The present invention refers to a system and a method for momentary hydrostatic operation of hydrodynamic thrust bearings for rotors in pumps or compressors designed to be operated in the underwater production of hydrocarbon fluids, wherein the pump or the compressor is driven by a motor and together with the motor arranged in a fluid displacement module having vertical orientation during operation, and in which barrier and lubrication fluids are circulated to prevent ingress of seawater and production fluids into cavities, seals and bearings of the fluid displacement module.
Pumps and compressors operated in the recovery of hydrocarbon products at great sea depths are subjected to a harsh environment including e.g. high pressures in the order of well over 100 bar. In order to prevent ingress of liquid, gas and solid particles into the motor and pump/compressor structures, hydraulic fluid at slightly higher pressure is circulated through the structures to provide lubrication and barriers that prevent intrusion of harmful matter. Typically, barrier and lubrication fluid is circulated through the motor structure at a first pressure, and barrier and lubrication fluid is circulated through the pump or compressor structure at a pressure that is slightly lower than the pressure in the motor fluid circuit. A pressure difference of about 5-10 bar is often applied and sufficient to separate the motor and pump/compressor fluid circuits, and the same pressure difference can be applied to separate the barrier and lubrication fluid circuits from the production fluid in the pump or compressor.
The motors, pumps or compressors used for this purpose are heavy duty designs requiring considerable power to bring the pump's or compressor's rotor(s) in rotation, as well as long life bearings to take up thrust load applied to the rotor by its weight and from the production fluid. Once in rotation lubrication fluid is pressurized and fed by the rotor or by means associated with the rotor to supply tilted pads of a thrust bearing to allow for hydrodynamic lubrication film build-up and thereby to keep thrust-engageable surfaces separated with a fluid film flow between the surfaces.
At stand still, the thrust-engageable surfaces may come into contact under the weight of the rotor, e.g., or in result of the static pressure in the pumped medium at stand still. Changeover from rotation to non-rotation and vice versa, i.e. at start-up and shut-down, imposes a problem as the hydrodynamic operation of the thrust bearing fails when the rotor speed is insufficient for separating the thrust-engageable surfaces. At start-up and shut-down, rotation of the “dry” bearing causes wear of the thrust-engageable surfaces. Start-up of a pump or a compressor with dry bearings results initially in a very high torque demand, which calls for a corresponding over-sizing of the subsea power distribution grid, motor and transformers, etc.
The present invention aims to avoid the problems of wear of thrust bearings and provides a solution that reduces the torque requirement and thereby the power and current requirement at start up of the motor and pump/compressor module.
The object is met in a system for momentary hydrostatic operation of hydrodynamic thrust bearings in a vertical fluid displacement module for subsea operation comprising a motor and a pump or compressor, wherein said module is connected to a pressure control unit located subsea and arranged for controlling the supply and the discharge of barrier and lubrication fluids to and from said module. Barrier and lubrication fluid is circulated within the motor at a first pressure in a barrier and lubrication fluid circuit, and barrier and lubrication fluid is circulated within the pump/compressor in a barrier and lubrication fluid circuit at a second pressure lower than said first pressure.
A fluid supply line is arranged, connecting a flow control unit and hydrodynamic thrust bearing(s) in the pump/compressor, and flow control means in the fluid supply line is controllable for momentarily supplying fluid to the thrust bearing(s) at a pressure sufficient to generate a fluid film between thrust-engageable surfaces in the thrust bearing(s) at start-up and shut-down, respectively, of the pump/compressor. A fluid communication is arranged for discharge of fluid from the thrust bearing(s) to the barrier and lubrication fluid circuit in the pump/compressor, whereby fluid flow (driving pressure) between the thrust-engageable surfaces at start-up and shut-down, respectively, is generated in response to fluid discharge from the pressure control unit to a process fluid flow.
Through this arrangement it is ensured that hydraulic fluid is instantly available at sufficient pressure and volume for separation of the thrust-engageable surfaces at start-up and shut-down of the pump or compressor. The discharge of fluid from the bearing(s) via the pump/compressor barrier and lubrication fluid circuit and the pressure control unit further ensures that appropriate pressure difference between the barrier and lubrication fluid circuits of the motor and the pump/compressor, respectively, can be maintained through pressure control in the pressure control unit. By arranging fluid supply to the bearing(s) from a flow control unit located subsea there is achieved fast response and a compact structure.
In a preferred embodiment the flow control means comprises a flow control valve, such as an on/off control valve, and a check valve arranged in series in the fluid supply line connecting to the thrust bearing(s). In addition, the flow control means may comprise a pressure regulating valve. The pressure regulating valve may be associated with an electrical motor drive allowing for remote adjustment of the hydrostatic pressure supply level.
The flow control means may be housed inside a subsea flow control unit, or in the pressure control unit, both of which may be arranged as retrievable units of the system.
Preferably, hydrostatic operation of the thrust bearings is managed from topside via electrically responsive flow control means.
Hydrodynamic operation of the thrust bearing(s) may include supply of hydraulic fluid from the pressure control unit (via the supply line connected to fixed pads of the thrust bearing(s)).
Hydrostatic operation of the thrust bearing(s) may include supply of hydraulic fluid from the flow control unit to fixed pads included in the thrust bearing(s).
The pressure control unit is connected to the process fluid flow on the inlet side or on the outlet side of the pump/compressor for discharge of fluid into the process fluid flow.
A system as briefly described above thus comprises means for practising a method for axial support of a pump or compressor rotor shaft during start-up or shut-down of a vertical fluid displacement module for subsea operation comprising a motor and a pump or compressor, comprising the step of momentarily supplying lubrication fluid for hydrostatic operation of hydrodynamic thrust bearing(s) from a topside or land-based fluid supply via flow control means arranged in conjunction with a subsea pressure control unit configured for controlling the supply and discharge of barrier and lubrication fluids to/from said module.
Further advantages as well as advantageous features of the subsea system and method according to the present invention will appear from the dependent claims and the following description.
The present invention will be more closely explained below with reference made to the accompanying drawings, schematically illustrating a subsea system implementing the invention. In the drawings,
In the drawing of
The motor 2 and the pump or compressor 3 may be any conventional structure for subsea operation known to the skilled person. For the purpose of disclosing the invention, and without limitation to the disclosed embodiment,
The motor 2 is arranged in a motor housing that protects the motor from the ambient sea. In the motor housing, the motor shaft is journalled for rotation in radial bearings 14 and 15. Although not shown in the drawing, thrust bearings may be arranged also in the motor housing to take up axial loads on the motor shaft. The motor housing interior is hydraulically separated from the pump housing interior by a seal arrangement 16, through which the motor shaft extends to be drivingly connected with the rotors via a flexible coupling 17.
A hydraulic fluid in the motor housing is controlled at a pressure above the internal pressure of the pump, acting as a barrier which prevents intrusion of process fluid and particles into the motor housing via the seal arrangement 16 sealing about the motor shaft 18. In result of the pressure difference, a leak flow of hydraulic fluid along the motor shaft is unavoidable. The leakage rate is dependent on fluid properties, differential pressure, the transient operating conditions of the pump, and the tightness of the seal(s). The leakage is compensated by refilling the motor housing from an external supply of hydraulic fluid. Likewise, hydraulic fluid is used for lubrication of pump bearings and timing gears. The pressure in the pump lubrication fluid is to be maintained above the pressure of the pumped medium internally of the pump, in order to prevent intrusion of process fluid and particles into pump bearings, seals and timing gears. Leakage via the pump seals into the pumped medium is compensated by refilling from an external supply of hydraulic fluid.
The volume and pressure management of hydraulic fluid supplied to the motor and pump units 2 and 3 is provided via a pressure control unit 19 to which fluid is supplied from topside in a fluid line 20. The pressure control unit 19 operates as a barrier and lubrication fluids pressure regulation means supplying or discharging barrier and lubrication fluid to/from the subsea motor and pump/compressor module 1. To this purpose motor barrier and lubrication fluid is circulated in a fluid circuit 21, 22, 23 providing supply and discharge of barrier and lubrication fluid to the motor and the motor shaft bearings. Flow of hydraulic fluid inside the motor unit 2 is conventionally generated by means of a pump or impeller (as indicated in
The pressure control unit 19 may advantageously be configured as disclosed in applicant's previous Norwegian patent application No. 20100902, the contents of which is incorporated herein by reference.
In a preferred embodiment, the pressure control unit 19 thus comprises first and second pressure compensators and flow control valves (not shown in
In order to balance the pressures in the barrier and lubrication fluid circuits 21-23 and 24-27 relative to the pumped medium pressure, the pumped medium pressure is communicated to the pressure control unit 19 via pilot lines 40, 28 acting as pressure reference lines.
For the same purpose, the pressure control unit 19 may in another preferred embodiment comprise first and second pressure reducing regulators and pressure control valves (not shown in
A detailed explanation of the internals and operation of the pressure control unit 19 is available from the referenced and incorporated Norwegian patent applications.
Now looking closer to the structure of the rotor thrust bearing 11, see also
In a pure hydrodynamic thrust bearing, the fluid pressure and flow of hydraulic fluid successively decreases with decreasing rotational speed of the rotor until thrust-engageable surfaces, i.e. the supporting pads in the bearing and opposing axial faces on the rotor, are brought into frictional contact during shut-down. In start-up from a stand-still mode the thrust-engageable surfaces rotate under frictional contact until rotor speed and resulting fluid pressure and flow is sufficient to separate the axial faces on the rotor from the pads.
According to the invention, the hydrodynamic thrust bearing 11 is momentarily operated as a hydrostatic bearing during start-up and shut-down until the rotor speed is sufficient to provide hydrodynamic operation. To this purpose hydraulic fluid is supplied to generate a fluid film at the interface between the pads and opposing axial faces on the rotor. Hydraulic fluid is supplied to this interface via apertures 31 formed through the pads 29. Each pad may be formed with an aperture 31 communicating hydraulic fluid to the interface from a common fluid cavity or channel 32 formed in a pad base 33 in which the pads are mounted. A sealed insert 34 provides fluid passage between each pad 29 and the pad base 33. The hydraulic fluid is supplied to the channel 32 in the pad base via a fluid supply line 35 connecting the thrust bearing 11 with the flow control unit 41. A flow control valve 36 in fluid supply line 35 controls the supply of hydraulic fluid to the thrust bearing 11. A check valve 37 in fluid supply line 35 prevents reverse flow. A pressure regulating valve 38 may additionally be provided to regulate the pressure of fluid supplied to the thrust bearing 11. The flow control valve 36, as well as the pressure regulating valve 38 if appropriate, is preferably electrically responsive to control signals from a topside control that operates the hydrostatic mode of the thrust bearing. The pressure regulating valve 38 may be associated with an electrical motor drive allowing for remote adjustment of the hydrostatic pressure supply level in the thrust-bearing lubrication fluid supply line 35.
Hydraulic fluid supplied via pad apertures 31 is allowed to leak into the pump/compressor barrier and lubrication fluid circuit 24-27. The resulting rise in pressure in the fluid circuit 24-27 is handled by the pressure control unit 19, from which excessive fluid is discharged to external recipient, typically to the process fluid flow via discharge line 40 which communicates reference pressure to the pressure control unit 19. The flow control unit 41 in this way provides a hydrostatic pressure between the pads 29 and opposing axial faces in the thrust bearing 11 at start-up and shut-down respectively. Further in result of communicating the hydrostatic pressure in the thrust bearing 11 via fluid circuit 24-27 to the pressure control unit 19, the pressure in the motor barrier and lubrication fluid circuit 21-23 is instantly balanced and maintained at the predetermined pressure above the pump/compressor barrier and lubrication fluid pressure in circuit 24-27, by the intrinsic operation of the pressure control unit 19 as previously explained.
The flow control means 36-38 may be arranged as a flow control unit in a separate housing 41 to which hydraulic fluid is supplied from topside. The flow control means 36-38 may alternatively be arranged together with the components of the pressure control unit 19 in a common housing 42 to which hydraulic fluid is supplied from topside. In both cases, the housings 41 or 42 may be connectable to the motor and pump/compressor module 1 through fast coupling means by which the housings are dismountable and retrievable, such as by means of a remotely operated vehicle ROV, e.g. Likewise, the pressure control unit 19 may be arranged dismountable and separately retrievable by means of a ROV, e.g.
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.
Number | Date | Country | Kind |
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20101770 | Dec 2010 | NO | national |
This application is a divisional application of co-pending U.S. patent application 13/329,767 filed 19 Dec. 2011 and claims priority to Norwegian patent application 20101770 filed 17 Dec, 2010.
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Number | Date | Country | |
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Number | Date | Country | |
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Parent | 13329767 | Dec 2011 | US |
Child | 14291153 | US |