Field Deployment of a Rigless Cable Deployed ESP Using a Vertical Wellhead

Roth, Brian A.; Xiao, Jie; Abdelaziz, Mohannad; Mack, John; Sarawaq, Yahya; Reid, Richard; Helvenston, Andrew

doi:10.2118/183821-ms

Cited by 6 publications

References 5 publications

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Advancing Electric Submersible Pump Alternative Deployment Technology: An Overview and Case Study

Roth

Xiao

Windiarto

et al. 2017

SPE Annual Technical Conference and Exhibition

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Traditional electric submersible pump (ESP) systems have drawbacks in terms of installation speed and efficiency. To overcome these obstacles, some alternatively deployed ESP systems, including the one selected, are deployed into the production tubing, subjecting the system to the properties of the produced fluids. A novel rigless-deployed ESP system developed for use in high hydrogen sulfide (H2S)/high chloride production environment is a solution. An initial step reviewed and ranked competing alternate deployment ESP technologies available in industry along with several new concepts. A new approach to alternate deployment technology was selected. Rigorous testing was conducted to qualify the selected technology and materials for harsh production environments. Testing included a modified NACE TM0175 test due to the processing of the power cable design. Integration testing was performed in a test well to validate the integrity and deployment of the new system prior to field deployment of the rigless-deployed ESP system. The cable deployed ESP (CD ESP) employs a fit-for-purpose power cable that incorporates an exterior metal jacket, providing strength to deploy ESPs thousands of feet into the well. The TransCoil system's power cable outside diameter is roughly 40% smaller than current 2-3/8-in cable-internal, coiled-tubing (CICT) systems; therefore, it is lighter in weight and reduces tubing pressure losses compared to previous products. Product reliability is enhanced as the power cable is fabricated in a continuous manufacturing and inspection process on a factory floor. The tightly controlled manufacturing process significantly improves the product quality over CT cable systems. The power cable can be fabricated from different metallurgies ranging from carbon steel to nickel allow based on the well requirements. A nickel alloy power cable laboratory qualified to 15% H2S and 150,000 ppm chlorides was field deployed in an onshore well and demonstrated an installation time reduction of nearly 50% over rig-deployed systems. A power cable rigless-deployed ESP system solves many of the challenges that currently plague the industry including operational efficiency, rapid replacement, and product reliability in wells in harsh environments worldwide. The power cable rigless-deployed ESP system has, in particular, the opportunity to transform ESP replacement in offshore wells.

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Advancing Electric Submersible Pump Alternative Deployment Technology: An Overview and Case Study

Roth

Xiao

Windiarto

et al. 2017

SPE Annual Technical Conference and Exhibition

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Rigless Deployment of Innovative Electrical Submersible Pumping System for First Time Worldwide

Winarno

Said

Shawly

et al. 2017

Day 2 Tue, November 14, 2017

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Electric Submersible Pumps (ESPs) is very popular artificial lift systems to boost oil production now days. Home ofmany ESP installations, with high frequency of change outs per year and with the harsh production environment, a development of ESP technologies to reduce change-out time and improve run life is keep ongoing. These technologies address business challenges timely in a proactive approach. Currently deployed ESPs require a time-consuming rig installation on jointed tubing. With several factors such as: an average run life of three years for ESPs, a rig-based change-out time of up to two weeks offshore, and an uncertainty of when a rig can be scheduled; the need for a more rapid rigless solution is critical for future operations. Majority of the ESP installation are completed as part of tubing completion and deployed by drilling rig which requires high spending to recover the well during ESP replacement. Several types of technologies to deploy ESP rig-lessly were introduced into industry to optimize the retrieval and deployment cost during ESP replacement. Limited success story was recorded and open more thought to overcome the challenges. The first worldwide new reliable cable rigless deployed electrical submersible pumping (ESP) system was successfully installed and put on production. What makes this system unique concept and the first worldwide of its kind are two main components. The first component is the innovative cable hanger design that insures total cable isolation while providing a non-restricted flow through the tubes that are built into the body of the spool. The second component is the specially designed and manufactured CT from selected material that has high resistance to H2S and CO2 and it was made exactly fit the ESP cable providing full protection from corrosive wellbore fluid. This design aimed to boost production of oil wells with lower ESPs installation and replacement cost. The new system eliminates the need for and expensive rig to replace the ESP and accelerate production restoration. This system will be a great addition especially for offshore environments where not only the rig intervention costs are expensive, but also limited rig availability can delay ESP replacement. This paper will share the concept, design, field implementation planning and technical challenges, lesson learnt during preparation and installation of this first of kind system.

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Case Study: Safe Thru-Tubing ESP Installation in Pressurized Well through Novel Killing Techniques

Abdelaziz

Roth

Xiao

2017

Day 2 Tue, November 14, 2017

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Cable Deployed ESPs (CD-ESPs) are foreseen as the future of ESP installations as they eliminate the need for full-fledge rig on location to perform ESP change out. One of the main challenges of performing ESP installation riglessly is the lack of mud circulation system which is used to monitor increase in fluid loss rate, indicate possible well kick and bring the well back to control in case of such emergencies. With the lack of this line of defense, there is a need to develop alternative method to ensure safe rigless ESP installation particularly when ESP components are being made-up and lowered down the well. The first high H2S vertical well CD-ESP worldwide was trial tested in a pressurized onshore well in Saudi Arabia. The candidate well had a shut-in pressure of 390psi, H2S concentration of 1.12% and fluid loss rate of 18-24 bbl per hour (bph) for 71 pound per cubic foot (pcf) kill fluid. Kill fluid has to be continuously supplied at a rate equivalent to the varying loss rate of the well. For this, the surface well testing equipment (required for well flow-back after ESP installation) was modified to monitor and store excess kill fluid return. The new modification allows pumping of kill fluid to continue while Blow-Out Preventer (BOP) equipment are open on top of the Christmas tree. The density of the kill fluid was monitored and maintained during the whole operation. The operation started by bullheading with one and a half wellbore volume. The well performance was monitored and then kill fluid rate was increased gradually to measure the loss rate of the well. Pumping of kill fluid was highly coordinated during the main installation phases of the CD-ESP: surface make-up of ESP assembly in sections, run in hole with cable to target depth and the final make-up of the cable hanger. The returns of any excess kill fluid could be measured by the modified surface testing package. Pumping rate of kill fluid was highly correlated with Tubing Casing Annulus (TCA) pressure since the volume of fluid in the annulus changed (due to the small contraction/expansion of the seal bore assembly). While the pump was inside the well, pumping kill fluid caused significant increase of weight reading. The pump (5.62") acted like a piston inside the (6.275") ID of the 7" tubing causing high weight values. At one point during the operation, the loss rate of the well increased dramatically. This caused negative readings on pressure gauges of the wellhead (loss rate was higher than maximum pump supply). The paper presents a novel comprehensive well killing measures for rig-less CD-ESP installation. To assure the safe conduct of future operations, the paper also shows lessons learnt and contingency measures for unexpected events during the operation.

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Field Deployment of a Rigless Cable Deployed ESP Using a Vertical Wellhead

Cited by 6 publications

References 5 publications

Advancing Electric Submersible Pump Alternative Deployment Technology: An Overview and Case Study

Advancing Electric Submersible Pump Alternative Deployment Technology: An Overview and Case Study

Rigless Deployment of Innovative Electrical Submersible Pumping System for First Time Worldwide

Case Study: Safe Thru-Tubing ESP Installation in Pressurized Well through Novel Killing Techniques

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