REAL-TIME DETECTION OF SOLID AND LIQUID CONTAMINANTS IN NATURAL GAS STREAMS USING MICROWAVE SENSING TECHNOLOGY

Nicholas Chan; Kamal K. Botros; Mohammed Saif Ur Rahman; Mohamed Abou-Khousa; Mohamed Alshehhi; Khaled Al-Wahedi; Keith Leong

doi:10.1115/IPC2024-133876

REAL-TIME DETECTION OF SOLID AND LIQUID CONTAMINANTS IN NATURAL GAS STREAMS USING MICROWAVE SENSING TECHNOLOGY

Nicholas Chan, Kamal K. Botros, Mohammed Saif Ur Rahman, Mohamed Abou-Khousa, Mohamed Alshehhi, Khaled Al-Wahedi, Keith Leong

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

1 Scopus citations

Abstract

The production and transportation of high-quality natural gas, that is free of liquid/solid contaminants, is critical to fulfilling the increasing global demand of this commodity. Despite several mitigation strategies from natural gas producers and distributors, liquid and solid contaminants are still commonly found within natural gas pipelines. As such, a need exists for real-time detection of these contaminants, within natural gas pipelines, in order to determine contaminant sources and reduce contaminant quantities. In this study, an in-line, non-perturbing, real-time, microwave-based contaminants sensing technology was developed and tested at a natural gas test facility located in Alberta, Canada. The contaminants detector was installed on DN150 pipe and tested over a gas velocity range of 1.3-13.2 m/s. First, glass oxide particles were intermittently injected into the gas stream immediately upstream of the detector. Two different glass oxide particles were tested with particle diameter ranges of 44–88 μm and 88–149μm. Second, liquid contaminant, in the form of compressor lubrication oil, was atomized into the gas stream immediately upstream of the detector. Three types of atomizing nozzles were used in conjunction with liquid injection pumps to test liquid injection rates in the range of 0.07-0.7 L/min. Liquid and solid contaminants were successfully detected using the standard deviation of in-phase and quadrature baseband voltage measurements from the contaminants detector. This paper quantitatively evaluates the solid/liquid contaminants detection performance of this detector in the context of natural gas pipeline applications.

Original language	British English
Title of host publication	Operations, Monitoring, and Maintenance; Materials and Joining
ISBN (Electronic)	9780791888568
DOIs	https://doi.org/10.1115/IPC2024-133876
State	Published - 2024
Event	2024 15th International Pipeline Conference, IPC 2024 - Calgary, Canada Duration: 23 Sep 2024 → 27 Sep 2024

Publication series

Name	Proceedings of the Biennial International Pipeline Conference, IPC
Volume	3

Conference

Conference	2024 15th International Pipeline Conference, IPC 2024
Country/Territory	Canada
City	Calgary
Period	23/09/24 → 27/09/24

Keywords

Liquid contaminants
Monitoring
Natural gas
Operations Monitoring & Maintenance
Pipelines & Facilities Integrity
Solid contaminants
Station Piping

Access to Document

10.1115/IPC2024-133876

Cite this

Chan, N., Botros, K. K., Saif Ur Rahman, M., Abou-Khousa, M., Alshehhi, M., Al-Wahedi, K., & Leong, K. (2024). REAL-TIME DETECTION OF SOLID AND LIQUID CONTAMINANTS IN NATURAL GAS STREAMS USING MICROWAVE SENSING TECHNOLOGY. In Operations, Monitoring, and Maintenance; Materials and Joining Article v003t04a020 (Proceedings of the Biennial International Pipeline Conference, IPC; Vol. 3). https://doi.org/10.1115/IPC2024-133876

@inproceedings{4c6a5ef2920647a38d9afb769577df24,

title = "REAL-TIME DETECTION OF SOLID AND LIQUID CONTAMINANTS IN NATURAL GAS STREAMS USING MICROWAVE SENSING TECHNOLOGY",

abstract = "The production and transportation of high-quality natural gas, that is free of liquid/solid contaminants, is critical to fulfilling the increasing global demand of this commodity. Despite several mitigation strategies from natural gas producers and distributors, liquid and solid contaminants are still commonly found within natural gas pipelines. As such, a need exists for real-time detection of these contaminants, within natural gas pipelines, in order to determine contaminant sources and reduce contaminant quantities. In this study, an in-line, non-perturbing, real-time, microwave-based contaminants sensing technology was developed and tested at a natural gas test facility located in Alberta, Canada. The contaminants detector was installed on DN150 pipe and tested over a gas velocity range of 1.3-13.2 m/s. First, glass oxide particles were intermittently injected into the gas stream immediately upstream of the detector. Two different glass oxide particles were tested with particle diameter ranges of 44–88 μm and 88–149μm. Second, liquid contaminant, in the form of compressor lubrication oil, was atomized into the gas stream immediately upstream of the detector. Three types of atomizing nozzles were used in conjunction with liquid injection pumps to test liquid injection rates in the range of 0.07-0.7 L/min. Liquid and solid contaminants were successfully detected using the standard deviation of in-phase and quadrature baseband voltage measurements from the contaminants detector. This paper quantitatively evaluates the solid/liquid contaminants detection performance of this detector in the context of natural gas pipeline applications.",

keywords = "Liquid contaminants, Monitoring, Natural gas, Operations Monitoring \& Maintenance, Pipelines \& Facilities Integrity, Solid contaminants, Station Piping",

author = "Nicholas Chan and Botros, \{Kamal K.\} and \{Saif Ur Rahman\}, Mohammed and Mohamed Abou-Khousa and Mohamed Alshehhi and Khaled Al-Wahedi and Keith Leong",

note = "Publisher Copyright: Copyright {\textcopyright} 2024 by ASME.; 2024 15th International Pipeline Conference, IPC 2024 ; Conference date: 23-09-2024 Through 27-09-2024",

year = "2024",

doi = "10.1115/IPC2024-133876",

language = "British English",

series = "Proceedings of the Biennial International Pipeline Conference, IPC",

booktitle = "Operations, Monitoring, and Maintenance; Materials and Joining",

}

Chan, N, Botros, KK, Saif Ur Rahman, M , Abou-Khousa, M , Alshehhi, M , Al-Wahedi, K & Leong, K 2024, REAL-TIME DETECTION OF SOLID AND LIQUID CONTAMINANTS IN NATURAL GAS STREAMS USING MICROWAVE SENSING TECHNOLOGY. in Operations, Monitoring, and Maintenance; Materials and Joining., v003t04a020, Proceedings of the Biennial International Pipeline Conference, IPC, vol. 3, 2024 15th International Pipeline Conference, IPC 2024, Calgary, Canada, 23/09/24. https://doi.org/10.1115/IPC2024-133876

REAL-TIME DETECTION OF SOLID AND LIQUID CONTAMINANTS IN NATURAL GAS STREAMS USING MICROWAVE SENSING TECHNOLOGY. / Chan, Nicholas; Botros, Kamal K.; Saif Ur Rahman, Mohammed et al.
Operations, Monitoring, and Maintenance; Materials and Joining. 2024. v003t04a020 (Proceedings of the Biennial International Pipeline Conference, IPC; Vol. 3).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - REAL-TIME DETECTION OF SOLID AND LIQUID CONTAMINANTS IN NATURAL GAS STREAMS USING MICROWAVE SENSING TECHNOLOGY

AU - Chan, Nicholas

AU - Botros, Kamal K.

AU - Saif Ur Rahman, Mohammed

AU - Abou-Khousa, Mohamed

AU - Alshehhi, Mohamed

AU - Al-Wahedi, Khaled

AU - Leong, Keith

PY - 2024

Y1 - 2024

N2 - The production and transportation of high-quality natural gas, that is free of liquid/solid contaminants, is critical to fulfilling the increasing global demand of this commodity. Despite several mitigation strategies from natural gas producers and distributors, liquid and solid contaminants are still commonly found within natural gas pipelines. As such, a need exists for real-time detection of these contaminants, within natural gas pipelines, in order to determine contaminant sources and reduce contaminant quantities. In this study, an in-line, non-perturbing, real-time, microwave-based contaminants sensing technology was developed and tested at a natural gas test facility located in Alberta, Canada. The contaminants detector was installed on DN150 pipe and tested over a gas velocity range of 1.3-13.2 m/s. First, glass oxide particles were intermittently injected into the gas stream immediately upstream of the detector. Two different glass oxide particles were tested with particle diameter ranges of 44–88 μm and 88–149μm. Second, liquid contaminant, in the form of compressor lubrication oil, was atomized into the gas stream immediately upstream of the detector. Three types of atomizing nozzles were used in conjunction with liquid injection pumps to test liquid injection rates in the range of 0.07-0.7 L/min. Liquid and solid contaminants were successfully detected using the standard deviation of in-phase and quadrature baseband voltage measurements from the contaminants detector. This paper quantitatively evaluates the solid/liquid contaminants detection performance of this detector in the context of natural gas pipeline applications.

AB - The production and transportation of high-quality natural gas, that is free of liquid/solid contaminants, is critical to fulfilling the increasing global demand of this commodity. Despite several mitigation strategies from natural gas producers and distributors, liquid and solid contaminants are still commonly found within natural gas pipelines. As such, a need exists for real-time detection of these contaminants, within natural gas pipelines, in order to determine contaminant sources and reduce contaminant quantities. In this study, an in-line, non-perturbing, real-time, microwave-based contaminants sensing technology was developed and tested at a natural gas test facility located in Alberta, Canada. The contaminants detector was installed on DN150 pipe and tested over a gas velocity range of 1.3-13.2 m/s. First, glass oxide particles were intermittently injected into the gas stream immediately upstream of the detector. Two different glass oxide particles were tested with particle diameter ranges of 44–88 μm and 88–149μm. Second, liquid contaminant, in the form of compressor lubrication oil, was atomized into the gas stream immediately upstream of the detector. Three types of atomizing nozzles were used in conjunction with liquid injection pumps to test liquid injection rates in the range of 0.07-0.7 L/min. Liquid and solid contaminants were successfully detected using the standard deviation of in-phase and quadrature baseband voltage measurements from the contaminants detector. This paper quantitatively evaluates the solid/liquid contaminants detection performance of this detector in the context of natural gas pipeline applications.

KW - Liquid contaminants

KW - Monitoring

KW - Natural gas

KW - Operations Monitoring & Maintenance

KW - Pipelines & Facilities Integrity

KW - Solid contaminants

KW - Station Piping

UR - http://www.scopus.com/inward/record.url?scp=85213692899&partnerID=8YFLogxK

U2 - 10.1115/IPC2024-133876

DO - 10.1115/IPC2024-133876

M3 - Conference contribution

AN - SCOPUS:85213692899

T3 - Proceedings of the Biennial International Pipeline Conference, IPC

BT - Operations, Monitoring, and Maintenance; Materials and Joining

T2 - 2024 15th International Pipeline Conference, IPC 2024

Y2 - 23 September 2024 through 27 September 2024

ER -

Chan N, Botros KK, Saif Ur Rahman M , Abou-Khousa M , Alshehhi M , Al-Wahedi K et al. REAL-TIME DETECTION OF SOLID AND LIQUID CONTAMINANTS IN NATURAL GAS STREAMS USING MICROWAVE SENSING TECHNOLOGY. In Operations, Monitoring, and Maintenance; Materials and Joining. 2024. v003t04a020. (Proceedings of the Biennial International Pipeline Conference, IPC). doi: 10.1115/IPC2024-133876

REAL-TIME DETECTION OF SOLID AND LIQUID CONTAMINANTS IN NATURAL GAS STREAMS USING MICROWAVE SENSING TECHNOLOGY

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Keywords

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