Production and Industrial Engineering

About Course

Production and Industrial engineering (PIE) is an interdisciplinary engineering discipline that includes manufacturing technology, engineering sciences, management science, and optimization of complex processes, systems, or organizations.

Course Curriculum

GATE – 21 ADDED SYLLAB

Chapter 1: Aptitude

E-Book – GATE – 21 ADDED SYLLABUS

Practice Set – GATE – 21 ADDED SYLLABUS

Theory of Machines

Chapter-1 Simple Mechanisms

1.0 Theory of Machines Introduction

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1.1 Kinematic Link or an Element and Kinematic Pairs

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1.2 Classification of Kinematic Pairs

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1.3 Kinematic Chains

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1.4 Degree of Freedom

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1.5 Kutzbach Equation and Gruibler’s Criterion

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1.6 Simple Mechanisms, its inversions and Grashof’s law

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1.7 Inversion of Single Slider Crank Mechanism

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1.8 Inversion of Double Slider Crank Mechanism

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1.9 Mechanical Advantage and Miscellaneous

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1.10 Chapter-1 GATE Questions

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Chapter-2 Velocity and Acceleration Analysis

Chapter-3 Gears and Gear Trains

Chapter-4 Analysis of Single Slider Crank Mechanism

Chapter-5 Flywheel

Chapter-6 Governors

Chapter-7 Balancing

Chapter-8 Mechanical Vibrations

Chapter-9 Cams and Followers

Chapter-10 Gyroscope

E-Book – Theory of Machines

Practice Set – Theory of Machines

THERMAL ENGINEERING

Chapter 1: Basics of Thermodynamics

Chapter 2: Second Law of Thermodynamics

Chapter 3: Available Energy/Exergy/Availability

Chapter 4: Thermodynamic Relation

Chapter 5: Introduction of Heat Transfer

Chapter 6: Conduction

6.1 Conduction (Through a Slab, Electrical Analogy of Heat Transfer, Conductive Thermal Resistance, Through Composite Slab)

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6.2 Conduction (Convection Thermal Resistance, Conduction-Convection Heat Transfer Through a Composite Slab, Overall Heat Transfer Coefficient, and Examples)

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6.3 Conduction (Radial Conduction Heat Transfer Through a Hollow Cylinder & Composite Cylinder and an Example)

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6.4 Conduction (Conduction-Convection Heat Transfer Through a Composite Cylinder and an Example)

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6.5 Conduction (Generalized Conduction Equation and Thermal Diffusivity)

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6.6 Conduction (Critical Radius of Insulation & Its Physical Significance, and Examples)

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6.7 Conduction (Heat Generation in a Slab and an Example)

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6.8 Conduction (Radial Conduction Heat Transfer Through a Hollow Sphere, Critical Radius of Insulation for Spherical Condition, and Variable Thermal Conductivity)

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6.9 Conduction (Heat Generation in Cylinder or Wire and an Example Based on Internal Heat Generation)

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Chapter 7: Radiation

Chapter 8: Convection

E-Book – THERMAL ENGINEERING

Practice Set – THERMAL ENGINEERING

Industrial Engineering (O Res & Pr Ma)

Chapter 1: Basic of Industrial Engineering

Chapter 2: Inventory Control

Chapter 3: Fore Casting

Chapter 4: Queuing Theory

Chapter 5: Sequencing

Chapter 6: Project Management

Chapter 7: Linear Programming

E-Book – Industrial Engineering (Operations Research & Project Management)

Practice Set – Industrial Engineering (Operations Research & Project Management)

Manufacturing Processes I and II

Chapter-1 Metal Casting

1.1 Basics of Metal Casting

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1.2 Allowances in Casting

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1.3 Types of Pattern and its materials

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1.4 Mould Making & Properties of Sand

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1.5 Core Making

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1.6 Paddings & Chills

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1.7 Pouring & Solidifications

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1.8 Gating System

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1.9 Aspiration Effect

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1.10 Solidifications Type, Time and Felting & Inspections

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1.11 Riser & Riser Design

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1.12 Riser for plate & Disc shaped casting

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1.13 Special Casting

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1.14 Defects in Casting

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1.15 Metal Casting GATE Questions

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Chapter-2 Metal Forming

2.1 Introduction of Metal Forming

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2.2 Strain Hardening

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2.3 Yield Point Phenomenon & Hot Working

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2.4 Flow stress & Flow curve Equations

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2.5 Plastic Deformation & Yield Criteria

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2.6 Rolling Process

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2.7 Wire drawing

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2.8 Tube Drawing & Extrusion Process

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2.9 Forging Operations

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2.10 Defects in Metal Forming

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2.11 Metal Forming GATE Questions

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Chapter-3 Sheet Metal Operations

Chapter-4 Metal Cutting

4.1 Introduction to Metal cutting

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4.2 Influence of tool geometry on various parameters

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4.3 Mechanics of Machining

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4.4 Shear Angle, Velocities, Shear Strain & Rate of Shear Strain

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4.5 Orthogonal and oblique Cutting

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4.6 Force in the Metal Cutting Operation

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4.7 Shear Stress, Work Done & Specific Cutting Energy

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4.8 Heat Generations in Cutting

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4.9 Tool Failure Criteria & Tool Life

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4.10 Economics of Machining

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4.11 Conversion of Oblique Cutting to Orthogonal Cutting

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4.12 Tool Materials

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4.13 Grinding Operations

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4.14 Metal Cutting GATE Questions

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Chapter-5 Non Traditional Machining

Chapter-6 Computer Integrated Manufacturing System

Chapter-7 Welding

Chapter-8 Metrology and Inspection

8.1 Introduction of Metrology and Linear Measurements

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8.2 Limits, Fits and Tolerances Part-1

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8.3 Limits, Fits and Tolerances Part-2

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8.4 Comparators

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8.5 Form and Finish Measurement

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8.6 Limit Gauges Part-1

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8.7 Limit Gauges Part-2

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8.8 Angular MeasurementsDraft Lesson

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8.9 Machine Tool Metrology (Alignment & Testing Methods)

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8.10 Metrology and Inspection GATE Questions

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E-Book – Manufacturing Processes I and II

Practice Set – Manufacturing Processes I and II

Engineering Mathematics

Chapter-1: Limit

1.1 Introduction to Limit

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1.2 Indeterminate forms

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1.3 Methods to Solve Limit

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1.4 Factoring Method

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1.5 Rationalisation method

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1.6 Expansion method

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1.7 L-Hospital Rule

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1.8 Failure of L-Hospital Rule

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1.9 Approximation method

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1.10 Limit involving modulus function

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1.11 Limit involving Riemann integration

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1.12 Limit involving greatest integer function

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1.13 Various exams questions and practice questions

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Chapter 2: Continuity

Chapter 3: Differentiabilty

Chapter 4: Properties of function

Chapter 5: Maxima & Minima

Chapter 6: Min value theorem

Chapter 7: Integration

Chapter 8: Linear algebra

8.1 Linear Transformation

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8.2 Introduction to matrices

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8.3 Rank & Nullity

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8.4 System of Linear equations

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8.5 Eigenvalues & Eigenvectors

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8.6 Number of linearly independent Eigenvectors

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8.7 Diagonalization of matrix

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8.8 Some important properties of special matrices

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8.9 GATE questions

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Chapter 9: Probability distribution

9.1 Discrete probability distribution

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9.2 Binomial distribution

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9.3 Poisson distribution

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9.4 Continuous probability distribution

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9.5 Uniform distribution

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9.6 Exponential distribution

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9.7 Normal distribution

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9.8 Mean, Median, and Mode of probability distribution

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9.9 Expectation, second moment, variance, and standard deviation

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9.10 Cumulative distribution

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9.11 Joint probability distribution

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9.12 GATE questions

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Chapter 10: Statistics

Chapter 11: Differential equation

11.1 Introduction to Differential equations

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11.2 Order and degree of Differential equations

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11.3 Ordinary and partial differential equations

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11.4 Linear and nonlinear differential equations

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11.5 Homogeneous and nonhomogeneous differential equations

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11.6 Methods to solve first-order first-degree differential equations

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11.7 Variable separable method

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11.8 Leibnitz differential equations

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11.9 Bernoulli’s differential equations

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11.10 Differential equations with homogeneous functions

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11.11 Differential equation dy/dx=f(ax+by+c)

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11.12 Higher order differential equations with constant coefficients

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11.13 Higher order differential equations with variable coefficients

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11.14 Partial differential equations

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11.15 GATE questions

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Chapter 12: Numerical methods

Chapter 13: Complex analysis

13.1 Introduction to complex numbers

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13.2 Limit, continuity, and differentiability

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13.3 Analytic functions

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13.4 Entire function

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13.5 Complex differentiation

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13.6 Zeros & Singularity: Poles, essential singularity, Harmonic singularity

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13.7 Residues at poles and essential singularity

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13.8 Complex integration – Open path closed path

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13.9 GATE questions

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Chapter 14: Vector analysis

Chapter 15: Laplace transform

E-Book – Engineering Mathematics

Practice Set – Engineering Mathematics

Verbal Ability

Chapter-1: Noun

Chapter-2: Pronoun

Chapter-3: Subject And Verb Agreement

Chapter-4: Tenses

Chapter-5: Modifiers

Chapter-6: Vocabulary Building

Chapter-7: Verbal Logic

Chapter-8: Reading Comprehension (RC)

Chapter-9: Articles & Prepositions

E-Book – Verbal Ability

Practice Set – Verbal Ability

Logical Reasoning

Chapter 1: Series

Chapter 2: Coding and Decoding

Chapter 3: Analytical Reasoning (AR) or Data Arrangement

Chapter 4: Blood Relations

Chapter 5: Calendars

Chapter 6: Data Interpretation

Chapter 7: Directions

Chapter 8: Syllogism

E-Book – Logical Reasoning

Practice Set – Logical Reasoning

Quantitative Aptitude

Chapter 1: Numbers System

1.1 Types of Numbers

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1.2 Divisibility Rules

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1.3 Cyclicity or Fundamental to Find Last Digit

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1.4 Concept of HCF/LCM and its Application

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1.5 Remainders

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1.6 Highest Power and Trailing Zeros

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1.7 Factors

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1.8 Number System Exam Questions

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1.9 Cyclicity – Last Digit (Unit Place)

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1.10 Cyclicity – Last 2 Digits

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1.11 Remainder Theorem

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1.12 Base System

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1.13 Right Most Non-zero Digit

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Chapter 2: Percentages and Application

Chapter 3: Ratio, Proportion, and Mixtures

Chapter 4: Time Speed and Distance

Chapter 5: Time and Work

Chapter 6: Geometry

Chapter 7: Permutation and Combination

Chapter 8: Probability and Set Theory

Chapter 9: Algebra

Chapter 10: Set Theory

Chapter 11: Previous Year Aptitude GATE Questions

11.1 Aptitude GATE Questions 2018 ME

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11.2 Aptitude GATE Questions 2018 EC

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11.3 Aptitude GATE Questions 2018 CE

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11.4 Aptitude GATE Questions 2018 CS

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11.5 Aptitude GATE Questions 2017 CH

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11.6 Aptitude GATE Questions 2016 EE

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11.7 Aptitude GATE Questions 2016 EC

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11.8 Aptitude GATE Questions 2019 All Branches

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11.9 Aptitude GATE Questions 2015 CS

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11.10 Aptitude GATE Questions 2015 ME

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11.11 Aptitude GATE Questions 2015 EC+IN

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E-Book – Quantitative Aptitude

Practice Set – Quantitative Aptitude

Applied Mechanics PART-1

Chapter 1: Force Systems

Chapter 2: Structure Analysis

E-Book – Applied Mechanics PART-1 (Engg. Mechanics)

Practice Set – Applied Mechanics PART-1 (Engg. Mechanics)

Fluid Mechanics

Chapter 1: Introduction & Fluid Properties

1.1 Introduction

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1.1.1_States of Matter / Distinction between Solid & Fluid

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1.1.2_Internal Forces

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1.1.3_Concept of Continuum

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1.2 FLUID PROPERTIES – I

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1.2.1_Density at a point

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1.2.2_Specific Weight & Specific Gravity

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1.2.3_Bulk Modulus of Elasticity

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1.2.4_Pressure

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1.3 FLUID PROPERTIES – II

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1.3.1_Absolute Viscosity & Kinematic Viscosity with their physical interpretation

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1.4 FLUID PROPERTIES – III

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1.4.1 to 1.4.6_Standard Problems

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1.5 FLUID PROPERTIES – IV

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1.5.1_Surface Tension

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1.5.2_Phenomenon observed in nature due to surface tension

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1.5.3_Standard Problems

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1.6 GATE PROBLEMS

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Chapter 2: Fluid Statics

2.1 FUNDAMENTAL EQUATION OF FLUID STATICS

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2.1.1_Derivation of Fundamental Equation of Fluid Statics

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2.1.2_Physics behind Fundamental Equation of Fluid Statics

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2.1.3_Results from Fundamental Equation of Fluid Statics

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2.2 PRESSURE & ITS MEASUREMENT

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2.2.1_Scale of Pressure

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2.2.2_Measurement of Atmospheric Pressure – Barometer

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2.2.3_Measurement of System Pressure – Piezometer

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2.2.4_U Tube Manometer – Positive Gauge Pressure

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2.2.5_U Tube Manometer – Negative Gauge Pressure

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2.3 SOME STANDARD PROBLEMS ON MANOMETERS

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2.3.1_Multiple Fluid Manometers

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2.3.2_Inverted Manometers

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2.3.3_Inclined Manometers

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2.3.4_ESE – 2008

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2.3.5_Rotating Manometer

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2.4 FORCES ON SUBMERGED BODIES – I

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2.4.1_Forces on Plane Surfaces Immersed in Fluid at rest

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2.4.2_Standard Problem

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2.5 FORCES ON SUBMERGED BODIES – II

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2.5.1_Forces on Curved Surfaces Immersed in Fluid at rest

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2.5.2_Example Problem

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2.5.3_Concept of Imaginary Surface

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2.5.4 to 2.5.6_Standard Problems

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2.6 BUOYANCY

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2.6.1_Fundamentals of Buoyancy

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2.6.2 to 2.6.8_Standard Problems

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2.7 STABILITY OF UNCONSTRAINED BODIES IN FLUID

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2.7.1_Introduction

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2.7.2_Stability of Fully Submerged Bodies

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2.7.3_Stability of Partially Submerged Bodies

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2.7.4_Standard Problem

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2.8 FLUID UNDER RIGID BODY MOTION / RELATIVE EQUILIBRIUM

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2.8.1_An open tank containing a liquid that is subjected to a uniform acceleration in horizontal direction

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2.8.2_Calculation of Maximum acceleration for no spill and calculation of spilled volume

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2.8.3_Rotating open cylindrical tank

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2.8.4_Calculation of maximum angular velocity for no spill and calculation of spilled volume

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2.9 TO 2.13 GATE PROBLEMS

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Chapter 3: Fluid Kinematics

3.1 FUNDAMENTALS

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3.1.1_Understanding Kinematics

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3.1.2_Description of Fluid Flow_Lagrangian & Eulerian Approach

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3.1.3_Variation of Flow Parameters with space and time_Stead v/s Unsteady Flows and Uniform v/s Non-uniform Flows

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3.1.4_Flow visualization_Concept of Streamlines, Pathlines and Streaklines

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3.2 FLUID TRANSLATION, ROTATION AND DEFORMATION – I

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3.2.1_Acceleration of Fluid Particle in a Velocity Field

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3.2.2_Linear Deformation of Fluid Element

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3.3 FLUID TRANSLATION, ROTATION AND DEFORMATION – II

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3.3.1_Angular deformation and concept of angular velocity

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3.3.2_Vorticity

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3.3.3_Concept of Rotational and Irrotational Flows

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3.4 STREAM FUNCTION AND VELOCITY POTENTIAL

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3.4.1_Stream function and its physical interpretation

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3.4.2_Velocity potential and its physical interpretation

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3.4.3_Relationship between Stream function and Velocity potential

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3.4.4_Conditions for Ir-rotational Flows

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3.5 SOME STANDARD PROBLEMS ON FLUID KINEMATICS

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3.5.1 to 3.5.4_Standard Problems

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3.6 to 3.8 GATE PROBLEMS

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Chapter 4: Integral form of Conservation Equations

4.1 FUNDAMENTALS OF REYNOLDS TRANSPORT THEOREM

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4.1.1_Need for Reynolds Transport Theorem (RTT)

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4.1.2_Intensive and Extensive Properties

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4.1.3_Understanding discharge and mass flow rate

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4.2 APPLICATION OF RTT TO CONSERVATION OF MASS

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4.2.1_Integral form of Continuity Equation

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4.3 APPLICATION OF RTT TO CONSERVATION OF LINEARE MOMENTUM OR MOMENTUM THEOREM

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4.3.1_The principle of conservation of linear momentum applied to a control volume

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4.4 APPLICATION OF RTT TO CONSERVATION OF ANGULAR MOMENTUM

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4.4.1_The principle of conservation of angular momentum applied to a control volume

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4.4.2_Standard Problem (Lawn Sprinkler)

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Chapter 5: Dynamics of Inviscid Flows – Fundamentals & Application

5.1 PHYSICS OF EULER’S EQUATION – I

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5.1.1_Fundamental Equation of Motion for In-viscid Flow in Cartesian Coordinates

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5.2 PHYSICS OF EULER’S EQUATION – II

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5.2.1_Pressure Differential between two points in an Inviscid Flow Field

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5.2.2_Derivation of Bernoulli’s Equation and Its Assumption

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5.2.3_Physics behind Bernoulli’s Equation

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5.3 APPLICATION OF BERNOULLI’S EQUATION – I

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5.3.1_Hydraulic Siphon

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5.3.2_Flow Measurement – Venturimeter

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5.4 APPLICATION OF BERNOULLI’S EQUATION – II

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5.4.1_Orifice meter

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5.4.2_Concept of Static, Stagnation and Dynamic Pressure

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5.4.3_Pitot tube

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5.5 VORTEX FLOWS

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5.6 GATE PROBLEMS – I

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5.7 GATE PROBLEMS – II

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5.8 GATE PROBLEMS – III

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Chapter 6: Dynamics of Viscous Incompressible Flow

6.1 SOME EXACT SOLUTION OF NAVIER STOKES EQUATION – I

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6.1.1_Introduction to Navier Stokes Equation

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6.1.2_Plane Poiseullie flow

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6.2 SOME EXACT SOLUTION OF NAVIER STOKES EQUATION – II

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6.2.1_Couette Flow

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6.3 SOME EXACT SOLUTION OF NAVIER STOKES EQUATION – III

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6.3.1_Hagen Poiseullie Flow

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6.4 VISCOUS FLOW THROUGH PIPES

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6.4.1_Minor Losses

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6.4.2_Losses due to sudden expansion

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6.4.3_Exit Loss

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6.4.4_Losses due to sudden contraction

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6.4.5_Entry Loss

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6.4.6_Losses in pipe bends

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6.4.7_Flow through branched pipes

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6.5 GATE PROBLEMS

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Chapter 7: Boundary Layer Theory

7.1 BOUNDARY LAYER THEORY – I

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7.1.1_Introductory Concepts

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7.1.2_Boundary Layer Equations

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7.1.3_Blausius Exact Solutions

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7.2 BOUNDARY LAYER THEORY – II

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7.2.1_Displacement Thickness

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7.2.2_Momentum Thickness

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7.2.3_Von Karman Momentum Integral Equation

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7.2.4_Derivation of profile based results

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7.2.5_Overall drag coefficient

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7.3 BOUNDARY LAYER THEORY – III

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7.3.1_Boundary Layer Theory for Turbulent Flows

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7.3.2_Results – Summary

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7.3.3_Standard Problems

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7.3.4_Boundary Layer Separation

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7.3.5_Forces on body immersed in fluid under motion

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7.3.6_Cricket ball dynamics

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7.4 GATE PROBLEMS OF BOUNDARY LAYER THEORY

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Chapter 8: Principle of Similarity and Dimensional Analysis

8.1 DIMENSIONAL ANALYSIS & PRINCIPLE OF SIMILARITIES – I

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8.1.1_Dimension Analysis-Importance of dimension analysis

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8.1.2_Buckingham π theorem

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8.1.3_Interpretation of results

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8.2 DIMENSIONAL ANALYSIS & PRINCIPLE OF SIMILARITIES – II

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8.2.1_Principle of similarities: Concept and size of similarities

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8.2.2_Different forces acting on fluid

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8.2.3_Dimensionless Numbers

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8.2.4_Applications in different cases

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8.2.5_Standard problem

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Chapter 9: Turbulent Flow

Chapter 10: Fluid Machines

10.1.1_Reynolds Transport Theorem Applied to Law of Conservation of Angular Momentum

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10.1.2_Lawn Sprinkler

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10.1.3_Introduction and Classification of Fluid Machines

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10.1.4_Different Components of Velocity

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10.2 FLUID MACHINES – II

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10.2.1_Fundamental Equation of Energy Transfer in Rotodynamic Machines

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10.2.2_Velocity Diagrams

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10.2.3_Different Components of Energy Transfer

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10.2.4_Physical Interpretation of Different Components of Energy Transfer

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10.2.5_Degree of Reaction

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10.3 FLUID MACHINES – III

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10.3.1_Impulse hydraulic turbine: The Pelton Wheel/Pelton Turbine

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10.3.2_Analysis of Pelton Bucket

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Standard Problems

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10.4 FLUID MACHINES – IV

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10.4.1_Reaction Hydraulic Turbine: Francis Turbine

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10.4.2_Analysis of Francis Runner

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10.4.3_Standard Problem on Francis Turbine

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10.4.4_Reaction hydraulic turbine: Kaplan turbine

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10.4.5_Standard Problem on Kaplan Turbine

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10.5 FLUID MACHINES – V

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10.5.1_Laws of similarities

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10.5.2_Concept of specific speed

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10.5.3_Comparison of turbines

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10.6 FLUID MACHINES – VI

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10.6.1_Centrifugal Pump – Introduction

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10.6.2_Velocity Diagram for Centrifugal Pump Impeller

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10.6.3_General Pumping System

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10.6.4_Thomas Cavitation Parameter

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10.6.5_Manometric Efficiency

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10.7 GATE PROBLEMS

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