Abimbola, Majeed Olasunkanmi (2016) Dynamic safety analysis of managed pressure drilling operations. Doctoral (PhD) thesis, Memorial University of Newfoundland.
[English]
PDF
- Accepted Version
Available under License - The author retains copyright ownership and moral rights in this thesis. Neither the thesis nor substantial extracts from it may be printed or otherwise reproduced without the author's permission. Download (4MB) |
Abstract
The exploration and development of oil and gas reserves located in harsh offshore environments are characterized with high risk. Some of these reserves would be uneconomical if produced using conventional drilling technology due to increased drilling problems and prolonged non-productive time. Seeking new ways to reduce drilling cost and minimize risks has led to the development of Managed Pressure Drilling techniques. Managed pressure drilling methods address the drawbacks of conventional overbalanced and underbalanced drilling techniques. As managed pressure drilling techniques are evolving, there are many unanswered questions related to safety and operating pressure regimes. Quantitative risk assessment techniques are often used to answer these questions. Quantitative risk assessment is conducted for the various stages of drilling operations – drilling ahead, tripping operation, casing and cementing. A diagnostic model for analyzing the rotating control device, the main component of managed pressure drilling techniques, is also studied. The logic concept of Noisy-OR is explored to capture the unique relationship between casing and cementing operations in leading to well integrity failure as well as its usage to model the critical components of constant bottom-hole pressure drilling technique of managed pressure drilling during tripping operation. Relevant safety functions and inherent safety principles are utilized to improve well integrity operations. Loss function modelling approach to enable dynamic consequence analysis is adopted to study blowout risk for real-time decision making. The aggregation of the blowout loss categories, comprising: production, asset, human health, environmental response and reputation losses leads to risk estimation using dynamically determined probability of occurrence. Lastly, various sub-models developed for the stages/sub-operations of drilling operations and the consequence modelling approach are integrated for a holistic risk analysis of drilling operations.
Item Type: | Thesis (Doctoral (PhD)) |
---|---|
URI: | http://research.library.mun.ca/id/eprint/12074 |
Item ID: | 12074 |
Additional Information: | Includes bibliographical references. |
Keywords: | Blowout, Rotating Control Device, Tripping operations, Well integrity operations, Loss function modelling |
Department(s): | Engineering and Applied Science, Faculty of |
Date: | May 2016 |
Date Type: | Submission |
Library of Congress Subject Heading: | Managed pressure drilling (Petroleum engineering)--Risk assessment; Managed pressure drilling (Petroleum engineering)--Safety measures; Offshore oil well drilling--Risk assessment; Offshore gas well drilling--Risk assessment |
Actions (login required)
View Item |