Patent Grant
8020623
1. Field of the Invention
This invention relates in general to hydraulically controlling valves and connectors of subsea equipment, such as a blowout preventer and lower marine riser package, and in particular to a control module containing electronics and hydraulic control valves.
2. Description of Related Art
Subsea Control Modules (SCMs) are commonly used to provide well control functions during the production phase of subsea oil and gas production. Typical well control functions and monitoring provided by the SCM are as follows: 1) Actuation of fail-safe return production tree actuators and downhole safety valves; 2) Actuation of flow control choke valves, shut-off valves, etc.; 3) Actuation of manifold diverter valves, shut-off valves, etc.; 4) Actuation of chemical injection valves; 5) Actuation and monitoring of Surface Controlled Reservoir Analysis and Monitoring Systems (SCRAMS) sliding sleeve, choke valves; 6) Monitoring of downhole pressure, temperature and flowrates; 7) Monitoring of sand probes, production tree and manifold pressures, temperatures, and choke positions.
The close proximity of the typical SCM to the subsea production tree, coupled with its electro-hydraulic design allows for quick response times of tree valve actuations. The typical SCM receives electrical power, communication signals and hydraulic power supplies from surface control equipment. The subsea control module and production tree are generally located in a remote location relative to the surface control equipment. Redundant supplies of communication signals, electrical, and hydraulic power are transmitted through umbilical hoses and cables of any length, linking surface equipment to subsea equipment. Electronics equipment located inside the SCM conditions electrical power, processes communications signals, transmits status, and distributes power to devices such as, solenoid piloting valves, pressure transducers, and temperature transducers.
Low flowrate solenoid piloting valves are typically used to pilot high flowrate control valves. These control valves transmit hydraulic power to end devices such as subsea production tree valve actuators, choke valves and downhole safety valves. Pressure transducers located on the output circuit of the control valves read the status condition of control valves and their end devices. Auxiliary equipment inside the typical SCM consist of hydraulic accumulators for hydraulic power storage, hydraulic filters for the reduction of fluid particulates, electronics vessels, and a pressure/temperature compensation system.
An SCM is typically provided with a latching mechanism that extends through the body of the SCM and that has retractable and extendable dogs or cams thereon to engage a mating receptacle in a base plate.
Many previous devices have used an oil-filled chamber to compensate for hydrostatic pressure increase outside of the device during use to keep seawater away from electronics and cable assemblies. More progressive SCMs, such as, for example, those described in U.S. Pat. No. 6,161,618, by Parks et al. incorporated by reference in its entirety, provides a serially modular design which includes a dry electronics chamber located under a pressure dome.
Recognized by the inventors, however, is that further modularization can reduce cost of individual SCMs, especially where a customer only requires a partial package, can allow for additional redundancy, can enhance functionality and the number of functions a module is capable of performing, can enhance survivability during deployment, operation, and retrieval, and can reduce maintenance repair time and costs, along with many other benefits.
In view of the foregoing, embodiments of the present invention advantageously provide a base subsea control module applicable for use in both the drilling and production phase, or in other applications, including application as a front end of a blow-out preventer (BOP) control system. Embodiments of the present invention provide a subsea control module which is modularized beyond that of other prior devices to facilitate tailoring the device to meet specific customer needs, to provide for additional redundancy, to enhance functionality and the number of functions a module is capable of performing, to enhance survivability during deployment, operation, and retrieval, and to reduce maintenance repair time and costs, along with many other benefits. The design can allow for replacement and retrieval of a faulty subsea control module with a single remotely operated vehicle (“ROV”) deployment from a vessel.
More particularly, an embodiment of the present invention advantageously provides a subsea control module including a module body having an axial bore extending therethrough, a proximal or upper body end portion, a distal or lower body end portion, and a medial body portion extending therebetween. The medial body portion of the module body includes an elongate annular recess extending radially into the medial body portion to define a valve module receptacle. A plurality of, e.g., trapezoidal shaped valve modules are each replaceably positioned radially along an inner surface of the valve module receptacle, approximately flush with the proximal and the distal body end portions, and are adapted to communicate hydraulic fluid with a separate one of a plurality of spaced apart apertures in the medial body portion of the module body. Each valve module can include a valve module housing containing at least one, but typically a pair of directional control valves, oriented axially within the respective valve module housing along a same longitudinal axis to thereby reduce a lateral physical signature of the respective valve housing. The subsea control module can also include a plurality of containers positioned to contain distributed electrical component defining a plurality of pilot valve modules. Each pilot valve module can include a pilot valve housing containing a plurality of pilot valves, a plurality of pressure transducers, and a plurality of solenoids.
The subsea control module can also include a central core positioned within the axial bore of the module body and can include a proximal end portion, a distal end portion, and a medial portion having an external surface spaced radially inward from the axial bore of the module body to form an annular cavity therebetween, to contain electronic circuitry. Further, the proximal end and the distal end portions of the central core can each have diameters greater than that of the medial portion of the central core. Additionally, the central core can include a cylindrical cover extending around the medial body portion of the central core, around at least a portion of an exterior surface of the proximal end portion of the central core, and around at least a portion of an exterior surface of the distal end portion of the central core. The cylindrical cover can be positioned within the axial bore of the module body and can have an inner surface spaced radially apart from the exterior surface of the medial portion of the central core. As such, the cylindrical cover can seal the annular cavity to form a housing to contain the electronic circuitry, which can include an electronic control module positioned to communicate with each of the plurality of pilot valve modules, and electrical circuitry in a subsea equipment receptacle, which, in turn, can provide a communication link with a surface computer.
According to a preferred configuration, the annular cavity is characterized by being a dry, air-tight cavity formed between the module body and the central core, is purged of air and containing nitrogen at a pressure of at or near approximately atmospheric pressure, and each pilot valve housing can contain a dry, air-tight cavity, purged of air and containing nitrogen at a pressure of at or near approximately atmospheric pressure. This advantageously enhances maintainability of the components inside each cavity.
The proximal body end portion of the module body can include a plurality of passageways formed in the proximal body end portion, which are collectively positioned to communicate hydraulic fluid between the plurality of pilot valve modules and the plurality of valve modules to define a plurality of mating passageways. Similarly, the proximal end portion of the central core can include a plurality of passageways formed in the proximal end portion, which contain or house an electrical penetrator sealingly positioned to communicate control signals between the electronic control module and a separate one of the plurality of pilot valve modules. The subsea control module can further include a seal plate positioned between each of the plurality of pilot valve modules and the plurality of mating passageways of the module body and the plurality of passageways of the central core to seal an interface between the plurality of pilot valve modules and the respective passageways.
The subsea control module can further include a plurality of hydraulic couplings extending distally from the distal body end portion of the module body and a plurality of electrical couplings similarly extending distally from the distal end portion of the central core. A cylindrical outer protective cover extending around an exterior of the medial body portion of the module body and around an exterior of the distal end portion of the module body, also extends axially beyond a distal end surface of the distal body end portion of the module body, to provide damage protection to the plurality of couplings when coupling the subsea control module to a subsea equipment receptacle.
Various other features according to embodiment of the present invention are also provided to enhance functionality and the number of functions a module is capable of performing, to enhance survivability during deployment, operation, and retrieval, and to reduce maintenance repair time and costs, along with many other benefits.
So that the manner in which the features and advantages of the invention, as well as others which will become apparent, may be understood in more detail, a more particular description of the invention briefly summarized above may be had by reference to the embodiments thereof which are illustrated in the appended drawings, which form a part of this specification. It is to be noted, however, that the drawings illustrate only various embodiments of the invention and are therefore not to be considered limiting of the invention's scope as it may include other effective embodiments as well.
The present invention will now be described more fully hereinafter with reference to the accompanying drawings, which illustrate embodiments of the invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the illustrated embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Like numbers refer to like elements throughout.
Referring to
A central core 21 is mounted inside body 13. Core 21 has a cylindrical cover 27 spaced radially inward from bore 15 of body 13, creating an annular cavity 23. Electronic circuitry 25 is located within annular cavity 23. In one embodiment, annular cavity 23 is purged of air, filled with nitrogen, and remains at or near atmospheric pressure while subsea. With this embodiment, there is no need to equalize the pressure of the atmosphere in the electronics cavity 23 with that of the sea. Alternately, annular cavity 23 could be filled with a dielectric fluid and pressure compensated.
A connecting rod 29 extends through a central passage in core 21 for connecting subsea control module 11 to a receptacle 12 mounted on a piece of subsea equipment. Rod 29 has a drive head 31 on its upper end for access by a tool of a ROV (not shown), and a latch mechanism 30 adapted to engage a mandrel (not shown) in the subsea electrical equipment receptacle 12.
Referring again to
As perhaps best shown in
At electrical penetrator 49 extends sealingly into each pilot valve module 43. The lower end of each penetrator 49 is in communication with annular electronics cavity 23 (
The electronic circuitry 48 within each chamber 44 of each separate pilot valve module 43 monitors and controls pilot valves 45 and pressure transducers 46 of the respective pilot valve module 43. Electronics circuitry 48 receives power from and communicates with electronics circuitry 25 in cavity 23.
Referring again to
The hydraulic couplings 55 register with hydraulic ports/passageways 53 (see, e.g.
A plurality of electrical couplings 57 are similarly mounted to, and protrude, from the lower (distal) end of central core 21 of subsea control module 11. Each electrical coupling 57 is connected to one or more wires leading to the electronic circuitry 25 for supplying power and communication. Fiber optic couplings may also be employed. Additional electrical couplings are available for powering and communicating with externally mounted instruments or devices.
The electronic circuitry contained in the electronic control module 25 shown schematically in
Subsea control module 11 is small and lightweight enough to be installed subsea by the use of a remotely operated vehicle (“ROV”). The ROV stabs it into mating receptacle 12, then rotates rod 31. When fully connected, hydraulic fluid pressure is supplied to various hydraulic couplings 55 and electrical power and communication signals are supplied to electronic circuitry 25 and 48, through electrical couplings 57.
To perform a particular function, an electrical or fiber optic signal will be sent from a remote location, such as a vessel at the surface, for example, via the umbilical cord associated with the subsea equipment (not shown). This signal causes electronic circuitry 25 to provide power to one of the pilot actuated valves 45, which in turn supplies hydraulic pressure to a hydraulic actuated device of the subsea equipment. In some instances, the pilot valves 45 will supply hydraulic pressure to one of the directional control valves 19, which in turn supplies a larger volume of hydraulic pressure for causing larger users of hydraulic fluid pressure, such as annular preventers, and large valve actuators. Optionally, some of the pilot valves 45 may supply hydraulic pressure directly to a hydraulic device rather than via one of the directional control valves 19.
Various embodiments of the present invention have several advantages. For example, embodiments of the present invention provide a modular design which concentrates actuatable hydraulic components in the removable subsea control module 11, in contrast to having actuatable components in a mating subsea equipment receptacle 12 to thereby allow efficient maintenance—i.e., maintenance can be accomplished in a single ROV deployment by replacing the subsea control module having a malfunctioning component. That is, a single ROV deployment can provide removal of a faulty subsea control module 11, replacement of a new subsea control module 11, and can include ancillary maintenance operations.
Embodiments of the present invention optimize maintainability of individual subsea control modules 11 by distributing electrical and electrically actuated components most likely to fail, e.g., pilot valves 45, solenoids, and pressure sensors 46, across multiple miniature, e.g., one-atmosphere pilot valves modules 43, which allows easy line replacement. Such modules 43, according to an embodiment of the present invention, can be oriented in a wedge shaped design and can readily contain up to eight solenoids, eight correlated pilot valves, and up to ten pressure transducers. Advantageously, such configuration can allow for up to four functions per module 43, and can allow for closed-circuit (return-to-surface) hydraulic function, in addition to open circuit (vent-to-sea) hydraulic function.
Embodiments of the present invention also optimize maintainability of the individual subsea control modules 11 by distributing hydraulic directional control valves 19 also across multiple miniature, e.g., directional control valves modules 18, which allow for easy “off-line” replacement. Further, advantageously, by orienting the directional control valves 19 longitudinally within each module 18, embodiments of the present invention have increased the number of directional control valves 19 to thirty-two, having, e.g., two per module 18, and preferable with sixteen modules 18 oriented radially around an outer portion of a module body 13 to allow for the easy removal/repair/replacement.
Embodiments of the present invention include a module body 13 that contains no hydraulic tubings or fittings, but rather, provides a manifold design that reduces likelihood of leakage. The hydraulic passageways 53 can communicate with one or more ring headers 61 embedded along outer surfaces of the module body 13. The ring headers 61 can advantageously function to distribute and/or collect hydraulic fluid.
According to embodiments of the present invention, advantageously, the module body 13 can include a relatively large central bore 15, which accommodates central core 21, with sealed cover 27 to provide an, e.g., one atmosphere, annular chamber or cavity 23 containing a central electronic control module 25, which can electrically communicate with each pilot valves module 43 and with electronics or other communication media of the mating subsea equipment receptacle 12. By providing such modular design with central control, problems with the subsea control module 11 can be easily identified, allowing less time spent on maintenance, and allowing for additional monitoring and emergency control.
Embodiments of the present invention also advantageously provide an extended protective cover or sleeve 20, which can advantageously extend beyond the module body 13 to protect individual hydraulic couplings 55 and electrical couplings 57 which couple or mate with compatible couplings located in the subsea equipment receptacle 12. The extension portion of the protective cover or sleeve 20 prevents damage during initial alignment during engagement of the subsea control module 11 with the subsea equipment receptacle 12. Further, one or more alignment keys 56 can advantageously enhance initial alignment with the subsea equipment receptacle 12, preventing risk of damage during mating of the subsea control module 11 with the subsea equipment receptacle 12.
Various other functions according to one or more embodiments of the present invention, provide a completely ROV retrievable subsea control module 11, which can provide up to thirty-two or more solenoids for drilling operations, up to sixty-four or more solenoids for production operations, up to ninety pressure transducers, up to thirty-two directional control valves, pilot filters, multiple supply manifolds, multiple hydraulic and/or electrical couplings, and electronics modules, up to eight electrical wet-mate connectors, a central collett latch, humidity detection in electrical chambers, and redundant power, communications, and controller; which does not require or include hydraulic tubing or fittings; and which allows for all repairs to be completed “off-line.”
This patent application is related to U.S. Patent Application No. 60/954,919, by Parks et al, titled “Control Module for Subsea Equipment,” filed on Aug. 9, 2007, U.S. patent application Ser. No. ——————, by Parks et al, titled “Control System for Blowout Preventer Stack,” filed on Aug. 11, 2008, and U.S. Patent Application No. 60/955,085, by Parks et al, titled “Control System for Blowout Preventer Stack,” filed on Aug. 10, 2007, each incorporated by reference herein in its entirety.
In the drawings and specification, there have been disclosed a typical preferred embodiment of the invention, and although specific terms are employed, the terms are used in a descriptive sense only and not for purposes of limitation. The invention has been described in considerable detail with specific reference to these illustrated embodiments. It will be apparent, however, that various modifications and changes can be made within the spirit and scope of the invention as described in the foregoing specification.
This patent application is a non-provisional application which claims priority to and the benefit of U.S. Patent Application No. 60/954,919, by Parks et al, titled “Control Module for Subsea Equipment,” filed on Aug. 9, 2007, and U.S. Patent Application No. 60/955,085, by Parks et al, titled “Control System for Blowout Preventer Stack,” filed on Aug. 10, 2007, both incorporated by reference herein in their entirety.
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