Challenging Wellbore Cleanouts With Coiled Tubing Made Easy With Computer Modeling Technology

Nasr‐El‐Din, Hisham A.; Al-Anazi, Mohammed Alhabib; Balto, Abdulelah Adel; Proctor, Robert; Saleh, Raed M

doi:10.2118/100129-ms

Cited by 13 publications

(6 citation statements)

References 10 publications

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“…Nitrifi ed cleanouts have been successfully used a number of times in the industry on low-pressure wells (Li et al 2008b, c;Nasr-El-Din et al 2006). Nitrifi ed cleanouts have been successfully used a number of times in the industry on low-pressure wells (Li et al 2008b, c;Nasr-El-Din et al 2006).…”

Section: Selecting the Cleanout Methodsmentioning

confidence: 99%

Pushing the Boundaries of Concentric-Coiled-Tubing Technology To Resurrect Subhydrostatic Gas Wells on an Unmanned Offshore Installation

Davies

Dunning

Kuchel

et al. 2012

SPE Production &Amp; Operations

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Ravenspurn North is a mature gas field in the southern North Sea with 42 wells, drilled (and many hydraulically fractured) in the late 1980s. By 2006, more than half of the wells had ceased to flow, and many were flowing intermittently. With ailing wells and consequently falling production rates, the longer-term future for Ravenspurn North field was uncertain.A wireline campaign suggested a common failure mode for many wells: Large amounts of proppant had accumulated in the wellbore. Modeling of the potential range of static and dynamic pressure losses caused by this proppant supported a significant enhancement to the remaining gas potential. However, the depths of the wells combined with subhydrostatic pressure conditions and large-diameter lower completions made achieving cleanout challenging. Furthermore, the target wells were located on unmanned offshore installations with minimal facilities, deck space, and deck loading.This paper details how each of these obstacles was successfully tackled to reinstate a target set of wells. It describes the various cleanout options that were considered, and why concentric-coiledtubing vacuum technology (CCTVT) was ultimately selected. Before this project, CCTVT had never been deployed in the North Sea, and nowhere in the world at these reservoir depths. The operation was delivered on the small unmanned installation by conducting the world's first boat-spooling operation of concentric coiled tubing (CCT); rigorously reassessing deck loadings; and running the operation completely self-sufficiently, with a maximum of 10 personnel onboard.Finally, this paper provides a detailed description of the successful CCTVT operations that recovered a total of 2,950 lbm of proppant from three wells to expose the perforations and unload the wells of liquid. Furthermore, CCT was used to mill out tubingprofile nipples and install a packer to hang off 1,200 ft of flushjoint tail pipe. Innovative thinking and close collaboration between operator and service companies were required, because the ability to perform multiple operations on CCT was in itself pioneering.Overall, this campaign has pushed the boundaries of intervention technology to deliver an extremely challenging project. This has resulted in a more-certain future for the Ravenspurn North field, as well as newly unlocked opportunities in deep depleted gas wells worldwide.

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Section: Selecting the Cleanout Methodsmentioning

confidence: 99%

Pushing the Boundaries of Concentric-Coiled-Tubing Technology To Resurrect Subhydrostatic Gas Wells on an Unmanned Offshore Installation

Davies

Dunning

Kuchel

et al. 2012

SPE Production &Amp; Operations

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“…Several cleanout techniques have been developed over the years, these include stationary circulation, wiper tripping (1,2,(4)(5)(6)(7)(8)(9)(10)(11)(12)(13)(14)(15)(16)(17)(18) , reverse circulation (19)(20)(21)(22) , sand vacuuming technology (23)(24)(25)(26)(27)(28)(29)(30)(31)(32)(33)(34)(35)36,37) , and venturi sand/junk bailers (4,22,(38)(39)(40) .…”

Section: Sand Cleanout Methodsmentioning

confidence: 99%

“…Wiper Trip Hole Cleaning (2,(4)(5)(6)(7)(8)(9)(10)(11)(12)(13)(14)(15)(16)(17)(18) A comprehensive experimental test program conducted over the past 15 years (7)(8)(9)(10)(11)(12) has investigated solids transport for both stationary circulation and wiper trip cleanouts. The effect of multiphase flow, rate of penetration (ROP), deviation angle, circulation fluid properties, particle density and size, fluid rheology, pipe eccentricity, wiper trip speed, and nozzle type on solids transport was examined in detail.…”

Section: Conventional Hole Cleaning Methodsmentioning

confidence: 99%

“…Based on this research, an effective solids-cleanout methodology/process using CT [see Figures 4(a) and (4c)] has been developed and proven by field operations (1,2,4,6,(14)(15)(16)(17)(18) . This patented (13) methodology is embodied in a comprehensive solids-transport simulator (10) and the method is further enhanced by a specialized downhole cleanout tool ( Figure 5).…”

Section: Conventional Hole Cleaning Methodsmentioning

confidence: 99%

“…The cleanout fluid is circulated through low energy uphole-facing nozzles which reentrain solids that have settled on the low side of the hole for subsequent transport along the wellbore. The methodology/process takes advantage of improved hole cleaning from jetting in the uphole direction, while tripping out of hole at a computed wiper trip speed (14)(15)(16)(17)(18) . "Wiper tripping," as defined in this paper, is the movement of the CT and bottom hole assembly (BHA) out of the hole a certain distance or to surface, while continuously circulating cleanout fluid through the wash nozzle or circulating valve if used.…”

Section: Conventional Hole Cleaning Methodsmentioning

confidence: 99%

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Sand Cleanouts With Coiled Tubing: Choice of Process, Tools and Fluids

Li¹,

Misselbrook²,

Sach³

2010

Journal of Canadian Petroleum Technology

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Summary Cleaning fill from wellbores is the most common coiled tubing (CT) application. The process is a function of multiple variables including fluid properties, flow velocities, wellbore geometry and deviation, pipe eccentricity, particle properties, fill penetration rate and wiper trip speed. Removing fill from wells with low bottom hole pressures (BHP) can be challenging especially if wells are completed with smaller diameter production tubulars which significantly reduce circulation flow cross-section and choke flow(1). Such challenges are further compounded by high deviation or horizontal well trajectories especially in large diameter wellbores. A variety of cleanout methods have been developed in the past, often incorporating high circulation rates, special fluids, wiper trips, or reverse circulation to remove solids. Many of these conventional sand cleanout methods often apply excess hydrostatic pressure on the formation, resulting in lost circulation in pressure depleted reservoirs. The conventional solution to overcome excess hydrostatic pressure has been to include nitrogen to reduce fluid density and thus lessen the hydrostatic head; however, sand vacuuming technology using a concentric coiled tubing (CCT) with a downhole jet pump is an alternative technique for removing fill without placing a hydrostatic load on the reservoir. This paper reviews the individual sand cleanout systems and discusses the advantages and limitations related to each method. In recent years, cleaning sand using the wiper trip method has become the preferred technique. However, an appropriate pump rate and reservoir pressure are needed to maintain a proper return flow rate to carry the sands to the surface. For pressure-depleted reservoirs completed with horizontal wells, a sand vacuuming system can be used to efficiently remove the debris without circulating nitrogen and without high pump rates. When the fill cannot be removed from large-diameter deviated wellbores using conventional low-cost cleanout fluids, then fluids with high solids suspension capability (under shear conditions) in conjunction with wiper tripping may be an economical option. The main application for the reverse circulation technique is cleaning sand from large diameter wellbores when the necessary pump rates for conventional "forward" circulation are not achievable. A venturi junk bailer is often used to retrieve larger or heavier material which cannot be circulated out by traditional methods. Field cases are provided, demonstrating how to select the proper cleaning method and how to efficiently remove sand from a wellbore based on both operational and logistical conditions.

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Repeatedly Increased Efficiency and Success Rate from a New Solids-Cleanout Process Using Coiled Tubing: A Review of Recent Achievements from Over 100 Operations

Sach¹,

Li²

2007

All Days

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Solids-cleanouts using Coiled Tubing (CT) remain a major part of total activity in the CT industry. Due to the multitude of parameters that influence solids-transport, it can be very challenging to design and successfully execute solids- cleanouts with CT in highly deviated, larger wellbores with e.g. 7″ production tubing, or even larger tubulars installed. Numerous papers have been written about the development of wiper trip cleanout technology and associated engineering design tools, but this paper is instead focused on important practical issues that directly impact the effective implementation of wiper trip technology in the field. This paper presents the results and lessons learned based on a database, which was compiled from more than 100 solids- cleanout operations using "wiper trip" methodologies. Results will be presented showing how the wiper trip cleanout methodology has improved cleanout efficiency and success rate. Examples are presented showing how the effectiveness of cleanout-bottom hole assemblies (BHA's) involving positive displacement motors (PDMs) and mills has been improved, while simultaneously reducing stress on surface equipment during the operation. Circulation rates higher than specified maximum rates for the PDM are being used without danger of damaging the PDM while reducing the total volume pumped through the PDM during the cleanout by 80–90%. Larger outer diameter (OD) items in the BHA are kept clean of solids while wiper tripping, reducing the risk of stuck CT and protecting sensitive completion components from undesirable interactions with the PDM/mill-BHA. Multiple wiper trips can be performed in one run without the use of drop balls, while having the ability of using selected functions of critical BHA components and full-size drifting of the wellbore for subsequent operations. Field proven procedures are explained, allowing solids-loading in the annulus to be controlled and reduced when necessary, as well as estimates of solids- volumes during the cleanout to be established, based on feedback from the cleanout BHA before any solids have actually reached surface. Background It is a known fact that many CT operations start with a cleanout before being able to conduct other work in the wellbore. A review of all CT operations performed in the Norwegian sector of the North Sea since 2001 shows that 74% of the CT operations involve cleanouts of solids from the wellbore. This is reason enough to concentrate on performing repeatedly successful cleanouts, so that the process is economical and allows subsequent operations in the wellbore to continue as planned. Solids-transport is affected by many variables and the complexity of the phenomena presents challenges to the field engineer who is trying to determine how the parameters affect solids-transport even as one, or more than one, of the variables are changing during an operation. Most of the previous solids- transport studies in the oil industry mainly focused on finding the minimum critical velocity in the wellbore annulus for conventional rotary drilling with mud fluids. The studies lack information related to the prediction of the equilibrium solids- bed's height during tripping in, the wiper trip speed during tripping out, and the prediction of the hole-cleaning time. In field operations, people often use outdated "rules of thumb", i.e., 2 hole volumes circulation to clean the well, annular fluid velocity two times of the solids-settling velocity or performing cleanout stages of a certain length. In our previous studies1–6, a comprehensive experimental test of solids-transport for both the stationary circulation and the wiper trip was conducted. The effect of multi-phase flow, rate of penetration (ROP), deviation angle, circulation fluid properties, particle density and size, fluid rheology, pipe eccentricity, wiper trip speed and nozzle type on solids- transport was investigated.

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Challenging Wellbore Cleanouts With Coiled Tubing Made Easy With Computer Modeling Technology

Cited by 13 publications

References 10 publications

Pushing the Boundaries of Concentric-Coiled-Tubing Technology To Resurrect Subhydrostatic Gas Wells on an Unmanned Offshore Installation

Pushing the Boundaries of Concentric-Coiled-Tubing Technology To Resurrect Subhydrostatic Gas Wells on an Unmanned Offshore Installation

Sand Cleanouts With Coiled Tubing: Choice of Process, Tools and Fluids

Repeatedly Increased Efficiency and Success Rate from a New Solids-Cleanout Process Using Coiled Tubing: A Review of Recent Achievements from Over 100 Operations

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