Método estructurado para el ajuste de las variables críticas en la línea de laminación continua en poliéster reforzado con fibra de vidrio

Arévalo Cervantes, Luis Daniel

dc.contributor.advisor	Paipa Galeano, Luis Alfredo
dc.contributor.author	Arévalo Cervantes, Luis Daniel
dc.date.accessioned	2024-03-19T13:42:44Z
dc.date.available	2024-03-19T13:42:44Z
dc.date.issued	2023-10-23
dc.identifier.uri	http://hdl.handle.net/10818/59498
dc.description	80 páginas	es_CO
dc.description.abstract	La competitividad en la industria requiere que las compañías implementen metodologías vigentes que conectan tres ejes centrales: la eficacia, la eficiencia y el mejoramiento continuo. Para este caso se plantea el diseño de un método que permita a la compañía incrementar la productividad de su línea de fabricación de cubiertas en poliéster reforzado con fibra de vidrio. Para este fin se utilizarán metodologías que permitan identificar la estabilidad del proceso y su grado de estandarización, así como las variables críticas de éxito, logrando establecer el método estructurado que armonice las decisiones en el ajuste inicial de los equipos y durante el proceso productivo.	es_CO
dc.description.abstract	Competitiveness in the industry requires that companies implement current methodologies that connect three central axes: effectiveness, efficiency, and continuous improvement. In this case, we propose the design of a method that allows the company to increase the productivity of its Fiberglass reinforced plastic roofing manufacturing line. For this purpose, methodologies will used to identify the stability of the process and its degree of standardization, as well as the critical variables of success, establishing a structured method that harmonizes the decisions in the initial adjustment of the equipment and during the production process.	en
dc.format	application/pdf	es_CO
dc.language.iso	spa	es_CO
dc.publisher	Universidad de La Sabana	es_CO
dc.rights	Attribution-NonCommercial-NoDerivatives 4.0 Internacional	*
dc.rights.uri	http://creativecommons.org/licenses/by-nc-nd/4.0/	*
dc.subject.other	Manufactura esbelta
dc.title	Método estructurado para el ajuste de las variables críticas en la línea de laminación continua en poliéster reforzado con fibra de vidrio	es_CO
dc.type	master thesis	es_CO
dc.type.hasVersion	publishedVersion	es_CO
dc.rights.accessRights	openAccess	es_CO
dc.subject.armarc	Toma de decisiones
dc.subject.armarc	Procesos de manufactura -- Innovaciones tecnológicas
dc.subject.armarc	Control total de calidad
dcterms.references	Alpa Tapan Bhatt, ,. P. (2018). Primary Manufacturing Processes for Fiber Reinforced, History, Development & Future Research Trends. Materials Science and Engineering, 330.
dcterms.references	Anderssson, R., Eriksson, H., & Tortensson, H. (2006). Similarities and Differences between TQM, Six Sigma and Lean. The TQM Magazine, 18, 282-296.
dcterms.references	Antil, P. S. (2019). Metaheuristic approach in machinability evaluation of silicon carbide particle/glass fiber–reinforced polymer matrix composites during electrochemical discharge machining process. Measurement and Control (United Kingdom), 52 7-8.
dcterms.references	Antonio Blázquez, J. J. (2018). A PROCEDURE FOR THE ESTIMATION OF THE SHAPE. ECCM18 - 18th European Conference on Composite Materials. Athens, Greece.
dcterms.references	Antony, J. (2006). Six-sigma for service processes. Business Process Management Journal, 12(2) 234- 248
dcterms.references	Baghel, N. B. (2005). An overview of continuous. Management Decision. https://doi.org/10.1108/00251740510597761
dcterms.references	Barraza, M. F. (2007). LA SOSTENIBILIDAD DE LA MEJORA CONTINUA DE PROCESOS EN LA ADMINISTRACIÓN PÚBLICA UN ESTUDIO EN LOS AYUNTAMIENTOS DE ESPAÑA.
dcterms.references	Bateman, N. (2002). Process improvement programmes: a model for assessing sustainability. International Journal of Operations & Production Management.
dcterms.references	Besterfield, D. (2009). Control de calidad. México: pearson educacion
dcterms.references	Bothe, D. R. (2002). Statistical Reason for the 1.5 <i>σ</i> Shift. Quality Engineering, 14(3), 479–487. https://doi.org/10.1081/qen-120001884
dcterms.references	Celaya, C. (2005). Evaluación de la implantación del sistema de análisis de peligros y puntos de control crítico (APPCC) en las pequeñas industrias alimentarias de la Comunidad de Madrid. Universidad Complutense de Madrid .
dcterms.references	Che, J. (2018). Relative analysis of the dependency of spectrophotometric data. Wiley
dcterms.references	Cheng-Ho Chen, J.-J. W.-S. (2012). Application of a UV curable hard coating containing j-aluminum oxide particles. SciVerse ScienceDirect.
dcterms.references	Crosby, P. (1980). Quality is Free: The Art of Making Quality Certain. New American Library
dcterms.references	Davenport, T. H. (1993). Process Innovation: Reengineering Work Through Information Technology. Harvard Business School Press
dcterms.references	Dean, J. W. (1994). Management Theory and Total Quality: Improving Research and Practice through Theory Development. The Academy of Management Review. https://doi.org/10.2307/258933
dcterms.references	Deming, W. (2000). Out of the Crisis. The MIT Press
dcterms.references	Dinis-Carvalho, J. R. (2016). Performance enhancing in the manufacturing industry: An improvement KATA application. Paper presented at the IEEE International Conference on Industrial Engineering and Engineering Management, (págs. 1250-1254).
dcterms.references	Edge, M. D. (2019). Statistical Thinking from Scractch. Oxford: Oxford University Press is a department of the University of Oxford.
dcterms.references	EL-Khalil, R., Leffakis, Z., & Hong, P. (2020). Impact of improvement tools on standardization and stability goal practices : An empirical examination of US automotive firms. Journal of Manufacturing Technology Management, 705-723
dcterms.references	EXIPLAST S.A.S. (2021). Informe Pareto de Causas Defectos 1H 2021 MPC. Bogotá.
dcterms.references	Farris, J. A. (2008). Learning from Less Successful Kaizen Events. Engineering Management Journal, 10–20.
dcterms.references	Farris, J. A. (2008). Learning from Less Successful Kaizen Events. Engineering Management Journal, 10–20.
dcterms.references	Feigenbaum, A. (1991). Total Quality Control. McGraw-Hill.
dcterms.references	Feng, X. Z. (2020). Simulation optimization framework for online deployment and adjustment of reconfigurable machines in job shops. aper presented at the IEEE International Conference on Industrial Engineering and Engineering Management, 20
dcterms.references	Fernández, S. V. (2016). Criticality of response time in the usage of metaheuristics in industry. Paper presented at the GECCO 2016 Companion Proceedings of the 2016 Genetic and Evolutionary Computation Conference, 937-940
dcterms.references	Galetto, F. F. (2002). Asymptotic defectiveness of manufacturing plants: An estimate based on process learning curves. International Journal of Production Research, 40:3, 537-545. https://doi.org/10.1080/00207540110090948
dcterms.references	Gastelum-Acosta, C. L.-R.-L.-C. (2022). Assessing the adoption of critical success factors for lean six sigma implementation. Journal of Manufacturing Technology Management, 33(1), 124-145. https://doi.org/10.1108/JMTM-12-2020-0488
dcterms.references	Gavriluţă, A. C. (2021). Algorithm to use some specific lean manufacturing methods: Application in an industrial production process. Processes, 9.
dcterms.references	Gitlow, H. a. (2004). Quality Management. McGraw-Hill.
dcterms.references	Goetsch, D., & Davis, S. (2015). Quality Management for Organizational Excellence: Introduction to Total Quality. Pearson
dcterms.references	Goldratt, E. (1992). The Goal: A Process of Ongoing Improvement. North River Press
dcterms.references	Guo, D. L. (2021). Synchroperation in industry 4.0 manufacturing. International Journal of Production Economics, 13.
dcterms.references	Hammer, M., & Champy, J. (2003). Reengineering the Corporation: A Manifesto for Business Revolution. HarperCollins.
dcterms.references	Harrington, D. (1991). Business process improvement: The breakthrough strategy for total quality, productivity, and competitiveness. New York: McGraw Hill.
dcterms.references	Henríquez-Machado, R., Muñoz-Villamizar, A., & Santos, J. (2021). Sustainability through operational excellence: An emerging country perspective. Sustainability (Switzerland), p. 13(6). https://doi.org/10.3390/su13063165
dcterms.references	Hunt, V. D. (1995). Reengeniering. John Wiley & Sons, inc.
dcterms.references	Imai, M. (1986). Kaizen: The Key To Japan's Competitive Success. McGraw-Hill Education
dcterms.references	Ishikawa, K., & Lu, D. (1985). What is Total Quality Control? The Japanese Way. Prentice-Hall.
dcterms.references	Ito, M. S. (2020). Internet of things and simulation approach . Journal of Advanced Mechanical Design, Systems and Manufacturing, 12.
dcterms.references	Jackson, M., & Sloane, A. (2003). Modelling information and communication technology in business. Business Process Management Journal, 81–113.
dcterms.references	Jagtar Singha, V. R. (2014). Implementation of 5S practices: A review. Uncertain Supply Chain Management.
dcterms.references	Juran, J. M. (1988). Juran´s Quality Handbook. McGraw-Hill.
dcterms.references	KLEIN, W. H. (1991). MEASUREMENT SYSTEMS, SAMPLING, AND. Houston, Texas: Quality Engineering.
dcterms.references	Koch, C. &. (2021). Towards agile standardization: Testbeds in support of standardization for the IIoT. IEEE Transactions on Engineering Management, 59-74
dcterms.references	Krajewski, L., Malhotra, M., & Ritzman, L. (2016). Operations Management: Processes and Supply Chains. Pearson.
dcterms.references	Kraus, S., Filser, M., Puumalainen, K., Kailer, N., & Thurner, S. (2020). Business Model Innovation: A Systematic Literature Review. International Journal of Innovation and Technology Management.
dcterms.references	Kumar, N., Shahzeb Hasan, S., Srivastava, K., Akhtar, R., Kumar Yadav, R., & Choubey, V. K. (2022). Lean manufacturing techniques and its implementation: A review. Materials Today: Proceedings, 64, 1188-1192. https://doi.org/10.1016/j.matpr.2022.03.481
dcterms.references	Liker, J. L. (2004). Las Claves del Exito de Toyota. McGraw-Hill.
dcterms.references	M. Mohan Prasad, J. D. (2020). A framework for lean manufacturing implementation in Indian textile industry. Mater. Today, 2986–2995.
dcterms.references	Magnusson, K. K. (2003). Six-sigma The pragmatic approach. 2nd ed. Lund. Sweden: Student literature.
dcterms.references	McClusky, R. (2000). The rise, fall and revival of six-sigma. Measuring Business Excellence, 6-17.
dcterms.references	Medina León, A., Nogueira Rivera, D., El Assafiri Ojeda, Y., Medina Nogueira, Y. E., & Hernández Nariño, A. (2020). De la documentación de procesos a su mejora y gestión. Revista Cubana De Administración Pública Y Empresarial, 4(2), 206–224.
dcterms.references	Mendling, J. v. (2018). Business Process Management Cases Digital Innovation and Business Transformation in Practice. Springer
dcterms.references	Mithun Sharma, S. P. (2019). Reduction of defects in the lapping process of the silicon wafer manufacturing: the Six Sigma application.
dcterms.references	Montgomery, D. C. (2004). Introduction to Statistical Quality Control. 5ª ed. Indianapolis, Ind., Wiley Publishing.
dcterms.references	Motorcu, A. R., & Abdulkadir , G. (2006). Statistical process control in machining, a case study for machine tool capability and process capability. Materials & Design, 364-372. https://doi.org/10.1016/j.matdes.2004.11.003.
dcterms.references	Nava Carbellido, V. M. (2005). ¿Qué es la calidad? Conceptos, gurús y modelos fundamentales. Mexico: Limusa
dcterms.references	Ohno, T. (1988). Toyota Production System: Beyond Large-Scale Production. Taylor & Francis.
dcterms.references	Page, S. (2010). The Power of Business Process Improvement . American Management Association.
dcterms.references	Paipa-Galeano, L., Bernal-Torres, C. A., Otálora, L. M., Nezhad, Y. J., & González-Blanco, H. A. (2020). Key Lessons to Sustain Continuous Improvement: A Case Study of Four Companies. Journal of Industrial Engineering and Management, 13(1).
dcterms.references	Pereira, R. B. (2016). Combining scott-knott and GR&R methods to identify special causes of variation. Journal of the International Measurement Confederation, 135-144.
dcterms.references	Pettersen, J. (2009). Defining lean production: some conceptual and practical issues. The TQM Journal Vol. 21, 27-142.
dcterms.references	Piñero, E. A., & Vivas, F. E. (2018). Programa 5S´s para el mejoramiento continuo de la calidad y la productividad en los puestos de trabajo.
dcterms.references	Prateek Guleria, A. P. (2022). Lean six-sigma implementation in an automobile axle manufacturing industry: A case study. Materials Today: Proceedings, 1739-1746. https://doi.org/10.1016/j.matpr.2021.09.177
dcterms.references	Pulido, G., & De la Vara Salazar, R. (2013). Control estadístico de la calidad y Seis Sigma. En Control estadístico de la calidad y Seis Sigma. México DF: Mc Graw Hill Education.
dcterms.references	Pulido, H. G. (2010). Calidad Total y Productividad. Mexico D.F.: Mc Graw Hill
dcterms.references	Pyzdek, T. (2003). The Six Sigma Project Planner. United States of America: McGraw-Hill.
dcterms.references	Randhawa, J. S. (2018). An investigation into manufacturing performance achievements accrued by Indian manufacturing organization through strategic 5S practices. International Journal of Productivity and Performance Management
dcterms.references	Ries, E. (2011). The Lean Startup. New York: Crown Business.
dcterms.references	Rohleder, T. R., & Silver, E. A. (1997). A tutorial on business process improvement. 15(2), 139–154. https://doi.org/10.1016/s0272-6963(96)00100-3
dcterms.references	Rother, M. a. (2003). Learning to See: Value Stream Mapping to Add Value and Eliminate Muda. Taylor & Francis
dcterms.references	Saleh, H. E.-D. (2012). Polyester. Rijeka, Croatia: Intech Open.
dcterms.references	Shores, A. R. (1994). Reengineering the Factory: A Primer for World-class Manufacturing. ASQC Quality Press
dcterms.references	Soler, M. P., & Gisbert, V. (2018). CONTROL ESTADÍSTICO DE LA CALIDAD: UNA APLICACIÓN PRACTICA. ÁREA DE INNOVACIÓN Y DESARROLLO, S.L. https://doi.org/10.17993/EcoOrgyCso.2018.44
dcterms.references	Sosa-Perez, V. P.-M.-C.-I. (2020). Lean manufacturing production management model focused on worker empowerment aimed at increasing production efficiency in the textile sector. IOP Conference Series: Materials Science and Engineering, 796(1).
dcterms.references	Stoner, J. A. (1996). Administración. En Management (pág. 223). México: Pearson
dcterms.references	Sutrisno, S. S. (2019). Study On Mechanical Properties of Composite Geomaterial. International Conference on Mechanical Engineering Research and Application. East Java, Indonesia
dcterms.references	Swarnakar, V. &. (2020). Evaluating the effect of critical failure factors associated with sustainable Lean Six Sigma framework implementation in healthcare organization. International Journal of Quality & Reliability Management. https://doi.org/10.1108/IJQRM
dcterms.references	Taguchi, G. (1986). Introduction to Quality Engineering: Designing Quality into Products and Processes. Asian Productivity Organization.
dcterms.references	Tague, N. R. (2005). The Quality Toolbox. Milwaukee, Wisconsin: ASQ Quality Press.
dcterms.references	Taylor, F. (1998). The Principles of Scientific Management. Dover Publications.
dcterms.references	Vamsi Krishna Balla, K. H. (2019). Additive manufacturing of natural fiber reinforced polymer composites: Processing and prospects. En Composites Part B: Engineering.
dcterms.references	Wari, E. &. (2016). A survey on metaheuristics for optimization in food manufacturing industry. Applied Soft Computing Journal, 328-343.
dcterms.references	Weske, M. (2007). Business Process Management: Concepts, Languages, Architectures. Springer Berlin Heidelberg.
dcterms.references	Wil van der Aalst, K. v. (2004). Workflow Management Models, Methods, and Systems. London: First MIT Press.
dcterms.references	Womack, J., & Jones, D. (2003). Lean Thinking: Banish Waste and Create Wealth in Your Corporation, Revised and Updated. Free Press
dcterms.references	Xu, J. Z. (2009). Curing process simulation of fiberglass-reinforced plastic (FRP) pipes. Materials and Manufacturing Processes, 24(6), 24(6).
dcterms.references	Yang, C. -. -..-.. (2022). The development of the new process of design for six sigma (DFSS) and its application. Sustainability (Switzerland), 14(15). https://doi.org/doi:10.3390/su14159294
dcterms.references	Yepes Piqueras, V. (2013). Repositorio Universidad Politécnica de Valencia. https://polimedia.upv.es/visor/?id=51a98747-6519-d949-bdbb-5e41c98ea265: https://riunet.upv.es/handle/10251/30562
dcterms.references	Zhang, L. H. (2021). Data-driven dispatching rules mining and real-time decision-making methodology in intelligent manufacturing shop floor with uncertainty. Sensors, 21(14), 14.
thesis.degree.discipline	Escuela Internacional de Ciencias Económicas y Administrativas	es_CO
thesis.degree.level	Maestría en Gerencia de Operaciones	es_CO
thesis.degree.name	Magíster en Gerencia de Operaciones	es_CO