1. Field of the Invention
Embodiments of the invention generally relate to a tool used in a subsea environment to help prevent the release of hydrocarbons into a body of water. More particularly, the invention relates to a tool that is connected to a remotely operated underwater vehicle (“ROV”), which provides a high flow rate of fluid at a high pressure to a blowout preventer (“BOP”) to manually actuate the BOP.
2. Description of the Related Art
A blowout preventer (“BOP”) is a large piece of specialized oilfield equipment that is used to seal, control and monitor oil and gas wells. In a subsea environment, the BOP is attached to the top of the wellhead at the bottom of the ocean. The BOP then connects to an offshore rig through a drilling riser. Drill strings are lowered inside the drilling riser and through the BOP and rotated by equipment on the offshore rig to turn a drill bit and drill an oil and/or gas well.
As an oil and gas well is being drilled, the well can receive what is called a formation kick, which is a burst of high pressure that comes from the reservoir. These kicks can cause a variety of catastrophic events, such as drill pipe and casing being blown out of the wellbore, and, in severe cases, hydrocarbons being released into the ocean. The BOP is designed to prevent these catastrophic blow outs from occurring, or at the very least, to minimize their effects when they do occur.
Typically, when a kick occurs, the BOP is closed so that fluids do not flow out of the wellbore. More specifically, rams or shears in the BOP are closed which effectively close and seal the drilling riser, drill strings and associated piping that runs through the BOP. The BOP rams or shears are closed remotely, either by workers actuating the BOP from an offshore rig or by an automated actuation system.
When the BOP cannot be actuated remotely, there is a need for an apparatus, system and method of manually actuating a BOP at a rapid speed in the event the BOP cannot be remotely actuated.
The invention relates to a tool, method and system for actuating a blowout preventer (“BOP”) in a subsea environment. In one embodiment, a tool for actuating a BOP includes one or more connections for receiving hydraulic power from a remotely operated vehicle (“ROV”), a first pump for increasing pressure of an operating fluid for the BOP, a second pump for increasing flow rate of the operating fluid, and a conductor for transporting the operating fluid to the BOP.
In one embodiment, a method of actuating a BOP includes hydraulically connecting the tool to the ROV, pumping a fluid through the tool, increasing pressure and flow rate of the fluid, connecting the tool to a BOP, and conducting fluid from the tool to the BOP until the BOP is fully actuated.
In one embodiment, a system of actuating a BOP includes an ROV, a fluid source, and a tool having one or more pumps, wherein the tool uses hydraulic power from the ROV to operate the one or more pumps, and wherein the tool increases pressure and flow rate of the fluid source and conducts the fluid source to the BOP until the BOP is fully actuated.
So that the manner in which the above recited features of the invention can be understood in detail, a more particular description of the invention, briefly summarized above, may be had by reference to embodiments, some of which are illustrated in the appended drawings. It is to be noted, however, that the appended drawings illustrate only typical embodiments of this invention and are therefore not to be considered limiting of its scope, for the invention may admit to other equally effective embodiments.
In one embodiment, a tool enables a blowout preventer (“BOP”) to be rapidly closed such as when the BOP cannot be closed by a remote means. The tool may be mounted to a remotely operated underwater vehicle (“ROV”), and the ROV provides hydraulic power to the tool. The tool is further connected to the BOP, such as by use of a hot stab connection, and is configured to push fluid to the BOP in order to actuate the BOP. The tool includes a high pressure pump and one or more high flow pumps. The tool first runs fluid through one or more high flow pumps until the fluid reaches a predetermined (elevated) pressure, and then switches the fluid flow to a high pressure pump. Because the tool is able to rapidly increase the pressure and flow rate of the fluid flowing to the BOP, the BOP may be closed at a rapid speed. In one embodiment, the tool of the present invention can fully actuate most BOPs in under 60 seconds, thereby sealing the wellbore and protecting the wellhead equipment and environment from further damage.
When the tool 100 is initially used, the ROV GFVP 250 routes hydraulic power to the pilot operated check valve 110B located upstream of a flow priority valve 120 and to high flow pumps 150A, B. The hydraulic pressure opens the pilot operated check valve 110B and allows the hydraulic pressure to flow to the flow priority valve 120. Once hydraulic pressure upstream of the flow priority valve 120 reaches a minimum pressure set by the flow priority valve 120, the valve 120 opens and allows the hydraulic pressure to operate the high flow pumps 150A, B. In one embodiment, the flow priority valve 120 is a flow divider valve, and the flow priority valve 120 ensures that each high flow pump 150A, B receives enough fluid to maintain even running of both pumps 150A, B. An exemplary high flow pump 150 for use in the tool 100 of the present invention is a Dynaset HPW 90/150-85 pump.
The high flow pumps 150A, B use the hydraulic pressure to pump the fluid 170 out to the BOP 300, and in one embodiment, through a hot stab connection 195. A check valve 164 ensures the fluid 170 does not flow back to the high flow pumps 150A, B. A gauge 180 on the downstream side of the high flow pumps 150A, B, and upstream of the BOP output 190, allows pressure of the fluid 170 to be monitored. As the fluid 170 circulates through the high flow pumps 150A, B, and out to the BOP 300, flow rate and pressure of the fluid 170 increases.
The fluid 170 may be seawater 170A, glycol 170B, or any other oil or fluid appropriate for subsea operations. If the fluid 170 is glycol 170B or any other oil, such fluid 170B is stored in reservoirs near the tool 100. The fluid is then connected via appropriate hoses to fluid connectors 175 in the tool 100. Examples of these fluid connectors 175A, B, which are attached to the pumps 140, 150 of the tool 100, are shown in
Turning back to
After pilot operated check valve 110A is opened, the hydraulic pressure from the ROV 220 flows through a flow control valve 130 to the high pressure pumps 140. An exemplary high pressure pump 140 for use in the tool 100 of the present invention is a Dynaset HPW 520/30-85 pump. The hydraulic pressure supplies the power to the high pressure pump 140 to pump the fluid 170 out to the BOP 300, preferably through a hot stab connection. A relief valve 162 is located downstream of the high pressure pump 140 to relieve fluid pressure from the system should the pressure exceed a specified pressure (preferably, the maximum pressure on the system is 5,000 psi). The check valve 164 prevents fluid 170 from flowing back to the high flow pumps 150A, B. When the tool 100 includes one Dynaset HPW 520/30-85 high pressure pump and two Dynaset HPW 90/50-85 high flow pumps, the tool 100 can increase the pressure of the fluid from approximately 3000 psi to 7000 psi, and can increase the flow rate of the fluid from approximately 100-150 L/min to 200-300 L/min.
The tool 100 may be configured as a component that can be bolted onto the ROV 200 directly, along with reservoirs for holding fluid 170 if desired, or the tool 100 may be placed on a skid and used on or near the ROV 200, depending on the ROV configuration.
In one embodiment, the method of actuating a BOP 300 includes hydraulically connecting an upstream side of a tool 100, such as the tool 100 disclosed above, to an ROV 200, and connecting a downstream side of the tool 100 to the BOP 300. Initially, hydraulic power from the ROV 200 is used to operate one or more high flow pumps 150A, B contained within the tool 100, and after the pressure of the fluid 170 being pumped through the tool 100 to the BOP 300 reaches 1300-1500 psi, the hydraulic power is switched to operate the high pressure pump 140 within the tool 100. In the preferred method of the invention, if the pressure of the fluid 170 drops below 1300 psi during operation of the high pressure pump 140, the hydraulic power is switched back to operate one or more high flow pumps 150A, B within the tool 100. After the BOP 300 is fully actuated, the tool 100 is disconnected from the BOP 300, and then depressurized by activating a depressurization valve 198 and allowing the pressure to bleed off, for example, to atmosphere.
While the foregoing is directed to embodiments of the invention, other and further embodiments of the invention may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.
This application claims benefit to U.S. Provisional Application No. 61/557,556 filed on Nov. 9, 2011, which is herein incorporated by reference in its entirety.
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