The present application relates to electric submersible motors and pumping systems, and more particularly, to shaft seals and motor protector devices in connection therewith.
Fluids are located underground. The fluids can include hydrocarbons (oil) and water, for example. Extraction of at least the oil for consumption is desirable. A hole is drilled into the ground to extract the fluids. The hole is called a wellbore and is oftentimes cased with a metal tubular structure referred to as a casing. A number of other features such as cementing between the casing and the wellbore can be added. The wellbore can be essentially vertical, and can even be drilled in various directions, e.g. upward or horizontal.
Once the wellbore is cased, the casing can be perforated. Perforating involves creating holes in the casing thereby connecting the wellbore outside of the casing to the inside of the casing. That can be done by lowering a perforating gun into the casing. The perforating gun has charges that detonate and propel matter through the casing thereby creating the holes in the casing and the surrounding formation to help formation fluids flow from the formation and wellbore into the casing.
Sometimes the formation has enough pressure to drive well fluids uphole to surface. However, that situation is not always present and cannot be relied upon. Artificial lift devices can therefore be used to drive downhole well fluids uphole, e.g., to surface. The artificial lift devices are placed downhole inside the casing. An artificial lift device often has an electric motor with internal parts. Preventing well fluids from reaching component parts of the motor is desirable.
The following descriptions of certain features are exemplary and are not to limit the claim scope or overall disclosure in any way.
An embodiment of features includes an electric submersible pump device having an electric submersible motor part that produces torque having coupled thereto a drive shaft that transmits the torque. The drive shaft extends in an axial direction from the motor part. A protector part coupled with the motor part. The drive shaft extends into the protector part. The protector part comprises a tubular shaped casing extending in the axial direction. A shaft tube surrounds a portion of the drive shaft thereby defining a space between the outer surface of the shaft and an interior of the shaft tube. An opening in the shaft tube connects the interior of the shaft tube with an exterior of the shaft tube. A first compensating element is connected with the opening. The first compensating element is an expandable and contractible vessel defining a volume that is correspondingly expandable and contractible.
Another embodiment of features includes an electric submersible pump device comprising an electric submersible motor part that produces torque. The electric submersible motor part has coupled thereto a drive shaft that transmits the torque. The drive shaft extends in an axial direction from the motor part. A pump part is rotationally coupled with the drive shaft. A protector part is coupled between the motor part and the pump part. The drive shaft extends into the protector part. The protector part comprises a tubular shaped casing extending in an axial direction having an inner surface defining an inner volume. A first shaft seal part is located inside the volume and divides the volume into an upper volume and a lower volume. The first shaft seal part comprises a first relief valve biased to only allow flow away from the motor part. A second shaft seal part is located inside the volume and divides the upper volume. The second shaft seal part comprises a second relief valve biased to only allow flow away from the first shaft seal part and the motor part. A first compensating element compensates pressure across the second shaft seal divide. The first compensating element is an expandable and contractible vessel defining an interior volume that is correspondingly expandable and contractible. At least one motor compensating element is in fluid communication with the motor part to compensate for thermal expansion and contraction of fluid in the motor part. During thermal fluid contraction a volume of fluid is between the first shaft seal part and the second shaft seal part and is prevented from fluidly flowing back into the motor part sufficiently to contribute more than half of the contraction compensation of fluid in the motor part.
Another embodiment of features includes a method including filling the motor part with motor fluid; running the motor and increasing temperature of the motor fluid and inducing thermal expansion of the motor fluid into the at least one motor compensating element beyond the maximum capacity of the at least one motor compensating element and forcing fluid through the first relief valve into the upper volume; subsequently lowering the temperature of the motor part and the motor fluid remaining in the motor part to induce thermal contraction of the motor fluid in the motor part and compensating for the thermal contraction by contracting the at least one motor compensation element; and preventing return of the motor fluid that traveled through the first biased relief valve during contraction compensation.
The above combinations of features are merely illustrative of some preferred embodiments and are not meant in any way to limit the overall scope of the present claims or any claims to which the applicants are entitled.
In the following description, numerous details are set forth to provide an understanding of the presently claimed subject matter. However, it will be understood by those skilled in the art that the present embodiments may be practiced without many of these details and that numerous variations or modifications from the described embodiments may be possible.
In the specification and appended claims: any of the terms “connect”, “connection”, “connected”, “in connection with”, and “connecting” are used to mean “in direct connection with” or “in connection with via another element”; and the term “set” is used to mean “one element” or “more than one element”. As used herein, the terms “up” and “down”, “upper” and “lower”, “upwardly” and downwardly”, “upstream” and “downstream”; “above” and “below”; and other like terms indicating relative positions above or below a given point or element are used in this description to more clearly describe some embodiments. Moreover, the term “sealing mechanism” includes: packers, bridge plugs, downhole valves, sliding sleeves, baffle-plug combinations, polished bore receptacle (PBR) seals, and all other methods and devices for temporarily blocking the flow of fluids through the wellbore. Furthermore, while the term “coiled tubing” may be used, it could actually be replaced by jointed tubing or any relatively small diameter tubing for running downhole.
A submersible pumping system can comprise several parts, such as a submersible electric motor part and a pump part. The submersible electric motor part supplies energy to the submersible pump part. The energy is transmitted by generating torque in the motor part and transmitting the torque that is transmitted to a drive shaft coupled with the motor part. The pump is preferably a centrifugal style pump or other rotating pump that uses the torque from the drive shaft to drive rotating impellers to drive well fluid. The system further may comprise a variety of additional components, such as a connector used to connect the submersible pumping system to a deployment system. Production tubing, cable and coiled tubing can be included as the connector. Power can be supplied to the submersible electric motor part via a power cable that runs through or along the deployment system.
Often, the subterranean environment (specifically the well fluid) and fluids that are injected from the surface into the wellbore (such as acid treatments) contain corrosive compounds that may include CO2, H2S and brine water. Those corrosive agents can be detrimental to components of the submersible pumping system, particularly to internal electric motor components, such as copper windings and bronze bearings. Moreover, irrespective of whether or not the fluid is corrosive, if the fluid enters the motor and mixes with the motor oil, the fluid can degrade dielectric and lubricating properties of the motor oil and insulating materials of motor components. Accordingly, it is desirable to keep those external fluids out of internal motor fluid and motor components. One possible mode of entrance into the motor part is by way of areas interfaces between the motor part and the drive shaft. Other interfaces are also potential entrances.
Another factor to consider is thermal expansion and/or contraction of motor fluids. For example, a submersible motor can be internally filled with a fluid, such as a dielectric oil, that facilitates cooling and lubrication of the motor during operation. In many applications, submersible electric motors are subject to considerable temperature variations due to the subterranean environment, injected fluids, and other internal and external factors. Those temperature variations may subject the fluid to expansion and contraction. For example, the high temperatures common to subterranean environments may cause the motor fluid to expand beyond a maximum capacity of the motor part thereby causing leakage and other mechanical damage to the motor components. Similarly, undesirable fluid expansion and motor damage can result from the injection of high-temperature fluids, such as steam, into the submersible pumping system. Further, after expansion, thermal contraction upon cooling of motor fluid can draw well fluids back into the motor carrying undesirable compounds noted earlier.
Accordingly, a submersible motor can benefit from an electric submersible motor protector that accommodates expanding/contracting motor fluid while maintaining protection against ingress of well fluids. Also, the internal pressure of the motor could potentially be allowed to equalize or at least substantially equalize with the surrounding pressure found within the wellbore. As a result, it becomes less difficult to prevent the ingress of external fluids into the motor fluid and internal motor components.
Also, a submersible motor can benefit from having a protector with redundant shaft seal parts isolating volumes of fluid there between, the shaft seal parts having compensator elements to accommodate thermal expansion and contraction of the fluids.
Also, a submersible motor can benefit from having a protector that is hydraulically connected with the motor part so that excess fluid can escape the motor part 1 upon thermal expansion, and expansion compensation can occur along with a release of excess fluid beyond the compensator's capacity, thereby relieving a danger of overfilling a motor part or protector with too much fluid.
Many configurations of electrical submersible pump (ESP) protectors include a labyrinth seal as part of a labyrinth protector.
As noted above, the compensation element 202 can be a small metal bellows either axially or radially expanding, an elastomer bag, or a piston (or other volume compensating mechanism), depending on the applications. For conventional applications, a small elastomer (or other oil resistant, expandable material) bag may be sufficient. For high temperature or high corrosive application, a small metal bellows or a small piston may be a most appropriate choice. The compensating element may be coaxial with the shaft 100 or non-coaxial with the shaft 100.
The protector section 3 can be combined with any other sections or components of the protectors, such as additional labyrinth protector sections, bag protector sections, metal bellows protector sections, piston protector sections, and so forth. Furthermore, the sealed shaft tube space described above can be replaced with a space other than the shaft tube space. For example, the space could be formed with a (curved) tube that connects the lower end of the shaft seal on the top and the upper end of the shaft seal at the bottom (not shown). Also, it could be a volume isolated by multiple shaft seal parts or other divides.
In practice, it is difficult to determine a precise amount of motor oil to meet requirements while avoiding overfilling a motor part 1, given a scale of temperatures and resulting thermal expansion that the motor parts 1 may be subjected to. Also, the motor oil undergoes much greater thermal contraction and expansion from manufacture (e.g., 75° F.), to shipping and storage (e.g., −40° F.), to installation (e.g., 60° F.), to operation (e.g., 600° F.), to non-operation (e.g., 500° F.). Thus, without relief valves, compensation of much greater capacity would be required. Accordingly, a motor compensating element 5 is provided, and the first shaft seal part 33a has a relief valve 201a. The relief valve 201a can be biased to preferentially only allow flow away from the motor part 1 during normal operation. The relief valve 201a is in a flow path that extends across the first shaft seal 33a, e.g., through opening 209a. Provision of the relief valve 201a is to allow for excess fluid to escape from the motor part 1 and is beneficial as it allows for self regulation of fluid volume in the motor part 1.
Above the first shaft seal part 33a is a second shaft seal part 33b having a relief valve 201b and a compensating element 202b. In a situation where it is desired to more perfectly isolate the motor part 1 fluidly from a protector part, or more perfectly fluidly isolate volumes between shaft seal parts, the relief valve 201b may be excluded and a relief valve may be provided connecting the motor part 1 to the wellbore. The compensating element 202b is shown as being non-coaxial with the motor part 1, the pump part 2, the casing 205 and the shaft 100, but the compensating element 202b may be coaxial too. The relief valve 202b is a biased one-way valve and in a flow path that extends across the second shaft seal part 33b, e.g., through the opening 209b. The compensating element 202b is an expandable and contractible vessel defining an internal volume that is correspondingly expandable and contractible. The compensating element 202b compensates pressure across the shaft seal divide. For example, the compensating element 202b could be a bellows. The bellows can be metal bellows, but could be other materials. The compensating element 202b could also be a piston or a bladder. Those features can apply to all compensating elements discussed in the present application.
Above the second shaft seal part 33b is a third shaft seal part 33c having a relief valve 201c and two compensating elements 202c, both shown as being bellows. Again, in a situation where it is desired to isolate the motor part 1 hydraulically from the protector part, or hydraulically isolate the volumes defined between the shaft seal parts, the relief valve 201c could be excluded. The relief valve 201c can be one-way valve and in a flow path that extends across the second shaft seal part 33b, e.g., through the opening 209c. The relief valve 201c can be biased to only allow flow away from the motor part 1.
Above the third shaft seal part 33c is a fourth shaft seal part 33d having a relief valve 201d and a compensating element 202d shown as being a bellows. Again, in a situation where it is desired to more perfectly isolate the motor part 1 hydraulically from the protector part, or the volumes between the shaft seal parts, the relief valve 201d could be excluded. The relief valve 201d can be a one-way valve and in a flow path that crosses the shaft seal part 202d, e.g., through the opening 209d. A chamber is above the fourth shaft seal part 33d and has a relief passage 204d leading to the wellbore 15. The relief valve 201d could be biased to only allow flow away from the motor part 1.
During operation, given the embodiment shown in
As shown in
A feature of the present application relates to the comparative size of the motor compensating element 5 and the compensating elements 202b-d in connection with the idea of self regulation of the amount of fluid in the motor part 1. That is, the motor compensating element 5 is sized so that it can substantially be expected to compensate for all thermal expansion of fluids in the motor part 1. For example, the compensating elements 202b-d in aggregate may have a much smaller volume than the motor compensating element 5, e.g., preferably at most 1/10 the volume of the motor compensating element 5. Alternatively, the ratio of the volume in the compensating elements 202 and the motor compensating element 5 could be approximately 2/10, 3/10, ⅖ or ½. Given the configuration in
It should be noted that additional shaft seal parts and compensators can be added with those shown in
It is preferable that the first shaft seal part 33a have only a relief valve 201a. However, it should be appreciated that there are many variations of configurations that the shaft seal parts 33a-d can take. For example, a compensating element preferably at most 1/10 the volume of the motor compensating element 5 may be added to shaft seal part 33a without compromising the ideas herein. For example, the shaft seal part 33d could be located anywhere in the sequence, e.g., directly after the first shaft seal part 33a. Also, the shaft seal part 33b could have one compensating element 202b and the shaft seal part 33c could have one compensating element 202c. Alternatively, the two compensating elements 33c could be replaced with a single compensating element 33c having the same overall maximum volume displacement. Alternatively, more than two compensating elements 33c could be used. Also, again, the relief valves could be excluded.
A filter 207 can be provided.
The first shaft seal part 33a leads into the second shaft seal part 33b. A fluid flow path in the second shaft seal part 33b is through a shaft seal 101b. Preferably that path is blocked fully by the shaft seal 101b. Another parallel fluid flow path is through a relief valve 201b that is a one-way valve that could be biased to preferentially allow flow away from the motor part 1. Another parallel fluid flow path is through a compensating element 202b that is shown as being a bellows. A filter 207 is shown outside of the second shaft seal part 101b. It should be noted that the filter 207 in the second shaft seal part 33b is outside the dotted line, but could be inside the dotted line, e.g., a shaft seal part could be considered as including or excluding a filter 207 depending on preferred design.
The second shaft seal part 33b leads into the third shaft seal part 33c. As noted above, the filter 207 is located between the second shaft seal part 33b and the third shaft seal part 33c. The third shaft seal part 33c has a shaft seal 101c blocking one fluid flow path. Preferably the shaft seal 101c entirely blocks that fluid flow path. A relief valve 201c is in another parallel fluid flow path, the relief valve being preferably one-way, e.g., biased to preferentially only allow flow away from the motor part 1. Two compensating elements 202c block the remaining parallel fluid flow paths. A single filter 207 is shown as being within the third shaft seal part 33c but could also be outside the third shaft seal part 33c. Also, multiple filters 207 could be used. The third shaft seal part 33c could lead to the wellbore 15.
During operation, as shown in
The fluid then expands into the second shaft seal part 33b and expands into the compensating element 202b. Preferably, no fluid travels through the path blocked by the shaft seal 101b. Once the compensating element 202b reaches maximum capacity any excess fluid will travel through the relief valve 201b and through the filter 207 into the third shaft seal part 33c.
The fluid passes through the third shaft seal part 33c thereby displacing fluid. Also, displacement is caused by expansion of the compensating element 202b. Thus, the fluid expands both compensating elements 202c thereby displacing adequate volume. Once the compensating elements 202c reach maximum capacity any excess volume passes through the relief valve 201c through the filter 207 and to the wellbore 15.
Upon cooling of the fluid in the motor part 1, the motor compensating element 5 will contract and compensate for thermal contraction of the fluid. When the volume of fluid isolated between the shaft seal parts 33a-c thermally contracts the compensating elements 202b and 202c compensate for such.
Some additional features relate to the assembly of the protector part 3. As shown in
While a number of embodiments relating to the inventive concept are discussed in the present application, those skilled in the art will appreciate numerous modifications and variations from those embodiments are contemplated and intended. It is intended that the appended claims cover such modifications and variations as fall within the true spirit and scope thereof.
This application is a divisional of application Ser. No. 12/669,866, filed Apr. 13, 2010, incorporated in its entirety herein, which is the National Stage of International Application No. PCT/US08/07059, filed on Jul. 18, 2008, incorporated in its entirety herein, claiming priority to U.S. Provisional Application No. 60/951,080, filed Jul. 20, 2007, incorporated in its entirety herein.
Number | Date | Country | |
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60951080 | Jul 2007 | US |
Number | Date | Country | |
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Parent | 12669866 | Apr 2010 | US |
Child | 14331162 | US |