Dynamic instabilities of the bottomhole assembly (BHA) such as whirl, stick/slip, and bit bounce have been the focus of the majority of research studies in drilling vibrations. Recently, elevated levels of high-frequency rotational vibrations were recorded in the field with a high-bandwidth downhole vibration monitoring device. New experimental and numerical insights into this relatively unexplored phenomenon of high-frequency torsional oscillations are presented and discussed in this paper.
A suite of laboratory and field tests were conducted to understand and characterize the phenomenon. Computer modeling with in-house drillstring dynamics software corroborated well with the field measurements and validated the research team approach.
The investigation concluded that the drilling process excites BHA torsional vibrations. These vibrations occur at much higher frequencies than drill collar resonance and are significantly dependent on the drilled formation. New insights are gained into drilling dynamics in general and high-frequency torsional oscillations in particular.
The paper presents worldwide field case studies to illustrate the phenomenon. Details are provided of testing where the drilling environment is strategically controlled to characterize the dependence of these high-frequency torsional oscillations on bit design, operating parameters, and formation properties. The implications on drilling performance are also discussed in an attempt to satisfy the quest for efficient and reliable drilling.
Drilling vibration can be harmful to the bit and the bottomhole assembly (BHA), resulting in damage and tool failure and subsequent non-productive time (NPT). Bit damage while drilling offshore is costly, and any improvement in bit life can save multiple unplanned trips and lead to savings for operators. Consequently, dynamic dysfunctions have been the focus of industry research to understand and mitigate their effects.
In this paper, the authors present a field case study from an offshore application. A high-frequency, in-bit sensing device (1400-Hz sampling frequency) was installed into the bit shank in conjunction with a well-established measurement while drilling (MWD) tool in the BHA. The intent was to capture the dynamics behavior of the BHA and the dynamics directly at the bit. Multiple measurements along the BHA gave a better understanding of the behavior of the entire drilling system. The measurements were then used, along with dynamics modeling and simulation, to correlate bit and cutter damages with instances of backward whirl and stick/slip. The developed kinematic model of whirl corroborated well with measurements and showed how polycrystalline diamond compact (PDC) cutters can exhibit relative backward motion that potentially leads to severe cutter damage. The extended frequency range of the measurement module also enabled the capture of new dynamics phenomena at much higher frequencies than are usually reported in literature.
The insights gained in bit dynamics and cutter damage helped to improve bit design by building dynamically stable PDC bits with increased rate of penetration (ROP) and reduced NPT. The need for high-frequency measurements is also discussed and the benefits are presented, i.e., avoiding bit design iterations around misunderstood vibration issues. In today's challenging drilling applications, the measurements are important in characterizing the harsh drilling environment and understanding high-frequency dynamics phenomena that are rarely measured or discussed.
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