High-resolution acoustic imaging technology provides operators the ability to extract submillimetric measurements of perforations at any depth into the casing wall. Due to its three-dimensional nature, submillimetric acoustic data permits the extraction of highly accurate area-based measurements at any radial distance into the perforation, with key distances at the inner and outer casing boundary. This novel technology is fluid agnostic and is unaffected by fluid opacity or clarity. The platforms robust 3D measurement capabilities have made it into an ideal means to evaluate casing and perforations in challenging environments such as hydraulically fractured wells. The integration of high-resolution acoustic imaging into numerous operators’ hydraulic fracture and completions evaluation workflows has resulted in a highly insightful aggregate submillimetric perforation dataset. This large dataset has led to the development of a method to virtually unplug perforations by using a well-specific "perforation entry and exit-hole area correlation". The correlation established can only be extracted using acoustic based imaging as it requires submillimetric resolution of both the ID and OD profile of each perforation Using this correlation, the resulting set of post-frac perforation exit-hole measurements improves an operators’ ability to complete a holistic well completion evaluation, even when well conditions cause perforations to be plugged. The outcome is improved operational insight through the ability to directly compare stages with plugged perforations to those without. This approach can be applied at any point in the well's life cycle, which allows operators to revisit assessments and virtually unplug obscured and proppant-filled perforations. The methodology requires a sound baseline knowledge of the performance of the downhole perforating charges. The baseline is commonly obtained through a calibration stage, which is a stage of charges that are shot but left unstimulated to provide the control measurements for the specific charge in the given well conditions. Current industry performance of downhole perforating charges is investigating through the aggregated dataset of calibration charges. To validate this solid-state acoustic technology and demonstrates its high degree of accuracy for entry and exit-hole perforation measurements, machined samples were scanned with this technology, and with a metrology-grade laser scanner for comparison. This paper presents a novel virtual unplugging methodology, enabled by highly accurate and validated entry-hole measurements, as well as other insights garnered from the aggregate analysis of the world's largest calibration perforation datasets.
An advanced high-resolution acoustic imaging technology was deployed for well integrity and deformation assessments in both vertical and horizontal wells. This high frequency acoustic tool collected three-dimensional data quantifying deformation and wall thickness with resolution unobtainable by existing multi-finger caliper, magnetic flux leakage, and rotating single element ultrasonic systems. Several novel imaging methods are enabled by the high number of transducers (up to 512) on the imaging probe. These methods, including beam forming, beam steering and semi-stochastic multipulse imaging, are outlined and discussed in this paper. In addition, multiple types of standardized visualizations enabled by this high-resolution 3D data capture tool are introduced and examples of each are shown. Lab qualification and imagery generated by the high-resolution solid-state imaging technology, when applied to various precision machined geometric anomalies, are presented. In addition to lab validation results, several field studies are showcased including assessments of ovalized casing, complex downhole corrosion, and isolated minor pitting. Leak paths, splits, and damaged regions within threaded casing collars were also identified, imaged, and quantified using the acoustic technology. Until now, these collar regions have been very difficult to image using legacy downhole tools due to fundamental limitations at the threaded connection geometry. Lastly, various downhole completion equipment case studies are presented showcasing several applications of acoustic imaging used to validate the set-position or condition of specialty downhole equipment. This paper outlines the usage of the solid-state acoustic technology to generate three dimensional geometry and wall thickness datasets with sub-millimetric resolution, providing operators with a holistic and actionable assessment of their well integrity.
High-resolution acoustic imaging has provided a novel means of quantifying casing thickness; the technology assesses both inner and outer diameter wall loss for downhole casing integrity applications. The technology deploys high-density solid-state arrays with up to 512 transducers to achieve sub-degree azimuthal resolution and submillimetric axial resolution with casing thickness measurements down to 0.08-in minimum thickness. This paper provides background on the technological advancement, details of laboratory validation results, exploration of burst pressure calculation methodologies, and a field case study based on the novel technology. Data gathered by the high-density, solid-state transducer array uses acoustic signals to measure both casing thickness and radial measurements in a single pass. The resulting 3D point cloud of data is analyzed with image-processing-based machine learning algorithms. Validation data was gathered from multiple machined and field samples. Machined defect dimensions were varied to test the detection, sizing, and accuracy capabilities of the platform. A field-based case study is presented to provide a comparison between high-resolution acoustic imaging data and computed tomography (CT) scan data. Finally, examples of RSTRENG burst pressure analyses are presented to showcase the advantages and sensitivities of using higher-resolution datasets and higher-accuracy burst pressure methodologies. The high-resolution acoustic imaging platform was found to offer fundamental improvements over legacy magnetic flux leakage (MFL) and single-element ultrasound-based tools. The acoustic technology relies on direct measurement principles; the results are not inferred through calibration. The time-of-flight-based approach permits a single casing string comprised of different diameters, wall thicknesses, and materials to be inspected from a single logging run. The technology is pipe material agnostic and directly measures the casing thickness of ferrous and non-ferrous metals. The electronic platform permits the capture and storage of submillimetric axial resolution which captures penetration profiles of entire defects. The high-resolution and spatially registered datasets have been leveraged to conduct effective area, RSTRENG, and modified B31G burst pressure calculations with greatly improved defect identification, penetration quantification, interaction rule application, and shape characterization. The advancements presented in this paper are highly pertinent to gas storage and carbon sequestration operators who seek integrity management advancements. The potential to extend well life, optimize workover schedules, and better manage gas storage pressure ratings are real-world benefits of the presented technology.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.