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The graduates pursuing B.Tech in Mechanical Engineering from MM(DU) are well prepared with the knowledge and technical information, refined with a professional touch and capable of undertaking mechanical engineering jobs to meet the challenges of the 21st-century industry. The course includes self-learning modules like assignments, seminars and case studies for understanding the industrial challenges and raising the potential of students. The course syllabus is used to be revised from time to time in order to ensure student’s awareness about the latest trends in technology.
Provides the knowledge of differential and integral calculus and enables understanding of linear algebra, linear programming and set theory.
Elaboration of biological concepts with emphasis on effective utilization of biological principles for technology development by engineering students.
Provide the knowledge of various ordinary, partial differential equations and in-depth understanding of various analytical and numerical methods needed for solving different differential equations.
Provides the knowledge of differential and integral calculus and enables understanding of linear algebra, linear programming and set theory.
Introduction to the fundamental concepts of electricity and electronics that involve direct current, alternating current, series and parallel resistive circuits, inductance, capacitance, transformers, motors, electronic components, and various types of test equipment found in industry.
Students have practice in applying their knowledge of mathematics, science, and engineering and to expand this knowledge into the vast area of “rigid body Mechanics”. Students prepared for higher level courses such as courses in Mechanics of Solids, Mechanical Design and Structural Analysis. Analyse various machining processes and calculate relevant quantities such as velocities, forces, powers etc.
Inculcate the knowledge of basic geometries, geometric tools, shapes and procedures used for engineering drawings and different concepts of theory of projections, development, sectioning.
Provide exposure about optical and atomic physics phenomenon through experimental observations and focuses on interpretation and analysis of technical data.
To gain fundamental knowledge on basics of computers hardware and number systems. Understand general principles of computer languages such as loops (while/for), conditional branching (if/switch), block structure, functions (including parameter passing, prototypes and recursion), input/output, arithmetic rules Develop problem-solving skills to translate 'English' described problems into programs written using the C language. Understand how to use and manipulate variables and types to change the program state, including numeric, character, array and pointer types, as well as the use of structures. Understand the purpose of pointers for parameter passing, referencing and dereferencing, and linking data structures.
The course develops basic skills in constructing and measuring electrical circuits using modern laboratory instruments.
Provide the knowledge of various ordinary, partial differential equations and in-depth understanding of various analytical and numerical methods needed for solving different differential equations.
The course covers all the areas of grammar necessary for the undergraduate students of engineering sciences.
This course focuses on the introduction to mechanical manufacturing methods by which materials are economically processed into different shapes.
Elaboration of biological concepts with emphasis on effective utilization of biological principles for technology development by engineering students.
This course intends to impart basic know-how of various hand tools and their use in different sections of manufacturing.
Provides the laboratory experience to accompany an introduction to the study of general biology, starting from basic scientific concepts and progressing to the natural laws that govern life and all living things.
This subject is concerned with designing and managing processes to carry out molecular transformations at large scale, in order to provide the products and materials we all need.
Familiarizes the students about the probability; impart the understanding of techniques to do statistics.
This course imparts the knowledge of engineering properties of materials; fundamental concepts of stress and strain, strength and stiffness, deformations and displacements, strain energy, and load carrying capacity. The course also introduces students to the basic engineering approach of materials selection.
This course will provide the student with an introduction to the concepts and technologies from a designer's viewpoint of the principal manufacturing processes utilized by industry.
This course provides information about work, heat, energy & various laws of thermodynamics. It also imparts knowledge about various thermodynamic cycles and processes their applications in day to day life.
Introduction to the behaviour of materials when subjected to different loading conditions and demonstrate the material test procedure on commonly used equipment for material testing.
To understand various types of lathe operations, surface finishing process and ability to understand gear making process.
Planning and execution of appropriate engineering projects. These investigations may be assigned on an individual or a team basis and in most cases will involve experimental work.
The course is framed to enhance timeless fundamentals of crystallography, solid state chemistry/ physics. It gives the basics to understand various materials, let it be fabric, plastic or steel. It helps understand how atoms/ molecules/ unit cells makeup the material and how their arrangement has effect on all the mechanical properties and need for engineering novel materials. More emphasis was put on Fe based materials and understands the importance of various processing methods for steel.
Imparts knowledge to understand the fundamentals of the theory of kinematics and dynamics of machines and motion of machines and their components.
Introduction to computer-aided graphics & design. Applications of graphics software and hardware with mini- and micro-computer systems. Interactive computer graphic techniques. Extensive laboratory study of wire-frame and raster computer graphics. Static and dynamics graphic presentation methods.
This laboratory has a good set-up for demonstrating aspects of both kinematics and dynamics of mechanism and machines. Experiments on cam mechanism, whirling of shafts, gyroscope, balancing vibrations etc. can be performed here.
Introduction to various applications of the basic fluid mechanics and machines principles and to provide a more intuitive and physical understanding of the concept.
This course provides students to demonstrate basic concepts of the AutoCAD software.
Planning and execution of appropriate engineering projects. These investigations may be assigned on an individual or a team basis and in most cases will involve experimental work.
Gain practical exposure through different types of scientific programming problems and mathematical modelling. Students will able to solve wide range of engineering problems.
Imparts knowledge to understand and experimentally analyse the conductivity of different materials. To analyse free and forced convective heat transfer. Further imparts knowledge to experimentally analyse radiation heat transfer.
This course provides students with a basic designing skill into 2-dimensional and 3-dimensional Computer-Aided Design (CAD) and modelling.
Students will develop and practice engineering design skills by working on a team-based project. Students will experience all phases of the design process.
This course provides the fundamentals of classical set theory and fuzzy set theory.
This course teaches the fundamentals of control theory with the addition of basic electronics theory.
Impart knowledge of optimizing the resources of industry by use of various methods of industrial engineering in various aspects of society.
Demonstrate a sound technical knowledge of their selected project topic. Undertake problem identification, design, formulation and solution.
The present course on Advanced Engineering Thermodynamics deals with in-depth theories of thermodynamics. Apart from classical theory, this course presents detail on kinetic theory as well as statistical theories
This course is designed to illustrate the application of basic principles of fluid dynamics and thermodynamics to various kinds of turbo machinery. Turbo machinery is a subject of considerable importance in a modern industrial civilization
This course introduces students to design, manufacture and operate automobiles like buses, trucks, cars etc.
Principal elements of pressurized water reactor nuclear power systems; overview of reactor physics, thermodynamics, and heat transfer; focus on systems with both function and interfaces stressed throughout; includes basic reactor physics, reactor heat generation, reactor plant systems, support systems, and reactor safety.
Introduce the new concepts of combustion and emission control of Internal Combustion Engine. Provide an introductory of combustion simulation and diagnose technology. Provide experiences of group discussion on combustion and emission control in Internal Combustion Engine.
Development of computational techniques for analysis of complex engineering processes by bringing together the knowledge gained in one or more of the following disciplines: fluid mechanics, thermodynamics, heat/mass transfer & numerical methods.
This course is designed to expand knowledge and skills in the field of linear and non-linear mechanics of solids and its application to structural analysis, machine design and material processing. The influence of non-linearity on the behavior of structures will be addressed.
This course aims to combine theoretical approaches with modern techniques of computer graphics, solid modeling and design automation for mechanical engineering applications.
The finite element method and its applications to engineering problems: truss and frame structures, heat conduction, and linear elasticity; use of application software; overview of advanced topics such as structural dynamics, fluid flow, and nonlinear structural analysis.
Tribology is an interdisciplinary course which deals with fundamentals of surface contact, friction, wear and lubrication. The course include description and modeling of engineering surfaces, popular surface contact theories, major modes of friction, wear, lubrication and adhesion.
To Implement the machine learning concepts and algorithms in any suitable language like Prolog or Python.
In this course students will study the representation and simulation of physical systems using a range of mathematical formulations. There are many modeling techniques to describe system characteristics. Students will learn to develop typical mathematical models.
To study the classical theory of linear elasticity for two and three dimensional state of stress and obtain solutions for selected problems in rectangular and polar coordinates as well as torsion of prismatic bars. To understand the plastic stress strain relations, criteria of yielding and elasto- plastic problems
This course will cover basic concepts in Design and Optimization of Energy systems which is described as follows :
Introduction to system design - Regression analysis and curve fitting - modelling of thermal equipment (very brief) - system simulation (successive substitution - Newton - Raphson method) - examples - economic analysis - optimization - Lagrange multipliers, search methods, linear programming, geometric programming- New generation optimization techniques - simulated annealing, Genetic Algorithms, Bayesian statistics.
Duration: 4 yrs.
The Candidate should have passed the 10+2 examination with Physics, Mathematics and English as compulsory subjects along with one of the Chemistry/ Biotechnology/ Biology/ Technical Vocational subjects. Obtained at least 60% marks (40% in case of candidates belonging to the reserved category) in the above subjects taken together
OR
Should have passed with minimum of 60% marks (40% in the case of SC/ ST category) in Diploma in Engineering / Tech., of three years or more duration from any recognized Board of Technical Education/ University or its equivalent Diploma examination.
| Course | Course Fee | |||
| Indian (INR) | International (USD) | |||
|
||||
| B. Tech in Mechanical Engineering |
|
- | ||
|
Note:
|
||||
| % Marks | Scholarship Criteria (% Tuition Fee Waiver) |
|---|---|
| 90% & above | 100% |
| 80 to 89.99% | 40% |
| 70 to 79.99% | 30% |
| 60 to 69.99% | 20% |
The graduates pursuing B.Tech in Mechanical Engineering from MM(DU) are well prepared with the knowledge and technical information, refined with a professional touch, and capable of undertaking mechanical engineering jobs to meet the challenges of the 21st-century industry. The course includes self-learning modules like assignments, seminars, and case studies for understanding the industry challenges and raising the potential of students. The course syllabus is revised from time to time in order to ensure students study about latest trends in technology.
Provides the knowledge of differential and integral calculus and enables understanding of linear algebra, linear programming and set theory.
Elaboration of biological concepts with emphasis on effective utilization of biological principles for technology development by engineering students.
Provide the knowledge of various ordinary, partial differential equations and in-depth understanding of various analytical and numerical methods needed for solving different differential equations.
Provides the knowledge of differential and integral calculus and enables understanding of linear algebra, linear programming and set theory.
Introduction to the fundamental concepts of electricity and electronics that involve direct current, alternating current, series and parallel resistive circuits, inductance, capacitance, transformers, motors, electronic components, and various types of test equipment found in industry.
Students have practice in applying their knowledge of mathematics, science, and engineering and to expand this knowledge into the vast area of “rigid body Mechanics”. Students prepared for higher level courses such as courses in Mechanics of Solids, Mechanical Design and Structural Analysis. Analyse various machining processes and calculate relevant quantities such as velocities, forces, powers etc.
Inculcate the knowledge of basic geometries, geometric tools, shapes and procedures used for engineering drawings and different concepts of theory of projections, development, sectioning.
Provide exposure about optical and atomic physics phenomenon through experimental observations and focuses on interpretation and analysis of technical data.
To gain fundamental knowledge on basics of computers hardware and number systems. Understand general principles of computer languages such as loops (while/for), conditional branching (if/switch), block structure, functions (including parameter passing, prototypes and recursion), input/output, arithmetic rules Develop problem-solving skills to translate 'English' described problems into programs written using the C language. Understand how to use and manipulate variables and types to change the program state, including numeric, character, array and pointer types, as well as the use of structures. Understand the purpose of pointers for parameter passing, referencing and dereferencing, and linking data structures.
The course develops basic skills in constructing and measuring electrical circuits using modern laboratory instruments.
Provide the knowledge of various ordinary, partial differential equations and in-depth understanding of various analytical and numerical methods needed for solving different differential equations.
The course covers all the areas of grammar necessary for the undergraduate students of engineering sciences.
This course focuses on the introduction to mechanical manufacturing methods by which materials are economically processed into different shapes.
Elaboration of biological concepts with emphasis on effective utilization of biological principles for technology development by engineering students.
This course intends to impart basic know-how of various hand tools and their use in different sections of manufacturing.
Provides the laboratory experience to accompany an introduction to the study of general biology, starting from basic scientific concepts and progressing to the natural laws that govern life and all living things.
This subject is concerned with designing and managing processes to carry out molecular transformations at large scale, in order to provide the products and materials we all need.
Familiarizes the students about the probability; impart the understanding of techniques to do statistics.
This course imparts the knowledge of engineering properties of materials; fundamental concepts of stress and strain, strength and stiffness, deformations and displacements, strain energy, and load carrying capacity. The course also introduces students to the basic engineering approach of materials selection.
This course will provide the student with an introduction to the concepts and technologies from a designer's viewpoint of the principal manufacturing processes utilized by industry.
This course provides information about work, heat, energy & various laws of thermodynamics. It also imparts knowledge about various thermodynamic cycles and processes their applications in day to day life.
Introduction to the behaviour of materials when subjected to different loading conditions and demonstrate the material test procedure on commonly used equipment for material testing.
To understand various types of lathe operations, surface finishing process and ability to understand gear making process.
Planning and execution of appropriate engineering projects. These investigations may be assigned on an individual or a team basis and in most cases will involve experimental work.
The course is framed to enhance timeless fundamentals of crystallography, solid state chemistry/ physics. It gives the basics to understand various materials, let it be fabric, plastic or steel. It helps understand how atoms/ molecules/ unit cells makeup the material and how their arrangement has effect on all the mechanical properties and need for engineering novel materials. More emphasis was put on Fe based materials and understands the importance of various processing methods for steel.
Imparts knowledge to understand the fundamentals of the theory of kinematics and dynamics of machines and motion of machines and their components.
Introduction to computer-aided graphics & design. Applications of graphics software and hardware with mini- and micro-computer systems. Interactive computer graphic techniques. Extensive laboratory study of wire-frame and raster computer graphics. Static and dynamics graphic presentation methods.
This laboratory has a good set-up for demonstrating aspects of both kinematics and dynamics of mechanism and machines. Experiments on cam mechanism, whirling of shafts, gyroscope, balancing vibrations etc. can be performed here.
Introduction to various applications of the basic fluid mechanics and machines principles and to provide a more intuitive and physical understanding of the concept.
This course provides students to demonstrate basic concepts of the AutoCAD software.
Planning and execution of appropriate engineering projects. These investigations may be assigned on an individual or a team basis and in most cases will involve experimental work.
Gain practical exposure through different types of scientific programming problems and mathematical modelling. Students will able to solve wide range of engineering problems.
Imparts knowledge to understand and experimentally analyse the conductivity of different materials. To analyse free and forced convective heat transfer. Further imparts knowledge to experimentally analyse radiation heat transfer.
This course provides students with a basic designing skill into 2-dimensional and 3-dimensional Computer-Aided Design (CAD) and modelling.
Students will develop and practice engineering design skills by working on a team-based project. Students will experience all phases of the design process.
This course provides the fundamentals of classical set theory and fuzzy set theory.
This course teaches the fundamentals of control theory with the addition of basic electronics theory.
Impart knowledge of optimizing the resources of industry by use of various methods of industrial engineering in various aspects of society.
Demonstrate a sound technical knowledge of their selected project topic. Undertake problem identification, design, formulation and solution.
The present course on Advanced Engineering Thermodynamics deals with in-depth theories of thermodynamics. Apart from classical theory, this course presents detail on kinetic theory as well as statistical theories
This course is designed to illustrate the application of basic principles of fluid dynamics and thermodynamics to various kinds of turbo machinery. Turbo machinery is a subject of considerable importance in a modern industrial civilization
This course introduces students to design, manufacture and operate automobiles like buses, trucks, cars etc.
Principal elements of pressurized water reactor nuclear power systems; overview of reactor physics, thermodynamics, and heat transfer; focus on systems with both function and interfaces stressed throughout; includes basic reactor physics, reactor heat generation, reactor plant systems, support systems, and reactor safety.
Introduce the new concepts of combustion and emission control of Internal Combustion Engine. Provide an introductory of combustion simulation and diagnose technology. Provide experiences of group discussion on combustion and emission control in Internal Combustion Engine.
Development of computational techniques for analysis of complex engineering processes by bringing together the knowledge gained in one or more of the following disciplines: fluid mechanics, thermodynamics, heat/mass transfer & numerical methods.
This course is designed to expand knowledge and skills in the field of linear and non-linear mechanics of solids and its application to structural analysis, machine design and material processing. The influence of non-linearity on the behavior of structures will be addressed.
This course aims to combine theoretical approaches with modern techniques of computer graphics, solid modeling and design automation for mechanical engineering applications.
The finite element method and its applications to engineering problems: truss and frame structures, heat conduction, and linear elasticity; use of application software; overview of advanced topics such as structural dynamics, fluid flow, and nonlinear structural analysis.
Tribology is an interdisciplinary course which deals with fundamentals of surface contact, friction, wear and lubrication. The course include description and modeling of engineering surfaces, popular surface contact theories, major modes of friction, wear, lubrication and adhesion.
To Implement the machine learning concepts and algorithms in any suitable language like Prolog or Python.
In this course students will study the representation and simulation of physical systems using a range of mathematical formulations. There are many modeling techniques to describe system characteristics. Students will learn to develop typical mathematical models.
To study the classical theory of linear elasticity for two and three dimensional state of stress and obtain solutions for selected problems in rectangular and polar coordinates as well as torsion of prismatic bars. To understand the plastic stress strain relations, criteria of yielding and elasto- plastic problems
This course will cover basic concepts in Design and Optimization of Energy systems which is described as follows :
Introduction to system design - Regression analysis and curve fitting - modelling of thermal equipment (very brief) - system simulation (successive substitution - Newton - Raphson method) - examples - economic analysis - optimization - Lagrange multipliers, search methods, linear programming, geometric programming- New generation optimization techniques - simulated annealing, Genetic Algorithms, Bayesian statistics.
Students who complete B.Tech in Mechanical Engineering has a plethora of opportunities majorly in the areas of manufacturing, automobile, aerospace, chemical plants, railway coach factory; oil field, research and development etc. The automobile is one of the traditional areas where mechanical engineers are needed for managing the production floors, maintenance, and project planning and leadership areas of people and plant management. Mechanical engineers can also focus their attention on their latest areas of research which are nanotechnology, biomedical applications, development of composite materials and environmental conservation, etc. With experience in mechanical engineering, people can grow to the career/hierarchical ladders in the organization and can even reach the top levels based on experience and capability.
Duration: 4 yrs.
The Candidate should have passed the 10+2 examination with Physics, Mathematics and English as compulsory subjects along with one of the Chemistry/ Biotechnology/ Biology/ Technical Vocational subjects. Obtained at least 60% marks (40% in case of candidates belonging to the reserved category) in the above subjects taken together
OR
Should have passed with minimum of 60% marks (40% in the case of SC/ ST category) in Diploma in Engineering / Tech., of three years or more duration from any recognized Board of Technical Education/ University or its equivalent Diploma examination.
| Course | Course Fee | |||
| Indian (INR) | International (USD) | |||
|
||||
| B. Tech in Mechanical Engineering |
|
- | ||
|
Note:
|
||||