A laboratory study to simulate hydrocarbon leakages and their induced sound
No. of Downloads: 0
No. of Files: 6646
File Size: 18.39 GB
File Format(s):
txt, BP file, xls, BP1, xlsx
Funded By:
National Academies of Sciences Gulf Research Program
Funding Cycle:
Safer Offshore Energy Systems 3
Research Group:
Passive Acoustic Technique for Detecting, Locating, and Characterizing Hydrocarbon Leakages
Zhiqu Lu
University of Mississippi
zhiqulu@olemiss.edu
underwater sound, oil leakage, bubble sound, methane, nitrogen, hydrophone, resonant frequency, total energy, flow rate, jet velocity, hydrocarbon, acoustic bubble, acoustic, hydrocarbon leakage
Abstract:
The U.S. outer continental shelf is a major source of energy for the United States. The rapid growth of oil and gas production in the Gulf of Mexico increases the risk of underwater oil spills at greater water depths and drilling wells. These hydrocarbons leakages can be caused by either natural events, such as seeping from fissures in the ocean seabed, or by anthropogenic accidents, such as leaking from broken wellheads and pipelines. In order to improve safety and reduce the environmental risks of offshore oil and gas operations, the Bureau of Safety and Environmental Enforcement recommended the use of real-time monitoring. An early warning system for detecting, locating, and characterizing hydrocarbon leakages is essential for preventing the next oil spill as well as for seafloor hydrocarbon seepage detection. Existing monitoring techniques have significant limitations and cannot achieve real-time monitoring. This project launches an effort to develop a functional real-time monitoring system that uses passive acoustic technologies to detect, locate, and characterize undersea hydrocarbon leakages over large areas in a cost-effective manner. In an oil spill event, the leaked hydrocarbon is injected into seawater with huge amounts of discharge at high speeds. With mixed natural gases and oils, this hydrocarbon leakage creates underwater sound through two major mechanisms: shearing and turbulence by a streaming jet of oil droplets and gas bubbles, and bubble oscillation and collapse. These acoustic emissions can be recorded by hydrophones in the water column at far distances. They will be characterized and differentiated from other underwater noises through their unique frequency spectrum, evolution and transportation processes and leaking positions, and further be utilized to detect and position the leakage locations. With the objective of leakage detection and localization, our approach consists of recording and modeling the acoustic signals induced by the oil-spill and implementing advanced signal processing and triangulation localization techniques with a hydrophone network. Tasks of this project were: 1. Conduct a laboratory study to simulate hydrocarbon leakages and their induced sound under controlled conditions, and to establish the correlation between frequency spectra and leakage properties, such as oil-jet intensities and speeds, bubble radii and distributions, and crack sizes. 2. Implement and develop acoustic bubble modeling for estimating features and strength of the oil leakage. 3. Develop a set of advanced signal processing and triangulation algorithms for leakage detection and localization. The experimental data have been collected in a water tank in the building of the National Center for Physical Acoustics, the University of Mississippi from 2018-2020, including hydrophone recorded underwater sounds generated by oil leakage bubbles under different testing conditions, such as pressures, flow rates, jet velocities, and crack sizes, and movies of oil leakages. Two types of oil leakages (a few bubbles and constant flow bubbles) were tested to simulate oil seepages either from seafloors or from oil well and pipe-line breaches. Two types of gases were investigated (nitrogen and methane). These data were analyzed for acoustic bubble modeling, oil leakage characterization, and localization. This dataset contains data for acoustic bubble sound modeling of nitrogen and methane, using a range of jet sizes and flow rates. The data for oil leakage source localization is available under GRIIDC Unique Dataset Identifier (UDI): S3.x911.000:0003 (DOI: 10.7266/4S9EBZKX).
Suggested Citation:
Lu, Zhiqu. 2023. A laboratory study to simulate hydrocarbon leakages and their induced sound. Distributed by: GRIIDC, Harte Research Institute, Texas A&M University–Corpus Christi. doi:10.7266/NPYZ3XFV
Purpose:
Conduct a laboratory study to simulate hydrocarbon leakages and their induced sound under controlled conditions, and to establish the correlation between frequency spectra and leakage properties, such as oil-jet intensities and speeds, bubble radii and distributions, and crack sizes.
Data Parameters and Units:
Recorded and processed bubble sounds (volt). This dataset contains recorded and processed laboratory test data. The folders of the dataset are described as follows: • the folders of “signals” contain raw underwater sounds in both excel and LabView formats. • the folders of “flow rates” contain flow rates for constant flow bubbles tests. • the folders of “results” contain processed data, such as histograms, resonant frequencies, and the total energy. More details of this dataset can be found in the corresponding ReadMe files in each folder.
Methods:
The experimental data have been collected in a water tank in the building of the National Center for Physical Acoustics, the University of Mississippi from 2018-2020, including hydrophone recorded underwater sounds generated by oil leakage bubbles under different testing conditions, such as pressures, flow rates, jet velocities, and crack sizes, and movies of oil leakages. Two types of oil leakages (a few bubbles and constant flow bubbles) were tested to simulate oil seepages either from seafloors or from oil well and pipe-line breaches. Two types of gases were investigated (nitrogen and methane). These data were analyzed for acoustic bubble modeling, oil leakage characterization, and localization.
Instruments:
The signals were recorded by seven hydrophones. For detailed description of the experimental setup, see the link:https://egrove.olemiss.edu/grpds.
Provenance and Historical References:
For detailed description of the experimental setup, see the link: https://egrove.olemiss.edu/grpds.