with Specialisation in Robotics and Automation

 

About the Programme

Mechanical Engineering is a diverse and broad field of engineering that focuses on the design, analysis, manufacturing, and maintenance of mechanical systems. It encompasses a wide range of applications and industries, making it one of the oldest and most fundamental engineering disciplines. Here are key aspects related to mechanical engineering:

  1. Core Disciplines:
    • Mechanics: Study of the behavior of physical bodies under the influence of forces.
    • Thermodynamics: Analysis of energy transfer and conversion in mechanical systems.
    • Fluid Mechanics: Understanding the behavior of fluids (liquids and gases) and their interaction with solid boundaries.
    • Materials Science: Study of the properties, behavior, and applications of materials used in engineering.
  2. Design and Analysis:
    • Mechanical Design: Application of engineering principles to design mechanical components and systems.
    • Computer-Aided Design (CAD): Use of computer software for designing and modeling mechanical components.
    • Finite Element Analysis (FEA): Simulation technique used for structural and thermal analysis of designs.
  3. Manufacturing Processes:
    • Machining, Casting, and Forming: Understanding various methods of shaping and forming materials to create mechanical components.
    • Additive Manufacturing (3D Printing): Rapid prototyping and manufacturing using additive techniques.
  4. Energy Systems:
    • Thermal Engineering: Analysis of heat transfer, thermodynamics, and energy conversion processes.
    • Renewable Energy: Study of alternative and sustainable energy sources, such as solar, wind, and hydropower.
  5. Control Systems:
    • Dynamics and Control: Analysis and design of dynamic systems, including control mechanisms.
    • Mechatronics: Integration of mechanical engineering with electronics and computer science to design intelligent systems.
  6. Aerospace and Automotive Engineering:
    • Aerospace Engineering: Design and development of aircraft and spacecraft systems.
    • Automotive Engineering: Design and analysis of automotive systems, including engines, chassis, and powertrains.
  7. Environmental Considerations:
    • Environmental Impact Assessment: Evaluating and minimizing the environmental impact of mechanical systems and processes.
  8. Project Work and Laboratories:
    • Hands-on projects, experiments, and laboratory work are essential components of a Mechanical Engineering Programme to provide practical experience.
  9. Internship and Industry Exposure:
    • Many Programmes incorporate internships or co-op experiences to expose students to real-world industry practices.
  10. Professional Development:
    • Mechanical engineers often need to pursue continuous learning to stay updated with evolving technologies and industry trends.
  11. Communication and Ethics:
    • Development of effective communication skills and understanding of professional ethics are emphasized in mechanical engineering education.
  12. Career Opportunities:
    • Mechanical engineering graduates can pursue diverse career paths in industries such as manufacturing, energy, automotive, aerospace, robotics, consulting, and more.
  13. Research and Innovation:
    • Opportunities for research and innovation exist, allowing mechanical engineers to contribute to advancements in technology and engineering solutions.

The interdisciplinary nature of mechanical engineering, along with its focus on fundamental engineering principles, makes it a versatile and in-demand field with a wide array of career opportunities. Mechanical engineers play a crucial role in designing, creating, and optimizing products and systems that impact various aspects of our daily lives

SBITians working in Leading Global Companies

Vinay Pawar

Ph.D (IIT Delhi)

Amit Shiroha

Amazon

Programme Educational Objectives (PEO):

Programme Educational Objectives (PEOs) for a Mechanical Engineering Programme describe the expected accomplishments and achievements of graduates after completing their academic Programme. PEOs guide the development of the curriculum and serve as a framework for assessing the effectiveness of the educational Programme. Here are Programme Educational Objectives for a Mechanical Engineering Programme:

  1. Professional Competence:
    • PEO: Graduates will demonstrate professional competence by applying fundamental knowledge, principles, and skills in mathematics, science, and engineering to analyze, design, and implement mechanical systems.
  2. Problem-Solving and Critical Thinking:
    • PEO: Graduates will excel in problem-solving and critical thinking, using analytical and creative approaches to address complex engineering problems in the field of mechanical engineering.
  3. Continuous Learning and Adaptability:
    • PEO: Graduates will engage in continuous learning, staying updated with emerging technologies and adapting to the evolving landscape of mechanical engineering throughout their careers.
  4. Effective Communication:
    • PEO: Graduates will possess effective communication skills, enabling them to articulate technical concepts clearly in both written and oral forms, and collaborate with peers and stakeholders.
  5. Teamwork and Collaboration:
    • PEO: Graduates will excel in collaborative work environments, contributing effectively to multidisciplinary teams and demonstrating leadership qualities when necessary.
  6. Ethical and Social Responsibility:
    • PEO: Graduates will adhere to ethical standards and exhibit social responsibility in their roles as Mechanical Engineering professionals, considering the impact of their work on society and the environment.
  7. Innovation and Entrepreneurship:
    • PEO: Graduates will demonstrate innovation and entrepreneurship, contributing to the development of new technologies, products, or solutions in the field of mechanical engineering.
  8. Leadership and Management Skills:
    • PEO: Graduates will demonstrate leadership and management skills, capable of overseeing projects, teams, and organizational initiatives in the mechanical engineering domain.
  9. Global Perspective:
    • PEO: Graduates will have a global perspective, understanding the international dimensions of mechanical engineering and contributing to the global engineering community.
  10. Life-Long Learning:
    • PEO: Graduates will pursue life-long learning opportunities, including professional development, certifications, and advanced degrees, to enhance their expertise and contribute to the advancement of the field.
  11. Success in Diverse Career Paths:
    • PEO: Graduates will achieve success in diverse career paths within the field of mechanical engineering, including roles in research, development, design, testing, and management.

These Programme Educational Objectives provide a roadmap for the educational outcomes and experiences of students in a Mechanical Engineering Programme. They ensure that graduates are well-prepared to meet the challenges of the professional landscape and make meaningful contributions to their chosen careers in mechanical engineering

Programme Specific Outcomes (PSO):

Programme Specific Outcomes (PSOs) for a Mechanical Engineering Programme specify the detailed knowledge, skills, and attributes that students are expected to acquire by the time they complete their academic Programme. PSOs provide a more granular understanding of the educational outcomes and guide the design and assessment of the curriculum. Here are Programme Specific Outcomes for a Mechanical Engineering Programme:

  1. PSO 1: Proficiency in Engineering Fundamentals
    • Outcome: Graduates should demonstrate proficiency in applying fundamental principles of mathematics, physics, and engineering to analyze and solve mechanical engineering problems.
  2. PSO 2: Design and Analysis Skills
    • Outcome: Graduates should be capable of designing and analyzing mechanical components and systems, considering factors such as strength, materials, and safety.
  3. PSO 3: Practical Application of Mechanical Engineering Tools
    • Outcome: Graduates should be proficient in using engineering software tools and techniques for modeling, simulation, and analysis of mechanical systems.
  4. PSO 4: Experimental and Laboratory Skills
    • Outcome: Graduates should possess practical skills in conducting experiments, measurements, and testing related to mechanical engineering, interpreting results, and drawing conclusions.
  5. PSO 5: Proficiency in Manufacturing Processes
    • Outcome: Graduates should have a deep understanding of various manufacturing processes, including machining, casting, forming, and additive manufacturing.
  6. PSO 6: Thermal and Fluid System Analysis
    • Outcome: Graduates should be capable of analyzing and designing thermal and fluid systems, including heat exchangers, pumps, and compressors.
  7. PSO 7: Mechanical System Dynamics and Control
    • Outcome: Graduates should possess skills in analyzing and controlling the dynamics of mechanical systems, including mechatronic systems.
  8. PSO 8: Proficiency in Renewable Energy Systems
    • Outcome: Graduates should be proficient in analyzing, designing, and implementing renewable energy systems, including solar and wind energy systems.
  9. PSO 9: Structural Analysis and Material Selection
    • Outcome: Graduates should be capable of analyzing and designing structures, selecting appropriate materials based on mechanical properties and application requirements.
  10. PSO 10: Automotive and Aerospace Engineering Skills
    • Outcome: Graduates should have skills in analyzing and designing mechanical systems related to automotive and aerospace engineering, including engines, chassis, and propulsion systems.
  11. PSO 11: Environmental Considerations in Mechanical Engineering
    • Outcome: Graduates should understand and consider the environmental impact of mechanical systems, applying sustainable practices in engineering design.
  12. PSO 12: Application of Robotics and Automation
    • Outcome: Graduates should be capable of applying robotics and automation technologies to enhance manufacturing and other mechanical engineering processes.
  13. PSO 13: Effective Communication and Presentation Skills
    • Outcome: Graduates should possess effective communication skills, including the ability to present technical information clearly and professionally.
  14. PSO 14: Teamwork and Leadership Abilities
    • Outcome: Graduates should demonstrate effective teamwork and leadership skills, collaborating with diverse teams and leading projects when required.
  15. PSO 15: Professional and Ethical Conduct
    • Outcome: Graduates should adhere to professional and ethical standards in their practice of mechanical engineering, considering social and global responsibilities.

These Programme Specific Outcomes are designed to ensure that graduates of a Mechanical Engineering Programme have acquired a comprehensive set of skills and knowledge that prepares them for a successful career in mechanical engineering. They serve as a basis for curriculum development, assessment, and continuous improvement of the Programme

Programme Outcomes (PO):

Engineering Knowledge (PO01):

  • Apply the knowledge of mathematics, science, engineering fundamentals, and an engineering specialization to the solution of complex engineering problems.

Problem Analysis (PO02):

  • Identify, formulate, review research literature, and analyse complex engineering problems reaching substantiated conclusions using first principles of mathematics, natural sciences and engineering sciences.

Design/Development of Solutions (PO03):

  • Design solutions for complex engineering problems and design system components or processes that meet the specified needs with appropriate consideration for the public health and safety, and the cultural, societal, and environmental considerations.

Conduct Investigations of Complex Problems (PO04):

  • Use research-based knowledge and research methods including design of experiments, analysis and interpretation of data, and synthesis of the information to provide valid conclusions for complex problems:
    • that cannot be solved by straightforward application of knowledge, theories and techniques applicable to the engineering discipline as against problems given at the end of chapters in a typical text book that can be solved using simple engineering theories and techniques;
    • that may not have a unique solution. For example, a design problem can be solved in many ways and lead to multiple possible solutions;
    • that require consideration of appropriate constraints / requirements not explicitly given in the problem statement such as cost, power requirement, durability, product life, etc.;
    • which need to be defined (modelled) within appropriate mathematical framework; and
    • that often require use of modern computational concepts and tools, for example, in the design of an antenna or a DSP filter.

Modern Tool Usage (PO05):

  • Create, select, and apply appropriate techniques, resources, and modern engineering and IT tools including prediction and modelling to complex engineering activities with an understanding of the limitations.

The Engineer and Society (PO06):

  • Apply reasoning informed by the contextual knowledge to assess societal, health, safety, legal and cultural issues and the consequent responsibilities relevant to the professional engineering practice.

Environment and Sustainability (PO07):

  • Understand the impact of the professional engineering solutions in societal and environmental contexts, and demonstrate the knowledge of, and need for sustainable development.

Ethics (PO08):

  • Apply ethical principles and commit to professional ethics and responsibilities and norms of the engineering practice.

Individual and Team Work (PO09):

  • Function effectively as an individual, and as a member or leader in diverse teams, and in multidisciplinary settings.

Communication (PO10):

  • Communicate effectively on complex engineering activities with the engineering community and with society at large, such as, being able to comprehend and write effective reports and design documentation, make effective presentations, and give and receive clear instructions.

Project Management and Finance (PO11):

  • Demonstrate knowledge and understanding of the engineering and management principles and apply these to one’s own work, as a member and leader in a team, to manage projects and in multidisciplinary environments.

Life-long Learning (PO12):

  • Recognize the need for, and have the preparation and ability to engage in independent and lifelong learning in the broadest context of technological change.

Major Subjects

  • Theory of Machines
  • Strength of Materials
  • Material Science and Metallurgy
  • Probability, Statistics and Linear Programming
  • Machine Design-I
  • Fluid Mechanics and Hydraullic Machines
  • Industrial Engineering
  • Heat and Mass Transfer
  • Automobile Engineering and Electric Vehicles
  • Refrigeration and Airconditioning
  • Mechanical Vibrations
  • Computer integrated Manufacturing
  • Geometric Modelling and Analysis
  • Automation in Manufacturing
  • Design of Mechanical Assemblies

Career Opportunities

Mechanical engineers have diverse career opportunities due to their broad skill set and the applicability of their knowledge across various industries. Here are some common career paths and opportunities for mechanical engineers:

  1. Mechanical Design Engineer:
    • Responsibilities include designing and developing mechanical components and systems using computer-aided design (CAD) tools.
  2. Manufacturing Engineer:
    • Involves optimizing manufacturing processes, improving efficiency, and ensuring the quality of products during production.
  3. Project Engineer:
    • Manages engineering projects from conception to completion, overseeing design, development, and implementation.
  4. Energy Engineer:
    • Focuses on designing and optimizing energy systems, including renewable energy projects and energy-efficient systems.
  5. Aerospace Engineer:
    • Involves designing and testing aircraft and spacecraft systems, working in the aerospace and aviation industry.
  6. Automotive Engineer:
    • Works on the design and development of automotive systems, including engines, chassis, and powertrains.
  7. HVAC Engineer:
    • Specializes in heating, ventilation, and air conditioning (HVAC) systems for residential, commercial, and industrial buildings.
  8. Thermal Systems Engineer:
    • Focuses on the design and analysis of thermal systems, including heat exchangers and refrigeration systems.
  9. Robotics Engineer:
    • Designs and develops robotic systems for various applications, such as manufacturing, healthcare, and automation.
  10. Control Systems Engineer:
    • Works on the design and implementation of control systems for mechanical and mechatronic systems.
  11. Materials Engineer:
    • Specializes in the selection and testing of materials for specific applications, considering mechanical properties and durability.
  12. Environmental Engineer:
    • Addresses environmental considerations in engineering projects, ensuring sustainable and eco-friendly practices.
  13. Quality Engineer:
    • Focuses on ensuring the quality of products through quality control and assurance processes.
  14. Consulting Engineer:
    • Provides expertise to clients on various engineering projects, offering solutions and advice.
  15. Research and Development Engineer:
    • Engages in research to develop new technologies, products, and processes.
  16. Project Manager:
    • Manages and oversees engineering projects, including budgeting, scheduling, and coordination of resources.
  17. Technical Sales Engineer:
    • Combines technical knowledge with sales skills to promote and sell engineering products or services.
  18. Renewable Energy Consultant:
    • Provides expertise in renewable energy solutions, advising on the implementation of sustainable practices.
  19. Academic and Research Positions:
    • Opportunities for teaching and research in academic institutions or research organizations.
  20. Entrepreneur/Start-up Founder:
    • Starts a business or contributes to the founding of a startup, leveraging engineering expertise for innovative solutions.

These career opportunities span various industries, including manufacturing, energy, aerospace, automotive, consulting, research and development, and more. Mechanical engineers can also pursue further education, certifications, and professional development to enhance their skills and advance in their careers.