Field Decommissioning - Chapter 1 PDF

Summary

This document provides an overview of the oil and gas decommissioning process, including discussions on project cycles, challenges, phases, causes of well abandonment, and financial and environmental aspects. It also presents relevant standards and guidelines.The document is suitable for undergraduate-level students studying oil and gas engineering or related fields.

Full Transcript

1.3 An oil and gas project cycle Source: Canadian Audit & Accountability Foundation n.d. Dr. Huyen Le Field Decommissioning 13 1.4 Challenges at the end of an oil & gas project cycle ❖ Output declines → Revenue will no longer su...

1.3 An oil and gas project cycle Source: Canadian Audit & Accountability Foundation n.d. Dr. Huyen Le Field Decommissioning 13 1.4 Challenges at the end of an oil & gas project cycle ❖ Output declines → Revenue will no longer surpass operating & maintenance costs ❖ Improvement of subsea tieback & extended reach technology → increase recoverable reserves & extend the production life BUT - Unplanned delays → additional expenditure (maintenance costs, insurance, bond premiums & fees to be paid until removal of installation) Source: Ferreira & Suslick 2000, p. 3 Dr. Huyen Le Field Decommissioning 14 1.6 Phases in the decommissioning process All activities managed by operator to support decommissioning process via planning & implementation A well isolated from the reservoir permanently Activities required to prepare the installation & associated infrastructure for total or partial removal Removal preparation, general management of removal vessel operations, offshore fastening of components, transportation & off-loading to an onshore yard… - Removal & management of subsea infrastructure - Returning the site to a state similar to that before development Near shore operations, breaking down of the asset once onshore & subsequent management of all waste streams Source: ARUP 2014, p. 19; Foreign & Commonwealth Office 2017, pp. 17-19 Dr. Huyen Le Field Decommissioning 25 2.1 Causes of well abandonment ❖ Temporary abandonment - Profitable but not having use options - Within production plans but being idle - Temporarily ceased to be repaired or prepared for use ❖ Permanent abandonment ❖ Non-profitable (well ending) ❖ Profitable but unsafe Source: POC1 2019; PVEP 2019a; Vrålstad et al. 2019, p. 478; Bộ Công thương 2020 Dr. Huyen Le Field Decommissioning 5 2.1 Causes of well abandonment ❖ Low oil prices → commercial viability & potential life extensions Decommissioning market → service contract prices Eg: Oil price on 19 September 2024 Text source: Offshore 2020 Figure source: Oilprice.com n.d. Dr. Huyen Le Field Decommissioning 6 2.1 Purposes of well abandonment → To emplace plugs consisting of cement plugs supported by mechanical plugs Text source: Walsh & Heagle 2016, p. 1 Image source: NORSOK Standard D-010, p. 105 Figure 1.1.2 Dr. Huyen Le Field Decommissioning 11 2.1 Environmental aims ❖ Of all P&A operations: Isolate & protect all fresh & near freshwater zones Figure 1.1.3 Figure 1.1.4 Text source: Abshire et al. 2012, p. 43 Figure source: Taha & Amani 2019, p. 4 Dr. Huyen Le Field Decommissioning 12 2.1 Environmental aims ❖ Of all P&A operations: Isolate & protect all future commercial zones Figure 1.1.5 Text source: Abshire et al. 2012, p. 43 Figure source: Diaz 2017 Dr. Huyen Le Field Decommissioning 13 2.1 Environmental aims ❖ Of all P&A operations: Prevent leaks in perpetuity from or into the well Figure 1.1.6: Potential leak paths Figure source: Vrålstad et al. 2019 Text source: Abshire et al. 2012, p. 43 Dr. Huyen Le Field Decommissioning 14 2.1 Financial aims ❖ P&A operations: time-consuming & costly - Offshore well abandonment costlier than onshore well abandonment - P&A costs: make up the majority of decommissioning costs (40%-60% of total decommissioning costs) E.g: ✓ North Sea: Up to £3 billion/year for decommissioning in the upcoming years, 50% of which on P&A ✓ UK: P&A costs over the next 30-40 years: $24 billion → Cost-efficiency → New cost-effective technologies, methods and solutions Source: Kaiser 2015, p. 200; Moeinikia et al. 2015, p. 2; Davison et al. 2017, p. 1; Smith & Tunget 2017, p. 4; Fam et al. 2018, p. 259; Vrålstad et al. 2019, p. 478 Dr. Huyen Le Field Decommissioning 16 2.2 TA definition ❖ Norway’s standards (NORSOK Standard D-010) Temporary abandonment – with monitoring - Well abandoned with primary and secondary well barriers continuously monitored & routinely tested - No maximum abandonment period Temporary abandonment – without monitoring - Well abandoned with primary and secondary well barriers NOT continuously monitored & NOT routinely tested - Maximum abandonment period to be 3 years Source: Standards Norway 2013, p. 84 Dr. Huyen Le Field Decommissioning 9 2.2 TA definition ❖ Vietnam’s legislation (Decision No. 10-VBHN-BCT & Circular 17/2020/TT-BCT ) TA seen as “bảo quản giếng” – use suitable fluids & install plugs & equipment inside the well to ensure safety in a defined period, after which the well can be explored, tested & produced conveniently - Well type 1: Wells need to be plugged for a long period (>3 years), including wells proved to be profitable but not having use options - Well type 2: Wells need to be temporarily plugged (1-3 years), including wells within production plans but being idle - Well type 3: Wells need to be shortly maintained (= External pressure → Burst loading → Surface pipe rupture → Surface pipe communication with the aquifer ❖ E.g.: Decision 10/VBHN-BCT (Art. 25) - Testing pressure of cement plugs > Pressure that tests the receivability of the formation at the outer casing shoe 500 psi - If the former much higher than the latter → Surface pipe rupture Figure 2.2.3 Text source: King & Valencia 2014, p. 10; Jerez 2015, pp. 37, 38 Figure source: DrillingFormulas.com 2014; Jerez 2015, p. 38 Dr. Huyen Le Field Decommissioning 11 2.5 Semisubmersible drilling rig ❖ Most expensive in UK waters (about US$5 to 6 million per well) ❖ One of the most expensive offshore activities (~ 3 million NOK per day for the rig alone) → rarely used for P&A ❖ Only viable option for P&A on the Norwegian Continental Shelf at water depths beyond the reach of jackup rigs ❖ Moves more slowly than a light well intervention vessel (LWIV) & must be used immediately at contract time Figure 2.3.2 Text source: Abshire et al. 2012, p. 44; Handal 2014, pp. 38, 39; Moeinikia et al. 2014, p. 2 Photo source: Rigzone n.d.b Dr. Huyen Le Field Decommissioning 8 2.5 Light well intervention vessel (LWIV) ❖ Advantages compared to rigs: - Significant cost savings (day rate for vessel: app. 30%-40% of rig cost) (cost falls between abandonment using a jackup rig & a semisubmersible rig) - Significant time savings (moving quickly and easily bw work site locations, operating with dynamic positioning) - Reduced operational times (30-60 hours) - Safer & more efficient lifting operations for well stubs, well heads & structures Source: Noble 2013; Agullar etal. 2016, p. 3 Dr. Huyen Le Field Decommissioning 10 2.5 Light well intervention vessel (LWIV) ❖ Used for Phase 0 (preparatory work) and complete Phase 3 (wellhead and conductor removal) in P&A ❖ P&A operations: - Kill the well - Punch the tubing - Set the deep-set and shallow temporary plugs - Remove the X-mas tree Source: Moeinikia et al. 2014, p. 2; Moeinikia et al. 2015, p. 5 Dr. Huyen Le Field Decommissioning 11 2.5 Wireline ❖ Run or pull tools or measurement devices into and out of the well to perform well interventions ❖ A continuous, small diameter cable with the attached equipment run in or out of the hole through an electro-hydraulic or diesel-powered winch ❖ Two cable systems: - Slickline: mechanical operations - Braided line (with or without an electric cable): tractor applications Figure 2.3.6 Text source: Henriksen 2013, pp. 110, 111 Figure source: Smith & Tunget 2017, p. 28 Dr. Huyen Le Field Decommissioning 13 2.5 Coiled tubing ❖ Like single strand wire (slickline) with the exception of a larger diameter and an internal passage for pumping fluids ❖ Operating mechanism: a flexible steel pipe (without connections) is run into and out of the well to perform different operations ❖ Used for cleaning out the well prior to a plug placement and for setting primary, secondary & surface barriers Figure 2.3.7 Text source: Henriksen 2013, p. 113 Figure source: Smith & Tunget 2017, p. 28 Dr. Huyen Le Field Decommissioning 14 2.6 Procedure and application ❖ Mill a window through all casing strings (cement pumped into the annuli and against the exposed formation) ❖ Remove any cement, settled mud or other debris from between the casing and the formation ❖ Used in many P&A operations globally Figure 2.4.3 Figure 2.4.4: Milled windows Source: Vrålstad et al. 2019, p. 485 Source: Abshire et al. 2012, p. 49 Text source: Abshire et al. 2012, p. 49; Vrålstad et al. 2019, p. 485 Dr. Huyen Le Field Decommissioning 8 2.6 Disadvantages of section milling Highly viscous drilling fluid Swarf Figure 2.4.5 Figure 2.4.6 Equivalent Circulating Densities > Easy damage of surface equipment the formation’s fracture gradient Losses while circulating, swabbing, well control, poor hole cleaning, and packing off of the Bottom Hole Assembly (BHA) Text source: Ferg et al. 2011, p. 1; Abshire et al. 2012, p. 49; Vrålstad et al. 2019, p. 485 Plug cementing: Photo source: Baker Huges n.d.; - Time-consuming → costly EPFL n.d. - Difficult to perform safely and effectively Dr. Huyen Le Field Decommissioning 9 2.6 PWC advantages - Remove old mud, swarf and settled mud weighting material from the annulus space through perforations → Eliminate the use of a high Equivalent Circulating Densities fluid to remove swarf → Reduce the potential of Bottom Hole Assembly’s “pack offs” - No need to section mill or cut-and-pull the casing → time efficient & cost-effective Source: Ferg et al. 2011, p. 2; Vrålstad et al. 2019, p. 485 Dr. Huyen Le Field Decommissioning 15 2.6 When to use which techniques? ❖ Quality of cement plugs set by SM better than by PWC ❖ PWC: more time-saving & thus cheaper AND executed more easily → Chosen instead of SM Figure 2.4.10: Barrier by Section Milling Figure 2.4.11: Barrier by PWC Source: Weatherford 2016 Source: Archer 2017 Dr. Huyen Le Field Decommissioning 18 2.6 Procedure and application ❖ Applied for some wells in the North Sea in 2013 ❖ Not commonly used in global P&A, especially for production wells ❖ Applied by PVEP team for SK305 project, offshore Malaysia, saving about US$5 million ❖ Nature of caprock: Create a non-permeable formation (caprock) above the production formation to prevent fluids from migrating to the surface Figure 2.4.12: Simplified illustration of a typical plug (PPGUA 3.0) and a caprock (OGUK & NORSOK) Source: PVEP 2019 Text source: PVEP 2019 Dr. Huyen Le Field Decommissioning 20 2.6 Advantages of caprock ❖ No retrieval of the whole production tubing to the surface → Limit risks → Save time/costs for P&A of production wells Figure 2.4.13: A P&A schematic using caprock Source: Yusof et al. 2018 Text source: PVEP 2019 Dr. Huyen Le Field Decommissioning 21 2.6 Advantages of caprock ❖ Suitable for wells with many packers & monobore wells ❖ For wells with poor annulus cement: much more cost-effective than Section Milling Figure 2.4.14: A typical offshore production well before and after P&A Text source: PVEP 2019 Source: Vrålstad et al. 2019, pp. 479, 480 Dr. Huyen Le Field Decommissioning 22

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