M.Phil (Mechanical Engineering) is a postgraduate academic research degree course. M.Phil (Mechanical Engineering) is a preliminary research stage of PhD that offers the candidate for applying principles of physics, mathematics and material science and studies the effects of many components in the field of mechanics. The course is well suitable for those candidates who want to gain expertise in material science and its effects on the real world. A pre-doctoral programme - Master of Philosophy (M.Phil.) is taken after successful completion of the Master's Degree. It is a specialized course that covers topics in Math and Science that require students to have background knowledge in mechanics, thermodynamics, and scientific computing. A candidates who have M.Phil degree can find job into fields of research and academia, in colleges and universities, kinetics, thermodynamics, robotics, oil exploration and refining, power plants, and etcetera. During the course candidates learn great mechanical engineering skills, as well as technical drawing and computing skills necessary in the designing of machines and equipment. Master of Philosophy in Mechanical Engineering course take around two year and its syllabus is divide in six semesters.
M.Phil (Mechanical Engineering) Career Prospect:
M.Phil (Mechanical Engineering) Job Position:
NOTE:- Students are requested to note that their application will not be considered for admission if the above certificates are not enclosed with their application.
Given below are few of the important highlights of the program.
Program Full Name | Master of Philosophy in Mechanical Engineering |
Program Level | Doctorate Degree Courses |
Duration of the Program | 2 Years |
Examination Type | Semester |
Eligibility | Master in Relevant Subjects With 55% Marks (50% For SC/ST) |
Admission Process | Entrance Exam and Merit Based |
Average Program Fee | Rs. 2 Lakh - Rs. 3 Lakh |
Syllabus of Management as prescribed by various Universities and Colleges.
Paper Code | Subjects of Study |
1 | CAD/CAM/CAE-I |
2 | Reverse Engineering |
3 | Manufacturing Systems |
4 | Computer Aided Manufacturing |
5 | Modern manufacturing systems |
6 | Low-Cost Automation |
7 | The course would offer in-depth knowledge of designing, testing and manufacturing of equipment through computer-aided programs |
8 | CAD/CAM/CAE-II |
9 | Advanced Materials & Processing |
10 | Technology Management |
11 | Database Management |
12 | Work system design |
13 | Precision Engineering |
14 | This course let the students interact with intricacies of designing equipment |
15 | Design-I |
16 | Advanced Theory of Elasticity (3-dimensional problems |
17 | Fracture Mechanics |
18 | Tribology Friction and Wear |
19 | Biomedical device design |
20 | System Design |
21 | This course deal with the advanced stage of elasticity pertaining to the mechanical system |
22 | Design II |
23 | Vibrations Micro Electro Mechanical Systems (MEMS) |
24 | Mechatronics |
25 | Robotics |
26 | This course provides students with the in-depth structure of designing and what role electro-mechanical system plays in it |
27 | Heat Power-I |
28 | Convective Heat Transfer |
29 | Conduction and radiation |
30 | Advanced Trends in Heat Exchanger |
31 | Advanced Topics in I C Engines |
32 | This course deals with the equipment like an air-conditioning providing stretch to know the trends of Heat in equipment |
33 | Production-I |
34 | Reliability Engineering |
35 | Modeling of Manufacturing Systems |
36 | Metal Forming |
37 | Advanced casting technology |
38 | Computational Welding Mechanics |
39 | Composite Materials |
40 | Material handling and plant layout |
41 | This course offers the study of production and manufacturing of mechanical systems |
42 | Elective Courses |
43 | Numerical Computation of Fluid and Heat Flow |
44 | Computational approach to Fluid Dynamics |
45 | Governing Equations |
46 | Finite Volume Method |
47 | Checkerboard pressure field and staggered grid approach |
48 | Practical aspects of computational modeling of flow domains |
49 | Objective and importance of CFDHT |
50 | Solution of N-S Equation for Incompressible Flows |
51 | Term paper |
52 | This elective course provides an in-depth study of heated micro channels |
53 | Energy Analysis of Thermal Systems |
54 | Introduction to Thermal System Design |
55 | Thermodynamic modeling and design analysis |
56 | Exergy Analysis |
57 | Heat transfer modeling and design analysis |
58 | Design of piping and pump systems |
59 | Thermo-economic analysis and evaluation |
60 | Thermo-economic optimization |
61 | Term Work |
62 | This course offers the practical knowledge of analysis of the design of thermal-fluid energy systems |
63 | DESIGN OF HEAT TRANSFER EQUIPMENT |
64 | Different Classification of Heat Exchangers |
65 | Design of Shell and Tube Heat Exchanger |
66 | Boiler furnace design |
67 | Design of Steam Condenser and evaporative condensers |
68 | Design of Fuel Oil Suction Heater |
69 | Design of Cooling Tower |
70 | Term Work I |
71 | Studies the designs of heat transfer from one fluid to another and its probable complications and modifications |
72 | Mathematical Modeling and Design Optimization |
73 | Research Modeling |
74 | Simulation |
75 | Classical Optimization Techniques |
76 | Single-variable Optimization Techniques |
77 | Multivariable Optimization Techniques |
78 | Taguchi Method |
79 | This course provides a knowledge of computer- based mathematical modeling |
80 | Advanced Theory of Vibrations |
81 | Fundamentals of Vibration |
82 | Two Degree Freedom System |
83 | Multi Degree Freedom System |
84 | Vibration of Continuous Systems |
85 | Experimental Methods in Vibration Analysis |
86 | Analytical Dynamic Analysis |
87 | Validation of Analytical Models |
88 | Non-Linear Vibrations |
89 | Random Vibrations |
90 | This course refers to the analytical methods and techniques regarding axial and torsional vibrations |
Mentioned below are some states in India that offer the program.