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Sl.No Chapter Name MP4 Download
1Lecture 01: Definition of the composite materialsDownload
2Lecture 02: Composite materials and its applications.Download
3Lecture 03: Classification of the composite materials.Download
4Lecture 04: What Makes fiber so strong?Download
5Lecture 05: Advantages and limitations of composite materials.Download
6Lecture 06: Properties of the composite materials.Download
7Lecture 07: Different Types of FiberDownload
8Lecture 08: Production process and different types of Glass FiberDownload
9Lecture 09: Graphite FibersDownload
10Lecture10: Aramid and Boron FibersDownload
11Lecture11: Ceramic FibersDownload
12Lecture12: Matrix – Properties and classifications.Download
13Lecture 13: Polymers as matrix material and its classification.Download
14Lecture 14: Thermosets and thermoplastics.Download
15Lecture 15: Properties of thermosets and thermoplasticsDownload
16Lecture 16: Thermoset materials and its production methods.Download
17Lecture 17: Thermoplastics and metals as matrix materials.Download
18Lecture 18: Ceramic and carbon matrices.Download
19Lecture19: What is a good fabrication process of a composite?Download
20Lecture20: Fabrication of Thermoset CompositesDownload
21Lecture21: Hand Lay-Up ProcessDownload
22Lecture22: Bag Molding ProcessDownload
23Lecture23: Resin Transfer Molding ProcessDownload
24Lecture24: Fabrication of Thermoplastic, Metal and Ceramic Matrix based CompositesDownload
25Lecture 25: Terminologies and basic conceptsDownload
26Lecture26: Orthotropic materialDownload
27Lecture 27: Modeling of unidirectional compositesDownload
28Lecture 28: Composite density as a function of mass fraction and volume fractionDownload
29Lecture 29: Calculation of longitudinal modulus for unidirectional compositesDownload
30Lecture30: Failure modes of unidirectional composite Download
31Lecture 31: Failure of Unidirectional Lamina Download
32Lecture 32: Minimum Volume Fraction and Critical Volume FractionDownload
33Lecture 33: Example based on Failure of Composite MaterialDownload
34Lecture 34: Example based on Minimum and Critical Volume Fraction Download
35Lecture 35: Transverse Modulus of Unidirectional CompositeDownload
36Lecture 36: Halpin-Tsai Relation for Transverse ModulusDownload
37Lecture 37: Transverse modulus of unidirectional composites Download
38Lecture 38: Transverse strength of unidirectional compositesDownload
39Lecture 39: Poisson’s ratio of unidirectional composites Download
40Lecture 40: Failure modes of composite materialsDownload
41Lecture 41: - Failure modes of composite materialsDownload
42Lecture 42: Other propertiesDownload
43Lecture 43: Concept of TensorDownload
44Lecture 44: Stress Transformation (Two Dimensional)Download
45Lecture 45: Analysis of Specially Orthotropic LaminaDownload
46Lecture 46: Analysis of Generally Orthotropic LaminaDownload
47Lecture 47: Transformation of Engineering Constants-Part I Download
48Lecture 48: Transformation of Engineering Constants-Part IIDownload
49Lecture 49: Variation of elastic constants with respect to fiber orientation for generally orthotropic laminaDownload
50Lecture 50 : Generally orthotropic laminaDownload
51Lecture 51: Generalized Hooke’s law for anisotropic materialsDownload
52Lecture 52: Generalized Hooke’s law for anisotropic materialsDownload
53Lecture 53: Elastic constants for Specially orthotropic materialsDownload
54Lecture 54 Elastic constants for Specially orthotropic materials in plane stressDownload
55Lecture 55: Relation Betweeen Engineering Constants and Elements of Stiffness and Compliance Matrices- Part I Download
56Lecture 56: Relation Betweeen Engineering Constants and Elements of Stiffness and Compliance Matrices- Part II Download
57Lecture 57: Stress Strain Relations for A Lamina With Arbitrary Orientation- Part IDownload
58Lecture 58: Stress- Strain Relation for A Lamina With Arbitrary Orientation- Part IIDownload
59Lecture 59: Strength of An Orthotropic LaminaDownload
60Lecture 60: Importance of Sign of Shear Stress in context of Strength of A Unidirectional LaminaDownload
61Lecture 61: Strain displacement relations for a laminateDownload
62Lecture 62: Stress-strain relations for individual layers of a laminateDownload
63Lecture 63: Resultant forces and momentsDownload
64Lecture 64: Relations between force and moment resultants and mid-plane strains and curvaturesDownload
65Lecture 65: Physical significance of extensional stiffness matrix [A], coupling matrix [B] and bending stiffness matrix [D] matricesDownload
66Lecture 66: Lamination sequence (standard laminate code)Download
67Lecture 67: Calculation of A, B and D Matrices.Download
68Lecture 68: Simplification of Stiffness Matrices: Part- I.Download
69Lecture 69: Simplification of Stiffness Matrices: Part- II.Download
70Lecture 70: Quasi-Isotropic Laminates: Part-I.Download
71Lecture 71: Quasi-Isotropic Laminate. Part-II.Download
72Lecture 72: Failure of Composite Laminates.Download

Sl.No Chapter Name English
1Lecture 01: Definition of the composite materialsDownload
To be verified
2Lecture 02: Composite materials and its applications.Download
To be verified
3Lecture 03: Classification of the composite materials.Download
To be verified
4Lecture 04: What Makes fiber so strong?Download
To be verified
5Lecture 05: Advantages and limitations of composite materials.Download
To be verified
6Lecture 06: Properties of the composite materials.Download
To be verified
7Lecture 07: Different Types of FiberDownload
To be verified
8Lecture 08: Production process and different types of Glass FiberDownload
To be verified
9Lecture 09: Graphite FibersDownload
To be verified
10Lecture10: Aramid and Boron FibersDownload
To be verified
11Lecture11: Ceramic FibersDownload
To be verified
12Lecture12: Matrix – Properties and classifications.Download
To be verified
13Lecture 13: Polymers as matrix material and its classification.Download
To be verified
14Lecture 14: Thermosets and thermoplastics.Download
To be verified
15Lecture 15: Properties of thermosets and thermoplasticsDownload
To be verified
16Lecture 16: Thermoset materials and its production methods.Download
To be verified
17Lecture 17: Thermoplastics and metals as matrix materials.Download
To be verified
18Lecture 18: Ceramic and carbon matrices.Download
To be verified
19Lecture19: What is a good fabrication process of a composite?Download
To be verified
20Lecture20: Fabrication of Thermoset CompositesDownload
To be verified
21Lecture21: Hand Lay-Up ProcessDownload
To be verified
22Lecture22: Bag Molding ProcessPDF unavailable
23Lecture23: Resin Transfer Molding ProcessDownload
To be verified
24Lecture24: Fabrication of Thermoplastic, Metal and Ceramic Matrix based CompositesDownload
To be verified
25Lecture 25: Terminologies and basic conceptsDownload
To be verified
26Lecture26: Orthotropic materialDownload
To be verified
27Lecture 27: Modeling of unidirectional compositesDownload
To be verified
28Lecture 28: Composite density as a function of mass fraction and volume fractionDownload
To be verified
29Lecture 29: Calculation of longitudinal modulus for unidirectional compositesDownload
To be verified
30Lecture30: Failure modes of unidirectional composite Download
To be verified
31Lecture 31: Failure of Unidirectional Lamina Download
To be verified
32Lecture 32: Minimum Volume Fraction and Critical Volume FractionDownload
To be verified
33Lecture 33: Example based on Failure of Composite MaterialDownload
To be verified
34Lecture 34: Example based on Minimum and Critical Volume Fraction Download
To be verified
35Lecture 35: Transverse Modulus of Unidirectional CompositeDownload
To be verified
36Lecture 36: Halpin-Tsai Relation for Transverse ModulusDownload
To be verified
37Lecture 37: Transverse modulus of unidirectional composites Download
To be verified
38Lecture 38: Transverse strength of unidirectional compositesDownload
To be verified
39Lecture 39: Poisson’s ratio of unidirectional composites Download
To be verified
40Lecture 40: Failure modes of composite materialsDownload
To be verified
41Lecture 41: - Failure modes of composite materialsDownload
To be verified
42Lecture 42: Other propertiesDownload
To be verified
43Lecture 43: Concept of TensorDownload
To be verified
44Lecture 44: Stress Transformation (Two Dimensional)Download
To be verified
45Lecture 45: Analysis of Specially Orthotropic LaminaDownload
To be verified
46Lecture 46: Analysis of Generally Orthotropic LaminaDownload
To be verified
47Lecture 47: Transformation of Engineering Constants-Part I Download
To be verified
48Lecture 48: Transformation of Engineering Constants-Part IIDownload
To be verified
49Lecture 49: Variation of elastic constants with respect to fiber orientation for generally orthotropic laminaDownload
To be verified
50Lecture 50 : Generally orthotropic laminaDownload
To be verified
51Lecture 51: Generalized Hooke’s law for anisotropic materialsDownload
To be verified
52Lecture 52: Generalized Hooke’s law for anisotropic materialsDownload
To be verified
53Lecture 53: Elastic constants for Specially orthotropic materialsDownload
To be verified
54Lecture 54 Elastic constants for Specially orthotropic materials in plane stressDownload
To be verified
55Lecture 55: Relation Betweeen Engineering Constants and Elements of Stiffness and Compliance Matrices- Part I Download
To be verified
56Lecture 56: Relation Betweeen Engineering Constants and Elements of Stiffness and Compliance Matrices- Part II Download
To be verified
57Lecture 57: Stress Strain Relations for A Lamina With Arbitrary Orientation- Part IDownload
To be verified
58Lecture 58: Stress- Strain Relation for A Lamina With Arbitrary Orientation- Part IIDownload
To be verified
59Lecture 59: Strength of An Orthotropic LaminaDownload
To be verified
60Lecture 60: Importance of Sign of Shear Stress in context of Strength of A Unidirectional LaminaDownload
To be verified
61Lecture 61: Strain displacement relations for a laminateDownload
To be verified
62Lecture 62: Stress-strain relations for individual layers of a laminateDownload
To be verified
63Lecture 63: Resultant forces and momentsDownload
To be verified
64Lecture 64: Relations between force and moment resultants and mid-plane strains and curvaturesDownload
To be verified
65Lecture 65: Physical significance of extensional stiffness matrix [A], coupling matrix [B] and bending stiffness matrix [D] matricesDownload
To be verified
66Lecture 66: Lamination sequence (standard laminate code)Download
To be verified
67Lecture 67: Calculation of A, B and D Matrices.Download
To be verified
68Lecture 68: Simplification of Stiffness Matrices: Part- I.Download
To be verified
69Lecture 69: Simplification of Stiffness Matrices: Part- II.Download
To be verified
70Lecture 70: Quasi-Isotropic Laminates: Part-I.Download
To be verified
71Lecture 71: Quasi-Isotropic Laminate. Part-II.Download
To be verified
72Lecture 72: Failure of Composite Laminates.Download
To be verified


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