Isolating a downhole-type electric machine

Abstract

An electric stator surrounds an electric rotor. A magnetic coupling is attached to an end of the electric rotor. The magnetic coupling is configured to transmit rotational force to or from a separate rotational device. A housing surrounds and isolates the electrical rotor, the electric stator, and a portion of the magnetic coupling from a wellbore fluid. A pressure within the housing is lower than a pressure within a wellbore environment.

Description

TECHNICAL FIELD

This disclosure relates to hermitically sealed electric machines.

BACKGROUND

Most wells behave characteristically different over time, as well as seasonally, due to geophysical, physical, and chemical changes in the subterranean reservoir that feeds the well. For example, it is common for well production to decline as the well reaches the end of its life. This decline in production is due to declining pressures in the reservoir, and can eventually reach a point where there is not enough pressure in the reservoir to push production through the well to the surface. In some wells, a top side compressor or pump is sometimes used to extend the life of the well by decreasing pressure at the top of the well. In some instances, an artificial lift system, such as an electric submersible pump, can be installed within the wellbore to a similar effect. This decrease in pressure decreases the pressure head on the production flow to the surface, enabling the well to continue producing when the reservoir pressures have dropped too low to drive the production to the surface.

SUMMARY

This disclosure describes technologies relating to isolating downhole-type electric machines which can be used to power, for example, an electric submersible pump or compressor.

An example implementation of the subject matter described within this disclosure is a high-speed downhole-type electric machine with the following features. An electric stator surrounds an electric rotor. A magnetic coupling is attached to an end of the electric rotor. The magnetic coupling is configured to transmit rotational force to or from a separate rotational device. A housing surrounds and isolates the electrical rotor, the electric stator, and a portion of the magnetic coupling from a wellbore fluid. A pressure within the housing is lower than a pressure within a wellbore environment.

Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. The lower pressure is substantially a vacuum.

Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. The electric rotor includes a permanent magnet rotor.

Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. The magnetic coupling includes a radial gap type coupling or an axial gap type coupling.

Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. A magnetic radial bearing is configured to radially support the electric rotor within the electric stator.

Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. The magnetic radial bearing is a passive magnetic radial bearing.

Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. A magnetic thrust-bearing is configured to axially support the electric rotor within the electric stator.

Aspects of the example implementation, which can be combined with the example implementation alone or in combination, include the following. The magnetic thrust-bearing includes an active magnetic thrust-bearing.

An example implementation of the subject matter described within this disclosure is a method with the following features. In an electric machine housed within a low-pressure sealed housing isolated from an outside environment, the housing having an internal low pressure environment having a pressure lower than a pressure in the outside environment, a rotational force is imparted to or from a rotor rotating, within the low pressure environment, within the electric machine via a magnetic coupling located at an end of the rotor.

Aspects of the example method, which can be combined with the example method alone or in combination, include the following. The internal low pressure environment is substantially a vacuum.

Aspects of the example method, which can be combined with the example method alone or in combination, include the following. An axial position of the rotor is actively maintained within an electric stator with a magnetic thrust-bearing.

Aspects of the example method, which can be combined with the example method alone or in combination, include the following. A radial position of the rotor is actively maintained within an electric stator with a magnetic radial bearing.

Aspects of the example method, which can be combined with the example method alone or in combination, include the following. A radial position of the rotor is maintained within an electric stator with a mechanical radial bearing.

Aspects of the example method, which can be combined with the example method alone or in combination, include the following. an axial and radial position of the rotor is maintained within an electric stator with a mechanical ball bearing.

Aspects of the example method, which can be combined with the example method alone or in combination, include the following. The rotor includes a permanent magnet rotor.

Aspects of the example method, which can be combined with the example method alone or in combination, include the following. The housing is constructed of a non-magnetic metal alloy.

Aspects of the example method, which can be combined with the example method alone or in combination, include the following. The housing is constructed of a non-magnetic, non-electrically conductive material.

An example implementation of the subject matter described within this disclosure is a high-speed downhole-type electric machine system with the following features. An electric rotor is configured to rotate or be rotated by a separate rotational device. An electric stator is configured to surround the electric rotor. A magnetic coupling is configured to transmit rotational force to or from the separate rotational device. A housing is configured to fluidically isolate the electrical rotor, the electric stator, and a portion of the magnetic coupling from a wellbore fluid. A pressure within the housing is lower than a pressure within a wellbore environment. A controller is configured to exchange an electric current to or from the electric stator.

Aspects of the example system, which can be combines with the example system alone or in combination, include the following. The controller is configured to be positioned outside of a wellbore.

Aspects of the example system, which can be combines with the example system alone or in combination, include the following. Electrical cables connect the controller and the electric stator. The housing includes penetration points for the electrical cables. The penetration points are configured to maintain the low pressure within the housing.

Aspects of the example system, which can be combines with the example system alone or in combination, include the following. An active magnetic thrust-bearing is configured to axially support the electric rotor within the electric stator.

Aspects of the example system, which can be combines with the example system alone or in combination, include the following. The controller is further configured to control the active magnetic bearing.

Aspects of the example system, which can be combines with the example system alone or in combination, include the following. A magnetic radial bearing is configured to radially support the electric rotor within the electric stator.

Aspects of the example system, which can be combines with the example system alone or in combination, include the following. The magnetic radial bearing includes an active magnetic radial bearing.

The details of one or more implementations of the subject matter described in this disclosure are set forth in the accompanying drawings and the description below. Other features, aspects, and advantages of the subject matter will become apparent from the description, the drawings, and the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a side half cross-sectional view of an example downhole-type artificial lift system.

FIG. 1B is a side half cross-sectional view of an example downhole-type artificial lift system.

FIG. 2 is a side half cross-sectional diagram of an example passive magnetic radial bearing.

FIGS. 3A-3B are side half cross-sectional views of an example downhole-type electric machine.

FIG. 4 is a cross-sectional view of a well system installed within a wellbore.

Like reference numbers and designations in the various drawings indicate like elements.

DETAILED DESCRIPTION

While producing well fluids from a wellbore with an artificial lift system, such as an electric submersible pump, parts of the artificial lift system are exposed to contaminants that can cause damage to the artificial lift system. Often times bearings and other vulnerable components are protected with seals, but seals wear overtime and only delay contamination of the vital components.

This disclosure describes a completely isolated, hermitically sealed, high-speed downhole-type electric machine that is designed to protect the electric machine components from downhole contaminants. The high-speed downhole-type electric machine includes a housing that fluidically isolates an electric rotor, an electric stator, and bearings from a downhole environment. A pressure within the housing is below that of the downhole environment. A rotational force is transmitted to or from the electric rotor by a magnetic coupling that is capable of transferring force magnetically through the housing. In the downhole system described below, the magnetic coupling is used to couple the electric machine to a fluid end. Specific operating speeds for the downhole system are defined based on the fluid, pressures and flows for the well parameters and desired performance. Speeds may be as low as 10,000 rpm or as high as 120,000 rpm. While the downhole system has an optimal speed range at which it is most efficient, this does not prevent the downhole system from running at less efficient speeds to achieve a desired flow for a particular well, as well characteristics change over time.

Particular implementations of the subject matter described in this disclosure can be implemented so as to realize one or more of the following advantages. The high-speed downhole-type electric machine will be isolated from possible contaminants that could lead to a shortened operational lifespan. In addition, having a lower pressure gas or eliminating the use of liquid within the housing reduces wind-age losses in the electric machine, making the machine more efficient, thus lowering required input power, reducing cable size and weight, and lowering current carrying requirements on connectors and feed-throughs. Higher efficiency can also result in a smaller, lighter electric machine to do the equivalent amount of work, as less power is lost due to inefficiency. In other words, the same machine size can provide more work with increased efficiency.

FIG. 1A shows an example half cross-sectional view of an example high-speed down-hole type electric machine 100 and fluid end 108. The example high-speed down-hole type electric machine 100 includes an electric rotor 102 surrounded by an electric stator 104. The electric rotor 102 is configured to rotate or be rotated by a separate rotational device, such as the fluid end 108. The electric rotor 102 can include a permanent magnet rotor, an inductive rotor, or any other type of electric rotor. A magnetic coupling 106 is attached to an end of the electric rotor 102. The magnetic coupling 106 is configured to transmit rotational force to or from the separate rotational device.

A housing 110 surrounds and isolates the electrical rotor 102, the electric stator 104, and the magnetic coupling 106 from a wellbore fluid 112. A pressure within the housing is lower than a pressure within a wellbore environment 114. In some implementations, the lower pressure within the housing is substantially a vacuum. In some implementations, the lower pressure within the housing is substantially a specific gas, such as Helium. The lower pressure reduces wind losses within the electric machine 100. In some implementations, the housing 110 is constructed of a non-magnetic metal alloy. In some instances, the housing 110 is constructed of a non-magnetic material, a non-electrically conductive material, or both.

The electric machine includes one or more radial bearings 116. The radial bearing 116 radially supports the electric rotor 102 within the electric stator 104. In the illustrated implementation, the radial bearing 116 includes a magnetic radial bearing configured to radially support the electric rotor 102 within the electric stator 104. Alternatively, a mechanical bearing, such as a fluid film bearing or an anti-friction bearing, can also be used to support the electric rotor 102. When a magnetic radial bearing is used, the magnetic radial bearing can be a passive magnetic radial bearing or an active magnetic radial bearing. Detailed examples of passive magnetic radial bearings are discussed later within this disclosure. An anti-friction bearing can include a mechanical ball bearing configured to radially and axially support the electric rotor within the electric stator.

The high-speed down-hole type electric machine 100 also includes a thrust-bearing 118 configured to axially support the fluid end 108 within the electric stator 104. As illustrated in FIG. 1A, the thrust-bearing 118 is a magnetic thrust-bearing. While a magnetic thrust-bearing is illustrated in FIG. 1A, a mechanical thrust-bearing can also be used without departing from the scope of this disclosure. In implementations in which a magnetic thrust-bearing is used, the magnetic thrust-bearing can include an active magnetic thrust-bearing. Details on an example magnetic thrust-bearing are discussed later in this disclosure.

In order to maintain an isolation for the housing 110, a magnetic coupling 106 is used to couple the electric machine 100 to the fluid end 108. The magnetic coupling 106 is configured to transmit rotational force to or from a separate rotational device, such as the fluid end 108. In other words, a rotational force is imparted to or from a rotor rotating within the electric machine via the magnetic coupling 106 located at an end of the rotor. As illustrated in FIG. 1A, the magnetic coupling 106 includes a radial gap type coupling. The radial gap type coupling includes an inner rotor 106a that is contained within the sealed housing 110, and a surrounding sleeve 106b that is configured to radially surround the inner rotor 106a. The inner rotor 106a, the surrounding sleeve 106b, or both, include one or more coupling magnets 106c that generate a coupling magnetic field between the inner rotor 106a and the surrounding sleeve 106b. In some implementations, the inner rotor 106a includes permanent magnets. In some implementations, the inner rotor 106a or outer rotor 106b include metal poles that interact with the permanent magnets. While inner rotor 106a is shown within the isolated housing (i.e. low pressure environment), in some instances, the outer rotor 106b can be included in the isolated, low pressure environment. The outer rotor generates more wind losses, and so putting it in the low pressure environment reduces wind losses in the coupling. In some implementations, the coupling magnets 106c can include electromagnets.

FIG. 1B shows a side half cross-sectional view of an example high-speed downhole-type electric machine 101 and fluid end 108. The high-speed downhole-type electric machine 200 is substantially similar to the high-speed down-hole type electric machine 100 with the exception of the magnetic coupling 107. In the illustrated implementation, the magnetic coupling 107 is an axial gap type coupling. The axial gap type coupling includes a first rotor plate 107a that is contained within the sealed housing 110 and a second rotor plate 107b that is configured to be axially aligned with and be axially spaced to be in close proximity to the first rotor plate 107a. In the context of this disclosure, close proximity is defined as proximity sufficient for magnetic coupling to occur. That is, a gap between the first rotor plate 107a and the second rotor plate 107b is small enough to allow torque transfer from the first rotor plate 107a to the second rotor plate 107b or vice versa. The first rotor plate 107a, the second rotor plate 107b, or both, include one or more coupling magnets 107c that generate a coupling magnetic field between the first rotor plate 107a and the second rotor plate 107b. In some implementations, the first rotor plate 107a includes permanent magnets. In some implementations, the coupling magnets 107c can include electromagnets. In some implementations, the axial gap magnetic coupling can transfer a thrust load. In such an implementation, the electric machine 100 can be axially supported by the thrust-bearing 118 housed within housing.

An example passive radial magnetic radial bearing 116 is shown in greater detail in FIG. 2. The passive magnetic bearing 116 includes a bearing shaft 202. The bearing shaft 202 can be included within either the fluid end 108 or the electric rotor 102. The bearing shaft 202 is made of a non-magnetic material and includes a shaft magnet assembly 224 which includes individual axially-magnetized magnets (204, 220, 216, and 214 in this example) that are radially imbedded into the bearing shaft 202 and each separated by a non-magnetic spacer 236. In some implementations, the exterior surface of the shaft magnet assembly 224 is substantially flush with the outer surface of the bearing shaft 202 within standard machining tolerances. The shaft magnet assembly 224 can be connected to the shaft by adhesive, slot fits, ring fits, an external sleeve, or any other manners of connection. The individual magnets within the shaft magnet assembly 224 can be arranged so that the magnet polarities alternate along the shaft axis. For example, a first shaft magnet 204 may have a north pole towards a downhole direction, a second shaft magnet 220 may have a north pole towards an uphole direction, a third shaft magnet 216 may have a north pole towards a downhole direction, and a fourth shaft magnet 214 may have a north pole towards an uphole direction. In some implementations, the individual magnets within the shaft magnet assembly 224, such as the first shaft magnet 204, the second shaft magnet 220, the third shaft magnet 216, and the fourth shaft magnet 214 shown in FIG. 2, may each be composed of multiple smaller magnets of similar polarities.

The illustrated passive magnetic bearing 116 also includes a stator magnet assembly 226. The stator magnet assembly 226 can be installed in a non-magnetic housing or holder and connected to either the fluid end 108 or the electric stator 104 and surround the bearing shaft 202. Each of the magnets in stator magnet assembly 226, such as magnets 206, 208, 210, and 212 in the example shown in FIG. 2, are separated by the non-magnetic, electrically-conductive, spacers 230. The spacer 230 can act as a generator to generate eddy currents when an induced magnetic field changes as a result of a relative motion between the electric rotor 102 and the stator magnet assembly 226. The eddy currents act to oppose the change in the magnetic field and create a passive damping of a rotor radial vibration. The magnets within the shaft magnet assembly 224 and the stator magnet assembly 226 can be arranged so that that the identical poles of the individual magnets inside the shaft magnet assembly 224 and the stator magnet assembly 226 are substantially in line with one another. For example, a first stator magnet 206 may have the same polarity as the first shaft magnet 204, a second stator magnet 208 may have the same polarity as the second shaft magnet 220, a third stator magnet 210 may have the same polarity as the third shaft magnet 216, and a fourth stator magnet 212 may have the same polarity as the fourth shaft magnet 214. In some implementations, the individual stator magnets can be made-up of multiple smaller magnets having a similar polarity. Having magnets of similar polarities in proximity to one another creates a repulsion force that keeps the bearing shaft 202 radially suspended within the stator magnet assembly 226. While the shaft 202 is suspended, the shaft 202 can have a rotation about a longitudinal axis 232 that is not reduced by a surface-to-surface friction.

In some instances, the multiple shaft magnets and multiple stator magnets can be arranged in such a way as to create an axial force 218, which could be directed either towards a thrust-bearing, resulting in an additional thrust pre-load, or away from the thrust-bearing, offsetting the weight of the rotor and therefore reducing the axial load on the thrust-bearing, and, consequently, increasing its service life if a mechanical thrust-bearing is used. This can be done by an axial offset in position of rotor magnets 204, 220, 216, and 214 to stator magnets 206, 208, 210, and 212 by less than a half of the axial magnet width. If the rotor magnets are shifted upwards with respect to the stator magnet, the axial force will be directed upwards and vice-versa. Even with the axial force 218 directed towards the thrust-bearing 118, a reversal of the axial thrust is possible during events such as transportation, start-up, or shut-down. Such a thrust reversal can be mitigated by a bumper 228 positioned at an end of the shaft 202 opposite of the direction of thrust load 218. In some implementations, an inner protective can 222 made out of a non-magnetic alloy can be installed to cover the inner diameter of the stator magnet assembly 226, protecting its components from mechanical damage. In some implementations, disk-shaped end pieces 234 can be added to the ends of the shaft magnet assembly 224, primarily to protect the free faces of the magnets within this assembly. The end pieces 234 can be made identical to the shaft magnet spacers 236. In some implementations, a sleeve made of a non-magnetic high strength alloy can be installed to cover the outer diameter of the shaft magnet assembly 224 and the end pieces 234 to secure relative position of its components during high speed operation, protect them from damage, and seal them from the environment. While passive magnetic radial bearings are described in detail within this disclosure, active magnetic radial bearings can be used without departing from the scope of this disclosure. In some implementations, fluid film radial bearings or anti-friction bearings can also be used.

In some instances, the downhole-type electric machine 100 of FIGS. 1A-2 can include both a motor and generator section. In such an instance, the electric machine 100 includes a generator structure that locally generates power in a downhole environment to provide power to a downhole-type tool. For example, a generator structure incorporated into a downhole-type system with a downhole power unit (e.g., electric motor) can generate power from rotation of a rotor of the downhole power unit. This local power generator can be used to power various downhole electronic components.

For example, FIG. 3A is a schematic side half cross-sectional view of an example electric motor 300. The example electric motor 300 is similar to and can be used in the electric machine 100 of FIGS. 1A-2, except the example electric motor 300 includes a generator assembly 302. The motor rotor section 304 includes a permanent magnet rotor that is axially levitated and supported, for example, by a thrust bearing (e.g., thrust bearing 118). The electric stator 306 surrounds the permanent magnetic rotor 304 along a first length of the permanent magnet rotor 304, and includes the electric coils 308. The generator assembly 302 includes a generator stator 310 that surrounds a second length of the permanent magnet rotor 304 (e.g., a substantial remaining length of the rotor 304), and includes generator coils 312. In the example electric motor 300 of FIG. 3A, the second length of the permanent magnet rotor 304 includes one or more permanent magnets 314 (one shown, though other types of generators are possible, such as induction type) (e.g., separate from or integral with the permanent magnet of the first length). As the electric coils 308 of the electric stator 306 are energized (e.g., from a Variable Speed Drive), the electric stator 306 drives the motor rotor 304 to rotate. As the motor rotor 304 rotates, the generator coils 312 generate current and the generator assembly 302 can act as a local downhole power generator. The generator assembly 302, and particularly the generator coils 312, can connect to one or more downhole-type tools, such as downhole sensors, controls, or other electronics. In some implementations, the generator assembly 302 connects to one or more rectifiers and/or voltage regulators (e.g., boost chopper, buck-boost converter, buck converter, and/or other) to provide a controlled form of power (e.g., constant voltage output) to the one or more downhole-type tools and/or internal electronics.

In some implementations, a barrier (not shown) separates the coils 312 of the generator stator assembly and the coils of the electric stator 308 of the motor 300 that drives the motor rotor 304. The barrier can include a disc-shaped structure that physically separates the generator stator assembly 302 and the electric stator 306. The barrier can act as an electrical insulator between the coils 312 of the generator stator assembly 302 and the coils 308 of the electric stator 306, for example, to isolate electrical operation of the generator stator assembly 310 and the electric stator 306 and/or to prevent or reduce electric interference between the generator stator 310 and the electric stator 306.

In some implementations, electrical components in the motor 300, such as electric stator 306 and the generator stator 310 and their respective electrical coils 308 and 312 shown in FIG. 3A, are fluidically isolated from the outside environment surrounding the motor 300. As described earlier, the motor 300 can operate under flooded or fully sealed conditions. Such isolation protects the electrical components from corrosion and other degradation mechanisms that can occur due to exposure to the downhole environment. In some implementations, the electric motor 300 and generator assembly 302 are isolated from the environment via an isolation barrier, where no components of the electric motor 300 or generator assembly 302 are exposed to the downhole environment. In such an instance, a magnetic coupling 360 can be used. As illustrated, the magnetic coupling 360 is a radial-gap-type coupling with an outer barrel 360a being coupled to the rotor 304 and an inner barrel 360b is coupled to a driven device, such as fluid end 108. While a radial-gap-type magnetic coupling is illustrated in this implementation, an axial gap type coupling, such as magnetic coupling 107, can be used with similar effects.

FIG. 4A shows the motor rotor 304 as a single, unitary rotor that extends within the electric stator 334 and the generator stator assembly 404. In some implementations, the motor rotor 306c can be segmented such that the first length of the rotor 306c is a motor rotor designated for the electric stator 334, and the second length of the rotor 406c is a generator rotor designated for the generator stator assembly 404. The motor rotor and the generator rotor can be mechanically coupled to each other with a coupling, for example, such that the rotation of the motor rotor is the same (substantially or exactly) as the rotation of the generator rotor. In some examples, the generator assembly 402 includes a separate generator housing and separate generator rotor, where the generator housing connects to the motor housing or another static support structure in the downhole environment, and the generator rotor mechanically couples, directly or indirectly, to the motor rotor to rotate with the motor rotor.

FIG. 3A shows the generator assembly 302 as a radial generator, for example, surrounding the rotor extending along a longitudinal centerline axis. In some implementations, the generator assembly 302 includes an axial generator, such as an axial gap generator, that provides an output power to the at least one downhole-type tools.

In the example electric motor 300 of FIG. 3A, the electric stator 306 and the generator stator 310 share a common rotor, but are positioned surrounding different length sections of the same rotor. In some instances, a generator assembly can be integral to the electric stator to pull power from the electric motor. For example, FIG. 3B is a schematic side half cross-sectional view of an example electric motor 350. The example electric motor 350 is similar to the example electric motor 300 of FIG. 3A, except the example electric motor 350 excludes the isolated generator assembly 302 and includes an integral generator 352 in the electric stator 354. The integral generator 352 can include a separate winding 358 in the set of stator windings of the electric stator 356, where the separate winding 358 is brought out of the electric stator 354 separately, and is used for taking power from the power supply to the electric stator 354. The separate winding 358 can be located in the same slots as the stator windings for the electric stator 354 that drives the motor rotor 304, or can be located in separate slots in the electric stator 354 designated for only the separate winding 358 of the integral generator 352. For example, the electric stator 356 can include a three phase winding for the motor and a three phase winding for the integral generator 352, where the turns for each winding can depend on operating requirements of the motor 350, generator 352, or both. However, the number of windings for the generator assembly 352, the electric stator 354, or both, can be vary.

The separate winding 358 of the integral generator 352 can connect to one or more downhole-type tools, such as downhole sensors, controls or other electronic systems. Similar to the separate generator assembly 302 of FIG. 3A, in some implementations, the integral generator 352 of FIG. 3B connects to one or more rectifiers and/or voltage regulators (e.g., boost chopper, buck-boost converter, buck converter, and/or other) to provide a controlled form of power (e.g., constant voltage output) to the one or more downhole-type systems.

FIG. 4 is a cross-sectional view an example well system 400. The well system 400 includes the high-speed down-hole type electric machine 100 and the fluid end 108 positioned within a wellbore 402. The wellbore 402 is formed within geologic formation 404. The fluid end 108 directs production fluid through production tubing 410 towards a wellhead 406. The production fluid can then be directed to a topside facility for processing. The well system 400 includes a controller 408 configured to exchange an electric current to or from the electric stator 104 (FIG. 1A). In the illustrated implementation, the controller 408 is positioned outside of the wellbore 402. The system 400 includes electrical cables 412 that connect the controller 408 and the electric stator 104. The housing 110 includes penetration points 414 for the electrical cables 412. The penetration points 414 are configured to maintain the environment within the housing. For example, the penetration points 414 can be include elastomers, thermoplastics, or TPEs that are configured to surround any penetrating cables and maintain the internal environment. In some implementations, an intermediate liquid interface can be used in addition to the elastomers, thermoplastics, or TPEs. Alternatively or additionally, in some implementations, redundant metal-to-metal deformable interfaces (ferrules, crush rings, etc.) can be used to maintain the environmental seal. In some implementations, glass filling can be used for conductor isolation in the electrical cables 412. Alternatively or additionally, metal-to-metal welding of the conductors within the cables 412 can also be used. In some implementations, an outer shielding of the cable can be welded to the housing to maintain the environmental seal. In some implementations, the controller 408 is configured to control any active magnetic bearings that are included in the high-speed down-hole type electric machine 100 and/or the fluid end 108 positioned within a wellbore 402. While the illustrated implementation shows the controller 408 being positioned outside the wellbore 402, the controller 408 can be integrated downhole with the high-speed down-hole type electric machine 100, in part or in its entirety, in some implementations.

The downhole-type system (e.g., electric machine 100 and the fluid end 108) can operate in a variety of downhole conditions of the wellbore 402. For example, the initial pressure within the wellbore 402 can vary based on the type of well, depth of the wellbore 402, production flow from the perforations into the wellbore 402, and/or other factors. In some examples, the pressure in the wellbore 402 proximate a bottomhole location is sub-atmospheric, where the pressure in the wellbore 402 is at or below about 14.7 pounds per square inch absolute (psia), or about 101.3 kiloPascal (kPa). The downhole-type system (e.g., electric machine 100 and the fluid end 108) can operate in sub-atmospheric wellbore pressures, for example, at wellbore pressure between 2 psia (13.8 kPa) and 14.7 psia (101.3 kPa).

Similarly, while operations are depicted in the drawings in a particular order, this should not be understood as requiring that such operations be performed in the particular order shown or in sequential order, or that all illustrated operations be performed, to achieve desirable results. Moreover, the separation of various system components in the implementations described above should not be understood as requiring such separation in all implementations, and it should be understood that the described program components and systems can generally be integrated together in a single product or packaged into multiple products.

Thus, particular implementations of the subject matter have been described. Other implementations are within the scope of the following claims.

Claims

1. A downhole-type electric motor comprising: an electric rotor;an electric stator surrounding the electric rotor, the electric stator comprising coils configured to receive an electric current and generate rotational motion imparted to the electrical rotor in response to receiving the electric current;a magnetic coupling attached to an end of the electric rotor, the magnetic coupling configured to transmit rotational force to or from a separate rotational device; anda pressure-sealed housing configured to reside in a wellbore, the housing surrounding and isolating the electrical rotor, the electric stator, and a portion of the magnetic coupling from a wellbore fluid and the housing maintaining an internal pressure within the housing less than atmospheric pressure, and the housing configured to isolate and maintain the pressure within the housing from an ambient pressure surrounding the exterior of the housing.

2. The downhole-type electric motor of claim 1, wherein the pressure is substantially a vacuum, while the ambient pressure is greater than a vacuum.

3. The downhole-type electric motor of claim 1, wherein the electric rotor comprises a permanent magnet rotor.

4. The downhole-type electric motor of claim 1, wherein the magnetic coupling comprises a radial gap type coupling or an axial gap type coupling.

5. The downhole-type electric motor of claim 1, further comprising a magnetic radial bearing configured to radially support the electric rotor within the electric stator, the magnetic radial bearing supporting the electric rotor to the housing.

6. The downhole-type electric motor of claim 5, wherein the magnetic radial bearing is a passive magnetic radial bearing.

7. The downhole-type electric motor of claim 1, further comprising a magnetic thrust-bearing configured to axially support the electric rotor within the electric stator.

8. The downhole-type electric motor of claim 7, wherein the magnetic thrust-bearing comprises an active magnetic thrust-bearing.

9. The downhole-type electric motor of claim 1, comprising a fluid end, and where the motor is operable at 10,000 rpm.

10. The downhole-type electric motor of claim 9, where the motor is operable at 120,000 rpm.

11. The downhole-type electric motor of claim 1, wherein the pressure-sealed housing is configured to maintain the internal pressure within the housing at a substantially constant pressure despite changes in ambient pressure surrounding the exterior of the housing.

12. The downhole-type electric motor of claim 1, further comprising the separate rotational device rotably coupled to the electric rotor by the magnetic coupling, wherein the rotational device comprises a fluid end configured to move fluid through the wellbore.

13. A method comprising: in an electric motor positioned within a well, the electric motor housed within a sealed housing pressure isolated from an outside environment, the housing maintaining an internal pressure within the housing less than atmospheric pressure, and the housing isolating and maintaining the pressure within the housing from an ambient pressure surrounding the exterior of the housing, generating, by electric coils within the electric motor, a high-speed rotational force;imparting, by the electric coils, the rotational force to an electric rotor of the electric motor within the housing; andimparting, by the electric rotor, the rotational force, via a magnetic coupling located at an end of the rotor.

14. The method of claim 13, wherein the internal pressure is substantially a vacuum.

15. The method of claim 13, further comprising actively maintaining an axial position of the rotor within an electric stator with a magnetic thrust-bearing.

16. The method of claim 13, further comprising actively maintaining a radial position of the rotor within an electric stator with a magnetic radial bearing.

17. The method of claim 13, further comprising maintaining a radial position of the rotor within an electric stator with a mechanical radial bearing.

18. The method of claim 13, further comprising maintaining an axial and radial position of the rotor within an electric stator with a mechanical ball bearing.

19. The method of claim 13, wherein the rotor comprises a permanent magnet rotor.

20. The method of claim 13, wherein the housing is constructed of a non-magnetic metal alloy.

21. The method of claim 13, wherein the housing is constructed of a non-magnetic, non-electrically conductive material.

22. The method of claim 13, wherein maintaining an internal pressure within the housing at less than atmospheric pressure reduces wind-age losses.

23. The method of claim 13, wherein the ambient pressure is greater than a vacuum.

24. The method of claim 13, further comprising: receiving, by a rotational device, the rotational force via a magnetic coupling located at an end of the rotor; androtating the rotational device in response to receiving the rotational force.

25. The method of claim 24, further comprising moving a wellbore fluid responsive to rotating the rotational device.

26. A downhole-type electric motor system comprising: an electric rotor configured to rotate a separate rotational device;an electric stator configured to surround the electric rotor, the electric stator comprising coils configured to receive an electric current and generate rotational motion imparted to the electrical rotor in response to receiving the electric current;a magnetic coupling configured to transmit rotational force to or from the separate rotational device;a pressure-sealed housing configured to reside in a wellbore, the housing configured to fluidically isolate the electrical rotor, the electric stator, and a portion of the magnetic coupling from a wellbore fluid, and the housing maintaining an internal pressure within the housing being less than atmospheric pressure, and housing the housing configured to isolate and maintain the pressure within the housing from an ambient pressure surrounding the exterior of the housing; anda controller configured to exchange an electric current to or from the electric stator.

27. The downhole-type electric motor system of claim 26, wherein the controller is configured to be positioned outside of a wellbore.

28. The downhole-type electric motor system of claim 27, wherein the system further comprises electrical cables connecting the controller and the electric stator, the housing comprising penetration points for the electrical cables, the penetration points configured to maintain the pressure within the housing.

29. The downhole-type electric motor system of claim 26, further comprising an active magnetic thrust-bearing configured to axially support the electric rotor within the electric stator.

30. The downhole-type electric motor system of claim 29, wherein the controller is further configured to control the active magnetic bearing.

31. The downhole-type electric motor system of claim 26, further comprising a magnetic radial bearing configured to radially support the electric rotor within the electric stator, the magnetic radial bearing supporting the electric rotor to the housing.

32. The downhole-type electric motor system of claim 31, wherein the magnetic radial bearing comprises an active magnetic radial bearing.

33. The downhole-type electric motor system of claim 26, wherein the electric stator is axially separate from the magnetic coupling.

34. The downhole-type electric motor system of claim 26, wherein the magnetic coupling comprises a first rotor and a second rotor, the first rotor being supported in an overhung arrangement.

35. The downhole-type electric motor system of claim 26, wherein the magnetic coupling comprises an axial gap type coupling.