Course Objectives: The objective of the course is to identify manufacturing constraints that affect the design of parts and part systems. Joining of metals: Evaluation of various welding processes, Factors in the design of welds - General design guidelines - Treatment before and after welds - Effects of thermal stresses on welded joints - Design of brazed joints. Plastics: Viscoelastic and creep behavior in plastics – Design guidelines for plastic components – Design considerations for Injection Molding.

Advantages of assembly: Development of assembly process, selection of assembly method Advantages of assembly social effects of automation. Manual assembly design: assembly plan fits into the design process, general manual assembly design guidelines, development of a systematic DFA methodology, assembly efficiency, manual handling classification system, manual insertion classification system and. of factors, effect of symmetry, effect of chamfered edge design on insertion operations, estimation of insertion time. Course results: At the end of the course, the student is able to use appropriate optimization techniques and solve problems.

Thermo-Fluid Engineering and Microsystem Design: Overview of basics of fluid mechanics in macro and mesoscales, basic equations in continuum fluid dynamics, laminar fluid flow in circular ducts, computational fluid dynamics, incompressible fluid flow in micropipes, fluid flow in submicrometer and nanoscale, Overview of heat conduction in solids, heat conduction in multilayer thin films and in solids in sub-micrometer scale, Design considerations, Process design Mechanical Design, Mechanical Design using FEM, Design of a silicon die for a micropressure sensor. At the end of the course, the student will be able to understand the working principle of electron beam, laser beam and laser beam processes. Design of FMS: Performance evaluation of FMS, Analytical model and Simulation model of FMS Case studies: Typical FMS problems from research papers.

Quality Value and Engineering: An overall quality system, quality engineering in production design, quality engineering in the design of production processes. Introduction to parameter design, signal to noise ratios, Parameter design strategy, some of the case studies on parameter and tolerance designs. To give the basic precision engineering methodology and modern concepts for the design of high-precision CNC machines and products.

Concepts of Accuracy: Introduction – Concept of Machine Tool Accuracy – Spindle and Displacement Accuracies – Accuracy of Numerical Control Systems – Errors Due to Numerical Interpolation Displacement Measuring Systems and Velocity Delays. Datum systems: freedom design, grouped datum systems - different types, two and three mutually perpendicular grouped datum planes; Precision Engineering in Manufacturing by Murthy R. Geometric Dimensioning and Tolerancing by James D. Engineering Design – A Systematic Approach by Matousek, Blackie &.

Basic Principles of Positioning and Clamping: Locating Methods and Devices, Jigs-Definition Types, General Considerations in Designing Drilling Jigs, Drill Bushing, Methods of Construction. Product development management: Establishing the architecture – creation – clustering – geometric layout development – ​​fundamental and incidental interactions – related system-level design issues – secondary systems – piece architecture – creation of detailed interface specifications. Industrial design: Integrate process design – Managing costs – Robust design – Integration of CAE, CAD, CAM tools – simulation of product performance and manufacturing process electronically – Need for industrial design – impact – design process.

Researching customer needs - conceptualization - refinement - industrial design process management - technology-oriented products - user-oriented products - industrial design quality assessment.

MANUFACTURING SIMULATION

PROMODEL 3. SLAM-II

PRECISION ENGINEERING

To demonstrate the capabilities of each method on a variety of problems Course Outcomes: Upon completion of this course, the student should be able to. Use professional-level finite element software to solve engineering problems in solid mechanics, fluid mechanics, and heat transfer. One dimensional problems: Formulation of stiffness matrix for a column element by principle of minimum potential energy, Properties of stiffness matrix, Properties of shape functions, quadratic shape functions.

Analysis of trusses: Derivation of stiffness matrix for trusses, stress and load calculations, Calculation of reaction forces and displacements. Analysis of beams: Derivation of stiffness matrix for two nodes, two degrees of freedom per node beam element, load vector, deflection, stresses, shear force and bending moment, problems on uniform and stepped beams for different types of loads applied to beams. Finite element – ​​formulation of 2D problems: Derivation of element stiffness matrix for two dimensional CST element, Derivation of shape functions for CST element, Equations of elasticity, constitutive matrix formulation, Formulation of gradient matrix.

Simultaneous Heat Transfer Analysis: One-Dimensional Finite Element Analysis of Fin and Composite Plates. Two-dimensional steady state heat transfer problems: Derivation of thermal stiffness matrix for 2D heat transfer problems-CST, Derivation of thermal force vector for 2D heat transfer problems. Equipment Selection Problem, Modeling the Manufacturing Equipment Selection Problem, Problem Solving Approach in KBSES, Structure of the KRSES.

Understand the skills required when writing a title Make sure the paper is of good quality on the first submission. Course Objectives: Students can do this. learn to demonstrate a critical understanding of key concepts in disaster risk reduction and humanitarian response. critically evaluate disaster risk reduction and humanitarian response policy and practice from multiple perspectives. develop an understanding of humanitarian response standards and practical relevance in specific types of disasters and conflict situations. gain a critical understanding of the strengths and weaknesses of disaster management approaches. planning and programming in different countries, especially in their home countries or the countries in which they work. Nishith, Singh AK, “Disaster Management in India: Perspectives, issues and strategy” ‘New Royal book Company.

Engineering scholars equipped with Sanskrit will be able to explore the vast knowledge of ancient literature. To discuss the role of socialism in India after the onset of the Bolshevik Revolution in 1917 and its influence on the initial drafting of the Indian Constitution. Discuss the growth of the demand for civil rights in India for the majority of Indians before Gandhi's arrival in Indian politics.

Discuss the intellectual origins of the argumentative framework that informed the conceptualization of social reforms that led to revolution in India.