26.12.2024, 23:23
Mechanics Of Materials Made Easy: Ace Your Engineering Exams
Published 12/2024
MP4 | Video: h264, 1280x720 | Audio: AAC, 44.1 KHz
Language: English | Size: 50.21 GB | Duration: 42h 39m
A Comprehensive Guide to Statics, Stress Analysis, and Structural Design for Engineering Students and Professionals.
What you'll learn
Understand Fundamental Concepts of Mechanics of Materials
Analyze Structural Components Under Various Loading Conditions
Apply Problem-Solving Techniques in Real-World Scenarios
Design Safe and Efficient Structural Elements
Master Stress Transformation Techniques
Evaluate Material Properties and Their Impact on Structural Behavior
Calculate Axial, Shear, and Bending Deformations
Analyze and Design Composite Beams and Eccentric Load Scenarios
Understand the Effects of Temperature on Structural Elements
Apply Compatibility Equations to Indeterminate Structures
Understand Torsional Effects in Circular Sections
Utilize Combined Loading Analysis
Assess Structural Safety with Allowable Stress Design
Prepare for Advanced Engineering Studies or Professional Exams
Requirements
Commitment for Learning Mechanics of Materials: No advanced knowledge or tools are required-just an interest in understanding how materials and structures behave under various loading conditions.
Access to a Calculator: Students should have a scientific or graphing calculator to solve numerical problems effectively.
Description
Course Description:Unlock the secrets of Mechanics of Materials with this comprehensive course designed for engineering students and professionals. Whether you're preparing for exams like the FE or PE, enhancing your engineering knowledge, or building a strong foundation in structural analysis, this course has everything you need.Starting with a review of statics and advancing to complex topics like stress transformation, torsion, and combined loadings, the course systematically covers all the essentials. You'll gain hands-on experience solving real-world problems and designing safe, efficient structures.What You'll Learn:Analyze and solve problems involving stress, strain, and deformation under various loading conditions.Master techniques like Mohr's Circle, compatibility equations, and allowable stress design.Calculate structural properties, including centroids, moments of inertia, and neutral axes.Evaluate material behavior, including ductility, toughness, and failure modes.Solve practical engineering problems step by step, preparing you for exams and real-world applications.What's Included:Over 160 detailed lectures covering concepts, examples, and exercises.Quizzes to test your knowledge and reinforce key concepts.Step-by-step solutions to problem sets, from basic to advanced scenarios.Focused sections on bending, torsion, transverse shear, and axial loads.This course is perfect for:Undergraduate engineering students in civil, mechanical, aerospace, or structural disciplines.Professionals preparing for the FE or PE exams.Anyone looking to refresh or deepen their understanding of mechanics of materials.With practical problem-solving techniques and clear explanations, this course is designed to help you succeed in your engineering studies and beyond. Enroll today and take the next step toward mastering Mechanics of Materials!
Overview
Section 1: Statics Review: Shear and Bending Diagrams
Lecture 1 Types of Supports, Loads, and Beams.
Lecture 2 Continued
Lecture 3 The Three Equilibrium Equations in 2-D Statics Problems
Lecture 4 Internal Forces
Lecture 5 Problem 1
Lecture 6 Problem 1 Continued
Lecture 7 Problem 2
Lecture 8 Problem 3
Lecture 9 Method of Equations
Lecture 10 Problem 4
Lecture 11 Method of Integration (Area Method)
Lecture 12 Continued
Lecture 13 Problem 5
Lecture 14 Problem 6
Lecture 15 Problem 7
Section 2: Stress
Lecture 16 Definition and Types of Stresses
Lecture 17 Units of Stresses
Lecture 18 Average Normal Stresses
Lecture 19 Mode of Failure Under Normal Stresses
Lecture 20 Problem 1 - Normal Stresses
Lecture 21 Problem 2 - Normal Stresses
Lecture 22 Problem 3 - Normal Stresses
Lecture 23 Problem 4 - Normal Stresses
Lecture 24 Problem 5 - Normal Stresses
Lecture 25 Problem 6 - Normal Stresses
Lecture 26 Average Shear Stresses
Lecture 27 Example of Average Shear Stresses
Lecture 28 Problem 7: Average Shear Stresses
Lecture 29 Mode of Failure Under Shear Stresses
Lecture 30 Problem 8 - Average Shear Stresses
Lecture 31 Problem 9 - Average Shear Stresses
Lecture 32 Problem 10 - Average Shear Stresses
Lecture 33 Problem 11 - Average Shear Stresses
Lecture 34 Bearing Stresses - Definition and Types
Lecture 35 Mode of Failure Under Bearing Stresses
Lecture 36 Problem 12 - Bearing Stresses
Lecture 37 Problem 13 - Bearing Stresses
Lecture 38 Problem 14 - Bearing Stresses
Lecture 39 Extra Exercises - Problem 15
Lecture 40 Extra Exercises - Problem 16
Lecture 41 Extra Exercises - Problem 17
Lecture 42 Allowable Stress Design
Lecture 43 Problem 18 - Allowable Stress Design
Lecture 44 Problem 19 - Allowable Stress Design
Lecture 45 Problem 20 - Allowable Stress Design
Section 3: Strain
Lecture 46 Axial Deformations
Lecture 47 Shear Deformations
Lecture 48 Shear Strain and Normal Strain
Lecture 49 Problem 1 - Average Normal Strain
Lecture 50 Problem 2: Average Normal Strain
Lecture 51 Problem 3: Average Normal Strain
Lecture 52 Problem 4: Average Normal Strain
Lecture 53 Problem 5: Average Normal Strain
Lecture 54 Problem 6: Average Normal Strain
Lecture 55 Law Of Cosines
Lecture 56 Problem 7: Average Shear Strain
Lecture 57 Continued
Section 4: Mechanical Properties of Material
Lecture 58 Strength and Ductility
Lecture 59 Toughness and Stiffness
Lecture 60 Tension Test
Lecture 61 Normal Stress Strain Diagram and Hooke's Law
Lecture 62 Inelastic Phase - Part 1
Lecture 63 Inelastic Phase - Part 2
Lecture 64 Load Removal - Elastic Phase
Lecture 65 Load Removal - Inelastic Phase
Lecture 66 Problem 1 - Normal Stress Strain Diagram
Lecture 67 Continued
Lecture 68 Shear Stress Strain Diagram
Lecture 69 Problem 2: Shear Stress Strain Diagram
Lecture 70 Problem 3: Average Shear Strain
Lecture 71 Poisson's Ratio
Lecture 72 Problem 4: Poisson's Ratio
Lecture 73 General State of Stress
Lecture 74 Example on the General State of Stress
Lecture 75 Problem 5: General State of Stress
Lecture 76 Problem 6: General State of Stress
Lecture 77 Problem 7: General State of Stress
Lecture 78 Continued
Lecture 79 Problem 8: General State of Stress
Lecture 80 Continued
Lecture 81 Problem 9: General State of Stress
Lecture 82 Dilation and Bulk Modulus
Section 5: Axial Load and Deformation
Lecture 83 Axial Deformation: General Formula
Lecture 84 Sudden Changes in Internal Force
Lecture 85 Sudden Changes in Area
Lecture 86 Sudden Changes in Modulus of Elasticity
Lecture 87 Continuous Change in Load
Lecture 88 Continuous Change in Area
Lecture 89 Temperature Effects
Lecture 90 Example on Temperature Effects
Lecture 91 Indeterminate Structures
Lecture 92 Compatibility Equation Form 1
Lecture 93 Problem 1: Compatibility Equation
Lecture 94 Continued
Lecture 95 Problem 2: Compatibility Equation
Lecture 96 Compatibility Equation Form 2
Lecture 97 Problem 3: Compatibility Equation
Lecture 98 Compatibility Equation Form 3
Lecture 99 Problem 4: Compatibility Equation
Lecture 100 Continued
Lecture 101 Compatibility Equation Form 4
Lecture 102 Problem 5: Compatibility Equation
Lecture 103 Compatibility Equation Form 5
Section 6: Bending
Lecture 104 Normal Stresses Due to Bending
Lecture 105 Linear Variation and the Neutral Axis
Lecture 106 Locating the Neutral Axis for Single Bending
Lecture 107 Locating the Centroid of a Cross Section
Lecture 108 Problem 1: Locating the Centroid
Lecture 109 Problem 2: Locating the Centroid
Lecture 110 Problem 3: Locating the Centroid
Lecture 111 Moment of Inertia
Lecture 112 Problem 4: Moment of Inertia
Lecture 113 Problem 5: Moment of Inertia
Lecture 114 Problem 6: Moment of Inertia
Lecture 115 Pure Bending About a Horizontal Axis
Lecture 116 Problem 7: Pure Bending About a Horizontal Axis
Lecture 117 Problem 8: Pure Bending About a Horizontal Axis
Lecture 118 Continued
Lecture 119 Problem 9: Pure Bending About a Horizontal Axis
Lecture 120 Continued
Lecture 121 Problem 10: Pure Bending About a Horizontal Axis
Lecture 122 Continued
Lecture 123 Pure Bending About a Vertical Axis
Lecture 124 Problem 11: Pure Bending About a Vertical Axis
Lecture 125 Locating the Neutral Axis in Double Pending
Lecture 126 Problem 12: Locating the Neutral Axis in Double Bending
Lecture 127 Continued
Lecture 128 Problem 13: Locating the Neutral Axis in Double Bending
Lecture 129 Continued
Lecture 130 Eccentric Loads (Part 1)
Lecture 131 Eccentric Loads (Part 2)
Lecture 132 Problem 14: Eccentric Loads
Lecture 133 Composite Beams
Lecture 134 Problem 15: Composite Beams
Lecture 135 Problem 16: Composite Beams
Lecture 136 Composite Beams in Circular Cross Sections
Section 7: Transverse Shear
Lecture 137 Vertical Shear Stresses (Part 1)
Lecture 138 Vertical Shear Stresses (Part 2)
Lecture 139 Problem 1 - Vertical Shear Stresses
Lecture 140 Continued
Lecture 141 Problem 2 - Vertical Shear Stresses
Lecture 142 Horizontal Shear Stresses
Lecture 143 Problem 3 - Horizontal Shear Stresses
Lecture 144 Shear Flow
Lecture 145 Problem 4 - Shear Flow
Lecture 146 Continued
Lecture 147 Problem 5 - Shear Flow
Section 8: Torsion
Lecture 148 Torsional Stress
Lecture 149 Problem 1 - Torsion
Lecture 150 Problem 2 - Torsion
Lecture 151 Problem 3 - Torsion
Lecture 152 Angle of Twist
Lecture 153 Problem 4 - Angle of Twist
Lecture 154 Gears in Mesh
Lecture 155 Power Transformation
Lecture 156 Statically Indeterminate Structures in Torsion
Lecture 157 Problem 5 - Statically Indeterminate Structures in Torsion
Section 9: Combined Loadings
Lecture 158 Combined Loadings - Part 1
Lecture 159 Combined Loadings - Part 2
Lecture 160 Combined Loadings - Part 3
Lecture 161 Combined Loadings - Part 4
Lecture 162 Problem 1 - Combined Loadings
Lecture 163 Continued
Lecture 164 Problem 2 - Combined Loadings
Lecture 165 Problem 3 - Combined Loadings
Lecture 166 Continued
Lecture 167 Problem 4 - Combined Loadings
Section 10: Stress Transformations
Lecture 168 Stress Transformation - Part 1
Lecture 169 Stress Transformation - Part 2
Lecture 170 Stress Transformation - Part 3
Lecture 171 Principal Stresses and Principal Planes
Lecture 172 Problem 1 - Principal Stresses and Principal Planes
Lecture 173 Maximum In-plane Shear Stresses
Lecture 174 Problem 2 - Maximum Shear Stresses
Lecture 175 Introduction to Mohr's Circle
Lecture 176 Mohr's Circle for Principal Stresses and Principal Planes
Lecture 177 Mohr's Circle for Maximum In-plane Shear Stresses
Lecture 178 Mohr's Circle for Rotating Element with Angle Theta
Lecture 179 Problem 3 - Mohr's Circle with Combined Loadings
Undergraduate Engineering Students: Ideal for civil, mechanical, aerospace, and structural engineering students who want a thorough understanding of mechanics of materials concepts and their applications.,Engineering Professionals: Perfect for practicing engineers looking to refresh their knowledge of stress, strain, deformation, and design principles to enhance their skills or prepare for professional certifications like the FE and PE exams.,FE and PE Exam Candidates: A valuable resource for individuals preparing for the Fundamentals of Engineering (FE) or Professional Engineer (PE) exams, providing in-depth problem-solving techniques and conceptual clarity.,STEM Educators: Useful for instructors or educators seeking a comprehensive resource to enhance their teaching materials and methods in mechanics of materials.,Curious Learners and Beginners: Open to anyone with an interest in structural analysis, mechanical properties of materials, and their practical applications, even with minimal prior knowledge. The course starts with a statics review to bridge the gap for beginners.,Graduate School Applicants: Helpful for students planning to pursue advanced studies in engineering fields, ensuring they have a strong grasp of foundational concepts.
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