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Dwivedi, Ayush
- Student Voice in Transformation from Studying Engineering to Doing Engineering
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1 Department of Electronics and Communication Engineering, Hyderabad Institute of Technology and Management (HITAM), Gowdavelly(V), Medchal(M), Hyderabad-500048, IN
1 Department of Electronics and Communication Engineering, Hyderabad Institute of Technology and Management (HITAM), Gowdavelly(V), Medchal(M), Hyderabad-500048, IN
Source
Journal of Engineering Education Transformations, Vol 29, No Spl Iss (2016), Pagination:Abstract
In the current trend of engineering education we have suddenly reached a point where it has become a certificatethat veryfew engineerswould recommend you to take. This is more of a case for engineering students from private colleges.To tackle this issue in our college the senior students decided along with the faculty to introduce a few good practices among the freshers. The objective was to give the students an overview of doing engineering practically, that included ways to create active and practical environment to do engineering and how engineering should be learnt best. These ideas were collected from various student groups and implemented in a short 1 day workshop on "Doing Engineering" in two batches. Student role was a major factor in this workshop as they were supposed to voice their opinion, think, create, design, implement and finally build the chair after completion of the workshop.Instructor's major role was to guide the students on the basics of designing a chair and pointing out the realistic side of the real time application of the results. These small tasks were introduced as steps for transformation in the current rat race for getting more than just an engineering certificate by involving students for making projects in the first year itself instead of waiting for 3rd and 4th year. This task had some smaller objectives too that included the following but were not limited to them: project based learning, induce creativity, technical understanding, practical skills, thinking beyond the present what eyes can see and the ability to question established facts and norms.Keywords
Doing Engineering, Project Based Learning, Practical Learning, Active Learning, Studying Engineering.- Computational Solvers for Iterative Hydraulic Loss Calculations in Pipe Systems
Abstract Views :147 |
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Authors
Affiliations
1 Department of Mechanical Engineering, School of Engineering, University of Petroleum and Energy Studies, Bidholi, Dehradun, Uttarakhand, 248007, IN
1 Department of Mechanical Engineering, School of Engineering, University of Petroleum and Energy Studies, Bidholi, Dehradun, Uttarakhand, 248007, IN
Source
Journal of Engineering Education Transformations, Vol 35, No 4 (2022), Pagination: 72-84Abstract
The study of fluid mechanics spans several engineering disciplines including Mechanical, Civil, Aerospace, Chemical, Environmental, Petroleum, and Biomedical Engineering. In all these disciplines, hydraulic loss calculations in pipes are extremely important. However, the iterative nature of the solution to these engineering problems makes it intricate and cumbersome to solve. Further, it gets very difficult to visualize the solutions to such iterative problems for a wide variety of cases. The current paper aims to bridge this gap by the creation of two open-source Excel-VBA based computational solvers. The first tool corresponds to the determination of the Darcy-Weisbach friction factor through the Colebrook Equation and its visualization on a Moody's chart, which can be effectively employed by engineering instructors as an active learning tool. Second, a complete tool covering all four kinds of pipe flow situations (including the iterative problems) has been developed. The developed computational tools were employed in an undergraduate Fluid Mechanics classroom and the detailed student responses were collected on ten aspects related to teaching and learning divided broadly under four categories – 'overall rating', 'student perceptions on self-learning', 'Improvement in teaching delivery', and 'recommendation for other courses'. The data collected from student responses were subjected to statistical analysis. The results of hypothesis testing and the p-value calculations clearly justify the immense usefulness of this tool in the improvement of the overall teaching-learning process of Fluid Mechanics. Finally, the developed computational tools are being hosted free on the web for the benefit of engineering instructors, learners and professionals alike.Keywords
Pipe Losses, Computational Tool, Fluid Mechanics, Hydraulic Loss, Moody's Chart, Excel VBA.References
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- Elegant Computational Frameworks For the Analysis of Cantilevers and Beams
Abstract Views :51 |
PDF Views:1
Authors
Affiliations
1 Department of Mechanical Engineering, School of Engineering, UPES Dehradun, Uttarakhand, 248007, IN
1 Department of Mechanical Engineering, School of Engineering, UPES Dehradun, Uttarakhand, 248007, IN
Source
Journal of Engineering Education Transformations, Vol 37, No 1 (2023), Pagination: 89-97Abstract
In various fields like automobiles, construction, etc., the structural analysis of each component or sub-system must be done to ensure its safe operation. The structural analysis of these components entails the determination of parameters like shear force, bending moment at different locations. Usually, such computations are cumbersome, and hence a simplified approach is adopted, that involves drawing shear force diagram (SFD) and bending moment diagram (BMD) for the components. These diagrams can be effectively utilized to determine the dimensions of the components, select the appropriate material for the structure etc. Also, by utilizing the values of maximum shear force and bending moments, the maximum deflection in a beam or other structure can be ascertained. However, the process of drawing these diagrams is cumbrous and involves a lot of meticulous effort and time, which sometime poses a challenge in the effective teaching and learning of these concepts. The current paper reports the development of computational tools using the excel VBA platform and its implementation in the pedagogy of an undergraduate solid mechanics classroom. The developed tools can be easily employed to instantaneously draw the SFD and BMD diagrams for the beam under a variety of loading conditions, facilitating the inference-based learning of cantilevers and beams. Two distinct tools were developed, one for drawing the SFD and BMD of both cantilever and simply supported beams, and another one to determine the deflection and slope in the same two beams. The tools reported in the current manuscript can be effectively utilized for teaching by the demonstration of parametric variations under various loading conditions, for improved comprehension of the concepts and self-learning as well as in real world engineering to get preliminary design guidelines. Upon the development of these computational tools, these have been introduced to undergraduate mechanical engineering class of a sizable population and student responses regarding the efficacy of such tools in aiding the learning process has been recorded through an anonymous feedback. The subsequent hypothesis testing and obtained p-values strongly justify the extreme usefulness of the tools, both as a teaching and learning strategy.Keywords
SFD, BMD, cantilever beam, simply supported beam, computational tool, Excel VBAReferences
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- Dwivedi, A., Sawant, G., & Karn, A. (2022b). Computational Solvers for Iterative Hydraulic loss Calculations in Pipe Systems. Journal of Engineering Education Transformations 35(4).
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