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M-TECH in Mechanical Engineering Thermal Engineering at Shri Krishan Institute of Engineering and Technology
Kurukshetra, Haryana
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About the Specialization
What is Mechanical Engineering (Thermal Engineering) at Shri Krishan Institute of Engineering and Technology Kurukshetra?
This Thermal Engineering program at Shri Krishan Institute of Engineering and Technology focuses on advanced principles of thermodynamics, heat transfer, and fluid mechanics. It addresses the design, analysis, and optimization of energy systems crucial for various Indian industries like power generation, automotive, and HVAC. The curriculum emphasizes both theoretical depth and practical applications, preparing engineers for critical roles in energy efficiency and sustainable technology development.
Who Should Apply?
This program is ideal for fresh Mechanical Engineering graduates seeking entry into the energy sector, working professionals looking to upskill in thermal system design or energy management, and career changers transitioning into sustainable energy roles. Candidates with a strong foundation in thermodynamics and fluid mechanics, and an interest in energy innovation, will particularly benefit from this advanced study.
Why Choose This Course?
Graduates of this program can expect to pursue India-specific career paths in power plants, R&D divisions, and HVAC manufacturing. Potential roles include Thermal Design Engineer, Energy Auditor, HVAC Consultant, and Research Scientist. Entry-level salaries typically range from INR 4-7 LPA, with experienced professionals earning INR 10-20+ LPA, reflecting strong growth trajectories in the burgeoning Indian energy market.
Student Success Practices
Foundation Stage
Build Strong Mathematical & Scientific Foundations- (Semester 1-2)
Dedicate consistent time to mastering advanced engineering mathematics, thermodynamics, and fluid mechanics. Form study groups to tackle complex problems and deepen conceptual understanding. Focus on problem-solving techniques beyond rote memorization.
Tools & Resources
NPTEL lectures on Advanced Engineering Mathematics/Thermodynamics, Relevant textbooks, Online problem-solving platforms like BYJU''''S Exam Prep for GATE
Career Connection
A solid foundation in these core areas is crucial for success in advanced thermal design, analysis, and research roles, and is often tested in technical interviews for R&D positions.
Excel in Software-Based Engineering Analysis- (Semester 1-2)
Actively participate in CAD, CAM, and CAE labs. Go beyond assigned tasks to explore software like SolidWorks, ANSYS, and MATLAB for advanced simulations and modeling. Undertake small personal projects to apply learned tools.
Tools & Resources
Lab manuals, SolidWorks tutorials, ANSYS/Fluent documentation, MATLAB/Simulink guides, Online forums
Career Connection
Proficiency in CAE tools like FEA and CFD is highly valued in design, R&D, and analysis roles across thermal industries, enhancing employability for positions like simulation engineer.
Develop Research and Presentation Skills Early- (Semester 2)
Take research methodology seriously. Practice literature reviews, academic writing, and public speaking through seminar presentations. Seek feedback from professors to refine your communication skills.
Tools & Resources
Google Scholar, IEEE Xplore, Scopus for literature search, LaTeX for scientific writing, Presentation software
Career Connection
Strong research and presentation skills are essential for M.Tech projects, future academic pursuits (Ph.D.), and for effectively communicating technical solutions in corporate settings.
Intermediate Stage
Specialize in Thermal Systems & Energy Technologies- (Semester 3)
Deep dive into your chosen electives (e.g., Refrigeration & AC, Renewable Energy, CFD). Pursue certifications or online courses specific to these areas. Actively engage in discussions and problem-solving related to these specialized topics.
Tools & Resources
NPTEL specialized courses, Coursera/edX programs on specific thermal subjects, Industry whitepapers, BEEP (Bureau of Energy Efficiency) certifications
Career Connection
Specialization is key for targeted roles like HVAC Design Engineer, Renewable Energy Consultant, or CFD Analyst. These focused skills attract niche employers and offer higher remuneration.
Initiate and Progress on Project Work (Stage I)- (Semester 3)
Proactively identify a research problem, conduct a thorough literature review, and define a clear methodology for your M.Tech Project Stage I. Collaborate with faculty mentors and leverage institutional resources.
Tools & Resources
University library databases, Research journals, Access to lab equipment/software, Regular mentor meetings
Career Connection
A well-executed project demonstrates independent research capability, problem-solving skills, and deep subject knowledge, significantly boosting your profile for R&D roles and higher studies.
Gain Practical Industry Exposure- (Semester 3)
Seek out and complete an industrial training program or internship relevant to thermal engineering. Focus on understanding real-world processes, challenges, and solutions. Network with industry professionals.
Tools & Resources
College placement cell, Internship portals (Internshala, LinkedIn), Industry contacts, Company websites
Career Connection
Direct industry experience is invaluable for understanding career demands, building a professional network, and often leads to pre-placement offers or faster employment in core companies.
Advanced Stage
Deliver a High-Impact M.Tech Project (Stage II)- (Semester 4)
Execute the experimental or simulation work for Project Stage II rigorously. Analyze results, draw conclusions, and meticulously document your findings in a comprehensive thesis. Prepare for a strong viva-voce defense.
Tools & Resources
Advanced simulation software, Lab facilities, Statistical analysis tools (SPSS, R), Thesis formatting guides
Career Connection
A strong final project is your most significant academic achievement, providing a major talking point in interviews and showcasing your ability to conduct impactful research and development.
Master Placement & Interview Preparedness- (Semester 4)
Attend placement workshops, practice technical questions specific to thermal engineering (e.g., thermodynamics, heat exchangers, fluid dynamics), and refine your resume and soft skills. Engage in mock interviews.
Tools & Resources
College placement cell resources, Online interview preparation platforms (GeeksforGeeks, InterviewBit), Technical books, LinkedIn for professional networking
Career Connection
Effective preparation directly translates to successful placements in desired companies, securing roles as thermal engineers, R&D specialists, or energy consultants.
Cultivate Professional Networking & Continuous Learning- (Semester 4 and beyond)
Join professional bodies like ISHRAE (Indian Society of Heating, Refrigerating and Air Conditioning Engineers) or IES (Indian Energy Society). Attend webinars, conferences, and workshops to stay updated on industry trends and build a professional network.
Tools & Resources
Professional association memberships, Industry conferences (e.g., HVACR Expo), Online professional communities, LinkedIn
Career Connection
Networking opens doors to new opportunities, mentorship, and keeps you abreast of industry innovations, ensuring long-term career growth and adaptability in the dynamic energy sector.
Program Structure and Curriculum
Eligibility:
- B.E./B.Tech in Mechanical/Production/Industrial Engineering or equivalent with 50% marks (45% for SC/ST). Admission through Online Entrance Test by HSTES or GATE.
Duration: 2 years / 4 semesters
Credits: 82 Credits
Assessment: Internal: Theory: 25%, Practicals/Projects/Seminar: 50%, External: Theory: 75%, Practicals/Projects/Seminar: 50%
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MME-101 | Advanced Engineering Mathematics | Core | 4 | Linear Algebra, Calculus of Variations, Probability & Statistics, Numerical Methods, Transform Techniques |
| MME-102 | Advanced Thermodynamics | Core | 4 | Laws of Thermodynamics Review, Maxwell Relations, Thermodynamic Stability, Combustion Thermodynamics, Irreversibility & Availability Analysis |
| MME-103 | Advanced Fluid Mechanics | Core | 4 | Kinematics of Fluid Flow, Viscous Flow Fundamentals, Boundary Layer Theory, Compressible Flow, Dimensional Analysis |
| MME-104 | Advanced Manufacturing Process | Core | 4 | Metal Casting Technologies, Metal Forming Operations, Advanced Machining Processes, Welding Metallurgy & Techniques, Powder Metallurgy & Additive Manufacturing |
| MME-105 | Computer Aided Design & Manufacturing (Practical) | Lab | 2 | CAD Software Operations, 2D and 3D Modeling, CAM Principles, CNC Programming, Manufacturing Simulations |
| MME-106 | Mechanical Engineering Lab-I (Practical) | Lab | 2 | Fluid Mechanics Experiments, Thermodynamics Practical Applications, Material Science Testing, Measurement Techniques, Data Acquisition & Analysis |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MME-201 | Research Methodology | Core | 4 | Research Process & Problem Formulation, Literature Review Techniques, Data Collection & Sampling, Statistical Analysis for Research, Report Writing & Presentation |
| MME-202 | Advanced Heat Transfer | Core | 4 | Conduction Heat Transfer (Steady/Unsteady), Convection (Forced/Natural/Phase Change), Radiation Heat Transfer, Heat Exchanger Design & Analysis, Boiling & Condensation |
| MME-203 | Finite Element Methods | Core | 4 | FEM Basics & Variational Principles, 1D & 2D Element Formulations, Shape Functions & Isoparametric Elements, Stiffness Matrix Assembly, Applications in Stress & Heat Transfer Analysis |
| MME-204 | Design of Thermal Systems | Core | 4 | Thermal System Modeling, Optimization Techniques for Thermal Systems, Component Design (Boilers, Condensers), System Simulation & Performance Analysis, Economic Analysis of Thermal Systems |
| MME-205 | Computer Aided Engineering Lab (Practical) | Lab | 2 | CAE Software Applications, Finite Element Analysis (FEA) Practice, Computational Fluid Dynamics (CFD) Simulations, Thermal System Design & Optimization Tools, Post-processing & Visualization |
| MME-206 | Mechanical Engineering Lab-II (Practical) | Lab | 2 | Advanced Heat Transfer Experiments, Thermal Systems Performance Testing, Advanced Fluid Flow Measurements, Experimental Data Interpretation, Report Generation |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MME-301 | Disaster Management | Core | 4 | Types of Disasters, Disaster Preparedness & Planning, Risk Assessment & Vulnerability Analysis, Mitigation Strategies, Rehabilitation & Reconstruction |
| MTE-301 | Refrigeration & Air Conditioning (Elective I - Option) | Elective | 4 | Vapor Compression & Absorption Cycles, Refrigerants & Environmental Impact, Psychrometrics & Air Conditioning Processes, HVAC System Components & Design, Cooling Load Calculations |
| MTE-302 | Renewable Energy Sources (Elective I - Option) | Elective | 4 | Solar Energy Utilization, Wind Energy Systems, Biomass & Biofuel Technologies, Geothermal Energy, Ocean Thermal Energy Conversion |
| MTE-303 | Cryogenic Engineering (Elective I - Option) | Elective | 4 | Gas Liquefaction Cycles, Cryogenic Refrigeration Principles, Low-Temperature Insulation, Cryogenic Storage & Transfer Systems, Applications of Cryogenics |
| MTE-304 | Advanced Power Plant Engineering (Elective I - Option) | Elective | 4 | Thermal Power Cycles Optimization, Nuclear Power Plant Design, Hydroelectric Power Generation, Gas Turbine & Combined Cycle Power Plants, Environmental Impact of Power Generation |
| MTE-305 | Computational Fluid Dynamics (Elective II - Option) | Elective | 4 | Governing Equations of Fluid Flow, Discretization Methods (FDM, FVM), Grid Generation Techniques, CFD Solvers & Algorithms, Turbulence Modeling |
| MTE-306 | Energy Conservation & Management (Elective II - Option) | Elective | 4 | Energy Audit Methodologies, Demand Side Management, Waste Heat Recovery Systems, Energy Conservation Techniques, Carbon Management & Emission Reduction |
| MTE-307 | Non Conventional Energy Systems (Elective II - Option) | Elective | 4 | Solar Photovoltaic & Thermal Systems, Wind Turbine Technology, Biofuels & Biogas Production, Fuel Cell Technology, Hybrid Energy Systems |
| MTE-308 | Thermal System Design & Analysis (Elective II - Option) | Elective | 4 | Steady-State & Transient Analysis, Heat Exchanger Design Principles, Fluid Network Design, Thermal System Optimization, Integration of Thermal Components |
| MME-302 | Project Stage – I | Project | 6 | Problem Identification & Formulation, Extensive Literature Survey, Methodology Development, Preliminary Design/Analysis, Interim Report Writing |
| MME-303 | Seminar / Industrial Training | Practical/Seminar | 2 | Technical Presentation Skills, Report Writing on Technical Topic, Industry Exposure & Practices, Problem Solving in Industrial Context, Networking & Professional Development |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| MME-401 | Project Stage – II | Project | 16 | Experimental Work/Advanced Simulations, Data Analysis & Interpretation, Results Discussion & Conclusion Formulation, Thesis Writing & Documentation, Viva-Voce Examination |
| MME-402 | Seminar | Seminar | 2 | Advanced Research Topic Presentation, In-depth Technical Communication, Question & Answer Session Management, Critical Analysis of Research, Public Speaking in Technical Domain |
