Effectiveness of involving the industrial and business professions into mechanical engineering capstone course

2017 ◽  
Vol 46 (1) ◽  
pp. 31-40 ◽  
Author(s):  
Na Zhu

Capstone design, along with the last courses before graduation, is one of the major performance indicators of the student outcome in an undergraduate mechanical engineering program. Educational topics on the capstone course, such as the instruction content, course design, procedures, and timeline schedule, have been deliberated by engineering instructors in higher education. Meanwhile, more and more universities started to invite mentorship or advisement from industrial personnel to the capstone design classes as practical experience is also a significant factor in the engineering study. In this article, a senior design course for undergraduate mechanical engineering program is introduced. Collaboration and mentoring by industrial and business professions are offered in the course, though optional for students. As a result, the students in the same capstone course, though got the same lecture classes and follow the same design schedule, can be divided into three different groups: Group 1 worked in traditional design format, Group 2 received mentorship not only from the instructor but also from industrial professions, and Group 3 received help from a business profession. The course and project outcome of the three groups are evaluated by various assessment and results are demonstrated and discussed.

Author(s):  
Patrick Dumond ◽  
Eric Lanteigne

Traditionally, mechanical engineering capstone courses focused on teaching students the application of fundamental engineering theory to complex mechanical designs. Recently, there has been a transition towards experiential learning initiatives, such as prototyping, in engineering design. This paper looks at the relationship between the mechanical engineering design capstone course and a course in product design and development, which provides students with the opportunity to build prototypes of their designs, at the University of Ottawa. The importance of the traditional capstone course is considered and the implications of implementing these designs are examined. Many capstone design projects would require extensive work so that they could be implemented. A large hurdle appears to exist between analytical design and design implementation, and the term time constraints limit the complexity of designs intended for prototyping. In fact, students require many design iterations before they can build full-scale functional prototypes of their design. Therefore, we have observed that simple products work best for teaching design implementation.


2014 ◽  
Vol 1716 ◽  
Author(s):  
Bridget M. Smyser

ABSTRACTThe Capstone Design course in the Department of Mechanical Engineering at Northeastern University requires students to build a physical prototype by the end of the two semester sequence. Although students have long been required to take an introductory materials science course as part of their curriculum, there was concern that materials selection was a weakness in the design process. Beginning in Fall 2011, the CES Edupack materials selection software was introduced into the Capstone Design class. The current work means to investigate: 1) how to assess designs for effective materials selection 2) whether the new software was actually used by the student teams and 3) whether there was evidence of improved materials selection in the projects that occurred after the new software was introduced. Final capstone design reports from 10 previous terms were examined to look for evidence of systematic materials selection procedures and clear discussion of materials properties as the basis for selecting a material. References to the software were also noted. Results show that 24% of the groups used the CES Edupack software in the first three terms that the software was available. In addition, there was an increase in the number of groups that used a systematic selection process based on research into published materials properties rather than choosing materials based on rough experimentation or convenience. Finally, there has been an increase in the number of projects which consider or incorporate composites, high temperature alloys, and advanced polymers as the software has increased awareness of these options.


Author(s):  
W.C.D. DeGagne ◽  
Paul Labossiere

One of the most effective and efficient ways for an engineering program to facilitate compliance with the Canadian Engineering Accreditation Board (CEAB) accreditation criteria is through capstone design projects and courses. Currently, the University of Manitoba Faculty of Engineering has several capstone design courses; however, each is independently focused on its own respective discipline. The resulting educational experience for students, though rigorous and challenging, is maintained within the boundaries of the students’ engineering discipline, thereby neglecting to provide the opportunity for students to work with people from multiple disciplines and across multiple fields. This style/mode of education, where students work in silos, arguably does not reflect real world engineering. Program representatives from the Faculty of Engineering agree. An interdisciplinary capstone course would provide a more rounded engineering education for students. Exposing students to other disciplines and facilitating their learning of the knowledge, skills and behaviours required to work in a multidisciplinary capacity will more effectively prepare students for the real world. Thus, to better comply with CEAB requirements and to increase the breadth and depth of students’ engineering education, an interdisciplinary capstone pilot course will be launched at the University of Manitoba.This paper explains how this multidisciplinary capstone pilot program has been developed, and touches on the early stages of its initiation and implementation.


Author(s):  
Ralph O. Buchal

All engineering programs in Canada must culminate in a significant design experience. This paper describes the capstone design course in the Mechanical Engineering Program at the University of Western Ontario. Self-selected student teams choose from several types of projects: faculty-defined projects, student-defined entrepreneurial projects, student design competitions, and industry-sponsored projects. These choices accommodate a wide range of interests and career goals. The primary sources of project funding are industry sponsorship fees and matching funding through the Ontario Centres of Excellence Connections Program. The majority of project expenses are for parts, materials, prototype construction and testing.


Author(s):  
William C.D. DeGagne ◽  
Paul E. Labossiere

One of the most effective and efficient ways for an engineering program to facilitate compliance with the Canadian Engineering Accreditation Board (CEAB) accreditation criteria is through capstone design projects and courses [2]. Currently, The University of Manitoba Faculty of Engineering has several capstone design courses; however, each is independently focused on its own respective discipline. The resulting educational experience for students, though rigorous and challenging, is maintained within the boundaries of the students’ engineering discipline, thereby neglecting to provide the opportunity for students to work with people from multiple disciplines and across different faculties. This method of education, where students work in isolation, arguably does not reflect real world engineering. Through internal focus group meetings, program representatives from the Faculty of Engineering at The University of Manitoba agree that the capstones should be more reflective of real life situations. Interdisciplinary courses are most important because they “…articulate the difference between educational problems and workplace problems” [1]. Hence, to allow “(students) persons from different disciplines to work collaboratively and are integrated to combine their knowledge to solve a problem” (sic)[4], interdisciplinary capstone courses are essential to a rounded engineering education. Furthermore, teaming with the Faculty of Architecture will provide several benefits for both facilities such as: develop lifelong learning patterns; foster cooperative and collaborative team relationships; and, allow both facilities to learn the other’s cultures and technical languages.Since 2016, The University of Manitoba has presented research papers at the Canadian Engineering and Education Association (CEEA) conferences on the development and future assessment of an interdisciplinary capstone course. These papers have shown the evolution of the course from a multidisciplinary engineering program to an interdisciplinary Engineering and Architectural dual faculty offering. The course was launched in January, 2018, and will be evaluated through the winter session and into the fall.This paper, will explore, define, and explain how the proposed new engineering/architecture interdisciplinary capstone and dual faculty course will be developed, highlight the early stages of its initiation, describe the ongoing implementation, outline how the performance of the new course will be evaluated, delve into how the new course will be improved to make it more meaningful and practical to both faculties and students, and; discover how engagement can improved student learning.


2018 ◽  
Vol 2 (2) ◽  
pp. 14-23
Author(s):  
Mohd Aderi Che Noh ◽  
Normurni Mohamad ◽  
Adibah Hasanah Abd Halim ◽  
Absha Atiah Abu Bakar

This study aims to see the implementation of project based learning methods (PBL) implemented by lecturers in the Science, Technology and Engineering P&P processes in Islam as an effort to enhance students' understanding in the Fiqh Method. Respondents in this study were students of second semester, Diploma of Mechanical Engineering program, Department of Mechanical Engineering, Politeknik Banting. Observation and interview methods are used for data collection purposes. The data were analyzed descriptively and presented in narrative form. The findings show that PBL activity is a fun and enjoyable P&P activity for students. Abstrak Kajian  ini  bertujuan  untuk  melihat  perlaksanaan  kaedah  pembelajaran  berasaskan  projek  (PBL)  yang dilaksanakan  oleh  pensyarah  dalam  proses  P&P Sains,  Teknologi  dan  kejuruteraan  dalam  Islam  sebagai usaha  meningkatkan  kefahaman  pelajar  pelajar  dalam  tajuk  Kaedah Fiqh.  Responden  dalam  kajian  ini adalah   terdiri   daripada   pelajar   semester   dua   progran   Diploma   Kejuruteraan   Mekanikal,   Jabatan Kejuruteraan  Mekanikal,  Politeknik  Banting.  Kaedah  pemerhatian  dan  temu  bual  digunakan  bagi  tujuan pengutipan data. Data dianalisis secara deskriptif dan dipersembahkan dalam bentuk naratif. Dapatan kajian menunjukkan aktiviti PBL merupakan aktiviti P&P yang disukai dan menyeronokkan bagi para pelajar.


Author(s):  
Emad Elnajjar ◽  
S.-A.B. Al Omari ◽  
Farag Omar ◽  
Mohamed YE. Selim ◽  
AHI Mourad

This paper focuses on the Mechanical Engineering Program (MEP) at United Arab Emirates University (UAEU) as a case study in terms of consistent accreditation by the internationally recognized Accreditation Board for Engineering and Technology, Inc. (ABET), where significant proportions of the study give attention towards the recent records of accreditation; granted in 2016. The paper describes the program educational objectives (PEOs), the student learning outcomes (SOs), and the curriculum, direct and indirect assessment tools of the SOs and it’s mapping to the PEO, and the level of attainment achieved is addressed through a case study example.


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