SPE Drilling & Completion
Volume 24, Number 1, March 2009, pp. 25-39

SPE-105885-PA

Optimization of Deep-Drilling Performance--Benchmark Testing Drives ROP Improvements for Bits and Drilling Fluids

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DOI  More information 10.2118/105885-PA http://dx.doi.org/10.2118/105885-PA

Citation

  • Judzis, A., Bland, R.G., Curry, D.A., Black, A.D., Robertson, H.A., Meiners, M.J., and Grant, T.C. 2009. Optimization of Deep-Drilling Performance--Benchmark Testing Drives ROP Improvements for Bits and Drilling Fluids. SPE Drill & Compl  24 (1): 25-39. SPE-105885-PA.

Discipline Categories

  • 1 Drilling and Completions

Summary

A critical cost in future deep-oil and -gas recovery is the cost to drill a well. This cost is dominated by the rate of penetration (ROP) that becomes increasingly important with increasing depth. Improving the technology of drilling and increasing the ROP was the object of full-scale laboratory testing conducted under a joint industry and Department of Energy (DOE) program titled "Improving Deep Drilling Performance" (Black and Judzis 2003). Simulations of deep-well drilling in the Arbuckle play and the Tuscaloosa trend were accomplished during 16 full-scale, high-pressure tests using four different 6-in. drill bits, three types of rock, and five different drilling fluids.

This paper describes what is believed to be the first set of full-scale laboratory drilling tests yet performed at bottomhole pressures in excess of 10,000 psi. Accomplishments of the testing and analysis include the following:

  • Laboratory data was compared with field data to confirm that the simulated laboratory conditions provided similar results to what would be expected in the field.
  • ROP reductions were significant when "mudding up" at high bottomhole pressures.
  • Polycrystalline-diamond-compact (PDC) bits provided substantially higher ROP performance than impregnated or roller-cone bits in the environment of this study.
  • The relationship between ROP and confined-rock strength is not a simple function of bottomhole pressure alone.
  • The mechanical specific energy (MSE) when drilling at high bottomhole pressure is often substantially higher than the rock's compressive strength, even when the bit is drilling efficiently.
  • Fluid invasion of intact rock and of rock broken up by the bit's cutting structure seems to play a major role in controlling ROP at these high bottomhole pressures.
  • Drilling-fluid compositions and properties that promote invasion without provoking formation damage, and bit-design features that facilitate the removal of rock debris from the hole bottom, hold promise for improving drilling efficiency in hard rock drilled at high bottomhole pressures.

© 2009. Society of Petroleum Engineers

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History

  • Original manuscript received: 22 November 2006
  • Meeting paper published: 20 February 2007
  • Manuscript approved: 25 February 2008
  • Published online: 16 March 2009
  • Version of record: 1 March 2009