Core Courses
π Semester 1 β Core Courses
- Mathematics 1
- Physics 1
- Structure of Matter
π Semester 2 β Core Courses
- Mathematics 2
- Physics 2
- Thermodynamics
βοΈ Semester 3 β Core Courses
- Mathematics 3
- Waves and Vibrations
- Fluid Mechanics
- Rational Mechanics
π¬ Semester 4 β Core Courses
- Thermodynamics 2
- Mechanical Manufacturing
- Mathematics 4
- Numerical Methods
- Strength of Materials
π οΈ Semester 5 β Core Courses
- Analytical Mechanics
- Mechanical Construction 1
- Strength of Materials 2
- Elasticity
π§ͺ Semester 6 β Core Courses
- Mechanical Construction 2
- Theory of Mechanisms
- Heat Transfer
- Structural Dynamics
These courses form the backbone of the Mechanical Construction curriculum, combining theoretical knowledge with applied engineering skills across mechanics, materials, and design.
Advanced Topics
π§ Semester 5 β Advanced Topics
- Analytical Mechanics: In-depth study of dynamic systems using advanced mechanics principles (Lagrangian and Hamiltonian formulations).
- Mechanical Construction 1: Design principles of mechanical structures and components (shafts, joints, supports).
- Strength of Materials 2: Extended stress and strain analysis, beam theory, buckling, and failure modes.
- Elasticity: Stress tensor, deformation, constitutive equations; applications in structural mechanics.
- Industrial Drawing: Technical communication through engineering drawings following ISO standards.
- CAD/CAM (Computer-Aided Design & Manufacturing): Digital modeling, simulation, and manufacturing processes using specialized software.
- Metrology Lab: Precision measurement tools and techniques, dimensional control.
βοΈ Semester 6 β Advanced Topics
- Mechanical Construction 2: Advanced component and assembly design including tolerancing and safety considerations.
- Theory of Mechanisms: Kinematic analysis and synthesis of mechanisms (linkages, cams, gears).
- Heat Transfer: Conduction, convection, radiation β theory and application in thermal systems.
- Structural Dynamics: Vibration analysis of structures, dynamic loading, modal analysis.
- Internal Combustion Engines: Operating principles, thermodynamic cycles, performance evaluation.
- Thermal Transfer Lab: Hands-on experimentation in heat exchanger efficiency and thermal conductivity.
- Capstone Project (Final Year Project): Real-world engineering design or research work under supervision.
- Hydraulic and Pneumatic Systems: Principles and applications in industrial automation.
- Non-Metallic Materials: Polymers, ceramics, composites β structure, properties, uses.
- Entrepreneurship & Business Management: Innovation, project planning, business models for engineers.
These advanced modules equip students with the technical and practical knowledge required for careers in mechanical design, energy systems, manufacturing, and maintenance, as well as for graduate studies or research.