To develop into a globally recognized department within the frontier areas of Metallurgical and Materials Engineering. Note: Department(s) offer minor (MI) course and ONLINE course (OC) to the willing students in addition to 24 points. 4 Mechanical behavior and testing of materials 4 PC 5 Metallography and heat treatment laboratory 2 ELR 6 Material testing and inspection laboratory 2 ELR.
Note: Department(s) may offer Minor Course (MI), ONLINE Course (OC) and Honors Course (HO) to those students willing in addition to 23 credits. Note: Department(s) may offer Minor Course (MI), ONLINE Course (OC) and Honors Course. HO) for those students willing in addition to 14 credits. Note: Department(s) may offer Minor Course (MI), ONLINE Course (OC) and Honors Course (HO) to those students willing in addition to 10 credits.
HO - Honors Degree: 15 credits in addition to the minimum credit as specified by the departments. Affiliation with an academic institution in the country (IISc/IITs/NITs/IIITs and CFTIs) or university abroad is also allowed in lieu of an industrial degree.
Sl.No. Course Code
COMPREHENSIVE VIVA Sl.No. Course
Code
PROJECT WORK (OPTIONAL COURSE) Sl.No. Course
The last two digits YY to be allotted by the Department
Programme Core Courses
Course
Code Course Title
Credits
MTPC10 Engineering Mechanics and
MTPC11 Metallurgical Thermodynamics and
MTPC13 Electrical, Electronic and Magnetic
MTPC14 Polymers, Composites and
MTPC15 Phase Transformation and Heat
Programme Elective Courses (PE) Sl.No. Course
Course Title Prerequisites Credits
MTPE07 Economics of Metal Production Processes MTPC18 3
MTPE11 Materials for New and Renewable Energy Nil 3
MTPE18 Design aspects of Welding and Casting MTPC19,
Sl.No. Course
MTOE11 Mathematical Techniques in Materials
MTOE18 Business and Entrepreneurship for Engineers Nil 3 Essential Programme Laboratory Requirements (ELR)
Sl.No. Course
MTLR31 Polymers, Composites and Ceramics
MTLR32 Metallography and Heat Treatment
MTLR35 Metal Forming and Particulate Processing
MTLR36 Non-Ferrous Metallography and
MTLR37 Corrosion and Surface Engineering
Course Title Prerequisites Credits
- MTMI12 Physical Metallurgy and Heat Treatment Nil 3
- MTMI15 Testing and Evaluation of Materials Nil 3
- MTHO10 Advanced Thermodynamics of Materials MTPC11 4
- MTHO13 Ladle Metallurgy and Continuous Casting
- MTHO15 Advanced Solidification Processing MTPC19 4 7. MTHO16 Recent Developments in Welding
- MTHO17 Recent Developments in Forming
PO2 Problem Analysis: Identify, formulate, review research literature and analyze complex engineering problems and arrive at well-founded conclusions using the first principles of mathematics, natural sciences and engineering sciences. PO3 Design/Development of Solutions: Design solutions to complex engineering problems and design system components or processes that meet the specified needs with appropriate consideration of public health and safety, and the cultural, societal and environmental considerations. PO4 Conduct investigations of complex problems: Use research-based knowledge and research methods, including design of experiments, analysis and interpretation of data, and synthesis of the information to provide valid conclusions.
PO5 Modern Tool Use: Create, select and apply appropriate techniques, resources and modern engineering and IT tools, including forecasting and modeling to complex engineering activities with an understanding of the constraints. PO7 Environment and Sustainability Capability: Understand the impact of the professional engineering solutions in societal and environmental contexts, and demonstrate the knowledge of and need for sustainable development. PO8 Ethics: Apply ethical principles and commit to professional ethics and responsibilities and norms of engineering practice.
PO10 Communication: Communicate effectively about complex engineering activities with the engineering community and with society at large, such as being able to understand and write effective reports and design documentation, make effective presentations and give and receive clear instructions. PO11 Project management and finance: Demonstrate knowledge and understanding of engineering and management principles and apply these in own work, as a member and leader of a team, to manage projects and in interdisciplinary environments.
Course Title : English for Communication (Theory & Lab)
Course Title : Matrices and Calculus
Students will learn about the essential needs of water and its importance in everyday life.
Electrochemistry and Corrosion
Phase rule
Water
Spectroscopy
Polymers and Composites
- Estimation of carbonate, non-carbonate and total hardness in the given water sample
- Estimation of dissolved oxygen in the given water sample
- Determination of the percentage of Fe in the given steel sample
- Estimation of Fe3+ by spectrophotometer
- Corrosion rate by polarization technique 6. Conductometric titration
- Potentiometric titration 8. pH-metric titration
- Percentage purity of bleaching powder
- Determination of molecular weight of the polymer by Viscometry 11. Study of three component system
- Demonstration experiments using Advanced Spectroscopic Techniques, (UV-Vis, FTIR, Raman)
CO1 Understand the principles of electrochemistry and corrosion CO2 Explain the phase rule and appreciate the applications of the phase rule. CO3 Students are familiarized with the importance of polymer and its application in industries. CO4 A brief introduction to the field of water, spectroscopy will be very useful for the students in the future.
The chemistry laboratory course will consist of experiments that illustrate the principles of chemistry relevant to the study of science and engineering.
Course Title : Introduction to Metallurgical and Materials Engineering
Course Title : Basic Electrical and Electronics Engineering
Course Title : Engineering Graphics
Course Title : Complex Analysis and Differential Equations
Understand and explain the concepts of matter waves, wave functions and their interpretation to understand matter at the atomic scale. Quantum Mechanics: Inadequacy of classical mechanics - black body radiation, photoelectric effect - wave and particle duality of radiation - de Broglie's concept of matter waves - electron diffraction. 28 | P a g e CO1 know the principle, construction and operation of lasers and their applications in various sciences and.
CO3 experience and evaluate the behavior of matter at the atomic scale and to provide insights into solving problems in modern science and engineering. CO4 understands the role of nuclear and particle physics in applications such as radioactivity and nuclear reactions. To conduct experiments to evaluate the properties of materials and to check their suitability in science and engineering.
CO2 To construct an experimental setup to test certain physical concepts of the wave and particle nature of light. CO3 Understanding of light propagation in fibers, light-matter interactions and the use of lasers in science and technology.
Course Title : Introduction to Computer Programming (Theory & lab )
List of Programs
- Programs using sequential constructs 2. Programs using selection constructs
- Programs using tuples and dictionaries 7. Simple Python functions
- File input and output
- Sorting and searching programs 10. Recursion
CO2 Use the syntax and semantics of the Python programming language to solve problems CO3 Code the given logic in the Python language.
Course Title : Basics of Civil Engineering (Theory & lab )
Course Title : Energy and Environmental Engineering
Course Title : Engineering Practice
Fitting: Preparation of joints, markings, cutting and filling for making; Semi-circle part with the given work piece, Dovetail part with the given work piece
Course Title : Engineering Mechanics and Strength of Materials
Course Title : Industrial Economics and Foreign Trades
Course Title : Metallurgical Thermodynamics and kinetics
CO5 Thermodynamics of gases in metals: Sievert's law and its significance, thermodynamics of slag-metal interactions - numerical examples. Develop an understanding of the basic principles of physical metallurgy and apply those principles to engineering applications. Crystallography - coordination number, effective number of atoms, packing factor, crystal system important for metals, indexing of crystal planes and directions in cubic and hexagonal system, linear and planar density, interplanar spacing.
Crystalline imperfections and their types; point defects, dislocations - unit dislocation, partial dislocation, movement of dislocations, slip and twin orientation, concept of texture, grains and grain boundaries, methods of grain size determination. Self-diffusion, diffusion in an alloy, diffusion mechanisms, activation energy, laws of diffusion - Fick's first law, second law, interdiffusion and the Kirkendall effect, types of diffusion and examples of diffusion; diffusion-based problems. Solid solutions and their types and intermediate phases - Hume Rothery's rule - solidification of metals and alloys, cooling curves, concepts of phase diagrams, nucleation and segregation in application to various binary systems, ternary systems.
At the end of the course, students will be able to understand PO Correlation Low Medium High CO1 The geometry and crystallography of crystalline. 5 2,4,12 1 CO2 Recognize the nature of the crystal defects; estimate the grain size 5 2.4 1 CO3 Apply the concept of diffusion when designing heat treatment 5 2.4 1 CO4 Understand the concept of phase diagram when recognizing the phase.
Course Title : Electrical, Electronic and Magnetic Materials
To learn various methods of manufacturing semiconductors and their processing methods used in the semiconductor materials industry. CO5 To learn about photoconduction phenomena, optical materials and various optical devices and their performance.
Course Title : Polymers, Composites and Ceramics
Course Title : Process Metallurgy Laboratory
Course Title : Polymers, Composites and Ceramics Laboratory
Course Title : Partial Differential Equations and Numerical Methods
Course Title : Phase Transformation and Heat Treatment
To understand basic concepts related to heat flow, fluid flow, mass transfer, in the context of metallurgical processes; to become familiar with the mathematical treatment and equations related to the above transport phenomena; to understand the science behind process modeling. Fluid flow - Viscosity – differential mass and momentum balances – overall momentum balance – mechanical energy balance – applications. Mass transfer - Diffusion: Diffusivity in gases, liquids, solids – convective mass transfer – concept of mass transfer coefficient.
Dimensionless analysis - Rayleigh's method, Buckingham's method - use of differential equations - similarity criteria - applications in physical modeling. Mohanty, “Rate Processes in Metallurgy”, PH India Ltd., 2000 2 B.R.Bird, Stewart, Lightfoot, ‘Transport Phenomena’, John Wiley, New. By the end of the course, students will be able to YES Low Correlation Medium High CO1 Solve the mass and energy balance calculations involved in fluid flow CO2 Use the heat conduction equations in solving 1D and 2D heat.
Course Title : Mechanical Behaviour and Testing of Materials
Course Title : Metallography and Heat Treatment Laboratory
Course Title : Materials Testing and Inspection Laboratory
Course Title : Iron Making and Steel Making
Course Title : Metal Casting Technology
Course Title : Materials Joining Technology
Course Title : Metal Forming Technology
Course Title : Foundry and Welding Laboratory
Course Title : Metal Forming and Particulate Processing Laboratory
Surface Strain prediction and Estimation of Forming Limit Curve
Course Title : Professional Ethics (Non-Circuit)
Course Title : Non-Ferrous Metallurgy
Course Title : Material Characterization
Course Title : Corrosion Engineering
Course Title : Non-Ferrous Metallography and Characterization Laboratory
MTPC22, MTPC23
To provide practical knowledge and hands-on experience in experiments related to plating, various forms of corrosion and remedies through different coating methods, covering a broad spectrum of corrosion and surface engineering. Electroplating copper, electroless plating, anodizing aluminum and determining the corrosion rate by weight loss method (with and without inhibitor). Corrosion rate by electrical resistance method, corrosion rate by potentiostatic polarization experiment (a) Table method and (b) LPR method.
At the end of the course, students will be able to PO Correlation Low Medium High CO1 Acquire practical experience in performing electroless plating of.
Course Title : Mineral Processing and Metallurgical analysis
Course Title : Instrumentation and Control Engineering
Course Title : Fatigue, Creep and Fracture Mechanics
Course Title : Special Steels and Cast Irons
Course Title : Special Casting Techniques
Course Title : Special Topics in Metal Forming
Course Title : Economics of Metal Production Processes
Course Title : Particulate Technology
CO6 Apply the concepts of particle processing to produce non-conventional materials that are difficult to produce with other techniques.
Course Title : Additive Manufacturing
Course Title : Computational Materials Science
Course Title : Materials for New and Renewable Energy
77 | P a g e CO1 Getting to know the energy needs and their sources for harvesting CO2 The solar energy and its efficiency in relation to. CO3 To study the technology of batteries and their future demand CO4 To learn the technology related to hydrogen storage through materials.
Course Title : Non-Ferrous Extraction
Course Title : Metallurgical Waste Management
Course Title : Non-destructive Testing
Course Title : Welding Metallurgy
Course Title : Materials for extreme environments
Course Title : Thermodynamics of Solidification
Course Title : Design aspects of Welding and Casting
Course Title : Alloy Development
Course Title : Ceramic Materials
Course Title : Ceramic Processing
Course Title : High Temperature Materials
Course Title : Emerging Materials
Course Title : Automotive Materials
Course Title : Metallurgical Failure Analysis
The aim of this course is to give students a fundamental understanding of different materials for biomedical applications and their in-vitro and in-vivo properties. Processing and properties of different biomaterials; Nanomaterials and nanocomposites for medical applications; Nanostructured coatings for bio-implants. Mechanical property evaluation and physicochemical characterization of biomaterials; In-vitro and In-vivo evaluation of biomaterials.
At the end of the course students will be able to understand PO Correlation Low Medium High CO1 The properties of different biomaterials, the. CO2 Understand the processing and testing of biomaterials 5 3 1 CO3 Characterize the biomaterials for their physico-chemical properties.
Course Title : Stainless steels and Advanced Ferrous Alloys
CO2 Understand the influence of various alloying elements on stainless steel microstructure, precipitation, mechanical properties and deformation mechanisms. CO4 Analyze and interpret the different types of corrosion in stainless steel and their prevention. CO5 Understand the physical metallurgy of various advanced iron alloys such as maraging steel, high N steel, high Si steel, etc.
Course Title : Nanomaterials and Applications
Course Title : Mathematical Techniques in Materials Research
Course Title : Design and Selection of Materials
Course Title : New Product Development
At the end of the course, students will be able to PO Correlation Low Medium High.
Course Title : Introduction to Quality Management
Course Title : Surface Engineering
Course Title : Process Modelling and Applications
Course Title : Intellectual Property Rights
Course Title : Business and Entrepreneurship for Engineers
CO2 Learn how to develop a business plan that determines the commercial viability of a product or service in a selected market and geographic location. CO3 Basically go "out of the building" to interact with potential customers, generate data, discover customers, and gradually iterate on the features of the product or service through a process of hypothesis testing.
Course Title : Materials Technology
Course Title : Fundamentals of Metallurgy
Course Title : Physical Metallurgy and Heat Treatment
Course Title : Deformation Processing
Course Title : Manufacturing Methods
Course Title : Testing and Evaluation of Materials
Course Title : Non-Metallic Materials
Course Title : Advanced Thermodynamics of Materials
Course Title : Aerospace Materials
Course Title : Ladle Metallurgy and Continuous Casting of steels
Course Title : Recent Trends in Nano materials
Course Title : Advanced Solidification Processing
Course Title : Recent Developments in Welding Processes
Course Title : Recent Developments in Forming Processes
