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M-TECH in Thermal Power Engineering at Sri Siddhartha Institute of Technology
Tumakuru, Karnataka
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About the Specialization
What is Thermal Power Engineering at Sri Siddhartha Institute of Technology Tumakuru?
This Thermal Power Engineering program at Sri Siddhartha Institute of Technology focuses on advanced principles of thermodynamics, fluid mechanics, and heat transfer. It addresses the critical demand for engineers in India''''s growing energy sector, covering conventional and renewable power generation, energy efficiency, and thermal system design. The program emphasizes sustainable energy solutions and optimizing thermal processes for various industrial applications.
Who Should Apply?
This program is ideal for mechanical engineering graduates seeking entry into the power generation, HVAC, or renewable energy industries. It also suits working professionals aiming to upgrade their skills in thermal systems design, energy management, or combustion engineering. Candidates with a strong foundation in thermodynamics and a keen interest in sustainable energy technologies would find this program highly beneficial.
Why Choose This Course?
Graduates of this program can expect promising career paths as Thermal Engineers, Energy Managers, R&D Engineers, or HVAC system designers in India. Entry-level salaries typically range from INR 4-7 lakhs per annum, with experienced professionals earning significantly more. The program prepares students for roles in power plants, manufacturing, research organizations, and consultancies, aligning with certifications like Certified Energy Manager.
Student Success Practices
Foundation Stage
Build Strong Core Engineering Fundamentals- (Semester 1)
Focus on mastering Advanced Thermodynamics, Fluid Mechanics, and Heat Transfer. Utilize online resources like NPTEL courses, MIT OpenCourseware, and solve challenging problems from standard textbooks. Form study groups to discuss complex concepts and prepare for competitive exams that often test these fundamentals.
Tools & Resources
NPTEL, Coursera, Thermodynamics by P.K. Nag, Fluid Mechanics by Cengel, Heat Transfer by Incropera
Career Connection
A solid grasp of these core subjects is essential for all thermal engineering roles, forming the basis for advanced design, analysis, and problem-solving in the energy sector.
Engage Actively in Lab Experiments- (Semester 1)
Participate enthusiastically in Thermal Engineering Lab – 1. Understand the experimental setups, data collection methods, and error analysis. Strive to connect theoretical concepts with practical observations and analyze results critically. Document findings meticulously in lab reports.
Tools & Resources
Lab manuals, simulation software (if available), peer discussions
Career Connection
Practical lab skills are crucial for R&D roles, testing, and commissioning, providing hands-on experience vital for industry.
Develop Research and Presentation Skills Early- (Semester 1)
Treat Research Methodology and IPR, and Technical Seminar-I as opportunities to develop strong academic writing, critical thinking, and presentation abilities. Select interesting and relevant topics for seminars, conduct thorough literature reviews, and practice presenting effectively.
Tools & Resources
Mendeley/Zotero for referencing, LaTeX for technical writing, PowerPoint/Canva for presentations, academic databases (Scopus, Web of Science)
Career Connection
These skills are invaluable for thesis writing, technical report generation, and professional presentations in any engineering career, especially in R&D or consulting.
Intermediate Stage
Specialize Through Electives and Apply Practical Knowledge- (Semester 2)
Strategically choose professional electives based on career interests (e.g., CFD, Advanced IC Engines, Renewable Energy). Simultaneously, apply theoretical knowledge from core courses like RAC and Energy Management in Thermal Engineering Lab – 2 experiments. Aim to conduct mini-projects related to elective subjects.
Tools & Resources
ANSYS Fluent/Star-CCM+ (for CFD), MATLAB/Python for data analysis, industry standards and codes
Career Connection
Specialization through electives makes students more marketable for specific roles, while practical application in labs enhances problem-solving capabilities required by the industry.
Undertake an Industry Internship- (Semester 3)
Actively seek and complete an internship in a relevant thermal power plant, energy consulting firm, or manufacturing industry during Semester 3. Focus on understanding real-world challenges, observing operational processes, and contributing to ongoing projects. Maintain a professional network built during the internship.
Tools & Resources
LinkedIn, college placement cell, industry contacts
Career Connection
Internships provide invaluable industry exposure, practical skill development, and often lead to pre-placement offers, significantly boosting career prospects.
Initiate and Plan Your Master''''s Project- (Semester 3)
For Project Work Phase I in Semester 3, identify a research problem that aligns with your interests and potential career goals. Conduct an extensive literature review, define clear objectives, and develop a robust methodology. Engage regularly with your faculty advisor for guidance and feedback.
Tools & Resources
Academic journals, research papers, project management tools, institutional research labs
Career Connection
A well-executed master''''s project showcases research capabilities, problem-solving skills, and contributes to a strong resume, appealing to R&D departments and higher education.
Advanced Stage
Drive Your Project to Successful Completion- (Semester 4)
Dedicate significant effort to Project Work Phase II. Systematically collect and analyze data, interpret results, and draw meaningful conclusions. Focus on presenting your work in a clear, concise, and professional thesis. Prepare thoroughly for the project defense and viva-voce.
Tools & Resources
Statistical software, simulation tools, thesis writing guides, presentation software
Career Connection
A strong final project is a cornerstone of an M.Tech degree, demonstrating expertise, independence, and critical thinking—highly valued traits in any advanced engineering role.
Refine Technical Communication and Presentation for Career Readiness- (Semester 4)
Utilize Technical Seminar-III to present your project''''s findings to a wider audience, focusing on clarity, impact, and effectively answering questions. Refine your ability to articulate complex technical concepts to both technical and non-technical listeners.
Tools & Resources
Public speaking workshops, peer feedback, faculty mentoring
Career Connection
Excellent communication skills are paramount for leadership roles, client interactions, and conveying technical information effectively in industry and research.
Strategize for Placements and Professional Growth- (Semester 4)
Actively participate in campus placement drives, tailor your resume and cover letter to specific job descriptions, and practice interview skills, including technical and HR rounds. Explore opportunities for further research or entrepreneurship in the thermal power sector.
Tools & Resources
Placement cell resources, mock interviews, industry networking events, career fairs
Career Connection
Proactive placement strategy ensures a smooth transition into employment, securing roles in desired industries and setting the stage for long-term career growth.
Program Structure and Curriculum
Eligibility:
- B.E./B.Tech. or equivalent degree in Mechanical Engineering / Industrial Production Engineering / Automobile Engineering / Mechatronics Engineering / Industrial Engineering and Management / Manufacturing Science and Engineering / Aeronautical Engineering with 50% aggregate marks (45% for SC/ST/Category-I candidates). Valid GATE score or PGCET score.
Duration: 2 years (4 semesters)
Credits: 92 Credits
Assessment: Internal: 50% (for theory/lab courses), 100% (for Internship/Seminar), External: 50% (for theory/lab courses and Project Work Phase II), 0% (for Internship/Seminar/Project Work Phase I)
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 22MTE11 | Advanced Thermodynamics | Core | 4 | First and Second Laws of Thermodynamics, Entropy and Exergy Analysis, Thermodynamic Properties of Pure Substances, Mixtures and Psychrometry, Chemical Equilibrium |
| 22MTE12 | Advanced Fluid Mechanics | Core | 4 | Inviscid and Viscous Fluid Flow, Boundary Layer Theory, Turbulence Modeling, Compressible Flow Fundamentals, Flow Measuring Devices |
| 22MTE13 | Advanced Heat and Mass Transfer | Core | 4 | Conduction Heat Transfer (Steady/Unsteady), Convection Heat Transfer (Forced/Natural), Radiation Heat Transfer, Phase Change Heat Transfer, Mass Transfer Principles |
| 22MTE14 | Research Methodology and IPR | Core | 4 | Formulating Research Problem, Data Collection and Analysis, Statistical Methods for Research, Technical Report Writing, Intellectual Property Rights |
| 22MTE15x | Professional Elective - I (Any one of the following) | Elective | 3 | Design of Thermal Systems, Advanced Power Plant Engineering, Combustion Engineering |
| 22MTEL16 | Thermal Engineering Lab – 1 | Lab | 1 | Heat Exchanger Performance Evaluation, IC Engine Testing and Analysis, Refrigeration System Performance, Fluid Flow Characteristics, Heat Pipe Demonstrations |
| 22MTEP17 | Technical Seminar- I | Seminar | 4 | Literature Review Techniques, Technical Report Preparation, Oral Presentation Skills, Emerging Thermal Engineering Topics, Critical Analysis of Research Papers |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 22MTE21 | Refrigeration and Air Conditioning | Core | 4 | Vapour Compression Refrigeration Cycles, Vapour Absorption Refrigeration Systems, Psychrometric Processes, Air Conditioning System Design, Duct Design and Air Distribution |
| 22MTE22 | Renewable Energy Systems | Core | 4 | Solar Energy Technologies, Wind Power Generation, Bioenergy Conversion Systems, Geothermal Energy Applications, Ocean Energy Systems |
| 22MTE23 | Energy Management and Auditing | Core | 4 | Energy Conservation Principles, Energy Audit Methodologies, Thermal Energy Audit, Electrical Energy Audit, Energy Economics and Project Management |
| 22MTE24x | Professional Elective - II (Any one of the following) | Elective | 3 | Advanced IC Engines, Computational Fluid Dynamics, Cryogenic Engineering |
| 22MTE25x | Professional Elective - III (Any one of the following) | Elective | 3 | Non-Conventional Energy Sources, Gas Dynamics and Jet Propulsion, Thermal System Design |
| 22MTEL26 | Thermal Engineering Lab – 2 | Lab | 1 | Vapour Compression Refrigeration Cycle, Air Conditioning System Performance, Solar Water Heater Characteristics, Wind Turbine Performance Testing, Heat Pipe Experimentation |
| 22MTEP27 | Technical Seminar- II | Seminar | 4 | Advanced Research Topic Selection, In-depth Literature Review, Scientific Presentation Techniques, Q&A Session Handling, Technical Communication Best Practices |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 22MTE31 | Project Work Phase – I | Project | 8 | Problem Identification and Formulation, Extensive Literature Survey, Methodology Development, Experimental Setup Design, Preliminary Results and Discussion |
| 22MTE32 | Internship | Internship | 8 | Industry Exposure and Practical Training, Application of Theoretical Knowledge, Professional Networking, Technical Skill Development, Internship Report Preparation |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 22MTE41 | Project Work Phase – II | Project | 24 | Data Analysis and Interpretation, Result Validation and Discussion, Drawing Conclusions, Thesis Writing and Documentation, Project Defense and Viva-Voce |
| 22MTE42 | Technical Seminar- III | Seminar | 4 | Project Findings Presentation, Technical Query Handling, Advanced Presentation Skills, Future Scope of Research, Dissemination of Technical Work |
