AN INTRODUCTORY REVERSE ENGINEERING PROJECT TO ENHANCE TEACHING STAFF AND STUDENT COMPETENCE

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AN INTRODUCTORY REVERSE ENGINEERING PROJECT TO ENHANCE TEACHING STAFF AND STUDENT COMPETENCE

A. Butt, X. Foster (2023).  AN INTRODUCTORY REVERSE ENGINEERING PROJECT TO ENHANCE TEACHING STAFF AND STUDENT COMPETENCE. 390-402.
2023 19th International CDIO Conference, NTNU, Norway
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This paper details the development and evolution of a reverse engineering project undertaken by all first-year engineering students at Nottingham Trent University (NTU). The paper elaborates on how the teaching and assessment methods used in the project can be utilised to enhance student as well as teaching staff competence. It is argued that technical staff play a vital role in supporting and delivering project-based learning and are likely to receive more student feedback outside of formal student surveys. Consequently, increased technician involvement in the development of the project is utilised in the hopes of better capturing student learning needs and ensuring students are given a good first introduction to using hand and measurement tools. Simultaneously, delivering such a project requires the staff to learn new tools and acquire relevant skills, thereby enhancing faculty competence. Instead of using multiple, smaller and discipline specific devices reported previously, a single and larger device is reverse engineered across all disciplines for the project at hand. Reverse engineering the same device across disciplines is proposed as a means to move away from engineering silos by unifying the tools used and the skills gained during the project. Furthermore, student feedback and technician perspectives are presented to paint a holistic picture of the delivery of the project from the standpoint of students, technicians and the academic. Finally, recommendations are put forth on how to further improve the delivery of such a project and increase technical staff involvement in an engineering curriculum.

Authors (New): 
Ahmed Tamkin Butt
Xzara Foster
Pages: 
390-402
Affiliations: 
Nottingham Trent University, UK
Keywords: 
Introduction to Engineering
reverse engineering
Engineering Design
CAD
CDIO Standard 1
CDIO Standard 2
CDIO Standard 3
CDIO standard 4
CDIO Standard 5
CDIO Standard 6
CDIO Standard 7
CDIO Standard 8
CDIO Standard 9
CDIO Standard 11
Year: 
2023
Reference: 
Altringer, B., & Habbal, F. (2015). Embedding design thinking in a multidisciplinary engineering curriculum. VentureWell. Proceedings of Open, the Annual Conference. National Collegiate Inventors & Innovators Alliance.: 
Autodesk. (2022). Autodesk Fusion 360. https://www.autodesk.com/products/fusion-360/: 
Brodeur, D. R., & Crawley, E. F. (2005). Program Evaluation Aligned with the CDIO Standards. Proceedings of the 2005 American Society for Engineering Education Annual Conference & Exposition Copyright 2005, American Society for Engineering Education.: 
Butt, A., & Siegkas, P. (2021). Integrated CAD and Reverse Engineering to Enhance Conception and Design. Proceedings of the 17th International CDIO Conference, Hosted Online by Chulalongkorn University & Rajamangala University of Technology Thanyaburi, Bangkok, Thailand, June 21-23, 2021.: 
Chen, C.-H., & Yang, Y.-C. (2019). Revisiting the effects of project-based learning on students’ academic achievement: A meta-analysis investigating moderators. Educational Research Review, 26, 71–81.: 
Deweck, O. L., Kim, Y., Graff, C., Nadir, W., & Bell, A. (2005). Engineering Design and Rapid Prototyping: A Rewarding CAD/CAE/CAM and CDIO Experience for Undergraduates. Proceeding of the 1st Annual CDIO Conference Queen’s University Kingston, Ontario, Canada June 7 to 8, 2005.: 
ebay. (2022). iMars® Motor 49cc Complete Pullstart Engine Quadbike ATV 2 Stroke Bike.: 
Fitzpatrick, J. J., Byrne, E. P., & Fitzpatrick, J. J. (2021, June 14). Non-discipline specific sustainability knowledge and competences in the Chemical Engineering Programme at UCC Non-Discipline Specific Sustainability Knowledge & Competences in the Chemical Engineering Programme at UCC.: 
Flarup, J., & Wivel, H. (2018). Training the Staff-How to Develop Personal and Interpersonal Competencies at Faculty Level. Proceedings of the 14th International CDIO Conference, Kanazawa Institute of Technology, Kanazawa, Japan, June 28 - July 2, 2018.: 
Gadola, M., & Chindamo, D. (2019). Experiential learning in engineering education: The role of student design competitions and a case study. International Journal of Mechanical Engineering Education, 47(1), 3–22.: 
Hmelo-Silver, C. E. (2004). Problem-Based Learning: What and How Do Students Learn? Educational Psychology Review, 16(3), 235–266.: 
Honda. (2022). Honda Engines - GP160. https://www.honda-engines-eu.com/en/products/engines/gp160: 
Hoople, G. D., Mejia, J. A., Chen, D. A., & Lord, S. M. (2018). Reimagining Energy: Deconstructing Traditional Engineering Silos Using Culturally Sustaining Pedagogies. 2018 ASEE Annual Conference & Exposition, Salt Lake City, Utah.: 
Jonassen, D., Strobel, J., & Lee, C. B. (2006). Everyday Problem Solving in Engineering: Lessons for Engineering Educators. Journal of Engineering Education, 95(2), 139–151.: 
Mazini, S. R., Leite, S., Aparecida Vieira De Moraes, P., Maria, M., Baptistella, T., & Ferreira Do Nascimento, R. (2018). The Integration of CDIO Standards in the Application of Project Based Learning as a Hands-On Methodology: An Interdisciplinary Case Study in Production Engineering. Proceedings of the 14th International CDIO Conference, Kanazawa Institute of Technology, Kanazawa, Japan, June 28 – July 2, 2018.: 
Mohedo, M. T. D., & Bújez, A. V. (2014). Project based Teaching as a Didactic Strategy for the Learning and Development of Basic Competences in Future Teachers. Procedia - Social and Behavioral Sciences, 141, 232–236.: 
Ralph, R. (2016). Post-Secondary Project-Based Learning in Science, Technology, Engineering and Mathematics. Journal of Technology and Science Education, 6.: 
Roy, M., & Roy, A. (2021). The Rise of Interdisciplinarity in Engineering Education in the Era of Industry 4.0: Implications for Management Practice. IEEE Engineering Management Review, 49(3), 56–70.: 
Siegkas, P. (2020). Reverse Engineering and Introduction to Engineering Design. Proceedings of the 16th International CDIO Conference, Hosted Online by Chalmers University of Technology, Gothenburg, Sweden, 9-11 June 2020.: 
Suzuki, J., Kawasaki, K., Yajima, K., Chiba, S., Takeshima, H., & Kubota, Y. (2022). Visualizing the Effectiveness of Cross-Course-Typed PBL on Generic Skills. Proceedings of the 18th International CDIO Conference, Hosted by Reykjavik University, Reykjavik Iceland, June 13-15, 2022, 292–301.: 
Thomas, L., & May, H. (2010). Inclusive learning and teaching in higher education. The Higher Education Academy.: 
Tynjälä, P. (1999). Towards expert knowledge? A comparison between a constructivist and a traditional learning environment in the university. International Journal of Educational Research, 31(5), 357–442.: 
Winberg, C. (2021). The Making of Engineering Technicians: Ontological Formation in Laboratory Practice. Engineering Studies, 13(3), 226–248.: 
Yadav, A., Subedi, D., Lundeberg, M. A., & Bunting, C. F. (2011). Problem-based Learning: Influence on Students’ Learning in an Electrical Engineering Course. Journal of Engineering Education, 100(2), 253–280.: 
Yang, Y. (2019). CDIO Implemented Projects in a Computer Aided Design Course. Proceedings of the 15th International CDIO Conference, Aarhus University, Aarhus, Denmark, June 25 – 27, 2019.: 
Zhu, J., Liu, R., Liu, Q., Zheng, T., & Zhang, Z. (2019). Engineering Students’ Epistemological Thinking in the Context of Project-Based Learning. IEEE Transactions on Education, 62(3), 188–198.: 
on November 21, 2023 - 09:01   frebyst
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