All COs of ME (UG)
Here is a draft for the Course Outcomes (COs) for the B.Tech in Mechanical Engineering program at Horizon College. These outcomes specify the knowledge, skills, and competencies that students will develop upon successfully completing each course in the program.
Course Outcomes (COs) – Mechanical Engineering Department
Demonstrate professional skills in design, analysis, and communication through a comprehensive project report and presentation.
Mathematics I
Apply mathematical concepts like differential calculus and linear algebra to solve engineering problems.
Analyze and solve engineering problems related to vectors, matrices, and basic geometry.
Physics I
Understand the fundamental principles of mechanics, waves, and thermodynamics.
Apply laws of physics to solve problems in mechanics, energy, and wave motion.
Engineering Chemistry
Understand the basic principles of chemistry as applied to material science, corrosion, and energy production.
Analyze chemical reactions and their applications in engineering.
Introduction to Mechanical Engineering
Develop a basic understanding of mechanical engineering principles and the role of mechanical engineers in various industries.
Analyze simple mechanical systems and components.
Engineering Drawing
Create technical drawings of mechanical components using standard drawing conventions and CAD tools.
Interpret and produce 2D and 3D mechanical designs.
Computer Programming
Understand the basics of programming and algorithm design.
Apply programming skills to solve engineering problems and model mechanical systems.
Mathematics II
Apply advanced mathematical concepts like differential equations and partial differential equations to analyze mechanical engineering problems.
Develop the ability to solve boundary value problems and model engineering systems.
Physics II
Understand the principles of electromagnetism, optics, and modern physics.
Apply the laws of physics to analyze problems related to electricity, magnetism, and optical systems.
Basic Electrical Engineering
Understand the fundamental principles of electrical circuits, electromagnetism, and electrical machines.
Apply electrical engineering concepts to solve problems related to power systems and devices.
Materials Science
Understand the properties, behaviors, and selection of materials used in mechanical engineering applications.
Analyze the structure-property relationship and their implications on material performance.
Manufacturing Processes
Learn about various manufacturing processes like casting, welding, and machining.
Analyze the efficiency and effectiveness of different manufacturing techniques.
Engineering Mechanics
Apply principles of statics and dynamics to solve engineering problems.
Analyze the behavior of forces, moments, and bodies under various conditions.
Mathematics III
Apply complex mathematical techniques to solve problems in mechanical systems, including Fourier series, Laplace transforms, and numerical methods.
Solve engineering problems using computational methods.
Fluid Mechanics
Understand the properties of fluids and their behavior under different conditions.
Apply fluid dynamics to solve problems in fluid flow, pressure, and velocity.
Strength of Materials
Apply knowledge of stress, strain, and deformation to analyze solid materials under various loading conditions.
Solve problems related to bending, torsion, and shear in structural elements.
Thermodynamics I
Understand the laws of thermodynamics and their applications in mechanical engineering.
Analyze thermodynamic cycles, energy systems, and the performance of engines and refrigeration systems.
Mechanics of Solids
Apply the principles of mechanics to analyze and design solid components in mechanical systems.
Use concepts of stress, strain, and material properties to evaluate structural performance.
Manufacturing Technology
Understand advanced manufacturing processes and their applications in production environments.
Analyze manufacturing methods such as CNC machining, additive manufacturing, and rapid prototyping.
Heat and Mass Transfer
Understand the modes of heat transfer (conduction, convection, and radiation) and apply them to solve practical engineering problems.
Analyze systems for effective heat and mass transfer in various engineering applications.
Mechanical Vibrations
Understand the principles of vibration analysis in mechanical systems.
Analyze dynamic response, resonance, and damping in machines and structures.
Fluid Machinery
Understand the working principles of pumps, turbines, and compressors.
Analyze fluid machinery systems for efficiency and performance.
Theory of Machines
Analyze kinematics and dynamics of machinery and mechanisms.
Design and analyze mechanical systems involving linkages, gears, cams, and bearings.
Machine Design
Apply design principles to develop safe and efficient mechanical components.
Analyze the material selection, loading conditions, and failure modes for mechanical components.
Refrigeration and Air Conditioning
Understand the principles of refrigeration and air conditioning systems.
Analyze and design systems for effective temperature control and energy efficiency.
Control Systems
Understand the fundamental concepts of control theory, including stability, feedback, and system dynamics.
Design and analyze control systems for mechanical applications.
Finite Element Analysis
Apply the principles of finite element method (FEM) to solve complex structural and thermal problems.
Use software tools to simulate and analyze mechanical systems.
Internal Combustion Engines
Understand the working principles of internal combustion engines.
Analyze engine performance, efficiency, and emissions, and design efficient engine systems.
Advanced Manufacturing Techniques
Understand and apply advanced manufacturing technologies such as additive manufacturing and automation.
Analyze the advantages and limitations of various modern manufacturing methods.
Mechatronics
Understand the integration of mechanical, electrical, and computing systems in the design of automated systems.
Design and implement mechatronic systems for real-world applications.
Project Work I (Industry Internship)
Apply knowledge of mechanical engineering in an industrial setting through hands-on project work.
Work collaboratively in teams to solve industry-specific engineering problems.
Machine Tool Design
Design machine tools and systems used in industrial manufacturing processes.
Analyze the performance of machine tools, including stability, precision, and operation.
Capstone Project (Project Work II)
Apply all acquired skills and knowledge to solve complex, open-ended mechanical engineering problems.