Estudio bibliométrico y prospectivo de la ingeniería industrial en América Latina: una revisión de la literatura y futuras tendencias
Palabras clave:
ingeniería industrial, estudio bibliométrico, futuras tendencias, américa latina
Resumen
En un mundo globalizado con economías aceleradas, el contexto empresarial y universitario debe incursionar en la búsqueda de nuevas metodologías que permitan mejorar y estar a la vanguardia del contexto internacional. En este sentido, el objetivo de este artículo es analizar la evolución y tendencias de la ingeniería industrial en America Latina, a través de un estudio bibliométrico y prospectivo. La investigación está basada en mecanismos exploratorios de fuentes bibliográficas y revisión de la literatura sobre la disciplina. La metodología planteada se basa en tres etapas fundamentales (i) Estudio bibliométrico, (ii) Revisión de la literatura y (iii) Futuras tendencias. Entre los resultados obtenidos se encontró que la ingeniería industrial es una disciplina predominante en el tiempo, con alto auge investigativo en América latina. Se concluye que presenta un escenario habilitador hacia futuras tendencias, considerando la aplicación de tecnologías avanzadas y metodologías modernas, con aplicabilidad en las universidades e industrias.
Citas
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Vidal, G. H., and Vega, J. C. H. (2016). Modelo de referencia operacional aplicado a una empresa de servicios de mantenimiento. Revista Venezolana de Gerencia, 21(75), 549-571.
Billings, C., Junguzza, J., Poirier, D., and Saeed, S. (2001). The Role and Career of the Industrial. Engineer in the Modern Organization. In Maynard’s Industrial Engineering Handbook, K. B. Zandin, Ed., 5th Ed New York: McGraw Hill.
Caro, A. and Navarro, W. (2010). Estado del arte del área problemica de operaciones y logística en programas de ingeniería industrial en Colombia. Monografía de grado (ingeniería industrial). Santa Marta, Colombia: Universidad del Magdalena.
Carvalho, N., Chaim, O., Cazarini, E., and Gerolamo, M. (2018). Manufacturing in the fourth industrial revolution: A positive prospect in sustainable manufacturing. Procedia Manufact, 21, 671–678.
Chen, C., Jiang, B., and Hsu, K. (2005). An empirical study of industrial engineering and management curriculum reform in fostering students creativity. European Journal of Engineering Education, 30(2), 191-202.
COIIAOC (2015). Los ingenieros industriales opinan: ‘El futuro de la ingeniería’
Conference on Systems Science, (2016). January 5–8, Maui, Hawaii. https://doi.org/10.1109/HICSS.2016.488
Cropley, D. and Cropley, A. (2000). Fostering creativity in engineering undergraduates. High Ability Studies, 11, 207–219.
Da Rosa, R., Alberti, A. and Singh, M. (2020). Blockchain Technology for Industry 4.0. Ed. Springer, Singapore. http://doi.org/10.1007/978-981-15-1137-0
Dastkhan, H., and Owlia, M. (2009). Study of trends and perspectives of industrial engineering research. South African Journal of Industrial Engineering, 20(1), 1-12.
Elsayed, E. (1999). Industrial engineering education: A prospective. European journal of engineering education, 24(4), 415-421.
Engelman, R. (2015). The second industrial revolution, 1870–1914. https://ushistoryscene.com/author/ryan-engelman-2/.
Feng, S., Li, L., and Cen. L. (2001). An Object-oriented Intelligent Design Tool to Aid the Design of Manufacturing Systems. Knowledge-Based Systems, 14(5), 225–232. https://doi.org/10.1016/S0950-7051(01)001009 .
Feorene, O. (1982). Organization and Administration of Industrial Engineering. In Handbook of Industrial Engineering, G. Salvendy, Editor, John Wiley & Sons, New York. 1982.
France: Industrie du Futur “Digital transformation monitor” (2012). http://ec.europa.eu/growth/toolsdatabases/dem/monitor/sites/default/files/DTM_Industrie%20du%20Futur%20v1.pdf
Grimson, J. (2002). Re-engineering the curriculum for the 21st century. Eur. J. Eng. Educ., 27, 31–37.
Hermann, M., Pentek, T. and Otto, B. (2016). Design Principles for Industrie 4.0 Scenarios. Proceedings of 2016-49th Hawaii International
Herrera, G., Carrillo, M., and Hernandez, B. (2019). Aplicación de la Metodología 5’S para la Mejora de la Productividad en el Sector Metalmecánico de Cartagena (Colombia). Revista Espacio, 40(11), 30.
Hicks, P. (1994). Industrial Engineering and Management. McGrawHill.
Howard, E. (2018). The evolution of the industrial ages: Industry 1.0 to 4.0. http://www.simio.com/blog/2018/09/05/evolution-industrial-ages-industry-1-0-4-0/
Ibarra-Balderas, V. y Ballesteros-Medina, L. (2017). Manufactura Esbelta. Conciencia Tecnológica, (53).
IIE-Ireland Industrial Engineering Standards in Europe (IESE). (2012). [Digital pdf Report]. http://www.iieireland.net/#/iesereport/4570401227
Industrial Internet Consortium. (2017). The industrial internet of things. http://www.iiconsortium.org/IIC_PUB_G1_V1.80_2017-01-31.pdf
Industry Innovation Movement 3.0. (2014). Ministry of trade, industry and Energy. http://english.motie.go.kr/en/tp/alltopics/bbs/bbsView.do?bbs_cd_n=3&bbs_seq_n=7
Jasperneite, J. (2012). Was Hinter Begriffen Wie Industrie 4.0 Steckt. Computer & Automatio, 12, 24–28.
Kagermann, H., Wahlster, W. and Helbig, J. (2013). Recommendations for Implementing the Strategic Initiative Industrie 4.0: Final Report of the Industrie 4.0 Working Group. Acatech-National Academy of Science and Engineering, Germany.
Kuo, W. and Deuermeyer, B., (1998). The IE curriculum revisited: the development of a new undergraduate program in industrial engineering at Texas A&M University. IIE Solutions, 30, 26–22.
Lima, R., Mesquita, D., Amorim, M., Jonker, G. and Flores, M. (2012). An Analysis of Knowledge Areas in Industrial Engineering and Management Curriculum. International Journal of Industrial Engineering and Management, 3, 75-82.
Mesquita, D., Lima, R., Flores, M., Marinho C., and Rabelo, M. (2015). Industrial engineering and management curriculum profile: developing a framework of competences. Mesquita, (32)
Moeuf, A., Pellerin, R. Lamouri, S. Tamayo-Giraldo, S. and Barbaray, R. (2017). The Industrial Management of SMEs in the Era of Industry 4.0. International Journal of Production Research. https://doi.org/10.1080/00207543.2017.1372647
National Research Council (US). (1985). Committee on the Education, & Utilization of the Engineer. Engineering Education and Practice in the United States: Foundations of our techno-economic future. National Academies Press.
Organización de las Naciones Unidas para el Desarrollo Industrial (ONUDI), (2015). Informe sobre el Desarrollo Industrial 2016. El rol de la tecnología y la innovación en el desarrollo industrial inclusivo y sostenible.
Paté-Cornell, E. (2001a). Management of post-industrial systems: Academic challenge and the Stanford experience. Int. J. Techno., Policy Manag., 151–159.
Paté-Cornell, E. (2001b). Managing technology in the information age: Stanford’s new department of management science and engineering. Int. J. Techno., Policy Manag., 160–172.
Phillips, D. (1989). Operations Research and Ergonomics Human Factors Form Scientific Roots of IE. Industrial Engineering, 21(4), 42-45.
Rojko, A. (2017). Industry 4.0 concept: background and overview. Int. Journal Interact Mob Technol, 11(5), 77–90. http://doi.org/10.3991/ijim.v11i5.7072.
Romero, O., Muñoz, D., and Romero, S. (2006). Introducción a la ingeniería, un enfoque industrial. Thomson Editores.
Salvendy, G. (2001). Handbook of industrial engineering: technology and operations management. Ed. John Wiley & Sons.
Schwab, K. (2017). The fourth industrial revolution. Crown Publishing Group.
Smart Industry in Korea (2015). A speech report by Jeong Eun Ha, officer for innovation, technology & science in the embassy of the Netherlands. http://www.rvo.nl/sites/default/files/2015/10/Smart%20Industry%20in%20Korea.pdf
Stern, D. and Kander, A. (2012). The role of energy in the industrial revolution and modern economic growth. Energy Journal, 33(3), 25–152. http://doi.org/10.5547/01956574.33.3.5
Taylor, F. (1947). Scientific Management, Comprising Shop Management. Harper & Row.
Tomory, L. (2016). Technology in the British industrial revolution. Hist Compass, 14(4), 152–167.
Two Centuries of Revolutionary Change (n.d.). The open door web site. https://www.saburchill.com/history/chapters/IR/014.html
Vásquez, F. (2015). Tendencias de la Ingeniería Industrial. Revista académica e institucional de la UCPR, 97, 93-108.
Vega, M. (2001). The Purpose and Evolution of Industrial Engineering. K. B. Zandin. In Maynard’s Industrial Engineering Handbook, McGraw Hill.
Vidal, G. H., and Vega, J. C. H. (2016). Modelo de referencia operacional aplicado a una empresa de servicios de mantenimiento. Revista Venezolana de Gerencia, 21(75), 549-571.
Publicado
2020-12-01
Cómo citar
Herrera Vidal, G., Carrillo Landazábal, M. S., & Cohen Padilla, H. E. (2020). Estudio bibliométrico y prospectivo de la ingeniería industrial en América Latina: una revisión de la literatura y futuras tendencias. Revista Venezolana De Gerencia, 25(4), 421-438. Recuperado a partir de https://www.produccioncientificaluz.org/index.php/rvg/article/view/35200
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