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Session 2566
Development of an Integrated Statics and Strength of Materials
Curriculum with an Emphasis on Design
Hugh A. Bruck, Dave K. Anand, William L. Fourney, Peter C. Chang, and
James W. Dally
Departments of Mechanical and Civil Engineering, University of Maryland,
College Park, MD 20742
Abstract
Traditionally, statics and strength of materials courses have been taught separately with the intent
of emphasizing the mechanics of rigid bodies in statics and transitioning to the mechanics of
deformable bodies in strength of materials. While this approach has proven to be effective in
reinforcing students’ understanding of basic principles in mechanics, it has been less than
effective in providing students with an understanding of the relationship between the two
subjects and their importance in designing structures. At the University of Maryland, the
Mechanical and Civil Engineering departments are seamlessly integrating these two courses
together, better preparing students to apply mechanics principles in the design of solutions to
engineering problems. The new courses are centered around a simple, but well-developed, design
project and efforts have been initiated to enhance the instruction with demonstration experiments
and computer tools that will be delivered in new interactive, multimedia "Studios". Metrics for
success concentrate on comparative evaluation of student performance in the traditional and
integrated versions of the curriculum, as well as student feedback on the curriculum’s satisfaction
of ABET 2000 criteria.
Introduction
Engineering students are facing new challenges in the 21st century that may not be satisfied with
existing undergraduate engineering curriculum [1-4]. These challenges require the development
of improved skills in a variety of areas, such as engineering design, problem solving, life-long
learning, and multidisciplinary teamwork. These skills have been identified in a new set of
criteria developed by ABET, known as ABET Engineering Criteria 2000, which is currently
being used as a guide for assessing engineering programs reaccreditation [5]. Although these
criteria provide a framework for developing 21st century engineering curriculum, implementation
of these criteria is being left to the discretion of individual engineering programs.
Five years ago, an effort was undertaken by the University of Maryland (UMD) to establish a
philosophical framework for developing new engineering curriculum capable of meeting
educational challenges for the 21st century [6]. As part of that effort, a proposal was made to
integrate components of the curriculum. The first implementation of this proposal is the
integration of statics and strength of materials with an emphasis on design.
While traditional instruction of statics and strength of materials has treated the development of
the subjects as mutually exclusive, there appears to be no sound rationale for continued adoption
of this approach. In fact, the only real difference between the two subjects is whether or not a
Development of Integrated Statics and Strength of Materials Curriculum, Bruck et al
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body is treated as rigid or deformable. Such a distinction does not in anyway impair the student
from understanding both subjects simultaneously. Rather, conventional curriculum has chosen to
adopt an approach which appears to better illuminate the differences between the two subjects.
In educating engineers for the 21st century, it is becoming increasingly clear that the seamless
integration of curriculum is more important than the delineation of differences in the subject
matter. With this in mind, it has become evident that statics and strength of materials are
probably two excellent candidates for integration in the undergraduate curriculum. The similarity
in their subject matter and their consecutive scheduling in many undergraduate programs
substantially reduces the effort involved in integrating them. Furthermore, by integrating the two
subjects it becomes possible to add meaningful design projects into the curriculum.
Some textbook authors have attempted to integrate the courses by simply abridging and unifying
separate textbooks on the subjects, while still maintaining their current chronological delivery. A
prime example of this is Hibbeler’s new Statics and Strength of Materials text, which is even
alluded to in it’s preface as being intended, "... for those students who do not need complete
coverage of these subjects." [9] While such an approach to integration has some merit in
facilitating delivery of the subject matter in the two courses to undergraduate students, it by no
means enhances the students’ understanding of engineering concepts and their relation to
designing solutions to engineering problems. Such an enhancement requires simultaneous
discussion of both subjects, as well as their applications to engineering design. Riley, Sturges
and Morris have introduced a more integrated approach in Statics and Mechanics of Materials:
An Integrated Approach, addressing design issues by concluding their chapters, "... with a
section on Design Problems ..." [10].
In the new curriculum being developed at the University of Maryland, an approach to integrating
statics and strength of materials has been proposed where the presentation of both subjects are
centered around a design project. The purpose of this design project is to further develop the
inchoate design skills students acquire in their freshman design course. To guide the students
through this new approach, a textbook has been initially conceived around the design of bridge
structures. Furthermore, computer tools and demonstration experiments are also being developed
to enhance the students’ physical understanding of mechanics principles, as well as providing
them with the tools they will use during the design process. Finally, metrics are being developed
to gauge the success of the new curriculum based on satisfaction of ABET 2000 (a) through (k)
criteria.
Textbook for the Integration of Statics and Strength of Materials Curriculum
A new textbook entitled, Design Analysis of Structural Elements, has been developed which
embodies a new educational philosophy for presenting the subject matter traditionally offered in
introductory Mechanics courses. The changes in philosophy were based on five premises:
1. Present fundamental mechanics concepts in a more relevant manner.
2. Provide a smooth transition from the introduction to engineering design course to the
introductory Mechanics course.
Development of Integrated Statics and Strength of Materials Curriculum, Bruck et al
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3. Emphasize modeling by stressing the importance of the free body diagram (FBD)
throughout the text
4. Integrate the contents of Statics with that contained in Strength of Materials
5. Emphasize the design of structural components for safety.
In short, this educational philosophy espouses developing the principles of engineering
mechanics by emphasizing its applications in designing structures. The first edition of the
textbook focuses on the design of a bridge structure. Although a civil structure has initially been
chosen for the design project, it is envisioned that in future versions, design problems specific to
manufacturing, materials, nuclear, aerospace, and mechanical systems could be substituted. The
flexibility in choosing the design problem reflects the diverse engineering interests of the
students who are currently required to take these courses as part of their core curriculum.
The organization of chapters for the first edition of the book can be seen in Table I. While many
of these topics can be found in existing statics and strength of materials texts, they can only
appear in this order when the subjects are taught concurrently. In many of the chapters, concepts
in both subjects are also presented concurrently. For example, in Chapter 2, the concepts of stress
and tensors are introduced at the same time forces and vectors are discussed. Another example
can be found in Chapter 5 where the one-dimensional deformation of bodies is introduced
through a discussion of cables. Such seamless integration of material from the two courses
allows students to better understand the whole of engineering mechanics through the
interrelationship of these traditionally disjointed topics. The format differs substantially from the
one adopted by Sturges et al, choosing to emphasis the introduction of Mechanics of Materials
concepts through common structural elements, such as cables and bars, that are applicable to the
design problem emphasized in the text.
Chapter Title
1Bridges
2 Basic Concepts in Mechanics
3 Forces and Moments
4 Equilibrium
5 Thread, String, Rope, Wire, and Cable
6Rods and Bars
7 Material Properties
8 Trusses, Space Structures, and Vector
Mechanics
9 Stresses in Beams
10 Friction
Table I. Table of contents for current edition of Design Analysis of Structural Elements
One chapter of special interest, and probably the most important chapter in the text, is the first
one on bridges. It is through this chapter that the connection between engineering mechanics and
design of structures is established for the student. The chapter begins with a brief discourse on
the history of designing bridges, citing their evolution in terms of materials development and
understanding of mechanical principles. This discourse is followed up with more details on the
Development of Integrated Statics and Strength of Materials Curriculum, Bruck et al
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mechanical advantages of different types of bridges and the materials used in their construction,
and concludes with the importance of using scale models for verifying design concepts that the
students will develop in their project. Thus, chapter one provides students with the foundation
they will need in studying mechanics principles as tools for the design process they will use in
the remainder of the course.
Currently, the first edition of the book is being use in the first semester of the Mechanics
curriculum, the time when Statics is traditionally taught. However, chapters will be included in
the next edition of the book to replace the traditional second semester Strength of Materials
course material. The tentative organization of these chapters is outlined in Table II. The proposed
course material includes introductions to a topic not traditionally covered in the first two
semesters of the Mechanics curriculum, the Finite Element Method. Also, concepts that are
generally addressed in more detail during advanced Mechanics course, such as pressure vessels
and failure criteria, can be given the attention necessary for students to fully understand and
apply them in the design process. These chapters will also provide students with the knowledge
necessary to analyze more complex design issues in their projects, such as reducing stress
concentrations at joints.
Chapter Title
11 Torsion
12 Pressure Vessels
13 Stress Equations of Transformation
14 Combined Loading
15 Beam Deflections
16 Failure of Columns
17 Stress Concentrations
18 Failure Criteria
19 Finite Element Method
Table II. Chapters to be added to future editions of Design Analysis of Structural Elements
Computer Tools and Demonstration Experiments
In the past, professors have been restricted to the use of chalk and chalkboards to illustrate
mechanics principles to students. More industrious faculty members were motivated to design
physical demonstrations to augment the crude chalkboard illustrations. While the use of these
demonstrations has substantially improved the student’s visualization of mechanics principles,
the computer has become a far more important tool in the design process which enables students
to not only visualize mechanics, but to also simulate the performance of mechanical designs.
Consequently, a plethora of new computer software has become available for visualizing and
solving mechanics problems. Some examples include: Make Engineering Statics & Dynamics a
Moving Experience [11], Statics & Dynamics Interactive Simulations using Working Model [12],
and Visual Mechanics: Beams and Stress States [13].
Development of Integrated Statics and Strength of Materials Curriculum, Bruck et al
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Computer software is not only used for visualizing mechanics principles, but is also employed as
a tool for solving mechanical design problems. An excellent example of this is the use of Finite
Element Analysis software for analyzing the stress states of structures. Once again, a variety of
computer tools are available to the student for solving mechanics problems. In choosing
appropriate computer tools for the integrated curriculum, it was decided to utilize tools the
students have already been introduced to in their freshman design course. At the University of
Maryland, the students are provided with a spreadsheet package, Excel, and a CAD tool,
Pro/Engineer, that comes with a finite element package, Pro/Mechanica. In the integrated
curriculum, students will be taught to utilize Excel to solve simple mechanics problems, while
Pro/Engineer and Pro/Mechanica will be used on more complex ones. They can then employ
these tools as they choose to perform initial analysis of their design concepts. Verification of the
students design analysis will be provided by experimental measurements on their design models.
In the new integrated curriculum, the aforementioned computer software will be provided to
instructors as a resource for their classroom presentations. In addition, simple demonstration
experiments are also being designed to illustrate mechanics principles such as trusses, cables,
and friction, as well as simple mathematical principles such as three-dimensional vector
orientations. In order to deliver these resources, new interactive, multimedia "Studios" originally
developed at Rensselaer Polytechnic Institute are being built that will replace the traditional
lecture/recitation/lab format [14]. Studios are more cost effective than traditional formats, and
provide an environment in which student performance and satisfaction are high. Not only will
Studios be used for delivering the newly integrated curriculum, but it will also be utilized as
instructional facilities by the freshman design course. The sharing of resources by multiple
courses further extends the seamless integration of the undergraduate curriculum into the
freshman year, while reducing cost and duplication of educational resources.
Computer tools, demonstration experiments, and Studios provide a basis for building an
infrastructure to deliver the integrated curriculum. However, for the infrastructure to be
complete, it is necessary that it be centrally organized and administered. The demands on an
instructor’s time alone in learning to utilize this infrastructure may prevent consistency in the
quality of delivering the new course content when new instructors are used. This dilemma will
necessitate the acquisition of additional support for the infrastructure by designating a faculty
coordinator for overseeing the administration of the course. The coordinator will also be assigned
to organize a team of teaching assistants and teaching fellows to assist students in the application
of the computer tools and in completing their design project. New instructors can then focus
simply on delivering the textbook material and "canned" demonstration experiments. More
instructors will also be employed to reduce class size and provide more individualized attention
to students. This infrastructure has already been developed successfully for the freshman design
course at the University of Maryland and should greatly enhance the delivery of the integrated
curriculum.
Metrics for Evaluating Success of Integrated Curriculum
Many new ideas have been introduced for the integrated statics and strength of materials
curriculum at the University of Maryland. However, the success of the new curriculum is not
Development of Integrated Statics and Strength of Materials Curriculum, Bruck et al
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guaranteed. Therefore, metrics have been proposed to provide a quantitative and qualitative
measure of success.
To measure success, one must first define it. In many cases, this definition can be found in the
philosophy that departments adopt in educating their students. For example, the philosophy of
UMD’s Mechanical Engineering department is to graduate students "... with the skills and the
knowledge base which are necessary for success in today’s marketplace and with the education
necessary to adapt and succeed in the future as technology continues to change." [15] This
philosophy is consistent with ABET’s Engineering Criteria 2000, another source for defining
success. Consequently, one metric developed by the Mechanical Engineering department for the
entire undergraduate curriculum is to provide a student evaluation form where the students
would rate the relevance of each course to the (a) through (k) criteria on a scale from 1 to 5.
Assessment of the curriculum by instructors is also obtained as a baseline for comparison.
The proposed metric was used for a pilot section taught with the new curriculum during the 1998
Fall semester, along with two sections using the old curriculum. Each section was taught by a
different instructor, however instructors collaborated on exam, homework, and even some lecture
preparation. In the case of the new curriculum, it was the opinion of the instructor that criteria
(a) through (h), and (k) would be appropriate (Figure 1). The consensus for the old curriculum
was it addressed only criteria (a), (c), and (e), while touching on criteria (d), (h), (i), and (k)
(Figure 1). Student assessment of the (a) though (k) criteria for the new curriculum mimicked the
instructor’s expectation, and even exceeded those expectations for some of the criteria (Figure 2).
Student confirmation of the instructor’s assessment provides some validation for the integrated
curriculum. However, comparing student assessments of the old and new curriculum indicated
that the new curriculum was only clearly better in addressing criteria (c) and (d), which concern
development of a student’s design and teaming skills (Figure 3). Some of the similarities in the
assessments could be attributed to the aforementioned collaboration, which resulted in students
taking the old curriculum being exposed to demonstration experiments and some unique
applications of mechanics principles, such as in the design of prosthetic devices, which were
developed for the new curriculum.
0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
5
abcdef ghI j k
Professor (Old 1)
Professor (Old 2)
Professor (New)
Figure 1. Comparison of evaluations by professors of the old and new curriculum using the
ABET 2000 (a) through (k) criteria
Development of Integrated Statics and Strength of Materials Curriculum, Bruck et al
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0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
5
abcdefghI j k
Professor (New)
Students (New)
Figure 2. Comparison of professor’s and students’ evaluation of the new curriculum using ABET
2000 (a) through (k) criteria
0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
5
abcde fgh I j k
Students (Old 1)
Students (Old 2)
Students (New)
Figure 3. Comparison of evaluation by students of the old and new curriculum using ABET 2000
(a) through (k) criteria
Not only is the success of the integrated curriculum being gauged by qualitative student
evaluations, but a more quantitative measure is also being developed. This measure will consist
of comparing student performance on identical exams administered to students taking sections of
the new and traditional curriculum during the same semester. This process eliminates many
variables that may otherwise invalidate the metric’s results. However, the variability in instructor
efficacy is not accounted for. To eliminate this variable, the same set of instructors will deliver
both versions of the curriculum over multiple semesters. This should result in a quantitative
measure over a statistically relevant sampling of students. However, initial analysis of student
performance on traditional Statics exams administered during the 1998 Fall semester indicates
very little difference between the old and new curriculum or between the instructors (Figure 4),
mimicking the previous results from student evaluations. Further delineation of the new
Development of Integrated Statics and Strength of Materials Curriculum, Bruck et al
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curriculum’s efficacy may be ascertained by including problems on the exams which address
specific elements of the ABET 2000 criteria not covered by the old curriculum, such as criteria
(c) concerning the design of a system, component, or process to meet desired needs.
.
50
60
70
80
90
100
110
Old curriculum (1st
section) Old curriculum (2nd
section) New curriculum
Exam 1
Exam 2
Figure 4. Comparison of student performance in sections of the old and new curriculum
Conclusions
Statics and strength of materials curriculum are being seamlessly integrated by the Departments
of Mechanical and Civil Engineering at the University of Maryland. The new integrated
curriculum is centered around a simple, but well-developed, design project and enhanced with
demonstration experiments and computer tools delivered in new interactive, multimedia
"Studios". Metrics for success concentrate on comparative evaluation of student performance in
the traditional and integrated versions of the curriculum, as well as student feedback on the
applicability of the curriculum to ABET 2000 criteria. Initial indications are that the new
curriculum is more successful at addressing ABET 2000 criteria concerned with the student’s
development of design and teaming skills without adversely affecting the student’s ability to
solve traditional Statics exam problems.
References
[1] "The Competitive Strength of U.S. Industrial Science and Technology: Strategic Issues", Report of the
National Science Board, August 1992.
[2] "Improving Engineering Design: Design for Competitive Advantage", National Research Council, National
Academy Press, 1991.
Development of Integrated Statics and Strength of Materials Curriculum, Bruck et al
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[3] Tobia, S., "Revitalizing Undergraduate Science", Research Corporation, Tucson, AZ, 1992.
[4] Pister, K.S., "Major Issues in Engineering Education", A Working Paper of the Board on Engineering
Education, National Research Council, Washington, D.C., 1993.
[5] "ABET Engineering Criteria 2000", 3rd Edition, Accreditation Board for Engineering and Technology,
Baltimore, MD, December 1997.
[6] Anand, D.K., Cunniff, P.F., Dally, J.W., Duncan, J.H., Magrab, E.B., Radermacher, R.K., Sirkis, J.S., and
Walston, W.H., "A Mechanical Engineering Curriculum for the Next Decade", 1995 ASEE Annual
Conference Proceedings, Anaheim, CA, 2, 2138-2146, 1995.
[7] Bruck, H.A., Dally, J., Fourney, W., Kiger, K., Albrecht, P., Chang, P., and Zhang, G., Design Analysis of
Structural Elements, College House Enterprises, LLC., 1998.
[8] Pipes, R.B. and Wilson, J.M., "A Multimedia Model for Undergraduate Students", Technology in Society, 18,
387-401, 1996.
[9] Hibbeler, R.C., Statics and Strength of Materials, Prentice Hall, Englewood Cliffs, NJ, 1973.
[10] Riley, W.F., Sturges, L.D., and Morris, D.H., Statics and Mechanics of Materials: An Integrated Approach,
John Wiley & Sons, Inc., New York, 1995.
[11] Gramoll, K., Abbanat, R., and Slater, K., Making Engineering Statics & Dynamics a Moving Experience,
Addison Wesley Interactive, 1996.
[12] Bedford and Fowler, Statics & Dynamics Interactive Simulations using Working Model, Addison Wesley,
1995.
[13] Miller, G.R. and Cooper, S.C., Visual Mechanics: Beams & Stress States, PWS Publishing Co., Boston, MA,
1998.
[14] Wilson, J.M., "The CUPLE Physics Studio", The Physics Teacher, 32, 518, 1994.
[15] Undergraduate Student Guide, Department of Mechanical Engineering, University of Maryland, 1998.
HUGH A. BRUCK
Prof. Bruck is Assistant Professor of Mechanical Engineering in the A. James Clark School of Engineering at the
University of Maryland. He received his B.S. and M.S. degrees in Mechanical Engineering from the University of
South Carolina in 1988 and 1989, completing his Ph.D. in Materials Science at the California Institute of
Technology in 1994. He has previously worked on engineering outreach programs for high school students, in
addition to his research activities in materials characterization and design.
DAVE K. ANAND
Prof. Anand is Professor and Chairman of the Mechanical Engineering Department in the A. James Clark School of
Engineering at the University of Maryland. He received his B.S., M.S., and Ph.D. degrees in Mechanical
Engineering from George Washington University in 1959, 1961 and 1965. He is actively involved in the reform of
undergraduate education and in manufacturing-related research activities.
WILLIAM L. FOURNEY
Prof. Fourney is Professor in the Department of Mechanical Engineering and Chairman of the Aerospace
Engineering Department in the A. James Clark School of Engineering at the University of Maryland. He received
his B.S.A.E. from West Virginia University in 1962, and his M.S. and Ph.D. from the University of Illinois-
Development of Integrated Statics and Strength of Materials Curriculum, Bruck et al
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Urbana/Champaign in 1963 and 1966. His research activities focus on the dynamic behavior of structures and
materials.
PETER C. CHANG
Prof. Chang is Associate Professor of Civil Engineering in the A. James Clark School of Engineering at the
University of Maryland. He received his B.S. in Civil Engineering from Texas A& M University in 1975, and his
M.S. and Ph.D. in Civil Engineering from the University of Illinois in 1979 and 1982 respectively. His research
activities focus on structural mechanics and the control of structures.
JAMES W. DALLY
Prof. Dally is Professor Emeritus of Mechanical Engineering in the A. James Clark School of Engineering at the
University of Maryland. He received his B.S. from the Carnegie Institute of Technology in 1951, and his M.S. and
Ph.D. from the Illinois Institute of Technology in 1953 and 1958. He is a nationally recognized leader in the reform
of Mechanical Engineering education, and has made significant research contributions in the area of Experimental
Mechanics.
