March 2015
ShaleTech Report

Positive displacement motors improve drilling efficiency, reduce time to first oil

With lower oil prices, unconventional plays require a high degree of efficiency to become profitable. The highest number of wells should be drilled with the fewest rigs and services, at the fastest possible rate. Three new positive displacement motors were developed for specific applications in the Williston and Niobrara basins. This focused engineering has delivered enormous savings to operators.
Ahmed Al-Essa / Baker Hughes, a GE Company Azar Azizov / Baker Hughes, a GE Company Brayden Jerde / Baker Hughes, a GE Company Norwood Augustine / Baker Hughes, a GE Company Steven Faulkner / Baker Hughes, a GE Company Wolfgang John / Baker Hughes, a GE Company

To maximize production in unconventional wells, operators must maximize the wellbore’s footage within the producing zone. Constructing the curve section with a high build-up rate (BUR) enables shorter curve sections that increase lateral footage within the producing reservoir, and decrease overall drilling time and cost.

Demand for curve sections with higher BURs has led to the development of the latest-generation of steerable motors with reduced bit-to-bend length. These motors have proven to be an effective and economical solution for drilling shorter curved sections in horizontal wells, in several North American basins. Overall, the short bit-to-bend motor system enables the lateral length within the production zone to be maximized while improving drilling efficiency. This is mainly because higher BURs are delivered with a smaller adjustable kick-off (AKO) angle, since the bend is closer to the bit. Improved overall directional control and more consistent BURs are the result. Moreover, this design also improves the ability to rotate the motor at higher RPMs, helping drilling performance in verticals and laterals.

A major obstacle for reducing drilling costs and improving efficiency is the need to drill many thousands of feet through various formations to reach the kick-off point. Downhole tool failures and bit damage have resulted in unplanned trips and significant non-productive time (NPT). One goal of optimization efforts is drilling through a vertical section as quickly as possible. Development of reliable and powerful positive displacement motors has been a key part of the solution.

DAILY FOOTAGE DRILLED UP 33%

The Williston basin encompasses portions of North Dakota and Montana, and the southern parts of Saskatchewan and Manitoba. Operators in the southern part of the Williston basin focus on the late Devonian and early Mississippian rock layers, in particular the Middle Bakken and Three Forks formations. Estimates indicate there are 5.0–6.3 Bbbl of recoverable oil held within the two formations.

The 7-in. Navi-Drill Ultra XL45 motor showed improved performance, compared to the rig average.
Fig. 1. The 7-in. Navi-Drill Ultra XL45 motor showed improved performance, compared to the rig average. Click image to enlarge.

An operator engaged in pad drilling in the Williston basin was seeking improvement in drilling efficiency to drive down overall E&P costs. The biggest area for improvement was in the vertical hole sections of the wells, where operators had to change out motors and bits after drilling the softer, shallower formations before the carbonate and salts, where bits and motors saw more demanding work.

 The operator wanted to drill the vertical hole section more efficiently, increasing the rate of penetration (ROP), particularly through the upper, softer formations. At the same time, a vertical trajectory was expected with minimal corrections.

The proposed solution was to deploy the new Baker Hughes 7-in. Navi-Drill Ultra XL45 motor. Nearly 45 ft long, the motor delivers unparalleled power at medium-to-low bit speeds. This improved the rate of penetration (ROP), particularly in the aforementioned upper formations.

As a result, a number of performance improvements were achieved. Total circulating hours were reduced 21%, and rotary table hours were reduced 16%. The most dramatic improvement was in ROP, where a 41% increase was seen in rotating ROP, and a 33% increase in daily footage drilled was achieved, Fig. 1.

Due to the higher power delivery in this motor, only 50–60% of maximum capacity was used, compared to more than 90% in other motors. This reduction helped increase motor life, and eliminated the need to change the motor at mid-section. Parameter guidelines were also developed to minimize torsional vibrations (stick/slip). Minimizing these damaging vibrations also drove an improvement in bit and motor life. Even when a bit change was required on longer sections, the operator still saw savings, because the motor did not need to be changed, or the stator re-lined, between runs. This also reduced trip time.

Inclination and DLS for a well drilled with Navi-Drill Ultra Curve motor.
Fig. 2. Inclination and DLS for a well drilled with Navi-Drill Ultra Curve motor. Click image to enlarge.

After seeing the efficiency and performance improvements, the operator decided to use the same solution for all wells going forward.

LOWER DRILLING TIME IN WILLISTON

A Williston operator in North Dakota was seeking a reduction in drilling time and improvements in steering control, which were the main challenges experienced in comparable wells. In this basin, the majority of the 8¾-in. build-up (curve) sections were drilled with rates of 10–12°/100 ft. However, wells would be planned initially with build-up rates up to 14°/100 ft, a rate that would increase the reservoir exposure and reach horizontal faster.

The challenge was that standard 6¾-in. motors could not achieve the required build-up rates, mainly because the 5½-ft to 6½-ft bit-to-bend distance made directional control more difficult and limited rotation due to the required higher AKO angles. Additionally, these motors would have to be tripped, because the high AKO angle would not be appropriate to drill the horizontal sections with the directional control needed.

The average drilling time for the Navi-Drill Ultra Curve motor was eight-plus hours less than a competing motor.
Fig. 3. The average drilling time for the Navi-Drill Ultra Curve motor was eight-plus hours less than a competing motor. Click image to enlarge.

The desired solution was to drill the curve sections, achieve the planned BURs of 10–14°/100 ft, and then continue drilling the horizontal without the need to trip and change the AKO angle. In addition, performance would be critical for drilling efficiently with the highest possible ROP.

Baker Hughes deployed the 6¾-in. Navi-Drill Ultra Curve motor with a 4½-ft bit-to-bend length. Improved results were seen immediately. The motor maintained control of the tool face while drilling the curves, delivering more consistent build rates and improved ROP throughout the section, Fig. 2.

The new motor achieved BURs of 11–18°/100 ft over 13 wells. The average drilling time with these motors was about 22 hr, beating the basin average of 31 hr experienced with similar motors, Fig. 3.

Time/depth plot compares drilling the intermediate section in one run vs. two runs.
Fig. 4. Time/depth plot compares drilling the intermediate section in one run vs. two runs. Click image to enlarge.

The operator had initial concerns that the AKO on Ultra Curve motors was adjustable, and not a fixed bent-housing, as seen in similar motors, and was of the opinion that only a fixed bend could achieve the required BURs. However, this motor has outperformed motors with a fixed bent-housing, and has proven to be the most consistent, best-performing motor for these applications.

IMPROVED DRILLING TIME IN NIOBRARA

The Niobrara shale covers over 5 million acres across various basins within Colorado, Nebraska and Wyoming. A customer working in the Niobrara was seeking efficiency improvements in drilling. Historically, 8¾-in. sections, which cover the vertical and curve intervals, were drilled over 6,600 ft. Total on-bottom drilling hours for both intervals averaged about 40 hr. The challenges were the need to trip to change the motor, and the limited directional control over the curve interval, leading to inconsistent build rates and more time spent in slide drilling.

The goal was to drill both the vertical and curve intervals in a single motor run and consistently deliver BURs up to 10°/100 ft. Baker Hughes deployed the new 6¾-in. Navi-Drill Ultra Curve motor because of its unique steering characteristics. The motor is designed to maintain a constant toolface while drilling curved sections. This delivers consistent BURs and an improved ROP while sliding, due to the reduced need to re-orient. A specially optimized Baker Hughes Talon 3D PDC bit was matched to the system, to achieve high ROP while drilling vertically and further enhance toolface control.

The Ultra Curve motor drilled the vertical and curve sections in a single run, eliminating a full trip and saving 10 hr, Fig. 4. The motor also delivered improved average ROP, leading to an overall drilling performance improvement that surpassed offset wells. wo-box_blue.gif 

About the Authors
Ahmed Al-Essa
Baker Hughes, a GE Company
Ahmed Al-Essa is global marketing manager, Directional Drilling, for Baker Hughes. He joined the company in 2006 after earning a BS degree in mechanical engineering from King Fahd University of Petroleum and Minerals in Saudi Arabia. He has held roles in field service, operations, supply chain, human resources and product management at Baker Hughes.
Azar Azizov
Baker Hughes, a GE Company
Azar Azizov is product manager of Drilling Motors, Directional Drilling, for Baker Hughes, based in Celle, Germany. He has more than 13 years of industry experience and is an OASIS Certified Drilling Applications Engineer. Mr. Azizov earned BS and MS degrees in computer-aided control systems from Azerbaijan State Oil Academy. He is a member of SPE, and author and co-author of many oil and gas technical papers.
Brayden Jerde
Baker Hughes, a GE Company
Brayden Jerde is an applications engineer, Drilling Services, for Baker Hughes in the Rocky Mountain area. He has carried out project roles in multiple basins, including Williston, Powder River, Piceance, Denver-Julesburg and Green River. Mr. Jerde joined Baker Hughes in 2012, and has held positions in field operations, engineering and product development. He earned a BS degree in civil engineering from Colorado State University.
Norwood Augustine
Baker Hughes, a GE Company
Norwood Augustine is an applications engineer for Baker Hughes in the Rocky Mountain area. He has been with Baker Hughes for more than five years, with roles in operations, reliability engineering, drilling optimization and tool development. He earned a BS degree in petroleum engineering from Louisiana State University, and has been published in technical journals.
Steven Faulkner
Baker Hughes, a GE Company
Steven Faulkner is an applications engineer, Drilling Services, for Baker Hughes in the Rocky Mountain area. He joined the company in 2010 and has more than eight years of oilfield experience, including positions in field operations, engineering, product improvements and reliability. He has worked in the Williston, Piceance, Denver-Julesburg, San Juan, Uinta and Pinedale basins. Mr. Faulkner earned a BS degree in design from Purdue University.
Wolfgang John
Baker Hughes, a GE Company
Wolfgang John is Business Analytics and Strategy manager, Drilling Systems, for Baker Hughes in North America. He joined the company in 1997 after earning a BS degree in mechanical engineering from the Fachhochschule in Hannover, Germany. He has held roles in technical services, product support, application engineering and marketing in Baker Hughes.
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