Successful Cementing Case Study in Tuscaloosa HPHT Well

Ravi, Kris; Vargo, Richard F.; Cox, Bronwyn

doi:10.2118/115643-ms

Cited by 2 publications

(1 citation statement)

References 9 publications

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“…In each of these stages, the thermal and structural loads experienced by formation, cement sheath, and casing will change. The importance of similar life of the well analysis has been presented in earlier work involving noncreeping salts (Bosma et al 1999;Ravi et al 2008). Because of the longitudinal nature of the wellbore model, there is an axial variation of stress and wellbore pressure.…”

Section: Building Analysis Proceduresmentioning

confidence: 97%

Design Procedure for Cementing Intercalated Salt Zones

Jandhyala

Ravi

Anjos

2015

Day 1 Tue, October 27, 2015

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Wells often require being drilled through and cemented across salt formations. In many parts of the world, salt sections consist of multiple salt types. These include Halite, Carnallite and Tachyhydrite. The last two salt types could move one hundred times faster than Halite and are chemically reactive. Typically, Carnallite and Tachyhydrite occur as streaks inserted between Halite. In these cases, cement sheath should withstand salt creep loading. Creep load is primarily compressive in cases of single salt types. For intercalated salts, varying creep rates can result in tensile loads, particularly at salt-salt junctions. Presalt exploration in offshore Brazil is an apt example displaying this behavior. In such a scenario, the cement sheath along a longitudinal well section should be analyzed for both tensile and compressive responses. It is well known that tensile strength of conventional cement systems is low, hence there is the need for detailed analysis and action to prevent damage to cement sheath.This work demonstrates cement design procedures by evaluating cement sheath mechanical integrity in intercalated salts. A typical presalt Brazilian well with different lengths of Tachyhydrite, Halite, and Anhydrite sections is used as an example in this work. A creep model for these salts is validated with data from triaxial creep testing. Responses of two cement systems, which are cured and tested, are compared. The analysis accounts for classical well loads during drilling and production etc., along with salt creep loading.This analysis shows that intercalated salts subject cement sheath to a series of tensile and compressive loads whose magnitude depends on the size and relative position of different salts. The salt-salt interface effects dominated the general tenet of increasing creep rate with increasing depth.This kind of detailed design procedure representing intercalated salt zones is the first of its kind known to the authors. Results from this analysis help fortify the importance of considering salt layering patterns during cement design for long term mechanical integrity. The design procedure discussed and presented in this study should help the industry design cement systems to withstand loads across single and intercalated salt zones and maintain well integrity.

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Section: Building Analysis Proceduresmentioning

confidence: 97%

Design Procedure for Cementing Intercalated Salt Zones

Jandhyala

Ravi

Anjos

2015

Day 1 Tue, October 27, 2015

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Accurate Downhole-Temperature Estimates are Critical to Proper Slurry Design-Improved Data-Collection Method Field Tested Successfully

et al. 2011

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Temperature is a parameter of great importance when simulating and modeling cementing or temperature-activated fluids (McSpadden and Glover 2008) because it affects the amount of retarders or accelerators needed to avoid undesired phenomena, such as premature cement setting or incomplete consolidation of the treatments. In 1964, API introduced the first set of tables (API 2005) that listed the circulating temperatures and hydrostatic pressures for certain wellbore circumstances and bottomhole conditions and the fluids that could be used in different well treatments, such as cementing, lost-circulation control, and water or gas control, etc. The API procedures have been widely adopted and recognized in the oil industry, and most operating companies feel comfortable using them. However, increased demand for oil and gas has forced operators to perform drilling, completion, and maintenance operations in deeper and more complicated zones. These zones are often classified as high-pressure/high-temperature (HPHT) fields. Currently, combining computational tools, such as computer simulation software and measurement sensors, allows operators to accurately measure temperature and pressure values and adjust them with well-known heat-transfer models; as a result, possible temperature changes during complex operations can be more accurately modeled. This paper presents multiple case histories showing the significance of using bottomhole pressure/temperature (P/T) measurement tools and the modified modeling of the heat-transfer effects as a function of operational parameters (flow rate, density, wellbore geometry). With more accurate temperature data, laboratory testing can be performed to better predict the behavior of the treatments mentioned when exposed to the more complex bottomhole conditions encountered.

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Successful Cementing Case Study in Tuscaloosa HPHT Well

Cited by 2 publications

References 9 publications

Design Procedure for Cementing Intercalated Salt Zones

Design Procedure for Cementing Intercalated Salt Zones

Accurate Downhole-Temperature Estimates are Critical to Proper Slurry Design-Improved Data-Collection Method Field Tested Successfully

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