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| Section I: Review of Design Considerations | |
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| 1; 2 | | | | Unit 1: Introduction and Design Overview
Why Structural Mechanics? Types of Structures; Structural Design Process; Factors in Cost. | | | | L1; L2 | | | | R: Ch.1
M: 7.1, 7.3, 7.4 | | | | | |
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| 3; 4 | | | | Unit 2: Loads and Design Considerations
Sources of Loads/Deflections; Types of Loads and Environments; Limit and Ultimate Loads; Factors and Margins of Safety; Example, the v-n Diagram; Definition of Failure; FAR's. | | | | L3; L4, R | | | | M: 7.2, 12.1, 12.2
G: 1.7 | | | | R-Assessment Exercise | |
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| Section II: General Elasticity | |
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| 4; 5 | | | | Unit 3: Language of Stress/Strain Analysis (Review)
Definition of Stress and Strain; Notation; Tensor Rules; Tensor vs. Engineering Notation; Contracted Notation; Matrix Notation. | | | | L4, R; L5 | | | | BMP: A.2, A.3, A.6
R: 2.1, 2.2
T&G: Ch. 1 | | | | HA1 out; DP1 out | |
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| 6; 7; 8 | | | | Unit 4: Equations of Elasticity (Review)
Equations of Elasticity (Equilibrium, Strain-Displacement, Stress-Strain); Static Determinance; Compatibility; Elasticity Tensor; Material Types and Elastic Components; Materials Axes vs. "Loading Axes"; Compliance and its Tensor; The Formal Strain Tensor; Large Strains vs. Small Strains; Linear vs. Nonlinear Srain. | | | | L6; L7; L8, R | | | | R: 2.3, 2.6, 2.8
T&G: 5.1-5.5, 5.8, 5.9, 7.1-7.4, 6.1-6.3, 6.5-6.7
J: 2.1, 2.2 (for
composites) | | | | | |
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| 8; 9; 10 | | | | Unit 5: Engineering Constants
Engineering Constants (Longitudinal Moduli, Poisson's Ratio, Shear Moduli, Coefficients of Mutual Influence, Chentsov Coefficients); Reciprocity Relations; Engineering Stress-strain Equations; Compliances and Engineering Constants; Purposes of Testing; Issues of Scale; Testing for Engineering Constants; Variability and Issues in Design. | | | | L8, R; L9; L10 | | | | R: 3.1-3.5, 3.9,
3.11
M: 1.16
J: 2.3, 2.4, 2.6 | | | | HA1 due; HA2 out;
DP1 due; | |
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| 11; 12; 13 | | | | Unit 6: Plane Stress and Plane Strain
Plane Stress; Plane Strain; Applications; Approximations and Modeling Limitations. | | | | L11; L12; L13 | | | | T&G: 8-16
J: 2.5
G: 7.2, 7.7, 8.1, 8.2 | | | | DP2 out;
HA2 due; HA3 out | |
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| 13; 14 | | | | Unit 7: Transformations and Other Coordinate Systems
Review of Transformations: Direction Cosines; 3-D tensor form (Axis, Displacement, Stress, Strain, Elasticity Tensor); Plane Stress Case (and Mohr's Circle); Principal Stresses/ Strains; Invariants; Extreme Shear Stresses/Strains; Reduction to 2-D; Other Coordinate Systems (Example: Cylindrical); General Curvilinear Coordinates. | | | | L13; L14 | | | | R: 2.4, 2.5, 2.7, 2.9
BMP: 5.6, 5.7, 5.14, 6.4, 6.8, 6.9, 6.11
T&G: 27, 54, 55, 60, 61
J: 2.6
G: 7.3, 7.4 | | | | | |
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| 15; 16; 17; 18 | | | | Unit 8: Solution Procedures
Exact Solution Procedures; Airy Stress Function; Biharmonic Equation; Inverse Method; Semi-Inverse Method; St. Venant's Principle; Examples: Uniaxiallyloaded Plate, Polar Form and Stress Around a Hole; Stress Concentrations; Considerations for Orthotropic Materials. | | | | L15, R; L16; L17; L18 | | | | R: Ch. 4
T&G: 17, Ch. 3, 4, 6 | | | | HA3 due; HA4 out;
DP2 due | |
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| 18; 19; 20; 21; 23 | | | | Unit 9: Effects of the Environment
Where Thermal Strains/"Stresses" come from; Coefficients of Thermal Expansion; Sources of Heating; Spatial Variation of Temperature; Self-equilibrating Stresses; Convection, Radiation, Conductivity (Fourier's Equation); Solution Techniques; "Internal" Stresses; Degradation of Material Properties; Other Environmental Effects; Examples: Moisture; Piezoelectricity. | | | | L18; L19, R; L20; L21; L22 | | | | R: 3.6, 3.7
T&G: Ch. 13
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| 22 | | | | No Lecture | | | | | | | | | | | | Evening Exam 1 ; HA5 out | |
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| Section III: Torsion | |
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| 23; 24; 25; 26 | | | | Unit 10: St. Venant Torsion Theory
"Types" of Cross-Sections; St. Venant's Torsion Theory; Assumptions; Considerations for Orthotropic Materials; Torsion Stress Function; Boundary Conditions; Summary of Procedure; Solution; Poisson's Equation; Example:Circular Rod; Resultant Shear Stress; Other Cross-Sections; Warping. | | | | L22; L23; L24, R; L25 | | | | R: 8.1, 8.2
T&G: 10.1, 10.4, 10.5, 10.6
M: 3.1, 3.2
G: 3.1-3.4 | | | | HA5 due; HA6 out | |
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| 26; 27 | | | | Unit 11: Membrane Analogy
Membrane Analogy; Uses; Application: Narrow Rectangular Cross-Section; Other Shapes. | | | | L25; L26 | | | | R: 8.3, 8.6
T&G: 107-110, 112-114
M: 3.1, 3.3, 3.4 | | | | | |
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| 27; 28; 29 | | | | Unit 12: Torsion of (Thin) Closed Sections
Thick-walled Closed Section; Special Case -- Circular Tube; Shear Flow; Bredt's Formula; Torsion Summary. | | | | L26; L27; L28, R | | | | R: 8.7, 8.8
T&G: 115, 116
M: 8.5
G: 3.10 | | | | HA6 due; HA7 out | |
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| Section IV: General Beam Theory | |
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| 29; 30 | | | | Unit 13: Review of Simple Beam Theory
Generic types of Loading (review); Review of Simple Beam Theory; Considerations for Orthotropic Materials. | | | | L28, R; L29 | | | | BMP: 3.8-3.10
T&G: 120-125
G: 5.1-5.9, 9.1-9.5, 10.1-10.4 | | | | | |
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| 30; 31; 32; 33 | | | | Unit 14: Behavior of General Beams and Engineering Beam Theory
Geometry Definitions; Assumptions; Stress Resultants; Deformation, Strain, Stress In General Shell Beams; Considerations for Orthotropic Beams; Modulus-Weighted Section Properties; "Thermal" Forces and Moments; Selective Reinforcement; Principal Axes of Cross-Section; Beams with Unsymmetric Cross-Sections; Applicability of Engineering Beam Theory; Transverse Shear Effects; Shear Center; Contribution of "Shearing" Deflection; Limitations of Engineering Beam Theory. | | | | L29; L30; L31; L32, R | | | | R: 7.1-7.5, 7.7, 7.8
T&G: 126
M: 2.6, 8.1-8.3
G: 5.10-5.12, 6.1-6.8 | | | | DP3 due | |
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| 34; 35; 36; 38; 39; 40 | | | | Unit 15: Behavior (Bending, Shearing, Torsion) of Shell Beams
General loading of a Shell Beam; Semi-monocoque Construction; Skin/stringer Construction; Single Cell "Box Beam"; Bending Stresses; Shear Stresses; Joint Equilibrium; Pure Shear and Pure Torsion Scheme; General Solution Procedure; "No Twist" Condition; Shear Center; Torque Boundary Condition; Deflections; St. Venant Assumption; Section Properties: Bending, Shear, and Torsional Stiffness; Multicell Shell Beams; "Equal Twist" Condition; Open Section Beams; Thick Skin Shells; Effective Width. | | | | L33; L34; L35; L36; L37; L38, R | | | | R: Ch.9, 8.7, 7.6
T&G: 126, 127
M: 7.3, 8.2-8.10, 9.3
G: Ch. 12 | | | | HA7 due; HA8 (Part A) out (not for hand-in);
HA8 (Part B) due | |
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| 37 | | | | No Lecture | | | | | | | | | | | | Evening Exam 2; HA8 (Part B) out | |
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| Section V: Stability and Buckling | |
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| 40; 41; 42 | | | | Unit 16: (Review of) Bifucation Buckling
Types of Buckling; Governing Equations for Bifucation Buckling; Application of Boundary Conditions; Euler Buckling Load; Coefficient of Edge Fixity; Geometrical Parameters; Considerations for Orthotropic/Composite Beams; Initial Imperfections; Primary and Secondary Moments. | | | | L38, R; L39; L40 | | | | R: 14.1, 14.2, 14.4
M: 6.1, 6.3
G: 11.1-11.4 | | | | HA10 out | |
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| 43; 44 | | | | Unit 17: The Beam-Column
Beam-column Definition; Equilibrium Equations; Governing Equations; Solution for Axial Force; Buckling of Beam-Column; Primary and Secondary Moments. | | | | L41; L42, R | | | | T: Ch.1
M: 6.4
G: 11.5-11.6 | | | | HA9 out | |
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| 44; 45; 46 | | | | Unit 18: Other Issues in Buckling/Structural Instability
Other Issues in Buckling; Squashing; Progressive Yielding; Nonuniform Beams; Plate Buckling; Cylinders; Reinforced Plates; Postbuckling; Curvature Expression for large Deflections; Galerkin Method; Buckling and Failure. | | | | L42, R; L43; L44 | | | | R: 14.3, 14.5-14.7, Ch. 15, Ch. 16
T: (Suggested)
J: Ch. 5
M: 6.2, 6.6-6.10 | | | | | |
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| Section VI : Introduction to Structural Dynamics | |
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| 46; 47 | | | | Unit 19: General Dynamic Considerations (Review)
System Response: The Regimes and Controlling Factors; Spring-mass System, Inertial Loads, Governing Equation; Initial Conditions; Damping; Multi-mass System, Matrix Equation Form; (Sources of) Dynamic Structural Loads; Consequences of Dynamic Structural Response. | | | | L44; L45, R | | | | | | | | | |
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| 47; 48 | | | | Unit 20: Solutions for Single Spring-Mass System (Review)
Single Degree-of-Freedom System; Free Vibration and Natural Frequency; Forced Vibration; Step Function; Unit Impulse, Dirac Delta Function; Arbitrary Force, Duhamel's convolution) Integral; Sinusoidal Force; Dynamic Magnification Factor; Resonance. | | | | L45, R; L46 | | | | | | | | HA10 due; HA11 out (not for hand-in) | |
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| 48; 49 | | | | Unit 21: Influence Coefficients
Generalized Forces and Displacements; Flexibility Influence Coefficients; Maxwell's Theorem of Reciprocity; Examples: Cantilevered Beam; Stiffness Influence Coefficients; Physical Interpretations. | | | | L46; L47 | | | | R: 6.6, 6.13, 10.5
M: 4.10, 11.1, 11.2 | | | | DP4 due | |
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| 50; 51 | | | | Unit 22: Vibration of Multi Degree-of-Freedom Systems
Governing Matrix Equation; Free Vibration; Eigenvalues and Eigenvectors--Natural Frequencies and Modes; Examples: Representation of Beam as Discrete Mass System; Physical Interpretation of Modes; Orthogonality Relations; Normal Equations of Motion; Superposition of Modal Responses; Forced Vibration. | | | | L48; L49, R | | | | | | | | | |
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| 51; 52 | | | | Unit 23: Vibrations of Continuous Systems
Generalized Beam-Column Equation with Inertia; Free Vibration; Separation of Spatial and Temporal Solutions; Example: Simply-Supported Beam; Natural Frequencies and Modes; Orthogonality Relations; Normal Equations of Motion; Forced Vibration; Superposition of Modal Responses; Resonance. | | | | L49, R; L50 | | | | | | | | | |
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