| Title | A Comprehensive Evaluation of Drill Pipe Insulation for Downhole Temperature Management Using Physics-Based Models |
|---|---|
| Authors | Yuxing WU, Yifan ZHANG, Nassima BETTIR, Pradeepkumar ASHOK, Eric Van OORT |
| Year | 2025 |
| Conference | Stanford Geothermal Workshop |
| Keywords | Drill Pipe Insulation, Thermal Benefits, Hydraulics, Drill String Dynamics |
| Abstract | High bottom-hole temperature is a leading cause of downhole tool failure in geothermal wells, with the potential to significantly increase well construction costs. While investment is being made in the development of high-temperature tools, an alternative solution is presented by drill pipe insulation, which can help manage downhole temperatures effectively. This would allow continued use of existing tools developed primarily for the oil and gas industry. Various approaches to insulating drill pipes exist, each with its own advantages and drawbacks. This paper systematically reviews these approaches and evaluates their effects on drillstring hydraulics and dynamics using high-fidelity physics-based models, providing guidance on selecting the most appropriate insulation method for well construction. The insulation methods analyzed in this study include: (i) internally coated or lined drill pipes, (ii) drill pipes with external coatings, and (iii) dual-wall drill pipes with vacuum or insulating material between the walls. The study examines how these insulation methods impact temperature control and fluid behavior within geothermal wells, considering both full and partial insulation coverage. Two well configurations are considered: a deep (~8.5 km TVD) vertical well and a horizontal well of the same TVD but also having a 2 km lateral section. A comprehensive thermo-hydraulic model is used to analyze heat transfer between the drilling fluid and the surrounding rock formation, and the hydraulic implications of using insulated drill pipe, which typically have a smaller internal diameter or larger outer diameter when compared to conventional pipes. The insulation leads to higher pressure drops at equivalent flow rates. Additionally, the study explores the effects of insulated pipes on drillstring dynamics using a multi-degree-of-freedom lumped parameter model. This analysis aims to provide quantitative insights into the trade-offs of various drill pipe insulation methods, offering practical recommendations for their future application in geothermal well construction. |