Propuesta de un Modelo de Estimación de Velocidad de Corrosión Externa para Tuberías Enterradas en Suelos Arcillosos

José Faría González; Lisseth Ocando

doi:10.22209/rt.v46a16

José Faría González Centro de Estudios de Corrosión, Facultad de Ingeniería, Universidad del Zulia, Estado Zulia, Maracaibo 4001, Venezuela
Lisseth Ocando Centro de Estudios de Corrosión, Facultad de Ingeniería, Universidad del Zulia, Estado Zulia, Maracaibo 4001, Venezuela https://orcid.org/0009-0002-7452-2605

Keywords: classification tree, external corrosion, neural networks, pipelines, prediction models

Abstract

Many studies have shown the need in the Venezuelan oil industry to implement viable alternatives in the field of pipeline integrity management. Thus, the aim of this work is to propose a prediction model for the external corrosion rate of buried transmission pipelines in a crude oil production field with clay soils, located in the west of Zulia State in Venezuela. After the collection, revision and classification of soil and operating parameter data in the field, a definition of input and output variables was carried out, used to generate 2 models, one regression type and the other classification type. For the neural network model, a low regression fit (R²) of 6.62 % and an RMSE of 2.13 were obtained, indicators of low model efficiency due to the restrictions of the data provided and sample size. On the contrary, for the decision tree classification model, an accuracy of 98.14 % was obtained, when classifying the corrosion rate in severity ranges. This classification tree model will serve as a starting point for subsequent research to delve deeper into the area.

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Author Biography

Lisseth Ocando, Centro de Estudios de Corrosión, Facultad de Ingeniería, Universidad del Zulia, Estado Zulia, Maracaibo 4001, Venezuela

Ingeniera Química (2002) con Maestría en Corrosión (2006), ambos títulos obtenidos en La Universidad del Zulia (LUZ). Es profesora a Investigadora en el Centro de Estudios de Corrosión de LUZ desde el año 2003. Tiene más de 20 años de experiencia en investigación y desarrollo en el área Corrosión Inducida Microbiológicamente (MIC), generando más de 20 publicaciones para revistas nacionales e internacionales y asesorando más de 20 tesis y trabajos especiales de grado, principalmente en el área de MIC. Posee las certificaciones “NACE Corrosion Technologist” y “NACE Senior Internal Corrosion Technologist” y ha realizado diversos cursos internacionales relacionados con el área, destacándose entre ellos: Cathodic Protection Tester (CP1), Internal Corrosion for Pipelines, Corrosion Control in the Refining Industry, Biofilm Summer School 2006 y STEM Corrosion in the Oil and Gas Industry

References

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A Prediction Model for External Corrosion Rate for Buried Pipelines in Clay Soil

Abstract

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References