AAE55500 - Mechanics of Composite Materials

Spring 2015

Days/Time: MWF / 11:30 am-12:20 pm
Credit Hours: 3

Learning Objective:
To introduce modern composite materials and their applications and to build proper background for stress and strength analysis in the design of composite materials and structures. At the end of this course, student should be able to: Describe the characteristics and the manufacturing principles of composite laminates. Carry out thermoelastic analyses for the determination of the stress and strain state in a multi-axial laminate subjected to inplane and bending resultants. Predict the strength of multi-axial laminates. Carry out interlaminar fracture calculations for unidirectional laminates. Understand the bending-twisting-extensional coupling in symmetric and unsymmetric laminates. Determine the stress state at the free-edge of a finite-width laminate.

This course provides students a background in modern lightweight composite materials which are being used in an ever-increasing range of applications and industries. Basic knowledge of composites will allow engineers to understand the issues associated with using these materials, as well as gain insight into how their usage differs from metals, and ultimately be able to use composites to their fullest potential. Topics covered include: current and potential applications of composite materials, fibers, matrices, manufacturing methods for composites, review of elasticity of anisotropic solids, methods for determining mechanical properties of heterogeneous materials, micromechanics of continuous and discontinuous fiber systems, laminated plate analysis, static analyses of laminated composites, edge effects in laminates and both macroscopic and microscopic failure analysis of composite materials and laminates.
Spring 2015 Syllabus

Topics Covered:
Fibers, Matrices, and Composite Materials; Elasticity of Anisotropic Materials; Analysis of Lamina; Effective Elastic Moduli; Elastic Analysis of Composite Laminates; Strength Criteria for Composites; De-homogenization for Micro Strength; Interlaminar Fracture; Unusual Bending Characteristics; and Free-edge Effects.

Course in Mechanics of Solids.

Applied/Theory: 50/50

Web Address:

Web Content:

Biweekly homework problem sets will be assigned and collected via email (jgoodsel@purdue.edu). The due dates can be found on the course syllabus.


2 midterm exams, 1 final exam.

Official textbook information is now listed in the Schedule of Classes. NOTE: Textbook information is subject to be changed at any time at the discretion of the faculty member. If you have questions or concerns please contact the academic department.
Tentative: No course materials are required for this section.

Computer Requirements:
The lectures were pre-recorded during the spring semester 2013. The student should disregard any discussions of dates in these lectures and follow the Course Calendar for Spring 2015 as shown in the syllabus. ProEd minimum computer requirements; syllabus, supplemental lecture notes, homework assignments, solutions will be available on course web. Students will be offered chat rooms for discussions of homework and test preparation. Adobe Connect will be required for an hour per week of direct discussion with instructor/TA.

ProEd Minimum Requirements: view

Tuition & Fees: view

Other Requirements:


Johnathan Goodsell
Purdue University
Neil Armstrong Hall of Engineering
701 W. Stadium Ave.
West Lafayette, IN 47907-2045
Instructor HomePage

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