum Courses (Required)
In addition to the program-specific courses, the student must also fulfill the requirements of the University Core Curriculum.
Some of these core curriculum requirements may be satisfied by courses in your program. Please review the Degree Evaluation or consult an academic advisor for more information.
Program Contact Information
Engineering 214
Telephone: (313) 993-1402
Email: rayesna@udmercy.edu