A flow-conditioning system includes a pump, process tubing coupling the pump to a source of multiple component process fluid, and an in-line flow-mixing device positioned in the process tubing upstream of the pump. A system includes a well disposed below a body of water and providing a source of multiple component fluid, a pump disposed in and exposed to the water, process tubing coupling the pump to the well, and an in-line flow-mixing device positioned in the process tubing upstream of the pump.
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1. A flow-conditioning system, comprising:
a pump unit, the pump unit comprising a pump that is configured to be disposed in a body of water;
a motor operably coupled to the pump;
process tubing coupling the inlet of the pump to a source of multiple component process fluid, wherein said process tubing is adapted to deliver at least a portion of the multiple component fluid to the inlet of the pump;
a separator disposed downstream of an outlet of the pump, wherein the separator is operable to extract a gas component from the multiple component process fluid;
a pathway operable to route at least a first portion of the gas component as a flushing medium for at least a portion of the pump unit;
a flushing pump operable to increase a pressure of the gas component; and
an in-line flow-mixing device positioned in the process tubing upstream of the inlet of the pump.
18. A system, comprising:
a well disposed below a body of water, the well providing a source of multiple component fluid;
a pump unit, the pump unit comprising a pump that is positioned outside of the well, the pump being disposed in and exposed to the body of water;
a motor operably coupled to the pump;
process tubing coupling the inlet of the pump to the well, wherein said process tubing is adapted to deliver at least a portion of the multiple component fluid from the well to the inlet of the pump;
a separator disposed downstream of an outlet of the pump, wherein the separator is operable to extract a gas component from the multiple component process fluid;
a pathway operable to route at least a first portion of the gas component as a flushing medium for at least a portion of the pump unit;
a flushing pump operable to increase a pressure of the gas component; and
an in-line flow-mixing device positioned in the process tubing upstream of the inlet of the pump.
19. A flow-conditioning system, comprising:
a pump unit, the pump unit comprising a pump that is configured to be disposed in a body of water;
a motor operably coupled to the pump, the motor comprising:
a rotor;
a stator disposed on the rotor; and
a first can isolating the stator from the rotor to at least partially define a rotor cavity at least partially encompassing the rotor;
a labyrinth seal disposed on the rotor at a first end of the rotor cavity, said labyrinth seal being adapted to restrict flow between the rotor cavity and the pump;
process tubing coupling the inlet of the pump to a source of multiple component process fluid, wherein said process tubing is adapted to deliver at least a portion of the multiple component fluid to the inlet of the pump; and
a separator disposed downstream of an outlet of the pump, wherein the separator is operable to extract a gas component from the multiple component process fluid;
a pathway operable to route at least a first portion of the gas component to the rotor cavity as a flushing medium;
an in-line flow-mixing device positioned in the process tubing upstream of the inlet of the pump.
2. The system of
3. The system of
4. The system of
5. The system of
a rotor;
a stator disposed around the rotor; and
a first can isolating the stator from the rotor to at least partially define a rotor cavity at least partially encompassing the rotor wherein the pathway is operable to route the first portion of the gas component to the rotor cavity.
6. The system of
7. The system of
a shaft;
a bearing operable to support the shaft; and
a second can enclosing at least a portion of the bearing, wherein the pathway is operable to route a second portion of the gas component to a second cavity defined by the second can.
8. The system of
a pumping element disposed on the shaft; and
a second labyrinth seal disposed on the shaft between the second can and the pumping element, said second labyrinth seal being adapted to restrict flow between the second can and the pump.
9. The system of
10. The system of
11. The system of
12. The system of
13. The system of
14. The system of
16. The system of
17. The system of
20. The system of
a shaft;
a bearing operable to support the shaft; and
a second can enclosing at least a portion of the bearing, wherein the pathway is operable to route a second portion of the gas component to a second cavity defined by the second can.
21. The system of
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This is a 371 of PCT/US09/42233, filed Apr. 30, 2009, which claimed priority from U.S. provisional patent application Ser. No. 61/050,899, filed May 6, 2008, U.S. provisional patent application Ser. No. 61/127,511, filed May 14, 2008, U.S. provisional patent application Ser. No. 61/075,135, filed Jun. 24, 2008, and U.S. provisional patent application Ser. No. 61/112,305, filed Nov. 7, 2008.
1. Field of the Invention
The disclosed subject matter relates generally to a flow-conditioning system for a pump including an in-line flow-mixing device.
2. Description of the Related Art
Electrically driven pumps have been in common use for many years. One application of such an electrically driven pump is in the field of hydrocarbon service, where subsea pumps may be used. Subsea pumps have been used to pump multiphase fluids, typically including any pump-able combination of oil, gas, water and/or solids, as well as single-phase fluids, e.g. water and/or oil. Conventionally, one of three subsea pump/motor technologies are typically deployed subsea on commercial applications. Two technologies may be characterized as having a “short-fat” induction motor driving a relatively short rotor-dynamic pump (e.g., up to 14 stages), or driving a twin-screw positive displacement pump, which is also relatively short. Typically, rotor-dynamic pumps have been oriented vertically with the induction motor positioned over the pump, whereas the twin-screw pump units have been oriented horizontally. The third pump/motor technology deployed subsea employs a repackaged electric submersible pump (ESP), which may be characterized as a “long-skinny” induction motor driving a long-skinny rotor-dynamic pump (e.g., including several tens of stages). Subsea ESPs may be deployed vertically in a caisson/dummy-well or riser, or in a near-horizontal orientation proximate the seabed, (e.g., on a foundation structure or in a flowline jumper).
The impellers 105 are unitized to a pump shaft 109, whereas the diffusors 106 are unitized to a pump pressure housing 110. The shaft 109 is supported by radial bearings 111, 112 and an axial bearing 113, the latter being designed to support the weight of the shaft 109 and components integrated thereto plus the thrust load developed by the pump hydraulic elements and the hydraulic piston effect associated with the barrier fluid system (BFS) acting on the shaft 109, flexible coupling 114, and an optional balance piston (not shown). Relevant design codes impose multiplication factors that add to axial bearing 113 load carrying capacity requirements. The shaft 109 is connected to an induction rotor 115 of the induction motor 116 by a flexible coupling 114 that transfers torque but not axial load. The rotor 115 is turned by the electro-magnetic forces generated by a stator 117. The rotor 115 is supported by radial bearings 118, 119 and an axial bearing 120, the latter being designed to support the weight of the rotor 115, the hydraulic piston effect associated with the BFS interaction therewith and on the flexible coupling 114, and design code multiplication factors. All the bearings are typically hydrodynamic tilting-pad mechanical bearings for which the rotating versus non-rotating elements are separated under dynamic (“hydraulic-lift”) conditions by a film from a pressurized fluid 121. Contact between bearing mechanical elements may occur whenever there is no relative movement between those elements. Fluid 121 for creating the film is provided by a BFS described in greater detail elsewhere in this document.
The barrier fluid 121 distributed widely within the pump unit 101 should ideally be maintained at a pressure greater than the outlet pressure of the pump 101 to serve its multiple functions in conventional systems, such as that illustrated in
In addition to lubricating and cooling the bearings 111, 112, 113, 118, 119, 120 and mechanical seals 122, 123, another function of the BFS is to provide electrical insulation and cooling for the stator 117 and associated items such as high-voltage power penetrators 124. The aforementioned items, especially the stator 117 generate large amounts of heat during operation. Damage resulting in system failure will occur quickly if heat beyond design capacity is not removed from the system. Owing partly to the pump and motor multiple, thick wall-section, limited externally-exposed-surface-area housings 110, 125 and 126, 127 respectively, and also to heat-transfer characteristics of the multiple materials involved, including the barrier fluid, heat transmitted naturally between the heat-generating elements and the barrier fluid 121 cannot be adequately moved by passive means alone to the environment surrounding the pump unit 100 (i.e., via conduction, convection and/or radiation). It is therefore necessary, for all but low-power systems, that barrier fluid 121 be circulated through an external long-conduit heat-exchanger, possibly including multiple flow-paths 128. Such a system typically also requires a pump to circulate the barrier fluid 121, which in
A typical barrier fluid system associated with prior art subsea pump systems comprises many components, some positioned proximate the subsea pump and others located on a topside (above water) facility usually several miles away. A typical BFS comprises a hydraulic power unit, fluid storage tanks, cleaning and dehydrating equipment, filters, pumps for moving fluids between various topside components and for delivering the barrier fluid to the subsea pump, flow restrictors, non-return valves, accumulators, full-bore valves, pipes and fittings, one or more lines in the subsea umbilical, pressure and temperature sensors, level-monitoring instruments, and control systems. Because several of these components are critical to the correct functioning of the system and therefore the integrity and reliability of the associated subsea pump, redundant such components are typically provided for each field application. Many of these components require periodic maintenance, and the amount and condition of the barrier fluid in the storage tank(s) must be carefully monitored and maintained at all times. Barrier fluid circulated within prior art subsea pumps and motors is also the primary means for removing heat therefrom, especially from electric motors, and there are several components associated with that function, including dedicated pumps/impellers and heat-exchanger tubes.
This section of this document is intended to introduce various aspects of art that may be related to various aspects of the disclosed subject matter described and/or claimed below. This section provides background information to facilitate a better understanding of the various aspects of the disclosed subject matter. It should be understood that the statements in this section of this document are to be read in this light, and not as admissions of prior art. The disclosed subject matter is directed to overcoming, or at least reducing the effects of, one or more of the problems set forth above.
One aspect of the present subject matter is seen in a flow-conditioning system including a pump, process tubing coupling the pump to a source of multiple component process fluid, and an in-line flow-mixing device positioned in the process tubing upstream of the pump.
Another aspect of the present subject matter is seen in a system including a well disposed below a body of water and providing a source of multiple component fluid, a pump disposed in and exposed to the water, process tubing coupling the pump to the well, and an in-line flow-mixing device positioned in the process tubing upstream of the pump.
The disclosed subject matter will hereafter be described with reference to the accompanying drawings, wherein like reference numerals denote like elements, and:
FIGS. 5A-5E-2 illustrate different embodiments of cooling elements for the pump unit of
While the disclosed subject matter is susceptible to various modifications and alternative forms, specific embodiments thereof have been shown by way of example in the drawings and are herein described in detail. It should be understood, however, that the description herein of specific embodiments is not intended to limit the disclosed subject matter to the particular forms disclosed, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the disclosed subject matter as defined by the appended claims.
One or more specific embodiments of the disclosed subject matter will be described below. It is specifically intended that the disclosed subject matter not be limited to the embodiments and illustrations contained herein, but include modified forms of those embodiments including portions of the embodiments and combinations of elements of different embodiments as come within the scope of the following claims. It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions must be made to achieve the developers' specific goals, such as compliance with system-related and business related constraints, which may vary from one implementation to another. Moreover, it should be appreciated that such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure. Nothing in this application is considered critical or essential to the disclosed subject matter unless explicitly indicated as being “critical” or “essential.”
The disclosed subject matter will now be described with reference to the attached figures. Various structures, systems and devices are schematically depicted in the drawings for purposes of explanation only and so as to not obscure the disclosed subject matter with details that are well known to those skilled in the art. Nevertheless, the attached drawings are included to describe and explain illustrative examples of the disclosed subject matter. The words and phrases used herein should be understood and interpreted to have a meaning consistent with the understanding of those words and phrases by those skilled in the relevant art. No special definition of a term or phrase, i.e., a definition that is different from the ordinary and customary meaning as understood by those skilled in the art, is intended to be implied by consistent usage of the term or phrase herein. To the extent that a term or phrase is intended to have a special meaning, i.e., a meaning other than that understood by skilled artisans, such a special definition will be expressly set forth in the specification in a definitional manner that directly and unequivocally provides the special definition for the term or phrase.
Referring now to the drawings wherein like reference numbers correspond to similar components throughout the several views and, specifically, referring to
In the event gas-slugs are anticipated within the inlet process stream, optional slug-catcher(s) 209 may be provided for receiving the multiphase process stream through an inlet 210 and exhausting predominantly gas through outlet 211 and liquids/solids through outlet 212. Alternative slug-catcher configurations, including single-outlet (multiphase) designs known to those of ordinary skill in the art, may also be implemented in conjunction with the disclosed subject matter.
An in-line mixer 213 receives a single raw process inlet stream in the event no slug-catcher is provided, or single or dual inlet streams in the event a slug-catcher is provided (i.e., depending on the slug-catcher configuration). For dual inlets, one will typically receive substantially gas and the other substantially liquids-solids. In all cases in-line mixer 213 exhausts a substantially homogenized multiphase flow stream to a process pump 214 via inlet 215.
When operating, the process pump 214 exhausts fluids at greater than inlet pressure via outlet 216. After passing through a non-return valve 217, pump outlet-pressure fluid will enter a gas/liquid extraction unit (G/LEU) 218 via inlet 219. The embodiment shown in
Gas provided to the G/LEU 218 outlet 220 is routed through a non-return valve 224 and split 225 on its way to motor 226 and pump 214 injection points 227 and 228, respectively. Alternatively, one or more non-return valve(s) 224 may be positioned anywhere downstream of the outlet 220 (e.g., one each adjacent injection points 227, 228) for reducing the compressible volume of fluid (e.g., gas) downstream thereof. The conduit and associated elements between the outlet 220 and injection points 227, 228 is referred to as the “flushing circuit”, and its function is to create and maintain a gas-buffer between the rotor 319 (see
Optional meters 229 on each injection-leg of the flushing circuit enable verification of flow in the associated conduit, and optional valves 230 enable select isolation of each injection-leg and corresponding concentration of flow in the other leg. Other means for verifying flow in the injection-legs may also be used (e.g., flow meters).
A pump, compressor or fan 231 (henceforward, “pump” 231) may be optionally provided for increasing pressure in the flushing circuit supply line to a level greater than pump 214 exhaust pressure. The location of the pump 231 in
Liquid fluid provided to the outlet 221 of the G/LEU 218 is routed through a choke 232 on its way to an inlet 233 of a slug-catcher 209 or some other point upstream of the pump 214. The conduit and associated elements between the outlet 221 and the inlet 233 is referred to as the “liquid recirculation circuit”, and its function is to increase the availability of liquid in the pump 214 inlet stream to improve pump performance, especially in the event a gas-slug passes through the system. The choke 232 reduces the pressure of the fluid at the G/LEU outlet 221 to a level approximating the pressure at the inlet 207 to the pump module 201.
Sensors/transmitters for pressure 234, differential pressure 235, temperature 236, position 237, and other sensors depending on the particular implementation, are distributed throughout the pump module 201 to enable condition and performance monitoring of the system. Use of the information provided by such devices enables improved performance and longevity for the pump unit.
A chemical injection supply line 239 and associated non-return valve 240 and isolation valve 241 enable controlled delivery of a fluid, such as methanol or glycol, into the flushing circuit to help avoid the formation of hydrates in downstream areas associated primarily with prolonged shut-downs. This circuit also provides the ability to purposely flush debris or blockages from downstream lines and/or cavities.
As mentioned previously, an optional pump 231 may be provided to increase pressure in the flushing circuit to a level greater than exhaust pressure from process pump 214 and, as a consequence, ensure that flow across labyrinth seals 306, 313 is from the flushing circuit-side toward process fluids inside the pump 214. Also noted previously, the pump 231 may take several forms, and as such its position in
Although the G/LEU 218 is illustrated as being disposed down stream of the pump module 201 (i.e., at outlet pressure), it is contemplated that the G/LEU 218 may, in some embodiments, be disposed upstream of the pump module 201 (i.e., at inlet pressure). In such applications a flushing pump may be used to increase the pressure of the extracted flushing medium (e.g., the gas component) to a pressure near or higher than the pump exhaust pressure.
One solution for increasing pressure in the flushing circuit is to add a conventional, substantially self-contained, electrically or hydraulically powered pump 231 thereto, powered from a remote location, and typically positioned between points 220 and 225. Alternatively, one-each such pump may be added to individual flushing circuit legs defined between points 225 and 227 and between points 225 and 228. Depending on the remote or local power source that drives such pump(s) 231, it/they may operate completely independently of the process flow or be available only when there is process flow through pump module 201 or the conduit defined by points 202 and 203. Flow in the flushing circuit itself, the liquid recirculation circuit, or a bypass line tapped-off either of those or any other process-supplied conduit associated with the pump system are exemplary process-flow-dependent sources.
The pump(s) 231 may also rely on flow through some other conduit, such as a chemical injection supply line, water injection line, gas-lift line, bypass line tapped-off any other fluid line, etc. Some of the latter sources may also be used to directly supply the injection points 227, 228 as an alternative to, or in combination with the flushing circuit embodiment illustrated in
Potential power sources local to the pump system encompass a wide variety of energy conversion means. For example, an impeller in any flow stream may be directly coupled via a shaft to drive an associated impeller to act on a separate flow stream, e.g. the pump(s) 231, 504, etc., or to drive a generator to produce electricity that can be used by any electrically powered device. Such directly coupled devices will typically, but not exclusively, share a common shaft that passes through a barrier that separates the discrete fluids. Such shaft will typically be supported by mechanical bearings, however magnetic bearings may also be used.
An impeller in any flow stream may alternatively be magnetically-coupled to another impeller residing in an adjacent, typically concentric, isolated flow path to effect pump functionality. An impeller in any flow stream may alternatively be magnetically-coupled to a generator stator to produce electricity that can be used by any of the pump(s) 231, 504, etc., or other electrically powered devices.
As will be described in greater detail below in reference to
The ability to operate the pump(s) 231, 504 independent of pump module 201 or process flow may be advantageous, especially following shut-down of the pump module 201. For some hydrocarbon well pumping applications in particular, the process bore shut-in static pressure (supplied by wells and/or flowline head, e.g. as a result of substantial water depth) can be greater than the pumped-process flowing pressure. Following shut-down, the potentially slow-building process pressure might affect the properties of the fluids in the motor rotor cavity 330 and pump magnetic bearing rotor cavity residing between the high pressure rated can (HPRC) 329 and the shaft 307. Depending on the reason for the shut-down, the chemical injection supply line 239 may enable displacement of the fluids in the aforementioned rotor cavities with methanol, glycol, or a fluid fulfilling a similar purpose.
Another advantage of being able to operate the pump(s) 231, 504 following cessation of process flow, especially when unplanned, is the ability to maintain forced-cooling for motors so equipped, thereby avoiding an equipment-life-threatening temperature rise that naturally follows loss of cooling fluid circulation for such motors.
The inlet device 302 may incorporate a labyrinth seal 306 toward the pump shaft 307. However, in some embodiments, that feature may be positioned elsewhere nearby, possibly in a dedicated part/parts. The labyrinth seal 306 acts as a restriction to resist flow/transfer of media between adjacent fluid volumes and, in the case of the illustrated embodiment, helps build and maintain pressure in the volumes supplied by the flushing circuit to a level at least as high as pump exhaust pressure. In so doing, the labyrinth seal 306 facilitates creation and maintenance of a preferred dynamic environment within the rotor cavity 330, directly, and within the cavity internal to the HPRC 329 associated with magnetic bearings 315, indirectly (i.e., gas devoid of debris and liquids). The labyrinth seal 306 in combination with flushing system effects described previously is intended to exclude raw process fluids from the noted areas. Various types of gas seals may be used in place of labyrinth seals 306, however those may be more subject to wear and typically generate heat.
To protect the pump body 308, the inlet chamber 303 may include a sleeve 309. Increased-pressure fluid exits the stack of impellers 304 and diffusers 305 into an outlet device 310 which redirects fluid from the exhaust chamber 311 to an outlet 312 and protects the pump body 308. The outlet device 310 may incorporate a labyrinth seal 313 toward the pump shaft 307. However, in some embodiments, that feature may be positioned elsewhere nearby (e.g., at location 314), possibly in a dedicated part/parts. The labyrinth seal 313 has the same function as described previously for the labyrinth seal 306, and may also be substituted by gas seals.
The pump body 308 and internal components may be constructed from inherently erosion and/or corrosion resistant materials, and/or they may be coated, overlayed or otherwise treated to improve their performance and/or durability under the service conditions anticipated for specific applications.
The impellers 304 are unitized to the pump shaft 307, whereas the diffusers 305 are unitized to the pump body 308. The shaft 307 is suspended at its lower end by a radial magnetic bearing 315 and at its upper end by a radial magnetic bearing 316, the latter through the effect of a rigid coupling 317. Axial loads, including predominantly the weight of the shaft 307 and impellers 304, thrust developed when the pump is operating, the hydraulic piston effect associated with the flushing system acting on the shaft 307, an optional balancing piston (not shown), the weight of the rotor 319 of the motor 226, and relevant design-code-imposed multiplication factors, are carried by one or more axial magnetic bearing(s) 318, also known as magnetic thrust bearings. The single axial magnetic bearing functionality may, as an alternative to a dedicated axial magnetic bearing, be provided integral to a radial magnetic bearing 315, 316, 324. Similarly, the multiple axial magnetic bearings functionality may, as an alternative to the stacked/staged arrangement shown at 318, be provided in distributed form, e.g. via dispersed dedicated axial magnetic bearings or by incorporating axial load-carrying functionality into one or more of the radial magnetic bearings 315, 316, 324.
The shaft 307 is connected to the rotor 319 by rigid coupling 317 that transfers torque via spline 320, bending loads via a press-fit stepped-socket interface including two axially-separated soft-metal inserts 321, and axial loads via shoulder 322.
The permanent magnet rotor 319, or in an alternative embodiment an induction rotor, is turned by the electro-magnetic forces generated by the stator 323. The rotor 319 is suspended by radial magnetic bearings 316, 324, and by axial magnetic bearing(s) 318.
The magnetic bearings 315, 316, 318, 324 may be passive (e.g., permanent magnet), active (e.g., electro-magnetic), or a combination thereof. Passive magnets require no external power source to be effective, which is useful to ensure suspension of dynamic components during shipping and storage (i.e., when power is not available) and also during spin-down following planned and/or unplanned removal of power for a previously operating system. When used in combination with appropriate sensors and a suitable control system, active magnets enable provision of supplemental and directional suspension force for maintaining desired positioning of dynamic components during process transients and/or other imbalance conditions. A combination of passive and active magnetic bearing components allows support in a non-powered state and positioning under dynamic conditions. Contingency mechanical bearings 345 may be provided as a backup to passive and/or active magnetic bearings.
A high-pressure rated can (HPRC) 325 is disposed between the rotor 319 and the stator 323 and forms pressure-tight seals 326 toward a base-flange 327 and a crown-flange 328 in such a way that significant pressure end-loads are not carried by the HPRC 325, thus enabling minimum wall thickness for a specified pressure rating. Generally, the HPRC 325 is capable of withstanding pressure up to the maximum head pressure generated at the pump 214 or the maximum wellhead shut-in pressure, whichever is greater. The pressure outside the HPRC 325 generally corresponds to the ambient pressure resulting from the submerged depth of the pump module 201. The worst case loading conditions may vary depending on the particular application environment for the pump unit 300, and may thus affect the strength requirements for the HPRCs 325, 329. While seals 326 are depicted as being radial seals they may also be face seals, corner seals, or any other configuration seals substantially satisfying the low-end-loads condition, including any form of direct interference and/or bonded interface, regardless if any bonding material is employed and regardless the nature of the bond (e.g., pressurized fluid, molecular/atomic (e.g., chemical or heat-fusion)), etc., between the HPRC 325 and the flanges 327, 328.
The rotor cavity 330 resides between the rotor 319, pump shaft 307, HPRC 325, seals 326, crown-flange 328, base-flange 327, gasket 331, pump body 308, inlet device 302, seal 332, and labyrinth seal 306. As shown in
The rotor cavity at least partially enclosed by the HPRC 329 in the pump 212 resides between the HPRC 329, the pump body 308, seals 326, the pump shaft 307, the outlet device 310, and the labyrinth seal 313. As shown in
The material of the HPRCs 325, 329 is selected to provide high magnetic field permeability and sufficient strength to enable thin wall sections for application-specific pressure conditions. A thinner wall section reduces the impact of the HPRCs 325, 329 on motor power factor and efficiency. Exemplary materials for the HPRCs 325, 329 include carbon fiber or similar composite material, ceramic, stainless steel, titanium, etc.
In an embodiment where one or more active magnetic bearings are employed, the relative position of important rotating and non-rotating suspension components may be monitored and power may be provided as needed to enable the active magnetic bearings to compensate for deviations from the desired relative positions. The mechanism for data communication and power transfer typically comprises wires routed between the active magnetic bearings and a controller (not shown in
Circumstances are different, however, for data communication and power transfer associated with typically dedicated axial magnetic bearings 318, which for the purposes of this discussion include active elements. In this case the bearings and sensor(s) are exposed directly to process pressure and fluids (i.e., an environment for which they are purposely designed), and the aforementioned wires (not shown in
The motor outer housing 333 is press-fit to the stator 323 to promote the transfer of heat therebetween and further into the surrounding environment. The outer housing 333 may be constructed from a variety of metallic or non-metallic materials that satisfy the structural strength requirements and promote heat transfer and/or increased resistance to external deposits accumulation. Calcareous deposits and biofouling may be issues for high-temperature surfaces, especially metallic surfaces, in contact with sea water. As discussed further below, the stator 323 may be unitized with the HPRC 325 or supported by some other means than suspension within an outer housing 333. In such circumstances, alternative means and material options become available for isolating the stator 323 from the ambient environment while promoting heat-flow there-into, e.g. “bags”/“bladders”, “shrink wrap”, composite-fiber windings and/or laminates, and coating solutions, among others.
The housing 333 is unitized to the crown-flange 328 and pump body 308 to transfer to the latter the end-loads imparted by pressure acting on the former.
A pressure-balanced high-voltage penetrator 334 is secured to the crown-flange 328 to conduit external electric power to inside the stator cavity 335.
In some embodiments, the HPRC 325 may be prevented from experiencing significant axial loads. The first two concepts shown in
The embodiment of
The embodiment shown in
The HPRC 325-1 illustrated in the embodiment of
Many alternative configurations consistent with the principles described above and illustrated in the embodiments of
FIGS. 5A-5E-2 illustrate alternative cooling elements that may be provided for a pump unit 501, such as the pump unit 300 of
Stator conduits 515, 516, 517 allow fluid to circulate within the stator cavity 335 in response to naturally occurring thermal currents and/or forced circulation driven by an associated pump, represented by the impeller 504. They may also be used as conduits for routing wires for various purposes. A dedicated pump (not shown) not integral to pump unit 501 is another of many potential alternatives to cause fluid to circulate through the noted conduits. While not specifically shown, it is apparent to one of ordinary skill in the art that appropriate barriers/restrictions may be provided to achieve and/or direct appropriate circulation flow. Stator conduits 515, 516, 517 run from one side of the stator core laminations stack 518 to the other, and are positioned anywhere across the radial expanse of the stack 518 (i.e., fully within the radial expanse 518), adjacent the inside diameter 516 or adjacent the outside diameter 517. The conduits 516, 517 may be wholly or partially within adjacent items, such as the HPRC 325 and the outer housing 333, respectively.
Because the pump unit 501, and especially the stator 323, will transfer a significant amount of heat to the surrounding environment, convection currents will evolve therein. The greater the temperature gradient imposed on the surrounding environment, the stronger the convection currents. The shroud 519 will tend to hold conducted/radiated heat near the housing 333 and thereby increase the thermal gradient between the top and bottom thereof. This will naturally increase the influx of cool environmental fluid into the bottom 520 of an annulus 521 and accelerate the fluid vertically across housing 333 on its way to exhausting out the top 522. This effect will expose the housing 333 to more cool fluid from the surrounding environment than would have been the case if the shroud 519 were not present. This effect may be enhanced by insulating the shroud 519 or by constructing the shroud 519 using a material with insulating properties; however, this is subject to specific design and application environment considerations.
Stand-off ribs 523 act as cooling fins to conduct additional heat from the housing 333 to the environment. In some cases, cooling fins (i.e., stand-off ribs 523 without the surrounding housing 519) may provide adequate cooling.
Various alternatives for the system illustrated in
Various materials may be employed for stator cooling, e.g., mineral oil or water-glycol based fluids, which are especially relevant for actively cooled/pumped systems requiring fluid circulation. For a passive cooling system a high-viscosity heat transfer compound, such as compounds offered by Thermon Manufacturing Co. of San Marcos, Tex. may be employed. Other compounds may also be used, such as those that can absorb and dissipate relatively large amounts of heat over a relatively small temperature range as they change phases, e.g. when liquid perfluorinate vaporizes and condenses. The particular cooling medium depends on the heat conduction and electrical insulation requirements of the particular implementation. Materials other than the exemplary materials illustrated herein may be used.
As depicted in
As depicted in
An alternative fixity embodiment for the stator 323 includes stator core laminations 605 that are closely fit or pressed over the HPRC 325. A vacuum-resin impregnation process may be used to remove voids and subsequently unitize and rigidize the stator core laminations 605 and stator windings 606 prior to installing the stator 323 over the HPRC 325 or subsequent to the latter operation. If performed subsequently, a more positive bond may be established between the stator 323 and the HPRC 325 to create a composite structure with enhanced resistance to external pressure as well as internal pressure. This construction will more effectively share loads between the stator 323 and the HPRC 325 than the previously discussed construction and in so doing may permit a reduced cross-section thickness for either or both elements, with accordant respective benefits. A thinner stator provides less thermal mass between the heat source (rotor coils) and the heat sink (surrounding water). A thinner HPRC enables less distance between the stator and rotor for improved motor power factor. If used, and regardless of the resin bonding versus assembly sequence, the inside diameter of the stator 323 may be machined to provide a smooth, constant diameter surface for interfacing with the HPRC 325.
The aforementioned alternative embodiment will, for ease of downstream assembly purposes, typically provide a clearance gap or only light interference fit between the outside of the stator 323 and the inside of the outer housing 333. To deliver high-performance heat-transfer properties, a thermal bridge may be provided. For the purpose of this disclosure a thermal bridge includes any heat conducting object or material that facilitates transfer of heat from one location to another, such as across a radial gap between the stator 323 and the outer housing 333 over at least a portion of the longitudinal and circumferential expanse of said gap. Some examples of suitable thermal bridge constructions include belleville washers, wave springs, accordion-bellows, longitudinal rods, longitudinal wave filaments, “finger” filaments, mesh, helical-coil springs arranged longitudinally or in circumferential bands or in a spiral, etc. Heat-conducting fibers pressed between the laminations and oriented to radiate from the inner part of the core stack (e.g., between the windings) to outside the core stack and engaging the inside of the outer housing 333 is one thermal bridge construction that also creates radial channels between the laminations in which coolant may flow and/or in which a high-thermal-conductivity compound may be placed. Other thermal bridge constructions include filling the gap with a thermal bridge substance post-assembly, and/or integrating tines protruding from the stator core laminations 605, typically providing an interference-fit local to the tines. Heat transfer efficiency across the thermal bridge will generally be proportional to the contact area between the thermal bridge and adjacent items.
Another alternative fixity embodiment for the stator 323 is a combination of the two preceding options. Specifically, the stator core laminations 605 are in direct and maintained contact with both the HPRC 325 and the external housing 333 in a manner that causes loads to be shared and heat to be efficiently transferred between them. Depending on a combination of factors including sourcing, logistics and other supply chain considerations, among others, the timing for implementing the vacuum-resin impregnation process may be a contributing factor to the effectiveness of the construction, i.e., before, during, or post-assembly of various components making up the composite construction.
Yet another alternative fixity embodiment for the stator 323 includes filling the stator cavity 335 with a material that fully unitizes motor static elements from structural and thermodynamic perspectives. The result is a stiff composite structure capable of withstanding extreme pressure differentials. From a practical perspective, such a material should accommodate introduction to the cavity 335 post-assembly of surrounding components, e.g., in the manner of the vacuum-resin impregnation process typically used to stabilize stator constructions. In fact, “stator resin” (typically epoxy) is one candidate material for the subject alternative embodiment fixity application, however its thermal properties make it less attractive than some alternatives. Other materials, including metallic materials and various close-packed powders, particles, beads, etc., may be candidates, as may combinations of such materials and/or thermal bridge constructions.
Generally, the magnitude of differential pressure across the HPRC 325 contributes significantly to the determination of the optimum fixity approach. As demonstrated by the several foregoing alternatives, the stator 323 provides structural support to the HPRC 325, and vice-versa, for applications that would benefit from such an effect.
The particular embodiments disclosed above are illustrative only, as the disclosed subject matter may be modified and practiced in different but equivalent manners apparent to those skilled in the art having the benefit of the teachings herein. Furthermore, no limitations are intended to the details of construction or design herein shown, other than as described in the claims below. It is therefore evident that the particular embodiments disclosed above may be altered or modified and all such variations are considered within the scope and spirit of the disclosed subject matter. Accordingly, the protection sought herein is as set forth in the claims below.
Cunningham, Christopher E., Fantoft, Rune, Hollingsaeter, Terje
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