The present invention relates generally to an actuator control system useful in sub sea production of hydrocarbons. It relates specifically to a sub sea valve actuator system and a method to achieve a simple and robust control system at low cost and low qualification effort. The actuator system is compatible with the concept of sub sea electric production control architecture.
In the following background discussion as well as in the disclosure of the present invention, the following abbreviations will be frequently used:
BL brush-less
DC direct current
DCV directional control valve
EH MUX electro-hydraulic multiplexer
ESD emergency shut down
I/O input/output
LVDT linear variable differential transformer
PM permanent magnet
PSD production shut down
SIL safety integrity level
SHPU sub sea hydraulic power unit
SMA shape memory alloy
XMT, Xmas tree Christmas tree
The prior art in control systems for hydrocarbon production comprises both hydraulic and electrical control, respectively.
Most concepts for electrical actuation of large gate valves include the use of an electrical motor and a roller screw or other form of rotary-to-linear mechanical conversion device, such as disclosed in e.g. U.S. Pat. No. 7,172,169 and in U.S. Pat. No. 6,572,076. Other concepts, such as disclosed in NO 322680, are based on use of a small SHPU, to combine the action of an electrical motor and a hydraulic piston/cylinder arrangement. Both approaches have merits and both also have certain limitations. The former approach tends to involve mechanical complexity and extensive instrumentation in non-retrievable components (i.e. for example integrated with an XMT module) and large dimensions. The latter approach tends to involve several hydraulic components demonstrated over many years to have less than desirable reliability in a sub sea context, e.g. DCV pilot valves requiring high fluid cleanliness for reliable operation, pressure relief valves and hydraulic accumulators. The latter, if in the form of nitrogen (N2) charged bladder design, are prone to leakage over time, which is the reason they are normally carried on easily retrievable modules. In deep water N2 charged accumulators are also inefficient. In the form of mechanical spring charged designs accumulators are bulky and unsuitable to be part of an actuator located on e.g. an XMT.
The present invention is based on a combination of principles pursued in both camps (roller screw and hydraulics) as per the above, and especially on the use only of the best components from each camp in a combination exhibiting unparalleled robustness and reliability combined with cost effectiveness.
The critical feature of a sub sea valve actuator as applied to e.g. an XMT is in the fail safe latch arrangement. This is a mechanism designed to work in conjunction with a return spring, the latter storing energy required to turn the valve from the production position to the safer position, usually from open to closed position.
For the case of electromechanical operation the latch is usually also electromechanical. Many versions have been devised, but few implemented and commissioned in the sub sea industry.
For the local (to the actuator) SHPU line of approach the fail safe feature is almost invariably provided by means of a DCV. Such valves have several unfortunate, but necessary design features. Traditionally the DCV has not been critical to the ESD functionality, except for a few installations characterised by very long offset of the sub sea production facility from the host platform. The universally accepted form of ESD for a traditional EH MUX production control system is in the form of hydraulic bleed down from the host platform, thus the safety critical DCVs are located on the host platform, and are thus accessible for repair or replacement.
Use of pressure relief valves sub sea has very little, if any, history in production control systems. The industry has shunned pressure regulating valves and pressure relief valves used sub sea. The full range of valves normally used in a mini SHPU dedicated to control of a single actuator are basically considered sensitive to particulate contamination and thus undesirable.
Electrical actuation should be defined in a system context, i.e. an actuator with only electrical (and possibly optical) interfaces, and no hydraulic interfaces, to the upstream parts of the production control system.
With reference to
This circuit is suitable for a topside installation where the components most sensitive to contamination, notably DCV pilot valve 10 and pressure relief valve 5 may be accessed for repair or replacement, and where the ambient pressure at 1 bar is suitable for use of a nitrogen charged accumulator 8, but less suitable for a sub sea installation.
The present invention aims for elimination of these three undesirable components, but still providing an operable actuation system of great robustness and reliability.
In the following, several features of radical improvement on this concept with respect to reliability in operation will be described as parts of the present invention.
The object of the present invention is achieved and the drawbacks of prior art essentially eliminated by the valve actuator system and method as defined in independent claims. Further advantageous features and embodiments provided by the invention are defined in subordinated claims.
In similarity with a conventional hydraulic actuator for a valve, the subject actuator comprises a cylinder/piston assembly and a return spring arranged in an actuator housing as the main elements. Also in similarity with a conventional hydraulic actuator the move from production mode to safe mode is by action of the return spring, and the move from safe mode to production mode is provided by means of hydraulic power generated in the auxiliary circuitry forming an integral part of the actuator concept, but preferably located in a separately retrievable unit.
The suggested circuit has no accumulator for storage of hydraulic power and no DCV pilot valve (or DCV). Nor has it a pressure relief valve. Thus the three least desirable components of the conventional concept have been eliminated. The motion of the piston/ cylinder follows simply as a function of fluid being pumped into the cylinder directly from the discharge port of the pump.
The fail safe latch is an electromechanical arrangement (ref: electromechanical arresting mechanism). The arrangement comprises mechanical parts able to handle the reaction forces from the return spring and from the well bore pressure and is held in locked position by means only of a small electrical current and at a very low wattage. It is the introduction of this electro-mechanical fail safe arrangement which facilitates removal of the otherwise required components: accumulator (compensating for DCV leakage), DCV (essential function is to handle the ESD situation) and the pressure relief valve (protection of pump and motor). The fail safe latch arrangement only requires electrical power, no hydraulic power.
The present invention also facilitates protection of motor and pump by detection of end-of stroke position.
The present invention has characteristic performance very different from those of either an electromechanical actuator or an SHPU based actuator as described in the prior art references. It is truly an electric actuator as it has only electrical (and in the future possible optical) interfaces with the other parts of the production control system.
As opposed to a typical roller screw based actuator with a high torque brushless, permanent magnet, direct current (BL PM DC) motor and gear arrangements the proposed design may be built for larger diameter and shorter length protruding from e.g. the trunk of an XMT, thus more compatible with sub sea XMT architectures.
One advantageous feature of the valve actuator system of the present invention is that it can easily be expanded to serve fail-to-last position actuation, typically for a manifold or choke application, by simply reversing direction of rotation of the electrical motor, removing the fail safe spring and designing the piston/cylinder for bidirectional action. This assumes full reversibility of the pump, usually the case for a gear pump, not always the case for a piston pump. In the case of a piston machine it would be beneficial to use a motor as pump as they are usually designed for true bidirectional operation both in pump and motor mode.
Briefly, the present invention provides a sub sea valve actuator system comprising a piston and cylinder assembly and a return spring arranged in an actuator housing, a hydraulic pump and electric motor assembly associated with the piston and cylinder assembly, hydraulic flow lines for hydraulic medium driving the piston and cylinder in relative displacement against the force of the return spring. The actuator system is characterized by detection means arranged for detecting an end-of-stroke position of the piston and cylinder assembly, said detection means is at least one of:
a motor current monitoring circuit unit;
a hydraulic medium pressure sensor unit;
a position sensor unit; and
a linear variable differential transformer unit;
wherein an electromechanical arresting mechanism is arranged to be energized for releasably arresting the return spring in a compressed state in result of the detected end-of-stroke position.
According to a preferred embodiment, at least one of the motor current monitoring circuit unit and the pressure sensor unit is contained in an electronics canister which is retrievably connected to the actuator housing.
According to another preferred embodiment, components of at least one of the position sensor unit and the linear variable differential transformer unit is contained in the actuator housing (i.e. the non-retrievable part of the actuator system).
The motor current monitoring circuit unit is preferably arranged to submit an end-of-stroke signal to a logic unit controlling the electromechanical arresting mechanism to hold the valve in production mode against the force of the return spring.
The pressure sensor unit is preferably arranged to generate a pressure signal in a logic unit controlling the electromechanical arresting mechanism to hold the valve in production mode against the force of the return spring.
At least one of the position sensor unit and the linear variable differential transformer unit is preferably arranged to submit an end-of-stroke signal to a logic unit controlling the electromechanical arresting mechanism to hold the valve in production mode against the force of the return spring.
Preferably, the hydraulic pump and electrical motor assembly are assembled in a hydraulic power unit which is retrievably connected to the actuator housing.
The hydraulic medium is preferably supplied to the piston/cylinder assembly from a reversible, fixed displacement hydraulic pump.
The hydraulic medium is also preferably supplied via a flow line opening in the end of the piston which preferably is stationary in the actuator housing.
The cylinder is preferably arranged displaceable on the piston in the actuator housing filled with hydraulic medium communicating with the hydraulic pump via a return flow line.
In a further preferred embodiment, the actuator housing comprises a stem projecting from the cylinder in a forward direction, and a locking bolt projecting from the cylinder in the aft direction, the locking bolt reaching through the piston to be releasably engaged, in the end-of-stroke position of the cylinder, by locking dogs arranged pivotally in the actuator housing.
The locking dogs are preferably controllable into locking engagement with the bolt upon energizing an electromagnet/solenoid or a shape memory alloy device.
Briefly, the present invention also provides a method for operation of a sub sea valve actuator system, comprising a piston and cylinder assembly and a return spring arranged in an actuator housing, a hydraulic pump and electric motor assembly associated with the piston and cylinder assembly, hydraulic flow lines for hydraulic medium driving the piston and cylinder in relative displacement against the force of the return spring. The method is characterized by the steps of:
arranging an electromechanical arresting mechanism effective for releasably arresting the return spring in a compressed state;
determining an end-of-stroke position of the piston and cylinder assembly through at least one of:
energizing the electromechanical arresting mechanism in result of the detected end-of-stroke position of the piston and cylinder assembly.
Further subordinated method steps include:
powering the motor at standstill in the end-of-stroke position while detecting at least one of the motor current consumption, the hydraulic medium pressure, the position of the piston relative to the cylinder, and the absolute position of the piston or the cylinder, and discontinuing the power supply to the motor (stator windings) upon detection of the end-of-stroke position of the piston/cylinder assembly;
activating the electromechanical arresting mechanism upon passage of a certain delay in time during which the motor is stalled at full torque;
accelerating the motor at minimum torque provided from a spring charged accumulator arranged in the flow of hydraulic medium from the pump to the cylinder;
arranging at least one of a motor current monitoring circuit unit and a hydraulic medium pressure sensor unit in a separate retrievable electronics canister which is connectable to the actuator housing;
arranging components of at least one of a position sensor unit and a linear variable differential transformer unit in the actuator housing.
assembling the hydraulic pump and the electrical motor in a hydraulic power unit which is retrievably connected to the actuator housing.
Further features and advantages provided by the present invention will be appreciated from the following detailed description of preferred embodiments.
The present invention will be more closely explained with reference to the schematic drawings. In the drawings:
In the following preferred embodiments of the invention will be described. A complete list of references is attached to the end of the detailed description.
With reference to
The simplified system of the present invention is correspondingly illustrated in
Turning now to
A piston 25 and a cylinder 11 are arranged for relative displacement in the housing 21. More specifically, the cylinder 11 is arranged movable in both axial directions on a piston 25 which is stationary arranged in the housing. From a forward end wall of the cylinder 11, a stem 26 projects through the housing end wall or bonnet 24. The stem 26 provides a valve interface and is moveable linearly to effect shifting of the valve into production mode when the cylinder and stem are extended in the forward direction (i.e. towards the left hand side of the drawing). From the opposite side of the cylinder end wall, a locking bolt 27 projects into a bore 28 that is arranged centrally through the piston 25. The locking bolt 27 cooperates with an electromechanical locking or arresting mechanism as will be further explained with reference to
A return spring 29, such as a helical metal spring, is supported on the cylinder exterior and acting between the housing end wall/bonnet 24 and a radial flange 30 which is formed in the aft end of the cylinder 11. In extended position, the cylinder 11 will be biased in the aft direction by the power of the compressed return spring 29. The return spring 29 is releasably arrested in the compressed state through an electromechanical assembly comprising an electrically controlled trigger mechanism. In the compressed state of the return spring 29, see
The locking dogs 31 are formed with seats 36 in their peripheral ends. The seats 36 are shaped to receive, in the arrested state, a respective locking pin or locking ball 37 as illustrated in
When the actuator is activated, the stem 26, cylinder 11 and locking bolt 27 are extended in the forward direction from the position illustrated in
The piston/cylinder assembly 25/11 is powered by a hydraulic pump and electric motor assembly, see
It should be noted that the preferred embodiment shows a movable cylinder 11 and an annular piston 25 fixed in position where the stem is in the centre. A more general case (see
A sub-sea hydraulic power unit SHPU is housed in a separate and retrievable SHPU-module comprising the motor and pump assembly encased in a housing 44. Reference number 45 refers to a protection cap for a metal bellows volume compensator 6, compensating for volume changes of the fluid in the actuator as a result of changes in pressure and temperature. Such devices are commonplace components in the sub sea industry and the component is shown for completeness of description. The SHPU connects to the actuator housing 21 via a connecting flange 47 and clamp interface 48. Reference numbers 49 and 50 refer to bearing arrangements journaling a rotor 51 for rotation relative to a stator 52. Electrical power and control is supplied from a host facility via lines connected to the gate valve actuator at wet mate connector 53. A supplementary connector 54 may advantageously be arranged for back up in a case where connector 53 is disconnected upon retrieval of the SHPU. Reference number 55 refers to a separately retrievable electronics canister housing the electric/electronics components necessary for operating the actuator.
The motor 1 can be designed in many forms. In a preferred embodiment of this invention a squirrel cage motor with the rotor 51 designed for very high resistance in the rotor bars is used. The bars could be made of a less conductive material than copper as opposed to the normal design of using copper, or the entire rotor can be a solid cylindrical piece of magnetic steel (in the latter case it is then strictly speaking not a squirrel cage anymore). This makes it possible for a motor of low efficiency when running at rated speed, but also for a motor of very low inrush current, high starting torque and very tolerant to heating. In the present invention efficiency of the motor running at rated speed (typically around 2900 rpm) is not a major issue, however, inrush current is a major issue in view of the long transmission lines used in sub sea field developments. Direct starting of the motor by means of conventional electromechanical contactors makes it possible for a robust scheme using simple equipment, but for a standard industrial induction motor of the squirrel cage design this tends to create large voltage drop on the transmission lines in response to large inrush currents and low load angle values at start-up. The motor only runs for 30-60 seconds per actuation, so the aggregated power loss in the form of heat is insignificant.
In the preferred embodiment the motor stator 52 is wound for very low voltages, typically 40-60 volts for a 5 kW unit (typical rating for a 5″ actuator). Thus the insulation requirements are moderate making the motor functional even at poor insulation values. The entire housing containing the motor/pump and auxiliary valves is filled with a suitable mineral oil based or synthetic hydraulic fluid. All such fluids have excellent electrical insulation characteristics at low voltages, even when absorbing sea water. The hydraulic fluid is thus optimised on lubrication for the motor and pump bearings and performance of the pump in addition to corrosion resistance of the wetted components.
It should be noted that gear pumps have inherently an internal leakage, normally considered a disadvantage, in this context however considered an advantage, as the actuator is certain to go to the valve safe position even if the pump or motor were to freeze up on their respective bearings. In this unlikely case the shut in time would increase, but shut-in would eventually happen.
The pump 3 is in the preferred embodiment of a gear type design for robustness and cost effectiveness, but could also be of an axial piston type design or some other form of fixed displacement machine. The basic requirement is that the pumping action is reversible such that the pump is run as a motor under the pressure generated by the return spring 29 in cylinder 11 when the motor 1 is de-energised and the locking dogs 31 are released for shut-in. Thus the hydraulic circuit has intentionally no capability to hold the stem 26 in the extended position at pump standstill. Once the motor is de-energized and the locking dogs 31 are released, the return spring 29 will drive the stem assembly to the safe position of the valve. Only the mechanical fail safe mechanism (ref: electromechanical arresting mechanism) shown in
The check valves 17 and 18 are of non-critical nature. They are put in to make sure the fluid which alternately runs in and out of the cylinder spring side is passed through the filter 15 (typically a 3 micron unit), as springs are known to contaminate the fluid. The most common failure mode of a check valve is leakage when subject to pressure in the blocking direction. The check valves are not subject to pressure of significance. Minor leakages are of no consequence, as they will only result in a marginal reduction of the fluid filtration process. Obviously, adding another two, non-critical check valves to this circuit (not shown) results in also the fluid being sucked into the spring side of the piston being filtered (rectifier circuit). By the same token a similar arrangement may be made for the suction side of the pump (not shown).
The hydraulic circuit, shown in
Reference numbers 11, 23, 24, 26, 56, 57 as referred in the list, are considered self explanatory to sub sea engineers, and are not described further. The essentially new elements in
When the actuation stroke starts fluid flows from the pump 3 through the interface 47-48, 19, 20 into and through the piston to push the cylinder 11 to the extended position thus compressing the return spring 29. Upon reaching the end-of-stroke (or end-of-travel) of the piston/cylinder the locking dogs 31 are tilted into the locking position and the locking pins 37 are brought into engagement with the locking dogs by actuation of the electromagnet or SMA device acting on the actuation arms or rods 38 to push the pins/balls 37 into position. As long as the electromagnet/SMA device is energised the balls/pins 37 will bar the locking dogs from moving back to release the cylinder, irrespective of any practical force from return spring 29.
For completeness of description, seals 63 (piston seal packages) are also arranged in the interface between the cylinder 11 and piston 25 to separate the cylinder interior from the oil-filled interior 64 of the actuator housing 21.
In
When the end-of-stroke is reached for the main piston 25 in the actuator cylinder 11 the electrical current detected by motor current transformer unit 94, and converted to a format readable to the PLC unit, is increased significantly (even for the case of an all iron rotor) since the rotor stalls. This is the signal for actuation of the latch solenoid unit 97 (39) or, as the case may be, the heater circuit of the SMA unit. A timer circuit in the PLC is activated to give the latch time to actuate and subsequently the relay 92 is deactivated by the PLC unit, thus de-energizing the motor.
In a preferred embodiment a pressure sensor/transducer unit 98 is fitted at a place where the hydraulic pressure in the actuator is to be measured, e.g. to the pump outlet port tubing 42 (
Some operator companies wish to achieve direct position detection of the valve at all times, rather than indirect position detection by the inferential methods described above. This can be provided by means of a linear variable differential transformer unit (LVDT unit) 100 comprising coils of wire, excitation circuit and a detector in a conventional way by mounting the slider of the LVDT unit in direct mechanical contact to the stem of the valve actuator. The electronic circuit of LVDT unit is embedded in the electronics canister 55 (see
Such arrangements are commonplace and have specifically been implemented on sub sea gate valve actuators. This implementation requires however considerable re-design as compared to the preferred embodiment of the LVDT implementation as schematically shown in
Both the pressure sensor unit 98 and the motor current monitoring circuit unit or motor current transformer unit 94 described above are located in a module or electronics canister 55 which is easily retrievable for maintenance or replacement by means of e.g. simple and proven ROV operations. Components relating to the position sensor 99 and the LVDT unit 100 have to be embedded in the non-retrievable part 21 of the valve actuator system. The preferred embodiments based on inferential detection of end-of-stroke position, i.e. motor current monitoring by means of a current transformer unit 94 or pressure sensing by means of a pressure sensor unit 98, requires only one ROV operated electrical connector 53 between the electronics canister 55 and the upstream power supply and communications centre (not shown). If either an LVDT unit or an inductive position sensor according to other preferred embodiments are implemented, then an additional ROV operated electrical connector 54 connecting electrical components in the cylinder part of the actuator with the electronic circuitry in the electronics canister 55 would be required. This represents additional cost and mechanical complexity, but represents well proven components and operations.
The invention is of course not in any way restricted to the embodiments described above. On the contrary, many possibilities to modifications thereof will be apparent to a person with ordinary skill in the art without departing from the basic idea of the invention such as defined in the appended claims.
1 an electric motor, in the preferred embodiments a squirrel cage or solid rotor design
2 flexible coupling
3 hydraulic pump, in the preferred embodiments a gear type
4 filter, typically a 50 micron particle size rejection pump inlet strainer
5 pressure relief valve (prior art)
6 volume compensator, in the preferred embodiments a bellows design
7 oil reservoir, typically defined by the external housing of the SHPU
8 hydraulic accumulator (prior art)
9 control valve (prior art)
10 solenoid operated pilot valve (prior art)
11 hydraulic cylinder
12 valve, such as a gate valve
13 check valve, in the position shown it is only referred to prior art
14 soft start hydraulic accumulator, piston type in preferred embodiments
15 return line filter
16 (not used)
17 check valve
18 check valve
19 hydraulic coupling
20 hydraulic coupling
21 forward portion of the actuator housing
22 aft portion of the actuator housing
23 ROV override facility
24 actuator interface bonnet
25 piston
26 valve interface/stem
27 locking bolt
28 aft section of the locking bolt
29 return spring
30 aft end flange on the cylinder
31 locking dogs
32 radial shoulder on the locking bolt
33 enlarged radius section of the locking bolt
34 locking dog sliding surface
35 locking dogs interface structure
36 seat formed in the peripheral end of the licking dogs
37 locking pin/ball
38 actuation rod for 37
39 solenoid or SMA actuation device
40 shoulder on the actuator housing
41 recess
42 flow line for hydraulic medium
43 flow line for hydraulic medium
44 motor/pump housing
45 metal bellows protection cap
46 (not used)
47 HPU flange
48 clamp interface
49 bearings
50 bearings
51 rotor of the electrical motor
52 stator of the electrical motor
53 wet mate connector
54 wet mate connector
55 electronics canister
56 port for venting leakage fluids from the production bore
57 stem main seal package
58-62 (not used)
63 piston seal packages
64 oil filled volume
65-70 (not used)
71 point on the pressure/time curve where the soft start accumulator reaches end-of-travel
72 curve on the pressure/time curve where the breakaway force in the valve actuator is overcome
73 point on the pressure/time curve where the piston in the cylinder 11 has overcome breakaway and started to move
74 point on the pressure/time curve when the actuator stroke is complete and the piston in cylinder 11 has reached end-of-stroke
75 point on the pressure/time curve when the pump/motor rotor is stalled or nearly stalled
76 point on the pressure/time curve when the latch actuation has completed its stroke
77-79 (not used)
80 starting point where the power is applied to the motor
81 maximum value of the inrush current of the motor
82 steady state at full motor speed, no load value of the motor current
83 point where the soft start accumulator hits end-of-stroke
84 point where the breakaway force of the valve is overcome
85 start-of-stroke in steady motion
86 end-of-stroke where the pump/motor rotor is decelerated to stalling (or very near stalling)
87 point where the stalled out current in the stator applies
88 point where the locking dogs have been actuated and the motor power is switched off
89-90 (not used)
91 transformer
92 primary relay
92′ secondary relay
93 control line from the PLC unit input/output driving relay solenoids
94 motor current transformer unit
95 programmable logic controller unit (PLC unit)
96 communications line
97 latch solenoid
98 pressure sensor unit
99 position sensor unit
100 linear variable differential transformer unit (LVDT unit)
Number | Date | Country | Kind |
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20082217 | May 2008 | NO | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB2009/005567 | 5/12/2009 | WO | 00 | 2/10/2011 |