Risk-based reliability assessment of subsea control module for offshore oil and gas production

Umofia, Anietie Nnana

January 2014

Offshore oil and gas exploitation is principally conducted using dry or wet tree systems, otherwise called the subsea Xmas tree system. Due to the shift to deeper waters, subsea production system (SPS) has come to be a preferred technology with attendant economic benefits. At the centre of the SPS is the subsea control module (SCM), responsible for the proper functioning and monitoring of the entire system. With increasing search for hydrocarbons in deep and ultra-deepwaters, the SCM system faces important environmental, safety and reliability challenges and little research has been done in this area. Analysis of the SCM reliability then becomes very fundamental due to the huge cost associated with failure. Several tools are available for this analysis, but the FMECA stands out due to its ability to not only provide failure data, but also showcase the system’s failure modes and mechanisms associated with the subsystems and components being evaluated. However, the technique has been heavily challenged in various literatures for several reasons. To close this gap, a novel multi-criteria approach is developed for the analysis and ranking of the SCM failures modes. This research specifically focusses on subsea tree-mounted electro-hydraulic (E-H) SCM responsible for the underwater control of oil and gas production. A risk identification of the subsea control module is conducted using industry experts. This is followed by a comprehensive component based FMECA analysis of the SCM conducted with the conventional RPN technique, which reveals the most critical failure modes for the SCM. A novel framework is developed using multi-criteria fuzzy TOPSIS methodology and applied to the most critical failure modes obtained from the FMECA evaluation using unconventional parameters. Finally, a validation of these results is performed using a stochastic input evaluation and SCM failure data obtained from the offshore industry standard reliability database, OREDA.

665.5

Risk-based Reliability Assessment of Subsea Control module for Offshore Oil and Gas production

Umofia, Anietie Nnana

09 1900

Offshore oil and gas exploitation is principally conducted using dry or wet tree systems, otherwise called the subsea Xmas tree system. Due to the shift to deeper waters, subsea production system (SPS) has come to be a preferred technology with attendant economic benefits. At the centre of the SPS is the subsea control module (SCM), responsible for the proper functioning and monitoring of the entire system. With increasing search for hydrocarbons in deep and ultra-deepwaters, the SCM system faces important environmental, safety and reliability challenges and little research has been done in this area. Analysis of the SCM reliability then becomes very fundamental due to the huge cost associated with failure. Several tools are available for this analysis, but the FMECA stands out due to its ability to not only provide failure data, but also showcase the system’s failure modes and mechanisms associated with the subsystems and components being evaluated. However, the technique has been heavily challenged in various literatures for several reasons. To close this gap, a novel multi-criteria approach is developed for the analysis and ranking of the SCM failures modes. This research specifically focusses on subsea tree-mounted electro-hydraulic (E-H) SCM responsible for the underwater control of oil and gas production. A risk identification of the subsea control module is conducted using industry experts. This is followed by a comprehensive component based FMECA analysis of the SCM conducted with the conventional RPN technique, which reveals the most critical failure modes for the SCM. A novel framework is developed using multi-criteria fuzzy TOPSIS methodology and applied to the most critical failure modes obtained from the FMECA evaluation using unconventional parameters. Finally, a validation of these results is performed using a stochastic input evaluation and SCM failure data obtained from the offshore industry standard reliability database, OREDA.

Reliability Assessment

SCM

API 17N

FMECA

Risk priority Number (RPN)

Fuzzy TOPSIS

SPS

NATO, Greece and the 2004 Summer Olympics

Brianas, Jason John

12 1900

Approved for public release; distribution in unlimited. / Since the end of the Cold War the Alliance's transformation has erased doubts about its survival. NATO continues to adapt to new threat environments by expanding its mission scope to out-of-area operations and by assuming new security missions. For the 2004 Summer Olympics in Athens, Greece, the 11 September 2001 terrorist attacks against the United States and subsequent 11 March 2004 Madrid bombings in Spain complicated an already robust Greek security plan. Greece's extensive security planning, in addition to coordinating NATO support, highlighted the challenges and readiness requirements for the Alliance in the 21st century. Terrorist concerns, burden-sharing, recognition of Greek sovereignty, political limitations in deploying NATO's CBR Defense team and NRF utilization were all elements of the challenges faced in security preparation for the Games. In assessing the dynamics behind NATO's history and its security participation in the 2004 Summer Olympics, this thesis serves as a case study in the continuing transformational role and adaptability of NATO. Overall, the Alliance's willingness to assume security support to a major international sporting event represented its long-time relationship with Greece, its ability to perform significant security missions and its commitment to and solidarity with its allied members. / Lieutenant, United States Navy

National security

Greece

Security, International

NATO

Alliance

Transformation

Olympics

Games

Greece

Security

Terrorism

17N

AWACS

Sovereignty

Burden-sharing

Truman Doctrine

Cyprus

Karamanlis

Strategic Concept

Solidarity

Public Opinion

11 September 2001

11 March 2004