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Manufacturing Process
"Manufacturing Processes" explores the fundamental methods and technologies used in the transformation of raw materials into finished products. The subject provides in-depth knowledge of various manufacturing techniques such as casting, forming, machining, joining, and advanced manufacturing (like additive manufacturing). It emphasizes material behavior, process selection, tool design, and quality control, equipping students with the theoretical and practical understanding required to optimize production systems in mechanical and industrial engineering domains
Mathematics III (PDE, Probability & Statistics)
This course equips engineering students with essential mathematical tools for modeling and analyzing complex physical systems. It is divided into three core modules: Partial Differential Equations (PDEs): Students learn to formulate and solve first and second-order PDEs, classify them, and apply methods such as D’Alembert’s solution, Duhamel’s principle, and separation of variables. Applications include heat conduction, wave propagation, and vibrational problems in mechanical and thermal systems. Probability Theory: This section introduces foundational concepts like random variables, probability distributions, expectation, and moments. It also covers key discrete and continuous distributions relevant to real-world data modeling. Statistics: Focused on data interpretation, students explore sampling, estimation, hypothesis testing, correlation, and regression analysis—crucial for engineering applications involving uncertainty and decision-making under variability. Together, these modules provide the analytical backbone needed for advanced subjects in fluid dynamics, thermodynamics, signal processing, and beyond.
Fluid Mechanics & Hydraulic Machines
Fluid Mechanics & Hydraulic Machines is a foundational course in mechanical engineering that focuses on the behavior of fluids (liquids and gases) at rest and in motion, and the practical applications of fluid dynamics in engineering systems. The subject introduces the fundamental principles governing fluid flow, including concepts such as pressure, viscosity, flow rate, conservation of mass and momentum, and energy equations. The course covers analytical methods to study incompressible and compressible flows, laminar and turbulent regimes, and flow through pipes and channels. Emphasis is placed on understanding and applying Bernoulli’s equation, the continuity and momentum equations, and dimensional analysis. In the hydraulic machines portion, students explore the working principles, design, and performance analysis of devices such as pumps, turbines, and hydraulic systems. Topics include impact of jets, Pelton, Francis and Kaplan turbines, centrifugal and reciprocating pumps, and model testing using similarity laws. By the end of this course, students gain the theoretical background and practical insight necessary to analyze fluid systems and hydraulic machinery, which are critical in industries ranging from power generation and water supply to aerospace and process engineering.
Applied Thermodynamics
Applied Thermodynamics builds upon the foundational principles of classical thermodynamics to analyze real-world engineering systems involving energy conversion and fluid flow. The course focuses on the thermodynamic analysis of power-producing and power-consuming devices such as internal combustion engines, gas turbines, steam power plants, compressors, and nozzles. Emphasis is placed on combustion processes, the behavior of pure substances and ideal gases, property relations, and the application of the first and second laws to open and closed systems. Key topics include fuel types and combustion stoichiometry, energy balances in reacting systems, entropy and availability analysis, psychrometrics, and thermodynamic cycles such as Otto, Diesel, Rankine, and Brayton. The course also introduces the principles of chemical equilibrium and the use of real gas models where appropriate. Through theoretical derivations, practical examples, and numerical problem-solving, students gain the ability to evaluate and optimize thermal systems for efficiency and performance.
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