This disclosure relates in general to electrical submersible well pumps and in particular to a below motor pressure equalizer assembly for reducing a pressure difference between lubricant in the motor and hydrostatic well fluid pressure, and for allowing the expansion and contraction of the lubricant to the motor.
Many hydrocarbon wells are produced by electrical submersible well pump assemblies (ESP). A typical ESP includes a centrifugal pomp having a large number of stages, each stage having an impeller and a diffuser. An electrical motor couples to the pump for rotating the impellers. A pressure equalizer or seal section connects to the motor to reduce a pressure differential between lubricant in the motor and the hydrostatic pressure of the well fluid. The pressure equalizer has a motor lubricant passage leading from a flexible barrier such as a bag or bellows into the Interior of the motor. The motor lubricant passage is always open to communicate well fluid pressure applied in the pressure equalizer to the flexible barrier to the motor lubricant in the motor.
With most prior art ESP's, the pressure equalizer or seal section is located between the motor and the pump. In others, the pressure equalizer is mounted below the motor. The pressure equalizer may comprise an upper and lower pressure equalizer in tandem. An intermediate connection between the upper and lower pressure equalizers has an intermediate motor lubricant passage for communicating motor lubricant between the flexible elements in each.
An electrical submersible pump assembly has a pump, a motor having a rotatable shaft extending along a longitudinal axis and operatively coupled to the pump for driving the pump. An upper pressure equalizer is coupled to a lower end of the motor. A lower pressure equalizer connects to the upper pressure equalizer. Each of the pressure equalizers has a movable equalizing element that communicates well fluid pressure exterior of the pressure equalizers to motor lubricant in the motor. A connection between an upper end of the lower pressure equalizer and a lower end of the upper equalizer has a liquid flow passage through which a liquid in the upper pressure equalizer communicates with a liquid in the lower pressure equalizer. At least one connection valve is located in the liquid flow passage and closes the liquid flow passage prior to connecting the pressure equalizers with each other. The connection valve opens the liquid flow passage after the connection between the lower pressure equalizer and the upper pressure equalizer is made.
Preferably the connection valve is spring-biased to a closed position and opens in response to abutment of the lower end of the upper pressure equalizer with the upper end of the lower pressure equalizer.
A motor equalizer adapter connects between an upper end of the upper pressure equalizer and a lower end of the motor. A motor equalizer passage in the motor equalizer adapter provides for the passage of motor lubricant between the motor and the upper pressure equalizer. A motor equalizer valve in the motor equalizer passage is movable between an open position and a closed position. In the preferred embodiment, an end portion of the shaft is in engagement with the motor equalizer valve while the motor equalizer valve is in a closed position. The motor equalizer valve moves to the open position in response to rotation of the shaft.
In the embodiment shown, the connection valve comprises an upper pressure equalizer lower valve and a lower pressure equalizer upper valve.
Preferably, the movable equalizing element within each of the upper and lower pressure equalizers comprises a bellows. Motor lubricant in fluid communication with the motor lubricant in the motor is located within an interior of the bellows of the upper pressure equalizer. A secondary liquid is located on an exterior of the bellows of the upper pressure equalizer and an interior of the bellows of the lower pressure equalizer. The bellows of the lower pressure equalizer is immersed in well fluid during operation.
The connection between the pressure equalizers includes an upper pressure equalizer lower adapter secured to a lower end of the upper pressure equalizer and a lower pressure equalizer upper adapter secured to an upper end of the lower pressure equalizer. The liquid flow passage extends through the upper pressure equalizer lower adapter and through the lower pressure equalizer upper adapter. The connection valve comprises an upper pressure equalizer lower valve and a lower pressure equalizer upper valve. The upper pressure equalizer lower valve is mounted in the liquid flow passage in the upper pressure equalizer lower adapter and spring biased downward to a closed position protruding from a lower end of the upper pressure equalizer lower adapter. The lower pressure equalizer upper valve is mounted in the liquid flow passage in the lower pressure equalizer upper adapter and spring biased upward to a closed position protruding from an upper end of the lower pressure equalizer upper adapter. Preferably, the upper pressure equalizer lower valve and the lower pressure equalizer upper valve are radially offset from each other relative to the axis such that they do not contact each other when the lower pressure equalizer upper adapter is secured to the upper pressure equalizer lower adapter.
In the embodiment shown, a sensor unit is mounted to a lower end of the low pressure equalizer. A sensor lower equalizer line extends from the sensor unit through the lower pressure equalizer to a lower terminal at the upper end of the lower pressure equalizer. A sensor upper equalizer line is releasably connected to the lower terminal and extends through the upper pressure equalizer to an upper terminal at an upper end of the upper pressure equalizer. A sensor motor line extends downward from the motor and in releasable engagement with the upper terminal.
In the embodiment shown, the liquid flow passage in the connection includes a first portion located on the axis and a second portion radially offset from the axis. The connection valve comprises a first valve mounted on the axis and a second valve radially offset from the first valve. A portion of the sensor motor line extends sealingly through the first valve.
So that the manner in which the features, advantages and objects of the disclosure, as well as others which will become apparent, are attained and can be understood in more detail, more particular description of the disclosure briefly summarized above may be had by reference to the embodiment thereof which is illustrated in the appended drawings, which drawings form a part of this specification. It is to be noted, however, that the drawings illustrate only a preferred embodiment of the disclosure and is therefore not to be considered limiting of its scope as the disclosure may admit to other equally effective embodiments.
The methods and systems of the present disclosure will now be described more fully hereinafter with reference to the accompanying drawings in which embodiments are shown. The methods and systems of the present disclosure may be 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 its scope to those skilled in the art. Like numbers refer to like elements throughout.
It is to be further understood that the scope of the present disclosure is not limited to the exact details of construction, operation, exact materials, or embodiments shown and described, as modifications and equivalents will be apparent to one skilled in the art. In the drawings and specification, there have been disclosed illustrative embodiments and, although specific terms are employed, they are used in a generic and descriptive sense only and not for the purpose of limitation.
Referring to
A pump 23 connects to the upper end of thrust bearing unit 15 in this example. Pump 23 could be a centrifugal pump with a large number of stages, each stage having an impeller and a diffuser. Alternately, pump 23 could be another type, such as a progressing cavity pump. Pump 23 has an intake 25 for admitting well fluid. A string of production tubing 26 secures to the upper end of pump 23 and supports ESP 11 in a well. Production tubing string 26 may be sections of tubing with threaded ends secured together, or it could be continuous coiled tubing.
Referring to
A flexible element in this example comprises an upper outer bellows 41 and an upper inner bellows 43, both located within upper housing section 29 surrounding upper guide tube 37. Upper outer bellows 41 has a fixed lower end sealed to intermediate connector 31 and a movable upper end sealed to upper inner bellows 43 by a bellows interconnect 45. Bellows interconnect 45 is a sleeve with a lower internal flange and an upper external flange. Bellows interconnect 45 seals the interiors of bellows 41, 43 from the exteriors. The upper end of upper inner bellows 43 is fixed and sealed to upper connector 27. Bellows interconnect 45 moves along axis 46 as inner and outer bellows 43, 41 extend and contract.
Similarly, a lower outer bellows 47 and a lower inner bellows 49 are located in lower housing section 33. A bellows interconnect 51 joins the lower end of lower inner bellows 49 to the upper end of lower outer bellows 47. The interiors of bellows 41, 43, 47 and 49 are in fluid communication with each other. The exteriors of bellows 41, 43, 47 and 49 are in fluid communication with each other.
Referring to
Guide tubes 55, 57 of lower pressure equalizer 19 are in fluid communication with each other, but not with guide tubes 37, 39 of upper pressure equalizer 17. The interiors of lower equalizer bellows 63, 65, 69 and 71 are in fluid communication with each other and with the exterior of upper pressure equalizer bellows 41, 43, 47 and 49. The exteriors of lower equalizer bellows 63, 65, 69 and 71 are in fluid communication with each other, but not with the exteriors of upper pressure equalizer bellows 41, 43, 47 and 49. Porting in guide tubes 37, 39, 55, 57 and in connectors 35, 53 results in this arrangement.
In this disclosure, upper pressure equalizer 17 and lower pressure equalizer 19 are prefilled at a service center or factory with a motor lubricant to a selected level, then brought to the well site as separate pieces. The selected level may provide room for thermal expansion of the lubricant. The lubricant expands with the temperature increase due to well depth and operation of motor 13. Optionally, one or both pressure equalizers 17, 19 may have check valves to release lubricant in the event of over-expansion. At the well site, pressure equalizers 17, 19 are connected together, to gauge unit 21, and to motor 13. The process of connecting pressure equalizers 17, 19 to each other automatically communicates the motor lubricant or secondary liquid in one with the other.
Referring to
Valve element 81 may have a variety of configurations. In this example, valve element 81 has upper ports 91 extending outward from an upper cavity 93, which contains spring 87. Upper ports 91 are located above seal 85, which is located on an enlarged diameter portion of valve element 81. Valve element 81 has lower ports 95 located below seal 85 and extending outward from a lower cavity 97, which is separated from upper cavity 93 by a barrier 98. While in the open position, fluid can flow from lower cavity 97 around seal 85 to upper cavity 93 via ports 91, 95. The outer diameter of valve element 81 at ports 91 and at ports 95 is less than the inner diameter of counterbore 79b, creating an annular passage to allow fluid flow while valve element 81 is in the open position.
In this embodiment, an electrical receptacle 99 has an upper end fixed and sealed in smaller diameter bore portion 79a. The lower end of electrical receptacle 99 extends down to and is supported by upper retaining ring 89. An electrical connector or plug 100 connects into an upper end of electrical receptacle 99. Electrical connector 100 is located on a lower end of a line or electrical wire 102 extending downward through guide tubes 37, 39 of upper pressure equalizer 17. Electrical receptacle 99 has a lower cavity 101 that registers with valve element upper cavity 93. Ports 103 extend outward through a side wall of electrical connector 100 to communicate fluid to and from a passage 105 leading to an upper end portion of intermediate connector 35.
Referring still to
A passage 117 communicates valve cavity 107 with an axial bore 119 formed in connector 53. Connector 53 also has a well 11 aid entry passage 121 that leads to the exterior of upper outer bellows 69 and upper inner bellows 71 (
An electrical receptacle 125 is fixed and sealed within an upper, smaller diameter portion of bore 119. A line or wire 127 extends downward from electrical receptacle 99 of connector 35 and has a plug or connector 129 on its lower end. Line 127 extends sealingly through a passage in part of valve element 81. The portion of line 127 sealed within valve element 81 moves axially in unison with valve element 81. When making connectors 53 and 35 up with each other, a worker will releasably plug electrical connector 129 into receptacle 125. A wire 131 is joined to electrical receptacle 125 and extends downward in bore 119 through guide tubes 55, 57 of lower pressure equalizer 19.
Referring to
Adapter 75 has a central upward facing cavity 139 that is in fluid communication with counterbore 133a when adapter 75 is connected to lower connector 61. An electrical receptacle 141 is located in cavity 139 on axis 46. Wire 131 has an electrical plug or connector 142 on its lower end that is inserted by a worker into receptacle 141 just before securing adapter 75 to connector 61. The portion of wire 131 below valve element 135 has enough slack to enable insertion of connector 142 into receptacle 141 before gauge unit adapter 75 is secured to lower connector 61. Bolts 143 or a threaded ring (not shown) may be used to secure adapter 75 to connector 61.
Motor 13 has a rotatably driven drive shaft 153 that extends into motor lower connector 28. There is no rotating shaft within pressure equalizers 17, 19. A tool 155 secured to the lower end of drive shaft 153 by threads has splines that will slide into mating engagement with splined receptacle 151 while valve element 147 is in the upper closed position. Rotating motor shaft 153 an increment after pressure equalizer connector 27 is connected to motor lower connector 28 will cause valve element 147 to unscrew from threaded section 145b and spring downward to the open position.
In this example, an electrical receptacle 157 is mounted offset from axis 46 to an upward facing portion of counterbore 145a. An electrical plug or connector 159 extending downward on a wire 160 from the Interior of motor 13 connects to electrical receptacle 157. Wire 160 leads to sensors for monitoring parameters in the motor lubricant, such as pressure and temperature. Wire 160 may also lead to an upper external connection (not shown) on motor 13, which connects to a motor lead or power cable extending from a wellhead at the surface. Signals may be transmitted from gauge unit 21 and power supplied via a separate wire or one bundled into the power cable. Alternatively, wire 160 extending to electrical connector 159 could be tied into a null point of the windings of motor 13 to superimpose signals from gauge unit 21 on the power cable. Prior to securing upper pressure equalizer 17 to motor 13, a worker will plug releasably electrical connector 159 into electrical receptacle 157. Motor 13 has passages 161 that communicate motor lubricant from motor 13 to bore 145.
During assembly, pressure equalizers 17, 19 will be prefilled with a liquid, preferably motor lubricant, to a desired level at a service center or factory and brought to the well site disconnected from each other. Referring to
When ready to connect upper pressure equalizer 17 to lower pressure equalizer 19, the operator will first insert electrical connector 129 into electrical receptacle 127. As bolts 123 are secured, connector 53 will push valve element 81 to the open position, and connector 35 will push valve element 109 to the open position, communicating motor lubricant between pressure equalizers 17 and 19.
The operator connects gauge unit 21 either before or after connecting pressure equalizers 17, 19 in a similar manner by first inserting electrical connector 142 into engagement with electrical receptacle 141, as shown in
Referring to
The operator attaches pump 23 and lowers ESP 11 on production tubing 26 into the well. Well fluid will act on pressure equalizers 17, 19, reducing a pressure differential between the hydrostatic pressure of the well fluid and the motor lubricant.
Various possibilities exist for equalizing the hydrostatic well fluid pressure with the motor lubricant pressure. In the embodiment shown, the porting within connectors 35, 53 as well as other places causes dielectric oil or motor lubricant in motor 13 to be in direct communication with motor lubricant located in guide tubes 37, 39 of the upper pressure equalizer 17. Ports in guide tubes 37, 39 cause this dielectric lubricant to be located within the interiors of bellows 41, 43 and 47, 49 of upper pressure equalizer 17. A secondary dielectric fluid, which may be the same lubricant as the lubricant in motor 13 or a different liquid, will be located on the exteriors of bellows 41, 43, 47 and 49 of upper equalizer 17; the secondary dielectric fluid is thus isolated from direct communication with the dielectric lubricant in motor 13. The secondary dielectric fluid will also be located in guide tubes 55, 57 and the interiors of bellows 63, 65, 69, and 71 of lower equalizer 19. The secondary dielectric fluid in lower equalizer 19 will be in direct communication with the secondary dielectric fluid in upper equalizer 17. Porting in lower equalizer, such as in lower connector 61 and/or lower intermediate connector 59 admits well fluid to the exteriors of bellows 63, 65, 69 and 71 of lower equalizer 19. The well fluid is thus isolated from the fluid within motor 13 by the secondary dielectric fluid in the interiors of lower equalizer bellows 63, 65, 69 and 71 and on the exteriors of upper equalizer bellows 41, 43 and 47, 49.
While the disclosure has been shown in only one of its forms, it should be apparent to those skilled in the art that various changes may be made.
This application claims priority to provisional application Ser. No. 62/025,316, filed Jul. 16, 2014.
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Entry |
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U.S. Appl. No. 14/683,557, filed Apr. 10, 2015, entitled: “Below Motor Equalizer of Electrical Submersible Pump and Method for Filling”. |
Number | Date | Country | |
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20160017701 A1 | Jan 2016 | US |
Number | Date | Country | |
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62025316 | Jul 2014 | US |