Maximizing Capital Efficiency by Expanding the Limiter Redesign Process to Flat Time Operations

Valenta, Marie Angela; Walker, Michael; Pastusek, Paul; Bailey, Jeffrey R.; Elks, William Curtis; Lewis, Scott Bracken; Mitchell, Nicholas

doi:10.2118/170751-ms

Cited by 9 publications

(3 citation statements)

References 46 publications

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“…This example was previously reported in Refs. [5,6] in the context of an early field trial of DAS in an offshore environment. The lithology for the section of interest for this previous DAS trial was comprised of carbonates, siltstones, and claystones in an interbedded calcite-cemented abrasive formation.…”

Section: Example #1: Large Hole Size From a Deepwater Floating Drillimentioning

confidence: 99%

“…The goal of this DAS application was to facilitate drilling through the abrasive sandstone (2,360 -2,460 ft) without pulling the PDC bit, as illustrated in Figure 18. Figure 19 shows the results of applying limiter redesign principles [1,6] to this operation, along with effective management of drilling parameters using DAS. Significant gains were made in the footage of hard-rock interval drilled (abrasive sandstone) and overall average ROP of the hole section.…”

Section: Example # 3: Onshore Unconventional Pad-drilling Applicationsmentioning

confidence: 99%

“…An example of such a workflow that has been used by the operator is real-time bit stick-slip surveillance monitoring (see for example Refs. [4][5][6]), which enables virtual real-time observation of stick-slip severity based on surface torque and RPM and a drilling mechanics model of the drilling assembly. Reacting to several interdependent (and sometimes conflicting) performance metrics (MSE, ROP, stick-slip severity) in real-time is a significant challenge.…”

Section: Introductionmentioning

confidence: 99%

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Mitigating Drilling Dysfunction Using a Drilling Advisory System: Results from Recent Field Applications

Payette

Pais

Spivey

et al. 2015

Day 4 Wed, December 09, 2015

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The ExxonMobil Drilling Advisory System (DAS™) is a rig-based drilling surveillance and optimization platform that encourages regular (guided) drill-off tests, carefully monitors drilling performance and provides recommendations for controllable drilling parameters to help improve the overall drilling process. It is well known that drilling with dysfunction(s), such as BHA whirl or bit stick-slip, among others, can damage drilling tools, lead to poor borehole quality and result in significant reductions in Rate of Penetration (ROP). The ultimate objective of DAS is to help drillers achieve consistently better and longer bit runs by identifying and mitigating drilling dysfunctions.In this paper we describe the DAS workflow, provide an overview of many of the key technical components of DAS and summarize results from several recent field applications. The DAS workflow includes a learning (or calibration) mode that encourages the driller to explore different operating parameters by conducting drill-off tests, which in turn allows the system to build an understanding of performance trends. This understanding is then exploited by an application mode which leverages results obtained during the learning (or calibration) phase. The workflow is iteratively applied in real-time as drilling operations and geological conditions change.Key technical components of the DAS application include: high quality adaptive filtering algorithms for computing various drilling system performance measures (e.g., MSE, ROP, and stick-slip severity, among others), data encapsulation/dimensionality reduction techniques (i.e., the notion of Љresponse pointsЉ) and reduced order modeling techniques (simplices, smooth response surfaces, etc.) which are ultimately used to generate recommendations for improved performance.Using examples from recent offshore field applications, we illustrate the use of adaptive filtering and data encapsulation to process noisy real-time data and extract meaningful trends to enable drilling performance optimization. We show how fitting response surfaces to response points can help elucidate, in real-time, the occurrence of classical drilling dysfunctions such as lateral vibrations (as manifest in increased MSE) and stick-slip torsional vibrations. Using results from recent applications of DAS to unconventional pad-drilling operations, we show the impacts of focused drilling performance limiter redesign and real-time DAS parameter changes on improved overall ROP in subsequent wells on a pad.

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Section: Example #1: Large Hole Size From a Deepwater Floating Drillimentioning

confidence: 99%

Section: Example # 3: Onshore Unconventional Pad-drilling Applicationsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Mitigating Drilling Dysfunction Using a Drilling Advisory System: Results from Recent Field Applications

Payette

Pais

Spivey

et al. 2015

Day 4 Wed, December 09, 2015

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A Framework for Transparency in Drilling Mechanics and Dynamics Measurements

Macpherson

Paul

Behounek

et al. 2015

SPE Annual Technical Conference and Exhibition

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The use of real-time mechanics and dynamics measurements has expanded and evolved significantly in the last thirty years, enabling the safe and reliable drilling of complex wells. Unfortunately, these measurements are poorly defined, which inhibits straightforward analysis and hinders development of models, simulators and automation applications. Adoption of open measurement guidelines will provide the transparency required to improve the value of existing measurements and accelerate the development and adoption of enhanced applications and automation. Mechanics and dynamics measurements currently can be processed and transmitted from downhole in near real-time and then merged with other surface measurements. Optimization of the drilling process uses these combined measurements for monitoring, advising and control, thereby delivering a quality borehole as planned, in a safe and reliable fashion. Processing includes real-time filtering, mathematical modeling, and simulation, which are significant parts of any systems approach. There are currently multiple methods used to quantify downhole and surface vibrations, displacements, and forces. Tools use dissimilar sensor and processing configurations, so they yield significantly different data. Regrettably, these different measurements are given the same name, and published descriptions often do not include the details required to understand and properly utilize the data. Examples of key information include sensor characteristics, sensor arrangement, bandwidth, and signal processing. Guidelines are suggested to resolve this state of confusion, including: terminology describing each drilling mechanics and dynamics sensor, configuration, and measurement; and metadata describing how a data value is derived, filtered, processed, transmitted and stored. This paper examines and defines drilling mechanics and dynamics measurements. It recommends measurement practices and good processing techniques of these measurements, with examples, and presents a recommended open measurement framework. Adoption of this framework will resolve the current state of confusion and uncertainty, enable all parties to develop monitoring, advising and control applications that use these data, and help lower well costs and improve borehole quality.

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Drill Rig Control Systems: Debugging, Tuning, and Long Term Needs

Pastusek

Owens

Barrette

et al. 2016

SPE Annual Technical Conference and Exhibition

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This paper documents some of the key findings on the data required and methods used to detect and correct issues with drilling control systems such as auto drillers, top drive active torsional damping systems, and heave compensation systems. It has been found that the rig control systems and how they are tuned can have a significant impact on drilling dynamics. Issues related to drilling dynamics have varied widely among rigs, even among those that are in the same field and that have the same equipment and specifications. The standard answer has been that drilling is different on the ‘other side of the road, river, or anticline', or that one rig crew is better than the other. While there are significant differences in the drilling environment and between crews, recognition of the effects of the control systems employed can explain many of these differences and expand the tools and techniques available to improve drilling performance and reduce dysfunctions. Once the fundamental elements of a control system are understood, the performance limiters identified can often be applied to other rigs in the fleet with different systems via effective documentation of the changes made and their results. Opportunities abound for improvement in oilfield drilling control systems, their basic design, and documentation on how they should be tuned and best used. There are also opportunities in crew training catered to different audiences: Drilling Engineers, Rig Supervisors, Drillers, Directional Drillers, and Rig Electricians. Lastly, there is often a knowledge and communication gap between the software/control/user experience and engineers designing the control systems. Since rig control systems are not usually identified as the source of drilling dysfunction, requests for software or interface redesign have not often been initiated in the past. Not surprisingly, the best progress has been made when four way work groups were formed with all key stakeholders involved: the operator's drill team, internal technical experts, rig contractor and crew, and OEM control systems experts. Investing the time and personnel in this process and establishing group trust has helped prevent gaps in understanding of overall system performance. It also allows each stakeholder to contribute their expertise, raise concerns, and get buy in from their extended teams. This process takes commitment from all parties to change the way work is done, but the performance improvements are immediate and can be clearly seen. Challenges for the future are to continue to upgrade rig site manuals, arrange for more crew training, upgrade the control system design, and to incorporate the control system response as part of the topside boundary condition for future drilling dynamics models.

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Maximizing Capital Efficiency by Expanding the Limiter Redesign Process to Flat Time Operations

Cited by 9 publications

References 46 publications

Mitigating Drilling Dysfunction Using a Drilling Advisory System: Results from Recent Field Applications

Mitigating Drilling Dysfunction Using a Drilling Advisory System: Results from Recent Field Applications

A Framework for Transparency in Drilling Mechanics and Dynamics Measurements

Drill Rig Control Systems: Debugging, Tuning, and Long Term Needs

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