Fiber-Optic Sensing Technology Providing Well, Reservoir Information - Anyplace, Anytime

Koelman, Jmva Vianney

doi:10.2118/0711-0022-jpt

Cited by 13 publications

(3 citation statements)

References 2 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Indeed, a FOC is usually made of several single and multi-mode fibers that can be used for a variety of applications. This potential has been evidenced and leveraged by the oil and gas industry for around one decade (Koelman et al, 2012;Koelman, 2011;Van Der Horst et al, 2013).…”

Section: Logging and Monitoring Capabilities Of Das Along Wellmentioning

confidence: 99%

“…Depending on the deployment design, which remains challenging for deep (hot) boreholes, this can provide information on temperature profiles, well completion integrity, in-and out-flow zones of the geothermal fluid, induced seismicity, etc. (Koelman, 2011;Koelman et al, 2012;Van Der Horst et al, 2013). For seismic monitoring, DAS along the borehole allows sensors to be positioned much closer to the reservoir than surface seismometers, thus closer to the potential seismicity.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Towards real-time seismic monitoring of a geothermal plant using Distributed Acoustic Sensing

Azzola

Thiemann

Gaucher

2022

Preprint

View full text Add to dashboard Cite

Abstract. Distributed Acoustic Sensing (DAS) is an emerging technology for acquiring seismic data on virtual sensors densely distributed along an optical fiber. The broadband response of the sensors, associated with the possibility of deploying fiber optic cables in harsh conditions and the relatively moderate cost of this sensing element gives clear perspectives for DAS in geothermal wells to contribute to the monitoring operations of geothermal plants. However, the technical feasibility of managing the large flow of data generated by the DAS and the suitability of the strain-rate acquisitions to monitor locally induced seismicity was yet to be assessed. We propose a monitoring concept establishing DAS as an effective component of the seismic monitoring of the Schäftlarnstraße geothermal plant (Munich, Germany). The underlying data management system links the existing on-site infrastructure, including the fiber optic cable deployed in one of the site’s injection wells and the associated DAS recorder, to a cloud Internet-of-Things (IoT) platform designed to deliver both a secure storage environment for the DAS acquisitions and optimized computing resources for their processing. The proposed solution was tested over a period of six months and showed the feasibility of efficiently acquiring and processing the large flow of continuous DAS data. For seismic risk mitigation purposes, we additionally investigate the potential of the monitoring concept to tend towards real-time monitoring. The processing outcomes, focusing especially on two detected local seismic events, demonstrates the relevance of DAS from geothermal wells for the (micro)seismic monitoring of the geothermal site. Despite the noisy operational conditions, the applied processing workflow takes advantage of the sensors’ high spatial density for data denoising and event triggering and highlights that higher detection sensitivity than conventional seismometers can be achieved. From a different perspective, further analyses of the DAS records confirm the logging capabilities of the technology, especially regarding well completion integrity. The 6-months test period shows that permanent DAS can be integrated as a routine seismic monitoring component of geothermal plants and advantageously complement surface seismometer-based networks, especially in urban environments.

show abstract

Section: Logging and Monitoring Capabilities Of Das Along Wellmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Towards real-time seismic monitoring of a geothermal plant using Distributed Acoustic Sensing

Azzola

Thiemann

Gaucher

2022

Preprint

View full text Add to dashboard Cite

show abstract

“…It leverages optical fibers to deliver repeatable in-situ observation of changes in temperature, strain and/or strain-rate. DOFS applications demonstrated that it could provide insight into, e.g., in-flow and out-flow zones, fluid flow rates, well integrity, and induced seismicity [7][8][9][10].…”

Section: Introductionmentioning

confidence: 99%

Seismic Monitoring of a Deep Geothermal Field in Munich (Germany) Using Borehole Distributed Acoustic Sensing

Azzola,

Gaucher

2024

Sensors

View full text Add to dashboard Cite

Geothermal energy exploitation in urban areas necessitates robust real-time seismic monitoring for risk mitigation. While surface-based seismic networks are valuable, they are sensitive to anthropogenic noise. This study investigates the capabilities of borehole Distributed Acoustic Sensing (DAS) for local seismic monitoring of a geothermal field located in Munich, Germany. We leverage the operator’s cloud infrastructure for DAS data management and processing. We introduce a comprehensive workflow for the automated processing of DAS data, including seismic event detection, onset time picking, and event characterization. The latter includes the determination of the event hypocenter, origin time, seismic moment, and stress drop. Waveform-based parameters are obtained after the automatic conversion of the DAS strain-rate to acceleration. We present the results of a 6-month monitoring period that demonstrates the capabilities of the proposed monitoring set-up, from the management of DAS data volumes to the establishment of an event catalog. The comparison of the results with seismometer data shows that the phase and amplitude of DAS data can be reliably used for seismic processing. This emphasizes the potential of improving seismic monitoring capabilities with hybrid networks, combining surface and downhole seismometers with borehole DAS. The inherent high-density array configuration of borehole DAS proves particularly advantageous in urban and operational environments. This study stresses that realistic prior knowledge of the seismic velocity model remains essential to prevent a large number of DAS sensing points from biasing results and interpretation. This study suggests the potential for a gradual extension of the network as geothermal exploitation progresses and new wells are equipped, owing to the scalability of the described monitoring system.

show abstract

A Literature Review

Li¹,

Karrenbach²,

Ajo‐Franklin³

2021

Geophysical Monograph Series

View full text Add to dashboard Cite

Fiber-Optic Sensing Technology Providing Well, Reservoir Information - Anyplace, Anytime

Cited by 13 publications

References 2 publications

Towards real-time seismic monitoring of a geothermal plant using Distributed Acoustic Sensing

Towards real-time seismic monitoring of a geothermal plant using Distributed Acoustic Sensing

Seismic Monitoring of a Deep Geothermal Field in Munich (Germany) Using Borehole Distributed Acoustic Sensing

A Literature Review

Contact Info

Product

Resources

About