Acoustical data transmission through the wall of drill pipes is considered. Drill pipes are known to behave like bandpass filters; the position of the pass bands can be determined analytically. This work extends the frequency domain drill pipe models presented by Barnes and Kirkwood [J. Acoust. Soc. Am. 51, 1606–1608 (1972)], and more recently by Drumheller [J. Acoust. Soc. Am. 85, 1048–1064 (1989)]. The approach discussed in this paper has the advantage that it yields explicit expressions for the fine structure of the drill pipe’s frequency response in the pass bands. It furthermore allows the effect of energy dissipation and pipe segment length variations to be included in the model. The emphasis of the paper, however, lies on the time domain modeling of the drill pipe. The propagation of sound energy pulses through its wall, and the effect of multiple reflections and/or transmissions during this propagation, are described using a Markov chain. Explicit expressions result for the expected duration of an...
[1]
Ijbf Ivo Adan,et al.
Fitting Discrete Distributions on the First Two Moments
,
1995,
Probability in the Engineering and Informational Sciences.
[2]
A.A.F. van de Ven,et al.
Interaction of electromagnetic and elastic fields in solids
,
1975
.
[3]
Henk Tijms,et al.
Stochastic modelling and analysis: a computational approach
,
1986
.
[4]
Sw Sjoerd Rienstra,et al.
1-D reflection at an impedance wall
,
1988
.
[5]
T. G. Barnes,et al.
Passbands for Acoustic Transmission in an Idealized Drill String
,
1972
.
[6]
Douglas S. Drumheller.
Acoustical properties of drill strings: Theory
,
1988
.