New Approach for the Teaching of Concrete Compression Tests in Large Groups of Engineering Students
Publication: Journal of Professional Issues in Engineering Education and Practice
Volume 143, Issue 2
Abstract
This paper presents a teaching approach aiming to give students the chance of applying theoretical concepts in virtual environments, thereby overcoming limitations in overcrowded classes or in large groups of engineering undergraduates using available testing equipment. The proposed approach deals with enhancing self-learning of one of the most common tests used in materials engineering and/or civil engineering, namely, the compression test of concrete samples. To achieve this goal, two didactic-propose computational tools were developed: a virtual laboratory (VL) and video tutorials (VTs). Furthermore, two different teaching/learning experiences are compared in this paper: (1) using actual laboratory after using both virtual environments (VL and VTs); and (2) using only virtual environments. In both cases the use of these virtual tools improves the student learning outcomes, especially when these resources fulfill a lack of real equipment. Besides, the results of survey questions show the high motivation that virtual environments awake, and the assessment results reflect an increase in the students’ marks.
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References
Achuthan, K., and Murali, S. (2015). “A comparative study of educational laboratories from cost & learning effectiveness perspective.” Software engineering in intelligent systems, Springer, Cham, Switzerland, 143–153.
Anderson, J. R., Greeno, J. G., Reder, L. M., and Simon, H. A. (2000). “Perspectives on learning, thinking, and activity.” Educ. Res., 29(4), 11–13.
Buttcher, P. G. (1986). “Computing aspects of interactive video.” Comput. Educ., 10(1), 1–10.
Chen, K. C., et al. (2009). “Creating a project-based curriculum in materials engineering.” J. Mater. Educ., 31(1-2), 37–44.
Chika, I. E., Azzi, D., Stocker, J., and Haynes, B. P. (2008). “Genuine lab experiences for students in resource constrained environments: The real lab with integrated intelligent assessment.” IEEE Multidiscip. Eng. Educ. Mag., 3(4), 112–119.
Collazos, C. A., et al. (2007). “Evaluating collaborative learning processes using system-based measurement.” Educ. Tech. Soc. J., 10(3), 257–274.
Crook, A., et al. (2012). “The use of video technology for providing feedback to students: Can it enhance the feedback experience for staff and students?” Comput. Educ., 58(1), 386–396.
Dobrzański, L. A., Jagiełło, A., and Honysz, R. (2008). “Virtual tensile test machine as an example of material science virtual laboratory post.” J. Achiev. Mater. Manuf. Eng., 27(2), 207–210.
Dobrzański, L. A., and Honysz, R. (2009). “On the implementation of virtual machines in computer aided education.” J. Mater. Educ., 31(1–2), 131–140.
European Standard. (2013). “Testing hardened concrete. Part 1: Shape, dimensions and other requirements for specimens and moulds.” UNE-EN 12390-1, Madrid, Spain.
Forcael, E., Glagola, C., and González, V. (2012). “Incorporation of computer simulations into teaching linear scheduling techniques.” J. Prof. Issues Eng. Educ. Pract., 21–30.
Foss, B. A., and Eikaas, T. I. (2006). “Game play in engineering education—Concept and experimental results.” Int. J. Eng. Educ., 22(5), 1043–1052.
García, J., and Entrialgo, J. (2015). “Using computer virtualization and software tools to implement a low cost laboratory for the teaching of storage area networks.” Comput. Appl. Eng. Educ., 23(5), 715–723.
Gerson, B. P., Sorby, S. A., Wysocki, A., and Baartmans, B. J. (2001). “The development and assessment of multimedia software for improving 3-D spatial visualization skills.” Comput. Appl. Eng. Educ., 9(2), 105–113.
Gokhale, A. A. (1995). “Collaborative learning enhances critical thinking.” J. Tech. Educ., 7(1), 22–30.
Goodhew, P. J. (2002). “Programas interactivos (software) para la enseñanza de materiales.” J. Mater. Educ., 24(1–3), 39–44.
Hashemi, J., Chandrashekar, N., and Anderson, E. E. (2006). “Design and development of an interactive web-based environment for measurement of hardness in metals: A distance learning tool.” Int. J. Eng. Educ., 22(5), 993–1002.
Hilfert, T., and König, M. (2016). “Low-cost virtual reality environment for engineering and construction.” Visualization Eng., 4(2), 1–18.
Kang, S., Chan, Y., Lu, C., Lai, J., and Lee, T. (2013). “Development of virtual equipment: Case study of the Venturi tube experiment.” J. Prof. Issues Eng. Educ. Pract., 281–289.
Koretsky, M., Kelly, C., and Gummer, E. (2011). “Student perceptions of learning in the laboratory: Comparison of industrially situated virtual laboratories to capstone physical laboratories.” J. Eng. Educ., 100(3), 540–573.
Mosterman, P. J., et al. (1994). “Virtual engineering laboratories: Design and experiments.” J. Eng. Educ., 83(3), 279–285.
Nicolson, R. I., Syder, D., and Freeman, M. (1994). “Construction of a visual (video-supported active learning) resource.” Comput. Educ., 22(1/2), 91–97.
Palmer, S. (2007). “An evaluation of streaming digital video resources in on- and off-campus engineering management education.” Comput. Educ., 49(2), 297–308.
Park, C., Le, Q., Pedro, A., and Lim, C. (2015). “Interactive building anatomy modeling for experiential building construction education.” J. Prof. Issues Eng. Educ. Pract., 04015019.
Perdukova, D., and Fedor, P. (2013). “Virtual laboratory for the study of technological process automation.” Int. J. Eng. Educ., 29(1), 230–238.
Quest 3D Power v.4 [Computer software]. Act-3D B.V., Warmond, Netherlands.
Reynolds, P. A., and Mason, R. (2002). “On-line video media for continuing professional development in dentistry.” Comput. Educ., 39(1), 65–98.
Smith, K. A. (1996). “Cooperative learning: Making ‘groupwork’ work.” New Direct. Teach. Learn., 67, 71–82.
Tori, R., Nakamura, R., Nunes, F. L. S., Bernardes, J. L., Ferreira, M. A. G. V., and Ranzini, E. (2011). “Interlab: Interactive technologies laboratory.” SBC J. 3D Interact. Syst., 2(2), 94–97.
Ullman, K. M., and Sorby, S. A. (1995). “Enhancing the visualization skills of engineering students through computer modeling.” Comput. Appl. Eng. Educ., 3(4), 251–258.
Venter, C., and Coetzee, J. (2011). “Interactive learning through gaming simulation in an integrated land use-transportation planning course.” J. Prof. Issues Eng. Educ. Pract., 04013003.
Vergara, D., Lorenzo, M., and Rubio, M. P. (2015a). “Virtual environments in materials science and engineering: The students’ opinion.” Handbook of research on recent developments in materials science and corrosion engineering education, H. Lim, ed., IGI Global, Hershey, PA, 148–165.
Vergara, D., and Rubio, M. P. (2012). “Active methodologies through interdisciplinary teaching links: Industrial radiography and technical drawing.” J. Mater. Educ., 34(5–6), 175–186.
Vergara, D., and Rubio, M. P. (2015). “The application of didactic virtual tools in the instruction of industrial radiography.” J. Mater. Educ. 37(1–2), 17–26.
Vergara, D., Rubio, M. P., and Lorenzo, M. (2012). “New computer teaching tool for improving students’ spatial abilities in continuum mechanics.” IEEE Tech. Eng. Educ., 7(4), 44–48.
Vergara, D., Rubio, M. P., and Lorenzo, M. (2014). “Interactive virtual platform for simulating a concrete compression test.” Key Eng. Mater., 572, 582–585.
Vergara, D., Rubio, M. P., and Lorenzo, M. (2015b). “A virtual environment for enhancing the understanding of ternary phase diagrams.” J. Mater. Educ., 37(3–4), 93–102.
Vergara, D., Rubio, M. P., and Lorenzo, M. (2015c). “Multidisciplinary methodology for improving students’ spatial abilities in technical drawing.” Sci. J. Educ. Tech., 5(1), 1–8.
Vergara, D., Rubio, M. P., Prieto, F., and Lorenzo, M. (2016). “Enhancing the teaching/learning of materials mechanical characterization by using virtual reality.” J. Mater. Educ., 38(3–4), in press.
Wei, C. S., and Ismail, Z. (2010). “Peer interactions in computer-supported collaborative learning using dynamic mathematics software.” Proc. Soc. Behav. Sci., 8, 600–608.
Wells, J., Barry, R. M., and Spence, A. (2012). “Using video tutorials as a carrot-and-stick approach to learning.” IEEE Trans. Educ., 55(4), 453–458.
Yang, S., and Lu, T. (2007). “T3 SOC design flow case study: Design a video processing pipeline.” Proc., IEEE Int. Conf. on ASIC, IEEE, New York.
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Information
Published In
Journal of Professional Issues in Engineering Education and Practice
Volume 143 • Issue 2 • April 2017
Copyright
© 2016 American Society of Civil Engineers.
History
Received: Mar 29, 2016
Accepted: Aug 4, 2016
Published online: Sep 16, 2016
Discussion open until: Feb 16, 2017
Published in print: Apr 1, 2017
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