Your search keyword '"Hamzeh Ghorbani"' showing total 54 results

51. A geomechanical approach to casing collapse prediction in oil and gas wells aided by machine learning

Author

Shadfar Davoodi, Mohammad Mehrad, David A. Wood, Hamzeh Ghorbani, Amirafzal Kiani Shahvand, Sina Rashidi, Alireza Soleimanian, and Nima Mohamadian

Subjects

Petroleum engineering, business.industry, Fossil fuel, Drilling, 02 engineering and technology, 010502 geochemistry & geophysics, Geotechnical Engineering and Engineering Geology, 01 natural sciences, Field (computer science), Fuel Technology, 020401 chemical engineering, Multilayer perceptron, Genetic algorithm, 0204 chemical engineering, Oil field, business, Casing, Casing string, Geology, 0105 earth and related environmental sciences

Abstract

The casing-collapse hazard is one that drilling engineers seek to mitigate with careful well design and operating procedures. However, certain rock formations and their fluid pressure and stress conditions are more prone to casing-collapse risks than others. The Gachsaran Formation in south west Iran, is one such formation, central to oil and gas resource exploration and development in the Zagros region and consisting of complex alternations of anhydrite, marl and salt. The casing-collapse incidents in this formation have resulted over decades in substantial lost production and remedial costs to mitigate the issues surrounding wells with failed casing string. High and vertically-varying horizontal stresses across the Gachsaran formation are the challenge to predict and overcome. This study investigates casing collapse in wellbores from an established petroleum geomechanics perspective to develop and compare two hybrid neural-network models, multilayer perceptron's tuned, respectively, with a genetic algorithm (MLP-GA) and a particle swarm algorithm (MLP-PSO). These machine-learning algorithms are configured to predict Poisson's ratio ( ϑ ) and maximum horizontal stress ( σ H ) from available well-log input data. A large dataset from three wellbores drilled though the Gachsaran Formation in the Marun oil field, the second largest in Iran, is used to construct and validate the hybrid MLP models. In the first step, 22323 data records from a collapsed wellbore are divided into training (15626 records; 70%) and independent testing subsets (6697 records; 30%). In the next step, in order to test whether the suggested algorithms could be generalized, the data sets of the other two wells in the field were tested. Those tests confirmed that the algorithms achieved high prediction accuracy for Poisson's ratio and maximum horizontal stress in other wellbores.

Published

2021

52. Adaptive neuro-fuzzy algorithm applied to predict and control multi-phase flow rates through wellhead chokes

Author

Amirafzal Kiani Shahvand, Sina Rashidi, David A. Wood, Shadfar Davoodi, Hamzeh Ghorbani, Mohammad Mehrad, Nima Mohamadian, and Alireza Soleimanian

Subjects

Neuro-fuzzy, Choke, Fuzzy logic, Defuzzification, Computer Science Applications, Modeling and Simulation, Wellhead, Range (statistics), Electrical and Electronic Engineering, Oil field, Instrumentation, Algorithm, Test data, Mathematics

Abstract

A Takagi-Sugeno adaptive neuro-fuzzy inference system (TSFIS) model is developed and applied to a dataset of wellhead flow-test data for the Resalat oil field located offshore southern Iran, the objective is to assist in the prediction and control of multi-phase flow rates of oil and gas through the wellhead chokes. For this purpose, 182 test data points (Appendix 1) related to the Resalat field are evaluated. In order to predict production flow rate (QL) expressed as stock-tank barrels per day (STB/D), this dataset includes four selected input variables: upstream pressure (Pwh); wellhead choke sizes (D64); gas to liquid ratio (GLR); and, base solids and water including some water-soluble oil emulsion (BS&W). The test data points evaluated include a wide range of oil flow rate conditions and values for the four input variables recorded. The TSFIS algorithm applied involves five data processing steps: a) pre-processing, b) fuzzification, c) rules base and adaptive neuro-fuzzy inference engine, d) defuzzification, and e) post-processing of the fuzzy model. The developed TSFIS model for the Resalat oil field database predicted oil flow rate to a high degree of accuracy (root mean square error = 247 STB/D, correlation coefficient = 0.9987), which improves substantially on the commonly used empirical algorithms used for such predictions. TSFIS can potentially be applied in wellhead choke fuzzy controllers to stabilize flow in specific wells based on real-time input data records.

Published

2020

53. Shear modulus prediction of embedded pressurized salt layers and pinpointing zones at risk of casing collapse in oil and gas wells

Author

David A. Wood, Sina Rashidi, Mehdi Ahmadi Alvar, Nima Mohamadian, Khalil Shahbazi, and Hamzeh Ghorbani

Subjects

Variables, 010504 meteorology & atmospheric sciences, media_common.quotation_subject, Well logging, 010502 geochemistry & geophysics, 01 natural sciences, Shear modulus, Geophysics, Creep, Shear (geology), Shear stress, Geotechnical engineering, Oil field, Casing, Geology, 0105 earth and related environmental sciences, media_common

Abstract

Rock shear and strain behaviors deep in the sub-surface are dependent on several geomechanical variables. These include various types of stress and rock formation moduli. Deformations of specific rock formations are usually quantified in a series of laboratory tests, which are costly and time-consuming and can only be performed on the few rock formation samples and cores available. Consequently, indirect estimates of geomechanical metrics from well-log data are required to measure variations throughout the entire length of a wellbore. Such measurements and detailed geomechanical models are required to identify zones at risk of casing collapse due to shear stress buildups. Such zones tend to occur in problematic ductile formations such as salt and swelling clays that are prone to creep. Machine-learning algorithms coupled with optimizers, and calibrated with a few mechanical rock test measurements, offer a practical method for predicting geomechanical characteristics along an entire wellbore. Hybrid models combining the optimizers, imperialist competitive (ICA) and gravitation search (GSA) algorithms, with the machine-learning algorithms, distance-weighted K-nearest neighbor (DWKNN) and multi-layer perceptron (MLP) are shown to achieve high prediction accuracy of shear modulus (Gs) from a large dataset (22,325 data records) crossing the problematic salt-rich Gachsaran formation in a wellbore from the Marun oil field (Iran). ICA-MLP, GSA-MLP, ICA-DWKNN and GSA-DWKNN models applied to four independent variables recorded by well logs were calibrated with some laboratory-derived Gs measurements. These models predict Gs with high levels of accuracy achieving coefficients of determination (R2) > 0.96. The GSA-DWKNN hybrid algorithm (R2 = 1) provided the highest prediction accuracy. Gs predictions can then be used to accurately identify zones at risk of casing collapse.

Published

2020

54. EFFECT OF SURFACTANTS ON THE SIZE, COLOR, PHOTOLUMINESCENCE AND RESISTIVITY OF INDIUM TIN OXIDE NANOPARTICLES PREPARED BY CO-PRECIPITATION METHOD

Author

Yadolah Ganjkhanlou, Ayyoob Jafari, Mahmood Kazemzad, and Hamzeh Ghorbani

Subjects

Materials science, Photoluminescence, Co-precipitation, indium tin oxide, band structure, resistivity, luminescence, Scanning electron microscope, Rietveld refinement, Band gap, Analytical chemistry, Nanoparticle, Surfaces and Interfaces, Condensed Matter Physics, Surfaces, Coatings and Films, Indium tin oxide, Materials Chemistry, Crystallite, Luminescence

Abstract

Indium tin oxide (ITO) nanoparticles were synthesized by co-precipitation method using ammonia as a precipitator in absence/presence of various surfactants (LABS and Triton X-100). The synthesized nanoparticles were investigated by scanning electron microscopy, resistance measurement, photoluminescence (PL) spectroscopy and X-ray diffractometry (XRD) techniques. The XRD patterns of nanoparticles were also studied by Rietveld refinement method for calculation of crystallite size, micro-strain and lattice parameter. The results indicate that by application of LABS and Triton X-100 as surfactant the particle size was increased. Two luminescence bands were observed in PL spectra of ITO nanoparticles with the excitation energy lower than their band gaps. It was found that the ratios of luminescence bands have relation with resistances and colors of ITO nanoparticles. In addition, the band structure of ITO nanoparticles was described considering the obtained results.

Published

2012