Combined Mechanical Engineering Materials Lecture and Mechanics of Materials Laboratory: Cross-Disciplinary Teaching

2005 ◽  
Author(s):  
Michael D. Nowak
Keyword(s):  
Biomedical Engineering ◽  
Mechanical Engineering ◽  
Engineering Students ◽  
Soft Tissues ◽  
Materials Science ◽  
Tensile Shear ◽  
Engineering Programs ◽  
Mechanics Of Materials ◽  
Engineering Materials ◽  
Selection Of

We have developed a course combining a Mechanical Engineering Materials Laboratory with a Materials Science lecture for a small combined population of undergraduate Mechanical and Biomedical Engineering students. By judicious selection of topic order, we have been able to utilize one lecture and one laboratory for both Mechanical and Biomedical Engineering students (with limited splitting of groups). The primary reasons for combining the Mechanical and Biomedical students are to reduce faculty load and required resources in a small university. For schools with medium or small Mechanical and Biomedical Engineering programs, class sizes could be improved if they could include other populations. The heterogeneous populations also aid in teaching students that the same engineering techniques are useful in more than a single engineering realm. The laboratory sections begin with the issues common to designing and evaluating mechanical testing, followed by tensile, shear, and torsion evaluation of metals. To introduce composite materials, wood and cement are evaluated. While the Mechanical Engineering students are evaluating impact and strain gauges, the Biomedical Engineering students are performing tensile studies of soft tissues, and compression of long bones. The basic materials lectures (beginning at the atomic level) are in common with both Mechanical and Biomedical student populations, until specific topics such as human body materials are discussed. Three quarters of the term is thus taught on a joint basis, and three or four lectures are split. Basic metal, plastic and wood behavior is common to both groups.

scholarly journals Developing ESP Supplementary Book Based on Project Based Learning Model For Mechanical Engineering Students

2021 ◽  
Vol 5 (2) ◽  
pp. 183-188
Author(s):  
Yuliana Firmanda ◽  
Widiarini Widiarini ◽  
Siti Rofi’ah ◽  
Istina Atul Makrifah
Keyword(s):  
Mechanical Engineering ◽  
Engineering Students ◽  
Process Development ◽  
Learning Model ◽  
Project Based Learning ◽  
English For Specific Purposes ◽  
Research Subject ◽  
Need Analysis ◽  
Engineering Materials ◽  
High Level

This paper aims to develop ESP Supplementary book for mechanical engineering students in high level education. This is a Borg & Gall Research and Development (R&D) by using questionnaire and unstructured interview instrument. The research subject is 20 fourth semester students of mechanical engineering major in UNU Blitar. The limitation of this study is developing ESP supplementary book based PBL with engineering materials as the topic of the book. The process development of Engineering Materials Supplementary Book Based on ESP and PBL consists of some steps those are (1) Need analysis; (2) Product arrangement; (3) Product testing; and (4) Product revision if it is necessary. This research finds that the supplementary book is valid in three aspects of media (77.5%), content (83.3%) and language (83.3%) and feasible to use as supplement material for the mechanical engineering students. Based on the satisfaction questionnaire this product is appropriate for the mechanical engineering students to learn about English for Specific Purposes in form of Project Based Learning model implementation in percentage about 80% agree and 15% very agree.

scholarly journals Self Evaluation for Compliance with the 12 CDIO Standards

2011 ◽  
Author(s):  
George Platanitis ◽  
Remon Pop-Iliev
Keyword(s):  
Mechanical Engineering ◽  
Engineering Students ◽  
Learning Experience ◽  
Value Added ◽  
Engineering Ethics ◽  
Engineering Curriculum ◽  
Engineering Programs ◽  
Practical Applications ◽  
Self Evaluation ◽  
Engineering Program

Throughout the 1980’s and 1990’s, collaboration began between universities, industry, and government to improve the quality and state of engineering education. Their paramount goal was to provide better ways to help students become successful engineers, possessing the necessary technical skills and expertise, exhibiting creativity, and having awareness of social, lawful, ethical, and environmental impacts as related to their profession. Traditionally, engineering programs emphasized the theoretical aspects required, while placing little emphasis on practical applications. An approach that has been introduced to provide a better learning experience for engineering students and to educate them as well-rounded engineers to be able to develop complex, value-added engineering products and processes is the CDIO (Conceive-Design-Implement-Operate) approach. This approach has been adopted by several universities within their engineering departments. At UOIT, the Mechanical Engineering curriculum has been developed around and continually evolves to line up with the goals of CDIO in terms of course and curriculum offerings for core and complementary engineering design courses, science, math, communications, engineering ethics, and humanities courses. Herein, we present an evaluation of the Mechanical Engineering program at UOIT against the twelve CDIO standards.

A novel approach to physiology education for biomedical engineering students

2007 ◽  
Vol 31 (1) ◽  
pp. 45-50 ◽  
Author(s):  
J. DiCecco ◽  
J. Wu ◽  
K. Kuwasawa ◽  
Y. Sun
Keyword(s):  
Rhode Island ◽  
Biomedical Engineering ◽  
Engineering Students ◽  
Engineering Programs ◽  
Anatomy And Physiology ◽  
Novel Approach ◽  
Engineering Department ◽  
Physiology Laboratory ◽  
The University ◽  
Mathematical Curriculum

It is challenging for biomedical engineering programs to incorporate an indepth study of the systemic interdependence of cells, tissues, and organs into the rigorous mathematical curriculum that is the cornerstone of engineering education. To be sure, many biomedical engineering programs require their students to enroll in anatomy and physiology courses. Often, however, these courses tend to provide bulk information with only a modicum of live tissue experimentation. In the Electrical, Computer, and Biomedical Engineering Department of the University of Rhode Island, this issue is addressed to some extent by implementing an experiential physiology laboratory that addresses research in electrophysiology and biomechanics. The two-semester project-based course exposes the students to laboratory skills in dissection, instrumentation, and physiological measurements. In a novel approach to laboratory intensive learning, the course meets on six Sundays throughout the semester for an 8-h laboratory period. At the end of the course, students are required to prepare a two-page conference paper and submit the results to the Northeast Bioengineering Conference (NEBC) for consideration. Students then travel to the conference location to present their work. Since the inception of the course in the fall of 2003, we have collectively submitted 22 papers to the NEBC. This article will discuss the nature of the experimentation, the types of experiments performed, the goals of the course, and the metrics used to determine the success of the students and the research.

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