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Thermodynamics For Engineers: Part 1
![]() Thermodynamics For Engineers: Part 1 Published 6/2025 MP4 | Video: h264, 1920x1080 | Audio: AAC, 44.1 KHz Language: English | Size: 3.96 GB | Duration: 11h 11m Fundamental Principles, and Laws What you'll learn Identify the work interaction by using the operational definition of work transfer Logically Interpret Joule's experiment for obtaining the definitions of energy change and heat transfer To systematically apply the first law of Thermodynamics to various closed and open system and draw meaningful inferences To check the possibility of a cycle and a process using the concept of the second law of Thermodynamics Estimate the exergy of simple thermodynamic systems Requirements Prior knowlwdge: Fundamental concepts of physics like Volume, Pressure, Velocity, Work ,Energy ,Concepts of mathematics like derivative, integration , nature of curves , slope of curve, Construction and working of common mechanical devices / machines Description Thermodynamics is a foundational subject in engineering that governs energy interactions in everything from engines and refrigerators to power plants and even the human body. A clear understanding of thermodynamics is essential for designing and analyzing efficient systems in virtually every branch of engineering.This course is designed to help engineering students and professionals master the fundamental concepts of thermodynamics with clarity and confidence. It focuses on building a strong conceptual base and developing the ability to systematically apply thermodynamic principles and laws to real-world engineering problems.Taught using the classical thermodynamics approach, the course emphasizes logical reasoning, clear explanations, and structured problem-solving techniques. Special attention is given to the concept of "entropy"-often considered abstract or challenging-which is introduced in an innovative and intuitive way to ensure deep understanding.The course is organized into short, focused video lectures, typically around 10 to 15 minutes each, to maintain interest and aid in retention. Almost every video session is followed by a Quiz that contains carefully framed conceptual questions to reinforce learning and build strong fundamental concepts.The course is ideal for undergraduate students in any engineering discipline. This course bridges the gap between theory and application, equipping learners with the tools necessary for academic success and professional growth in energy-related fields. Overview Section 1: Introduction Lecture 1 Introduction Section 2: Fundamental Concepts Lecture 2 How to define system Lecture 3 Classification of Thermodynamic systems Lecture 4 How to describe a thermodynamic system ? Lecture 5 Classification of Thermodynamic Properties Lecture 6 Viewpoints Lecture 7 The concept of Thermodynamic Equilibrium Lecture 8 Thermodynamic Process & cycle Lecture 9 The two important Characteristics of Property Section 3: The Work Interaction Lecture 10 Work and heat transfer Lecture 11 Work of Expansion Lecture 12 Other types of work transfer Lecture 13 Operational definition of Work trasfer Lecture 14 Complexity of a stsem Lecture 15 State postulate and simple compressible system Section 4: First Law of Thermodynamics: Closed System Formulation Lecture 16 Joules Experiment: Introduction Lecture 17 Joules Expt. Part-I : with insulation Lecture 18 Joules Expt: Part-II : without insulation Lecture 19 A special case: Adiabatic process Lecture 20 Generalization of the First Law Lecture 21 Special case: Thermodynamic Cycle Lecture 22 Summary Section 5: The First Law of Thermodynamics: Open System Formulation Lecture 23 Examples of Open systems with steady flow: Part-1 Lecture 24 Examples of Open systems with steady flow: Part-2 Lecture 25 Examples of Open systems with steady flow: Part-3 Lecture 26 Flow energy Lecture 27 Steady Flow Energy Equation (SFEE) Derivation Lecture 28 Units and Negligible quantities Lecture 29 Summary Section 6: Applications of the first law Lecture 30 Reduced form of SFEE for Work Transfer Devices Lecture 31 Reduced form of SFEE for Heat Transfer Devices Lecture 32 Reduced form of SFEE for "other" Devices Lecture 33 Procedure to Apply the First Law Lecture 34 Cricket Ball Lecture 35 Electric Heater - part 1 Lecture 36 Electric Heater - part 2 Lecture 37 Table Fan Lecture 38 Numerical_Shower Section 7: The Second Law Lecture 39 Limitations of the first law: Part1 Lecture 40 Limitations of First Law: Part 2 Lecture 41 The Heat Engine Lecture 42 Refrigerator Lecture 43 Heat Pump and comparison Lecture 44 Statements of Second Law of Thermodynamics Lecture 45 Equivalence of Kelvin Plank and Clausius statements-part 1 Lecture 46 Equivalence of Kelvin Plank and Clausius statements- part 2 Lecture 47 The concept of reversibility Lecture 48 Carnot Theorem Lecture 49 Proof of Carnot Theorem 1 Lecture 50 Proof of Carnot Theorem 2 Lecture 51 The Carnot Cycle Lecture 52 How to calculate efficiency of a reversible cycle Section 8: Entropy Lecture 53 Criteria to check the possibility of a Cycle: The Clausius Inequality Lecture 54 Identifying new property change Lecture 55 How to calculate entropy change of an actual process Lecture 56 Entropy relation Lecture 57 Modified form of Entropy relation Lecture 58 How to calculate "Sg" and check possibility of process Lecture 59 How second law overcomes the limitations of the First Law Section 9: Availability (Exergy) Lecture 60 Introduction Lecture 61 Availability K.E. and P.E. Lecture 62 Availability of source at constant temperature (Infinite source) Lecture 63 Loss of Exergy Lecture 64 Availability of finite source -Part 1 Lecture 65 Availability of finite source -Part 2 Lecture 66 Illustrative example Students pursuing Engineering Graduation or Diploma or anyone who wants to build strong foundation of Engineering Thermodynamics Цитата:
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