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Curriculum & Syllabus

Curriculum & Syllabus of Mechanical Engineering Department

Here’s a draft for the Curriculum & Syllabus section of the Mechanical Engineering Department at Horizon College. This section outlines the structure and contents of the program, ensuring students are aware of the various subjects and their academic progression.

Curriculum & Syllabus of the Mechanical Engineering Department

The Mechanical Engineering Department at Horizon College offers a well-structured curriculum designed to provide students with a strong foundation in both theoretical and practical aspects of mechanical engineering. The program covers fundamental concepts, cutting-edge technologies, and industry-relevant topics, preparing students for careers in a wide range of industries, including automotive, aerospace, manufacturing, energy, and robotics.

The B.Tech in Mechanical Engineering program is a four-year undergraduate course divided into eight semesters, with each semester focusing on key areas of mechanical engineering. The curriculum is updated regularly to include emerging technologies and industry practices, ensuring that students are equipped with the skills and knowledge necessary to succeed in the dynamic field of mechanical engineering.

Curriculum Structure Overview

  1. Semester 1: Foundation of Engineering
    • Mathematics I
    • Physics I
    • Engineering Chemistry
    • Introduction to Mechanical Engineering
    • Engineering Drawing
    • Computer Programming
  2. Semester 2: Core Engineering Concepts
    • Mathematics II
    • Physics II
    • Basic Electrical Engineering
    • Materials Science
    • Manufacturing Processes
    • Engineering Mechanics
  3. Semester 3: Core Mechanical Engineering Principles
    • Mathematics III
    • Fluid Mechanics
    • Strength of Materials
    • Thermodynamics I
    • Mechanics of Solids
    • Manufacturing Technology
    • Engineering Thermodynamics
  4. Semester 4: Advanced Engineering Concepts
    • Mathematics IV
    • Mechanical Vibrations
    • Fluid Machinery
    • Theory of Machines
    • Machine Design
    • Heat and Mass Transfer
    • Applied Thermodynamics
  5. Semester 5: Specialized Mechanical Engineering Topics
    • Finite Element Analysis
    • Internal Combustion Engines
    • Control Systems
    • Refrigeration and Air Conditioning
    • Advanced Manufacturing Techniques
    • Engineering Materials
    • Elective I (e.g., Robotics, Automation, etc.)
  6. Semester 6: Application of Engineering Knowledge
    • Design of Mechanical Systems
    • Dynamics of Machines
    • Production Planning and Control
    • Power Plant Engineering
    • Mechatronics
    • Elective II (e.g., Computational Fluid Dynamics, Renewable Energy Systems)
    • Industrial Engineering
  7. Semester 7: Advanced Topics and Research
    • Machine Tool Design
    • Mechanical Engineering Lab II
    • Computational Mechanics
    • Elective III (e.g., Advanced Heat Transfer, Nano-Technology)
    • Project Work I
    • Industry Internship
  8. Semester 8: Final Year and Capstone Project
    • Design Project
    • Engineering Management
    • Project Work II (Capstone Project)
    • Elective IV (e.g., Aerospace Engineering, Smart Materials)
    • Final Year Industrial Training or Research Project

Syllabus Highlights

  1. Engineering Mechanics
    This subject focuses on the analysis of forces and the effects they have on bodies in motion or at rest. Students learn about static and dynamic equilibrium, moment of forces, and the laws of motion.
  2. Strength of Materials
    It introduces students to the behavior of materials under different loads, including stress, strain, shear force, and bending moments, crucial for designing safe structures and mechanical components.
  3. Fluid Mechanics
    Students explore the properties and behaviors of fluids in motion and at rest, studying concepts like fluid dynamics, Bernoulli’s equation, and flow through pipes, which are essential for applications in aerodynamics and hydraulics.
  4. Thermodynamics
    The syllabus covers the principles of energy, heat, and work, and students learn to apply the laws of thermodynamics in the design of engines, heat exchangers, and HVAC systems.
  5. Machine Design
    This course focuses on designing mechanical components and systems using material selection, stress analysis, and failure theories, ensuring durability, safety, and performance.
  6. Manufacturing Technology
    It introduces students to various manufacturing processes such as casting, welding, machining, and additive manufacturing. The course also covers automation and quality control techniques used in modern manufacturing industries.
  7. Heat Transfer
    Students learn the fundamental modes of heat transfer—conduction, convection, and radiation—and apply these concepts to solve practical engineering problems like heat exchangers, refrigeration systems, and heat management in engines.
  8. Mechatronics and Robotics
    A multidisciplinary approach integrating mechanical engineering, electronics, and computing, this subject teaches students to design and control automated systems and robotic mechanisms.
  9. Finite Element Analysis
    An essential tool in modern engineering design, this course teaches students how to simulate and analyze the behavior of materials and structures under different loads using software tools.
  10. Elective Subjects
    Elective courses in the later semesters allow students to specialize in areas such as:
    • Robotics and Automation
    • Computational Fluid Dynamics (CFD)
    • Renewable Energy Systems
    • Nano-Technology
    • Aerospace Engineering

Practical Training and Projects

  • Laboratory Work: Hands-on experience is a critical aspect of the curriculum. Students work in well-equipped labs, such as the Mechanical Engineering Workshop, Fluid Mechanics Lab, Heat Transfer Lab, and Materials Science Lab.
  • Industrial Training: Students are required to undergo industrial training, typically in the summer between their 6th and 7th semesters, which helps them gain practical experience and apply theoretical knowledge in real-world scenarios.
  • Capstone Project: In their final year, students undertake a Capstone Project, where they apply all their learning to design, analyze, and fabricate a mechanical system or solve an engineering problem. This project is often done in collaboration with industries.

Conclusion

The Mechanical Engineering Curriculum at Horizon College is designed to produce engineers with a deep understanding of mechanical engineering principles and the ability to apply them to solve complex problems. Through a combination of rigorous academic coursework, hands-on labs, industrial exposure, and research opportunities, students are well-prepared to enter the workforce as skilled and innovative professionals.

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