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M. Tech. - Thermal Engineering

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M. Tech. - Thermal Engineering NATIONAL INSTITUTE OF TECHNOLOGY WARANGAL M. Tech. - Thermal Engineering DEPARTMENT OF MECHANICAL ENGINEERING SCHEME OF INSTRUCTION AND SYALLABI Effective from 2019 – 20 VISION Towards a Global Knowledge Hub, striving continuously in pursuit of excellence in Education, Research, Entrepreneurship and Technological services to the society MISSION Imparting total quality education to develop innovative, entrepreneurial and ethical future professionals fit for globally competitive environment. Allowing stake holders to share our reservoir of experience in education and knowledge for mutual enrichment in the field of technical education. Fostering product oriented research for establishing a self-sustaining and wealth creating centre to serve the societal needs. DEPARTMENT OF MECHANICAL ENGINEERING VISION To be a global knowledge hub in mechanical engineering education, research, entrepreneurship and industry outreach services. MISSION Impart quality education and training to nurture globally competitive mechanical engineers. Provide vital state-of-the-art research facilities to create, interpret, apply and disseminate knowledge. Develop linkages with world class educational institutions and R&D organizations for excellence in teaching, research and consultancy services. NIT Warangal M.Tech (Thermal Engineering Syllabus) Page 2 DEPARTMENT OF MECHANICAL ENGINEERING M.TECH. IN THERMAL ENGINEERING PROGRAM EDUCATIONAL OBJECTIVES (PEOS): Program Educational Objectives (PEOs) are broad statements that describe the career and professional accomplishments that the program is preparing graduates to achieve. They are consistent with the mission of the Institution and Department. Department faculty members continuously worked with stakeholders (local employers, industry and R&D advisors and the alumni) to review and update them periodically. Analyze, design and evaluate thermal systems using state of the art engineering PEO1 tools and techniques PEO2 Develop methods of energy conservation for sustainable growth PEO3 Communicate effectively and support constructively towards team work Pursue lifelong learning for professional growth with ethical concern for society PEO4 and environment MAPPING OF MISSION STATEMENTS WITH PROGRAM EDUCATIONAL OBJECTIVES: Mission Statement PEO1 PEO2 PEO3 PE04 Imparting quality education to the students and enhancing their skills to make them globally 3 1 3 2 competitive mechanical engineers. Maintaining vital, state-of-the-art research facilities to provide its students and faculty with opportunities to 3 3 3 3 create, interpret, apply and disseminate knowledge. To develop linkages with world class R&D organizations and educational institutions in India and 2 2 3 3 abroad for excellence in teaching, research and consultancy practices. 1: Slightly 2: Moderately 3: Substantially NIT Warangal M.Tech (Thermal Engineering Syllabus) Page 3 PROGRAM OUTCOMES: Program Outcomes (POs) are narrower statements that describe what the students are expected to know and be able to do upon the graduation. These relate to the knowledge, skills and behavior the students acquire through the program. The POs are specific to the program and facilitate the attainment of PEOs. PO1 Carryout independent research/investigation and development work to solve practical problems PO2 Write and present a substantial technical report/document PO3 Demonstrate a degree of mastery over thermal engineering at a level higher than the Bachelor’s program. PO4 Design, develop and analyze thermal systems for improved performance PO5 Identify viable energy sources and develop effective technologies to harness them PO6 Engage in lifelong learning adhering to professional, ethical, legal, safety, environmental and societal aspects for career excellence. MAPPING OF PROGRAM OUTCOMES WITH PROGRAM EDUCATIONAL OBJECTIVES: PEO PO1 PO2 PO3 PO4 PO5 PO6 PEO1 3 3 2 3 3 2 PEO2 3 2 2 3 2 2 PEO3 2 2 2 2 2 3 PEO4 3 2 3 3 3 3 1: Slightly 2: Moderately 3: Substantially NIT Warangal M.Tech (Thermal Engineering Syllabus) Page 4 CURRICULAR COMPONENTS Category I Year, I Year, II Year, II Year, Total No. of Sem – I Sem – II Sem – I Sem – II credits to be earned Core courses 12 06 -- -- 18 Electives 06 12 -- -- 18 Lab Courses 04 04 -- -- 08 Comprehensive -- -- 02 -- 02 Viva-Voce Seminar 01 01 -- -- 02 Dissertation -- -- 09 18 27 Total 23 23 11 18 75 NIT Warangal M.Tech (Thermal Engineering Syllabus) Page 5 M.Tech. (THERMAL ENGINEERING) SCHEME OF INSTRUCTIONS AND EVALUATION I Year - I Semester Sl. No. Course Cat. Course Title L T P Cr Code Code 1 ME5101 Advanced Fluid Mechanics 3 0 0 3 PCC 2 ME5102 Computational Methods in Thermal 3 0 0 3 PCC Engineering 3 ME5103 Advanced Heat and Mass Transfer 3 0 0 3 PCC 4 ME5104 Internal Combustion Engines and Alternate 3 0 0 3 PCC Power Sources 5 Elective – 1 3 0 0 3 DEC 6 Elective – 2 3 0 0 3 DEC 7 ME5141 Thermal Engineering laboratory 0 1 2 2 PCC 8 ME5142 CFD laboratory 0 1 2 2 PCC 9 ME5143 Seminar-I 0 0 3 1 PCC Total 18 2 7 23 PCC – Program Core Course; DEC: Department Elective Course I – Year, II – Semester Sl. No. Course Cat. Course Title L T P Cr Code Code 1 ME5151 Gas Turbines and Jet Propulsion 3 0 0 3 PCC 2 ME5152 Experimental Methods in Thermal 3 0 0 3 PCC Engineering 3 Elective – 3 3 0 0 3 PCC 4 Elective – 4 3 0 0 3 PCC 5 Elective – 5 3 0 0 3 DEC 6 Elective – 6 3 0 0 3 DEC 7 ME5191 Simulation laboratory 0 1 2 2 PCC 8 ME5192 Energy Systems Laboratory 0 1 2 2 PCC 9 ME5193 Seminar-II 0 0 3 1 PCC Total 18 2 7 23 II – Year, I – Semester S. No. CourseCode Course Title Credits Cat.Code 1 ME5148 Comprehensive Viva-voce 2 PCC 2 ME5149 Dissertation Part-A 9 PCC Total 11 II – Year, II – Semester S. No. Course Code Course Title Credits Cat.Code 1 ME5199 Dissertation Part-B 18 PCC Total 18 NIT Warangal M.Tech (Thermal Engineering Syllabus) Page 6 List of Elective Courses (M.Tech – Thermal Engineering) I Year I Semester S. No. Course Code Course Title 1 ME5111 Refrigeration Technology 2 ME5121 Power Plant Engineering 3 ME5122 Renewable Sources of Energy 4 ME5123 Energy Systems and Management 5 ME5321 Enterprise Resource Planning 6 ME5336 Soft Computing Techniques 7 ME5422 Mathematical Methods in Engineering I Year II Semester S. No. Course Code Course Title 1 ME5161 Heating, Ventilation and Air Conditioning 2 ME5162 Advanced Computational Fluid Dynamics 3 ME5163 Convective Heat and Mass Transfer 4 ME5164 Rocket Propulsion 5 ME5165 Conduction and Radiation Heat Transfer 6 ME5166 Multi – Phase flow 7 ME5167 Design and Optimization of Thermal Systems 8 ME5168 Gas Dynamics 9 ME5171 Design of Heat Transfer Equipment 10 ME5172 New Venture Creation 11 ME5274 Fluid Power Systems 12 ME5281 Precision Manufacturing 13 ME5378 Industry 4.0 and IIoT 14 ME5387 Project Management 15 ME5479 Optimization Methods for Engineering Design 16 ME5482 Finite Element Method 17 ME5483 CAD 18 ME5571 Combustion and Emission Control 19 ME5572 Alternate Fuels & Emissions 20 ME5674 Thermal Coatings NIT Warangal M.Tech (Thermal Engineering Syllabus) Page 7 Courses offered to other Specialization S. No. Course Code Course Title 1 ME5131 Computational Fluid Dynamics 2 ME5187 Solar Energy Systems 3 ME5188 Energy Conservation & Waste Recovery NIT Warangal M.Tech (Thermal Engineering Syllabus) Page 8 Assessment of Academic Performance for Theory Courses: Continuous Evaluation : 20 marks Mid-semester Examination : 30 marks (as per academic calendar) End-semester Examination : 50 marks (as per academic calendar) Total : 100 marks Assessment of Academic Performance for Laboratory Courses: Continuous Evaluation : 35 Marks (Lab report, viva, Quiz etc) Skill test : 25 Marks End Semester Examination : 40 Marks Total : 100 Marks NIT Warangal M.Tech (Thermal Engineering Syllabus) Page 9 DETAILED SYLLABUS I- Year, I- Semester ME5101 ADVANCED FLUID MECHANICS 3 – 0 – 0 (3 Cr) Prerequisites: Nil Course Outcomes: CO1 Ascertain basic concepts in the fluid mechanics CO2 Analyze the performance of fluid flow devices in laminar and Turbulent flows. CO3 Design components used in Turbo machines and air- conditioning based on the principles of fluid mechanics CO4 Apply the concepts in the analysis of fluid flow problems CO-PO Mapping: CO PO1 PO2 PO3 PO4 PO5 PO6 CO1 2 2 3 3 2 1 CO2 2 2 3 3 2 1 CO3 2 2 3 3 2 1 2 2 3 3 2 1 CO4 CO5 2 2 3 3 2 1 Detailed Syllabus: 1. Introduction: Review of the fundamentals of Fluid mechanics. 2. Kinematics of Fluids: Lagrangean and Eulerian systems, Velocity potential, Stream function and Vorticity. 3. General theory of Stress and Rate of Strain: Stress-strain relations. 4. Fundamental Conservation Equations: Integral and differential forms. 5. One-dimensional Inviscid Incompressible Flow: Euler’s equation and Bernoulli’s equation- applications of the Bernoulli’s equation. 6. Exact solutions of Navier-Stokes Equations: Couette flow, Hagen-Poiseuille flow, Flow between coaxial and concentric rotating cylinders, Hydrodynamic theory of lubrication, Creeping flows, Unsteady motion of flat plate. 7. The Laminar Boundary Layer: Prandtl’s Boundary Layer Equations, Blasius solution, Momentum-integral equations and its applications, Boundary layer separation and control. 8. Turbulent Flows: Introduction to Turbulent Flow, Reynolds modification of N-S equations, Semi - empirical theories, Turbulent boundary layer for internal and external flows, Turbulence modelling. 9. Dimensional Analysis: Flow over a bluff body – Lift and Drag, Dimensional analysis and similitude. 10. Introduction to Compressible Flow: isentropic flow, Flow across normal and oblique shocks, Fanno flow, Rayleigh flow, Expansion waves. NIT Warangal M.Tech (Thermal Engineering Syllabus) Page 10 Readings: 1. Yuan, S. W., Foundations of Fluid Mechanics, Prentice Hall of India, 2000 2. Yahya, S. M., Fundamentals of Compressible Flow with Aircraft and Rocket Propulsion, 6th Edition, New Age International Publishers, 2018. 3. Anderson, J. D. Jr., Modern Compressible Flow –with Historical Perspective, 3rd edition, TMH, 2017. 4. Schlichting, H and Gersten, K, Boundary Layer Theory, 9th Edition, Springer, 2018.
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