Use of Settable Spotting Fluid Improves Expandable Casing Process—Case History

New and innovative technology has a way of significantly influencing peripheral products and processes. A case-in-point is the relationship between solid expandable tubulars and cementing practices. The early years of cementing expandable casing were filled with researchers working to develop novel chemistries and resourceful techniques for annular sealants that varied from modified conventional cements to highly-specialized non-Portland systems such as resins. Experience and time relegated many of these chemistries and systems to specific situations. Instead of needing atypical techniques and unique products, the more effective and applicable approach with solid expandables consisted of modified placement practices, training, logistics, and refined engineering of conventional cementing methods. But, as solid expandable tubulars are installed in deeper and higher-angled wells, annular sealant methods and products will be required to function in more extreme conditions. This paper will examine the evolution of cementing processes and products for solid expandable tubulars. Emphasis is placed on best practices and lessons learned, with the intent of giving the reader a practical field guide. Checklists for key slurry design issues and how they correlate with the job logistics of the expansion operation will be included. This paper will also discuss foreseeable application trends in expandable use and logical modifications and enhancements in cementing procedures, technology and chemistries. Introduction Solid expandable tubulars have built a reputation as a practical and enabling technology with well over 600 installations in seven years. Initially used as a last resort to preserve hole size, the systems now are frequently planned into the original wellbore design to optimize hole size. The systems are being installed at greater depths and in more extreme conditions. Although the operating parameters are dynamic and continue to be redefined (Figure 1), the technology's provenance remains rooted in proven principles. Predecessor technology, such as expandable casing patches, has been used for decades, but significant differences include the following: Since the technology's inception, miles of solid expandable tubulars have been installed in diversely varied applications (Figure 2 & 3). An early concern in the development of these systems was that their use would require development of new and novel cementing products.1, 2 This issue is analogous to the concerns for extended reach drilling, slimhole drilling, casing drilling, and other specialized well construction methods. Cementing service suppliers acted accordingly, developing specialized extended-set cements, non-Portland cements, and even revisited mud-to-cement chemistry, also known as settable spotting fluids.3 This reaction was a natural response to ancillary processes required for new technology introduction. However, while these new systems are relevant and have all been successfully used, much of the early concern about the requirement for novel and unique cement systems or additives for solid expandable applications has abated. Common sense recognized that due diligence in planning and training, informational and logistical coordination between multiple service providers and modification of laboratory testing and pumping procedures allows adaptation of most existing cementing systems and engineering practices for solid expandable tubular installations. 4–6

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Extending the Frontiers of Solid Expandable Tubular Technology (SET): The Challenges - A Review of Installations in the Niger Delta

Owoeye

Nwabueze

Odita

et al. 2002

SPE Annual Technical Conference and Exhibition

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With the vision to improve production in SPDC by 20% (to over 1.0MMbopd) in the short term coupled with incessant community disturbance &the thrust to reduce environmental impact, most new wells favour utilising existing facilities and innovative technology to reduce cost &boost production. Expandable Tubular Technology (ETT) was one the key technologies identified for to achieve this. Over 150 wells were identified for this technology in the medium term with 3 wells selected as quick wins for deployment of the SET in 2001. The selection criteria were based on low risk, reduced unit technical cost and the need to extend the envelope of the technology. This paper focuses on the challenges encountered in the planning &execution phase. It addresses the contracting, procurement and logistics constraints associated with the first deployment of the technology outside the Gulf of Mexico. It emphasises the engineering considerations applied to assess the technical feasibility of deploying SET. The applications also utilised a novel cementing technique "Settable Spotting Fluid" from Halliburton to minimise the risk of cross flow &low side channelling, a common situation in high angle applications in the Niger Delta. Finally, It reviews the economic justifications and highlights the value of the technology (accelerated production, reduced risk cost &lost opportunity). The challenges encountered and mitigated during execution climaxed with the installation of the World's first horizontal Open Hole Liner (OHL) in Agbada 1ST. The successes have now extended the application of the technology from the current 20% of the global market to 80% of the global market (high-angle/horizontal wells) with a thrust of revolutionizing the concept of well delivery. What is SET? Expandable Tubular Technology or "Xwell" technology is a Shell group initiative to achieve a step change in drilling operations. It is grouped into Expandable Slotted Tubular (EST) &Solid Expandable tubular (SET). EST's are pipes with staggered but overlapping slots cut axially along its entire length(1). Expansion depends on the dimension and placement of slots and the size of the expansion cone. Expansion principle is based on bending the metal strips between two overlapping slots(1) thus requiring small expansion forces (~ 10 tons). SET on the contrary involves the cold working of steel to the required size at down hole conditions. It expands based on the principle of 3-D plastic deformation of the material and expansion forces are in order of 10–30 times that of an average EST(1). SET can be utilised in all facets of well life (drilling, intervention &abandonment). It has the potential to reduce the unit development costs by significantly down sizing wells, improving opportunities for complex designs (side-tracks/ML level 6), extended reach drilling and economic exploitation of oil and gas in hitherto uneconomic and hostile environments(2). In offshore operations it serves dual purpose; it can be used to reduce riser size thus necessitating a lower cost semi/drillship. In onshore operations, lighter capacity rigs could be used to deliver wells without a loss in potential. Background SPDC's drive to increase &sustain production at over 1.00MMbopd at reduced Unit Technical Cost favoured accelerated production achievable through the drilling of high-rate wells. Asset teams through the Volume for Value campaign (V2V) identified several candidate wells &in line with the drive to minimise the impact of oil exploitation to the environment (reduced land uptake, efficient and effective waste management, community disturbance etc), horizontal side-tracks were favoured to achieve this goal(2).

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Use of Settable Spotting Fluid Improves Expandable Casing Process—Case History

Cited by 3 publications

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Contamination effects of drilling fluid additives on cement slurry

Contamination effects of drilling fluid additives on cement slurry

Enhanced Cementing Practices Address Unique Issues Found With Solid Expandable Tubular Applications

Extending the Frontiers of Solid Expandable Tubular Technology (SET): The Challenges - A Review of Installations in the Niger Delta

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