Cost reductions through converting platforms from permanently manned to manned-evacuated
Matt KeysAtkins SNC-Lavalin, 191 St Georges Terrace, Perth, WA 6000, Australia. Email: Matt.Keys@atkinsglobal.com
The APPEA Journal 60(2) 637-640 https://doi.org/10.1071/AJ19181
Accepted: 19 February 2020 Published: 15 May 2020
Abstract
Most platforms in Australia and the North Sea were originally designed to be permanently manned facilities. As long-term predictions of extreme weather events have intensified, it has become challenging to demonstrate acceptable life safety levels. Extreme weather events have been an ongoing area of development. With an increasing database of information and potential climate change effects, the intensity of the environmental conditions for even recently installed facilities have increased significantly. The Gulf of Mexico estimate of environmental loading has increased 63% in the past 15 years alone, with similar increases in all other regions. To continue to operate these facilities as permanently manned while maintaining the original design safety level requires extensive strengthening. In cases assessed, associated costs have been shown to easily exceed US$100 million. With the advancements in forecasting, facilities now have adequate information available to ensure a facility is evacuated, shut in or both before any major risk to the safety of the personnel and environment is intolerable. The platform response to a forecast can be referred to as a severe weather action plan (SWAP). These can be shown to be a more cost-effective means than strengthening the asset, and most assets may only require evacuation or shut-in once in their lifetime. The benefits of a manned-evacuated platform also extend to new platforms where the cost of the jacket or hull can be reduced to achieve a target risk level provided a SWAP is in place.
Keywords: demanning, down manning, evacuation, offshore structures, safety, structural risk.
Matt Keys is the Global Technical Director for Offshore Structures at Atkins SNC-Lavalin in the Oil and Gas Division and works with over 250 integrity experts who, together, manage a significant proportion of the world’s aging fleet of offshore platforms. Matt has over 20 years of experience in the oil and gas industry in both brownfield and greenfield structural analysis, design and integrity management from conceptual through to detailed design, complex reassessments and overall integrity management while operating, including the specialist skills of non-linear FEA, structural reliability analysis and fluid structure interaction using CFD. Matt’s experience ranges from some of the oldest assets in the North Sea, Middle East, Australia and Gulf of Mexico to the newest floating facilities recently installed in Australian waters. |
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