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In response to the drilling industry breaching new frontiers, specifically ultra-deep waters (5,000 ft or more of water depth), new blowout control measures are necessary. This paper outlines a study into the control of ultra-deepwater blowouts using the dynamic kill technique.1 The study was conducted using a newly developed dynamic kill simulator, COMASim, to model blowout initial conditions and blowout control in simple wellbore geometries. The simulator was validated theoretically through textbook examples.1 The simulation runs first entailed initial condition analyses of the various blowout conditions for an array of wild well conditions. Next, the simulator was used to determine the dynamic kill requirements to control these blowouts based on a range of relief well parameters.1 The results showed that ultra-deep waters definitely have an effect on the blowing conditions due to the increased hydrostatic pressure of the water. Initial conditions were also significantly affected by the length of openhole section.1 The dynamic kill requirements were adversely affected as the projected relief wells became longer. In addition to relief well parameters and blowout flowrate, the dynamic kill requirements were also related to the wild wellbore drillstring status.1 This study has highlighted several key trends and interesting future research topics in the area of ultra-deepwater blowouts and control of these blowouts.1 Introduction As the easier to find and produce hydrocarbons are depleted, the oil and gas industry must move into new areas to continue supplying the world with hydrocarbons. Many of these frontiers are in what is considered ultra-deep waters, 5,000 feet or more of water depth. This is a unique environment that requires many new techniques and technologies to safely explore and produce. As the various areas of the oil and gas industry advance their ultra-deepwater technology, one area has had to remain at the forefront: drilling. Often these frontiers are harsh environments either downhole, on the surface or both. Ultra-deep water is a good example of a dangerous and unknown drilling environment. It is on these frontiers however that the advancement of technology is often disjointed. While drilling as whole may be advancing to keep up with these environments, some parts lag behind. An area that has seen this stagnation and resulting call for change has been blowout control in deep and ultra-deep waters. Blowouts have been a problem for this industry since its inception. However, in spite of the development of many safety measures such as BOPs, as well as numerous types of equipment and drilling procedures, blowouts still occur. In fact, since 1960 blowouts have occurred at a fairly stable rate.2 This rate has not changed even though blowout prevention equipment and procedures have drastically changed (Fig. 1). As evidenced by Fig. 1 the number of blowouts per feet drilled on the Outer Continental Shelf of the Gulf of Mexico stayed relatively constant from 1960 to 1996. These numbers point to an irrefutable conclusion: blowouts will always happen no matter how far technology and training advance. It is important to remember that the data in Fig. 1 is taken from relatively shallow OCS wells. Ultra-deepwater wells will have similar well control issues but in an exaggerated manner mostly due to the increased hydrostatic pressure. Indicators and measurements of influxes such as pit gain and pressure values will often be deceptively benign until the situation has escalated to the point that control of problem will become a very complicated and dangerous task. A significant difference between previously recorded blowouts and potential ultra-deepwater blowouts is the increased risk of underground blowouts high pore pressures and low fracture gradients in ultra-deep waters. Underground blowouts will increase the likelihood of subsea equipment damage.
In response to the drilling industry breaching new frontiers, specifically ultra-deep waters (5,000 ft or more of water depth), new blowout control measures are necessary. This paper outlines a study into the control of ultra-deepwater blowouts using the dynamic kill technique.1 The study was conducted using a newly developed dynamic kill simulator, COMASim, to model blowout initial conditions and blowout control in simple wellbore geometries. The simulator was validated theoretically through textbook examples.1 The simulation runs first entailed initial condition analyses of the various blowout conditions for an array of wild well conditions. Next, the simulator was used to determine the dynamic kill requirements to control these blowouts based on a range of relief well parameters.1 The results showed that ultra-deep waters definitely have an effect on the blowing conditions due to the increased hydrostatic pressure of the water. Initial conditions were also significantly affected by the length of openhole section.1 The dynamic kill requirements were adversely affected as the projected relief wells became longer. In addition to relief well parameters and blowout flowrate, the dynamic kill requirements were also related to the wild wellbore drillstring status.1 This study has highlighted several key trends and interesting future research topics in the area of ultra-deepwater blowouts and control of these blowouts.1 Introduction As the easier to find and produce hydrocarbons are depleted, the oil and gas industry must move into new areas to continue supplying the world with hydrocarbons. Many of these frontiers are in what is considered ultra-deep waters, 5,000 feet or more of water depth. This is a unique environment that requires many new techniques and technologies to safely explore and produce. As the various areas of the oil and gas industry advance their ultra-deepwater technology, one area has had to remain at the forefront: drilling. Often these frontiers are harsh environments either downhole, on the surface or both. Ultra-deep water is a good example of a dangerous and unknown drilling environment. It is on these frontiers however that the advancement of technology is often disjointed. While drilling as whole may be advancing to keep up with these environments, some parts lag behind. An area that has seen this stagnation and resulting call for change has been blowout control in deep and ultra-deep waters. Blowouts have been a problem for this industry since its inception. However, in spite of the development of many safety measures such as BOPs, as well as numerous types of equipment and drilling procedures, blowouts still occur. In fact, since 1960 blowouts have occurred at a fairly stable rate.2 This rate has not changed even though blowout prevention equipment and procedures have drastically changed (Fig. 1). As evidenced by Fig. 1 the number of blowouts per feet drilled on the Outer Continental Shelf of the Gulf of Mexico stayed relatively constant from 1960 to 1996. These numbers point to an irrefutable conclusion: blowouts will always happen no matter how far technology and training advance. It is important to remember that the data in Fig. 1 is taken from relatively shallow OCS wells. Ultra-deepwater wells will have similar well control issues but in an exaggerated manner mostly due to the increased hydrostatic pressure. Indicators and measurements of influxes such as pit gain and pressure values will often be deceptively benign until the situation has escalated to the point that control of problem will become a very complicated and dangerous task. A significant difference between previously recorded blowouts and potential ultra-deepwater blowouts is the increased risk of underground blowouts high pore pressures and low fracture gradients in ultra-deep waters. Underground blowouts will increase the likelihood of subsea equipment damage.
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