Meso-scale testing and development of test procedures to maintain mass balance

Meso-scale testing and development of test procedures to maintain mass balance

The Conrad Blucher Institute for Surveying and Science (Texas A&M University––Corpus Christi) has conducted numerous petroleum experiments at the Shoreline Environmental Research Facility (Corpus Christi, Texas, USA). The meso-scale facility has multiple wave tanks, permitting some control in ex...

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Bibliographic Details
Published in:Marine pollution bulletin Vol. 47; no. 9; pp. 406 - 414
Main Authors: Bonner, James, Page, Cheryl, Fuller, Chris
Format: Journal Article
Language:English
Published: England Elsevier Ltd 01-01-2003
Subjects:
Accidents
Dispersant
Environmental Monitoring
Equipment Design
Forecasting
Geologic Sediments - chemistry
Mass balance
Materials balance
Models, Theoretical
Oil
Petroleum
USA, Texas, Corpus Christi
Water Movements
Water Pollutants - analysis
Wave tank
ASW, USA, Texas, Corpus Christi Bay
Mass balance
Dispersant
Oil
Wave tank
Materials balance
Petroleum
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Summary:The Conrad Blucher Institute for Surveying and Science (Texas A&M University––Corpus Christi) has conducted numerous petroleum experiments at the Shoreline Environmental Research Facility (Corpus Christi, Texas, USA). The meso-scale facility has multiple wave tanks, permitting some control in experimental design of the investigations, but allowing for real-world conditions. This paper outlines the evolution of a materials balance approach in conducting petroleum experiments at the facility. The first attempt at a materials balance was during a 1998 study on the fate/effects of dispersant use on crude oil. Both water column and beach sediment samples were collected. For the materials balance, the defined environmental compartments for oil accumulation were sediments, water column, and the water surface, while the discharge from the tanks was presumed to be the primary sink. The “lessons learned” included a need to quantify oil adhesion to the tank surfaces. This was resolved by adhering strips of the polymer tank lining to the tank sides that could be later removed and extracted for oil. Also, a protocol was needed to quantify any floating oil on the water surface. A water surface (oil slick) quantification protocol was developed, involving the use of solid-phase extraction disks. This protocol was first tested during a shoreline cleaner experiment, and later refined in subsequent dispersant effectiveness studies. The effectiveness tests were designed to simulate shallow embayments which created the need for additional adjustments in the tanks. Since dispersant efficacy is largely affected by hydrodynamics, it was necessary to scale the hydrodynamic conditions of the tanks to those expected in our prototype system (Corpus Christi Bay, Texas). The use of a scaled model permits the experiment to be reproduced and/or evaluated under different conditions. To minimize wave reflection in the tank, a parabolic wave dissipater was built. In terms of materials balance, this design reduced available surface area as a sink for oil adsorption.
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ISSN:0025-326X
1879-3363
DOI:10.1016/S0025-326X(03)00201-7