Implementation of the V methodology as the focal point of the development of a pin-on-disk tribometer
Abstract
The process of design involves a series of procedures and decision-making activities. A method is necessary to achieve the highest possible efficiency during this process. Graduates of mechatronic engineering or related fields must learn to design products efficiently to bring increasingly complex systems to the market in minimum time and cost. They must incorporate technological changes into the design process to speed up the results of procedure execution. This article presents the modified and updated V methodology in the documentation and results analysis stages. The Pin-on-Disk Tribometer, created for the Surface Analysis and Tribology Laboratory of the IPN-CICATA Querétaro, serves as an example of the implementation of the V methodology. New evaluation tools and techniques such as 3D printing, computer-aided design, and electronic design automation were incorporated into the design. The system uses a Raspberry Pi 3 B+ and Python development language. Currently, the system is in the registration process, having passed the formal examination evaluated by IMPI through the management of the IPN.
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References
Anton Paar (2018). TRB3: Tribómetro pin-on-disk. disponible en: https://www.anton-paar.com/mx-es/productos/detalles/trb3-pin-on-disk-tribometer/. [Revisado el: 28 de Junio de 2023]
ASTM G 99-17 (2016). Standar Test Method Wear Test. with a Pin-on- Disk Apparatus”, PA Estados Unidos, American Society for Testing and Materials.
Bathelt, Jens, Jönsson, Anders, Bacs, Christian, Dierssen, Stefan and Meier, Markus. (2005). Applying the new VDI design guideline 2206 on mechatronic systems controlled by a PLC. International Conference on Engineering Design. ICED o5 Melbourne. August 15-18, 2005.
Blanco-Ortega, Andrés, Magadán, Andrea, Gómez, Fabio A., Guzmán, Cesar H., y Antúnez, Edgar. (2018). Diseño de sistemas mecatrónicos: prototipos virtuales. Pistas Educativas, No. 130, noviembre 2018, México. Disponible en: https://core.ac.uk/download/pdf/229040955.pdf
Ferreira, A., Cardoso, W., Contador, J. C. Fragomeni, M.A., Goncalves, R.F., Martens, M.L. and Pereira, F.H. (2023). The “V” model for decision analysis of additive manufacturing implementation. Journal of Manufacturing Technology Management Vol. 34 No. 3, 2023 pp. 414-434 DOI: 10.1108/JMTM-10-2022-0377.
Forsberg, K. and Mooz, Harold (1998). System Engineering for Faster, Cheaper, Better. Vol 8, Issue 1. Vancouver, BC Canada. 26-30. https://doi.org/10.1002/j.2334-5837.1998.tb00130.x
Graessler, I., Hentse, J., and Bruckmann, T., (2018). V-Model for Interdisciplinary Systems Engineering. 15th International Design Conference. Serie: Design, pp. 747-756.
Graessler, I. and Bruckmann, T., (2020). The new V-Model of VDI 2206 and its validation. at – Automatisierungstechnik 2020; 68(5): 312–324.
DOI: https://doi.org/10.21278/idc.2018.0333
Lozano E., Mercado-Solís, D., Juarez-Hernandez, A., Hernández-Rodríguez, M.A.L., Garza-Montes-de-Oca, F. (2015). Wear mechanisms experienced by an automotive grade Al-Si-Cu alloy under sliding conditions, Sociedad Mexicana de Ingeniería Mecánica, Tecnoloagía y Desarrollo, Vol.5, No. 3, pp. 339-345, 2015.
MATLAB (2021). System Identification Toolbox. Disponible en: https://es.mathworks.com/products/sysid.html. [Revisado el: 28 de junio de 2023].
Pardo, F. y Boluda J. (2011). VHDL. Lenguaje para síntesis y modelado de circuitos. 3ª edición. Ra-ma, España.
Pelta Resano, Raquel (2013). Tendencias en la teoría y la metodología del diseño. Universitat Oberta de Catalunya. http://hdl.handle.net/10609/75946.
Perez, A., Berreteaga, O., Ruiz de Olano, A., Urkidi, Perez Ikerlan A. J. (2006) Una metodología para el desarrollo de hardware y software embebidos en sistemas críticos de seguridad Sistemas, cibernética e informática. Vol. 3. No 2. 2006. ISSN: 1690-8627.
Pietrusewicz, Krzysztof. (2019). Metamodelling for Design of Mechatronic and Cyber-Physical Systems. Applied Sciences. MDPI. Appl. Sci. 2019, 9, 376; doi:10.3390/app9030376
Sahagún-Angulo, Rubén. (2012). Evolución de los métodos en el Diseño Industrial. Taller Servicio 24 Horas, UAM. ISSN: 2007-8684. Vol. 8, núm. 16, pp. 41-54.
Sosa-Savedra, Julio C., Ortega-González, Rubén., García-Ortega Víctor H., Hernández-Tovar Rubén, y García-García Adrián L. (2020). Desarrollo de competencias en Diseño Digital. XII Taller Internacional Pedagogía de la Educación Superior, Universidad 2020. 14 de febrero de 2020, La Habana, Cuba.
UTS Company (2018). Tribometer T30M-HT. Disponible en: http://www.uts-design.com/index.php?page=urundetay&uid=1. [Revisado el: 28 de junio de 2023].
Vazquez-Santacruz, J.A., Portillo-Velez, R., Torres-Figueroa, J. et al. Towards an integrated design methodology for mechatronic systems. Res Eng Design (2023). https://doi.org/10.1007/s00163-023-00416-4
VDI 2206 (2004). Design methodology for mechatronic systems, 2206, Beuth Verlag, 2004.
Zheng, Chen, Bricogne, Matthieu, Le Duigou, Julien, Eynard, Benoît. (2014). Survey on mechatronic engineering: A focus on design methods and product models. Advanced Engineering Informatics 28 (2014) 241–257. https://doi.org/10.1016/j.aei.2014.0
Copyright (c) 2023 Julio Cesar Sosa-Savedra, Martin Aaron Trejo-Estrella, Adrián Luis García-García, José Dolores Oscar Barceina-Sanchez, Roberto Sostrand Velazquez-Gonzalez, Rubén Hernández-Tovar
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