Wireless Propagation in a Metallic Pipe for the Transmission of Sensory Oil and Gas Well Data

The feasibility of a wireless system is examined for propagation inside an oil and gas well pipeline. The well bore environment is modeled as a circular aluminium pipe and treated as a metallic microwave waveguide. The experimentation test bed was based on the nominal diameters of commercially avail...

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Bibliographic Details
Published inIEEE antennas and wireless propagation letters Vol. 21; no. 6; pp. 1124 - 1128
Main Authors Kossenas, Konstantinos, Podilchak, Symon K., Beveridge, Martin
Format Journal Article
LanguageEnglish
Published New York IEEE 01.06.2022
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Aluminum
Circular waveguide
Data transmission
Diameters
Dipole antennas
Directivity
Experimentation
Gas pipelines
Gas wells
half-wave dipole
Loss measurement
Microwave frequencies
Modems
Natural gas
OFDM
oil and gas well
Oils
Orthogonal Frequency Division Multiplexing
Petroleum pipelines
pipeline
Pipelines
Pipes
Propagation modes
Real time
Real-time systems
sensory data
Software radio
Transceivers
transmission path loss
Waveguides
Wireless communication
Wireless communication systems
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Summary:The feasibility of a wireless system is examined for propagation inside an oil and gas well pipeline. The well bore environment is modeled as a circular aluminium pipe and treated as a metallic microwave waveguide. The experimentation test bed was based on the nominal diameters of commercially available oil and gas well pipelines. At the transceivers, half-wave dipole antennas operating at 2.5 GHz were employed. Due to the excitation frequency and the enclosed pipe environment, parameters such as the propagating mode, the directivity, and the realized effective gain of the antennas also needed to be investigated for this scenario. Additionally, a numerical transmission path loss model was developed and verified using full-wave simulations and measurements. The communications link facilitated the continuous monitoring of sensory data with real-time temperature and pressure levels transmitted using N210 universal software radio peripheral modems by National Instruments and symbol coding using orthogonal frequency division multiplexing. This study and experimental work can be a basis for the implementation of a high-speed wireless communications system for deployment inside oil and gas well pipelines for real-time data transmission at microwave frequencies.
ISSN:1536-1225
1548-5757
DOI:10.1109/LAWP.2022.3158805