Project-based learning of advanced CAD/CAE tools in engineering education

Berselli, Giovanni; Bilancia, Pietro; Luzi, Luca

doi:10.1007/s12008-020-00687-4

Cited by 32 publications

(21 citation statements)

References 50 publications

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“…Idealized systems are often those that are evaluated in class to teach the basic concepts, but do not allow the students to expand their thinking as much as a more complex, true to life system would. Without limitations of laboratory space or budget for materials, students are able to solidify the basic concepts they learned in class as well as apply their understanding to new situations [4]. In contrast to using software to simulate the purely mechanical, Sert discusses the potential benefits of using computational fluid dynamics (CFD) in undergraduate engineering education.…”

Section: Tfec-2022-40708mentioning

confidence: 99%

Integration of Computational Fluid Dynamics Into an Introductory Fluid Mechanics Course

Wismer

Dosse

Barry

2022

Proceeding of 7th Thermal and Fluids Engineering Conference (TFEC)

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Traditional didactic collegiate thermal-fluid engineering courses, in particular those without a laboratory component, lack the opportunity for experiential learning, among other beneficial aspects of hands-on learning. The process of conducting experiments and comparing results to theoretical predictions provides invaluable educational experiences, of which include but are not limited to the introspective questioning of established paradigms, the conversion of short-term memories into long-term memory recall through practice, and the ability to be actively engaged in learning through partner or group activities. In an attempt to overcome this deficiency, the use of Computational Fluid Dynamics (CFD) software was integrated into a lecture-based junior-level introductory Fluid Mechanics course. The use of ANSYS CFX, a commercially available CFD software, was used to complement the presentation and instruction of the subject of differential description of fluid motion, namely the Navier-Stokes equations. Students used ANSYS CFX to not only generate visualizations of flow and pressure fields, but also to validate analytic solutions for potential and laminar viscous flows for various geometries, boundary conditions, and fluid properties, after a brief introduction to the theory of the Finite Volume Method. Student perceptions on the use of ANSYS CFX toward their learning and engagement were quantified through mixed-method open-and closed-ended survey questions, which were coded and analyzed to provide qualitative and quantitative feedback. The results of the survey are intended to guide the implementation of CFD into a junior-level mechanical engineering course, with an emphasis on increasing student engagement with the material and satisfaction.

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Section: Tfec-2022-40708mentioning

confidence: 99%

Integration of Computational Fluid Dynamics Into an Introductory Fluid Mechanics Course

Wismer

Dosse

Barry

2022

Proceeding of 7th Thermal and Fluids Engineering Conference (TFEC)

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“…Project-based Learning (PBL) has proven to be a very valuable strategy for developing the competencies addressed in learning product development subjects in real work experience (Barbero & García, 2011;Berselli et al, 2020;Pindado et al, 2018). Students can develop a certain product in the scope of a project using the usual tools of the industry in a learning environment.…”

Section: Training New Engineers Using Cax In An Active Learning Environmentmentioning

confidence: 99%

Teaching CAD/CAM/CAE tools with project-based learning in virtual distance education

2021

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Computer-aided design, manufacturing and engineering technologies (CAD/CAM/CAE) are a mainstay in today’s industry and therefore they should be an important part in the current training plan of the graduate engineers. However, their implementation in the university environment presents certain barriers that make it difficult. In this work, we study the feasibility of the teaching proposal of the management of this type of tools through a Project-Based Learning method in a distance learning environment. The methodology has been implemented transversally in two Master’s degree subjects related to advanced design and manufacturing and has been carried out thanks to the operation of the product lifecycle management platform software by virtual machines. The practice has given very good pedagogical results in the work of skills related to the field of industrial design and manufacturing. The virtual system has demonstrated high efficiency and students have shown a satisfactory evolution in their professional training.

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“…As for education, CAD software offers flexibility for students to create and test their designs in various configurations without the need for physical facilities or equipment, which is safer and more cost‐effective [7,24]. Using CAD solutions enable students to model mechanical and mechatronic systems using a base geometry and parametric representations, thus eliminating physical constraints while allowing students to build and see product and process interactions [5].…”

Section: Introductionmentioning

confidence: 99%

Using machine learning to predict engineering technology students’ success with computer‐aided design

Singh

Perera

Magana

et al. 2022

Comp Applic In Engineering

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Computer‐aided design (CAD) programs are essential to engineering as they allow for better designs through low‐cost iterations. While CAD programs are typically taught to undergraduate students as a job skill, such software can also help students learn engineering concepts. A current limitation of CAD programs (even those that are specifically designed for educational purposes) is that they are not capable of providing automated real‐time help to students. To encourage CAD programs to build in assistance to students, we used data generated from students using a free, open‐source CAD software called Aladdin to demonstrate how student data combined with machine learning techniques can predict how well a particular student will perform in a design task. We challenged students to design a house that consumed zero net energy as part of an introductory engineering technology undergraduate course. Using data from 128 students, along with the scikit‐learn Python machine learning library, we tested our models using both total counts of design actions and sequences of design actions as inputs. We found that our models using early design sequence actions are particularly valuable for prediction. Our logistic regression model achieved a >60% chance of predicting if a student would succeed in designing a zero net energy house. Our results suggest that it would be feasible for Aladdin to provide useful feedback to students when they are approximately halfway through their design. Further improvements to these models could lead to earlier predictions and thus provide students feedback sooner to enhance their learning.

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Project-based learning of advanced CAD/CAE tools in engineering education

Cited by 32 publications

References 50 publications

Integration of Computational Fluid Dynamics Into an Introductory Fluid Mechanics Course

Integration of Computational Fluid Dynamics Into an Introductory Fluid Mechanics Course

Teaching CAD/CAM/CAE tools with project-based learning in virtual distance education

Using machine learning to predict engineering technology students’ success with computer‐aided design

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