2000-08-11

Abstract of CA2298284 A modular stator for use in an electric motor includes a plurality of stator sections 32 and a plurality of connectors 36. The plurality of stator sections 32 have conductors 54 extending therethrough with exposed terminal ends. The connectors 36 have corresponding conductive elements with receptacles for receiving the terminal ends. Thus, a given stator may be assembled to a variety of desired lengths by connecting the appropriate number of modular components.

26

2000-08-11

H02K3/30 ; H02K3/52 ; H02K16/00 ; H02K3/00 ; H02K3/46 ; H02K16/00 ; (IPC1-7): H02K1/12 ; H02K15/02

H02K3/30 ; H02K3/52A ; H02K16/00

CA20002298284 20000210

US19990248864 19990211

US6288470 (B1); GB2348743 (A)

2298284 A

EEER

2003/11/14

+ EXAMINATION REQUEST

1	MODULAR MOTOR CONSTRUCTION
	Inventor: BREIT STEPHEN M (US)	Applicant: CAMCO INT (US)
	EC:H02K3/30; H02K3/52A; (+1)	IPC: H02K3/30; H02K3/52; H02K16/00(+5)
	Publication info: CA2298284 A1 - 2000-08-11
2	Modular motor construction
	Inventor: BREIT STEPHEN M (US)	Applicant: CAMCO INT (US)
	EC:H02K3/30; H02K3/52A; (+1)	IPC: H02K3/30; H02K3/52; H02K16/00(+7)
	Publication info: GB2348743 A - 2000-10-11 GB2348743 B - 2003-12-10 GB9930326D D0 - 2000-02-09
3	Modular motor construction
	Inventor: BREIT STEPHEN M (US)	Applicant: CAMCO INT (US)
	EC:H02K3/30; H02K3/52A; (+1)	IPC: H02K3/30; H02K3/52; H02K16/00(+4)
	Publication info: US6288470 B1 - 2001-09-11

CLAIMS

What is claimedis : 1. A modular stator for use in an electric motor, comprising:

a plurality of stator sections ; and

a plurality of connector regions, wherein the plurality

of stator sections are selectively coupleable at

the plurality of connector regions to form a

stator of a desired length.

2. The modular stator as recited in claim 1, wherein each statorsection comprises a plurality of laminations.

3. The modular stator as recited in claim 2, wherein each stator section includes a plurality of axial slots.

4. The modular stator as recited in claim 3, wherein each stator section inclues a plurality of conductors extending along each axial slot and terminating at a plurality of corresponding protrusions.

5. The modular stator as recited in claim 4, wherein each connector region inclues an independent connector having a plurality of conductive elements insulated from one another, further wherein each conductive element is designed for engagement with one of the corresponding protrusions when the plurality of stator sections and the plurality of independent connectors are assemble.

6. The modular stator as recited in claim 5,wherein the plurality of conductors are molded in a polymeric material.

7. The modular stator as recited in claimG, wherein each conductive element inclues a hollow receptacle at each end, each hollow receptacle being sized to received a corresponding protrusion.

8. An electric motor, comprising :

an outer housing having a generally hollow

interior ; and

a stator sized to fit in the generally hollow

interior, the stator having a plurality of

stator sections including :

a first stator section having a plurality of first

stator section conductors extending

therethrough;

a second stator section having a plurality of

second stator section conductors extending

therethrough ; and

a connector region at which the first stator

section conductors are selectively,

electrically coupleable to the second stator

section conductors.

9. The electric motor as recited in claim 8, further comprising a connector unit into which the first and the second stator section conductors may be plugged to form conductiveconvection at the connector region.

10. The electric motor as recited in claim 9, wherein the connector unit inclues a plurality of receptacles and the first and second stator section conductors include corresponding connector ends sized for insertion into the plurality of receptacles.

11. The electric motor as recited in claim 8, wherein the first stator section inclues a plurality of first longitudinal slots through which the first stator section conductors extend and the second stator section inclues a plurality of second longitudinal slots through which the second stator section conductors extend.

12. The electric motor as recited in claim 11, wherein each first longitudinal slot of the plurality of first longitudinal slots is at least partially filled with a moldable polymeric material that insultes the first stator section conductors from one another in each first longitudinal slot.

13. The electric motor as recited in claim 12, wherein each second longitudinal slot of the plurality of second longitudinal slots is at least partially filled with a moldable polymeric material that insultes the second stator section conductors from one another in each second longitudinal slot.

14. The electric motor as recited in claim 13, wherein the moldable polymeric material comprises a PEEK material.

15. The electric motor as recited in claim 8, further comprising an end coil having a plugable end that may be plugged into electrical communication with at least one of the first and second stator sections.

16. A method for facilitating the assembly of an electric motor, comprising :

assembling individual stator laminations into a

plurality of modular stator sections that

each have a plurality of electrical

conductors that may be selectively,

electrically coupled to each other ;

determining a desired motor length for a given

application ; and

electrically coupling an appropriate number of the

plurality of modular stator sections.

17. The method as recited in claim 16, further comprising forming a plurality of longitudinal slots through each stator section ; and disposing at least two electric conductors through each longitudinal slot.

18. The method as recited in claim 17, further comprising molding a polymeric material in each longitudinal slot to hold the at least two electric conductors.

19. The method as recited in claim 16, further comprising forming connectors having opposing plug regions into which a pair of sequential, modular stator sections may be plugged to form an electrical connection therebetween.

20. The method as recited in claim 19, wherein forming inclues disposing at least two conductive elements in a polymeric insulating material ; and orienting the at least two conductive elements to extend between the opposing plug regions for engagement with the at least two electric conductors of corresponding modular stator sections.

21. A modular motor construction, comprising :

a modular stator section having a plurality of

conductors extending generally longitudinally

therethrough ; and

at least one end coil that may be selectively

coupled into electrical communication with

the plurality of conductors.

22. The modular motor construction as recited in claim 21, wherein the at least one end coil inclues a pair of end coils that each may be selectively coupled into electrical communication with the plurality of conductors.

23. The modular motor construction as recited in claim 22, wherein each end coil inclues a plug end that may be plugged into communication with the modular stator at a connection region.

24. The modular motor construction as recited in claim 23, wherein the connection region inclues an independent connector that may be engaged and disengaged from the stator section and the at least one end coil.

25. The modular motor construction as recited in Claim 24, further comprising a second modular stator section electrically coupleable to the modular stator section.

26. A modular motor construction substantially as hereinbefore described with reference to the accompanying drawings.

MODULAR MOTOR CONSTRUCTION

FIELD OF THE INVENTION

The present invention relates generally to electric motors, and particularly to a modular stator assembly that facilitates motor construction.

BACKGROUND OF THE INVENTION

Currently, electric motors, particularly elongate motors such as those used in electrical submergible pumping systems for pumping petroleum, are constructed with unitary stators. Traditionally, individual stator laminations have been stacked together to the full length of the desired stator, and conductive wires have been wound through correspondingopenings formed longitudinally through the stator laminations.

Depending on the horsepower required of the motor, electric submergible pumping system motors can utilize stator assemblies thirty feet long or more. Preparation of the stator windings requires long, thin polished rods that serve as needles for pulling the insulated, conductor wires through the lengthy assembly of stator laminations during winding of the motor. This conventional process is a comparatively slow and expensive process for manufacturing such motors. Additionally, repair or rebuilding of such motors often requires complete destruction or tear down of the motor with little component repair value due to the unitary stator assembly.

It would be advantageous to have a modular stator that could be used to construct motors, such as motors utilized in electric submergible pumping systems. Benefits of such a modular construction would include reduced cost and assembly time, reduced repair time and reduced motor component inventory.

SUMMARY OF THE INVENTION

The present invention features a modular stator for use in an electric motor. The stator comprises a plurality of stator sections and a plurality of connectors. The connectors are dispose between sequential stator sections, and the stator sections are selectively coupleable with the plurality of connectors to form stators in a variety of desired lengths.

According to another aspect of the invention, an electric motor is provided that utilizes a modular stator assembly. The electric motor inclues an outer housing having a generally hollow interior. A stator is sized to fit within the hollow interior and is formed from a plurality of stator sections. The stator inclues at least a first stator section and a second stator section. The first stator section inclues a plurality of first stator section conductors extending therethrough. Similarly, the second stator section inclues a plurality of second stator section conductors extending therethrough. A connector region is dispose between the first and second stator sections and permits the first and second stator section conductors to be selectively electrically coupled together.

According to another aspect of the invention, a method is provided for facilitating the assembly of an electric motor. The method inclues assembling individual stator laminations into a plurality of modular stator sections.

Each stator section has a plurality of electrical conductors that may selectively be coupled to each other. The method further inclues determining a desired motor length for a given application, and electrically coupling an appropriate number of the modular stator sections to construct the desiredmotor.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will hereafter be described with reference to the accompanying drawings, wherein like reference numerals denote like elements, and :

Figure 1 is a front view of an electric motor, according to a preferred embodiment of the present invention;

Figure 2 is a partial cross-sectional view taken generally along line 2-2 of Figure 1 ;

Figure 3 is a cross-sectional view similar to that of

Figure 2 but showing modular stator components in an exploded view ;

Figure 4 is an end view of the stacked stator laminations;

Figure 5 is a an end view of the completed stator illustrated in Figure 2 ;

Figure 6 is an end view of a plurality of conductors mounted in an individual slot of the stator illustrated in

Figure 5 ;

Figure 7 is a cross-sectional view taken generally along line 7-7 of Figure 5 ;

Figure 8 is an enlarged cross-sectional view taken generally along line 8-8 of Figure 7 ;

Figure 9 is an end view of a connector dispose between stator sections ;

Figure 10 is an enlarged view taken generally along line 10-10 of Figure 9 ;

Figure 11 is a cross-sectional view taken generally along line 11-11 of Figure 9 ;

Figure 12 is anenlarged view of the upper portion of the illustration in Figure 11 ; and

Figure 13 is a front elevational view of a submergible pumping system positioned in a wellbore and utilizing an electric motor of the type illustrated in Figure 1.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Referring generally to Figure 1, an electric motor 20 is illustrated according to a preferred embodiment of the present invention. Motor 20 is an exemplary motor, such as an elongate, submergible motor that may be connecte in a submergible pumping system of the type deployed in a wellbore to pump production fluids, e. g. petroleum.

However, the present invention should not be limited to submergible motors.

Referring also to Figures 2 and3, electric motor 20 generally inclues a stator assembly 22 mounted in an outer housing 24. Additionally, a rotor 26 is mounted to a shaft 28 for rotation about an axis 30 within outer housing 24, as is understood by those of ordinary skill in the art.

Stator assembly 22 is a modular assembly including a plurality of stator sections 32 that may be selectively coupled to one another at one or more connection regions 34.

Stator assembly 22 typically inclues at least two stator sections 32 and often several stator sections 32, depending on the desired length of motor 20. The use of modular stator sections 32 allows the construction of stator assemblies of a variety of lengths simply by selecting the appropriate number of individual sections 32 and electrically coupling them together.

Preferably, each connection region 34 comprises a connector 36 to which adjacent stator sections 32 may be selectively plugged and unplugged. The ability of connectors 36 and adjacent stator sections 32 to be easily connecte and disconnected facilitates assembly and disassembly of stator assembly 22 as well as electric motor 20.

Stator assembly 22 further inclues a pair of modular end coils 38. End coils 38 may be selectively coupled and uncoupled from the axially outlying stator sections 32 via the axially outlying connectors 36, as illustrated best in

Figure 2. It should be noted that the end coins 38 also can be coupled and uncoupled from a single stator section. The use of a single modular stator section and modular end coils similarly eliminates winding the conductive wires, thereby simplifying construction and repair of the motor.

The various stator sections 32 and connectors 36 may be mounted within outer housing 24 by a variety of methods. In the illustrated embodiment, a retainer 40 abuts each axially outlying connector 36 (see Figure 2) An exemplary retainer 40 comprises a snap ring 42 dispose in a groove 44 formed in the inside surface or wall of outer housing 24.

As best illustrated in Figure 3, the preferred stator sections 32 are made from a plurality of metallic laminations 46 that are stacked together, as in conventional stator construction. The laminations 46 have an interior opening 48 into which the rotor 26 and shaft 28 are received when the motor 20 is fully assemble. Additionally, each lamination 46 inclues a plurality, e. g. 18, of axial openings 50 that are radially outlying from interior opening 48, as best illustrated in the end view of Figure 4. As the laminations 46 are stacked together to form a stator section 32, the axial openings 50 are aligned to create longitudinal slots 52 through each stator section 32.

As illustrated in Figures 5 through 8, a plurality of conductors 54 are dispose longitudinally through each stator section 32. Preferably, at least two (and more typically eight conductors 54) are dispose through each longitudinal slot 52 (see Figure 5). As illustrated best in

Figure 6, the individual conductors 54 are insulated from one another and from laminations 46.

Because of the unique design of stator sections 32, bare wire conductors, such as copper wires, can be insulated from one another and held in place by an insulator block 56 that may be readily formed from a moldable polymeric material. For example, the individual conductors 54 can be held in proper position and orientation within each longitudinal slot 52 while a moldable polymeric material is injecte into each longitudinal slot 52 and allowed to solidify. Exemplary insulating materials includepolyetheretherketone {PEEK), kapton, and mylar. Once the moldable material sets, the bare wire conductors 54 are securely held in place within their corresponding longitudinal slots 52.

Individual stator sections 32 may be coupled together in a variety of ways at the various connection regions 34 dispose between adjacent stator sections 32. However, in the preferred embodiment, each stator section 32 is formed with a plug connection 58 dispose at each of its longitudinal ends, as best illustrated in Figures 7 and 8.

In the embodiment illustrated, each plug connection 58 inclues a plurality of protrusions or terminal ends Go that are electrically coupled to conductors 54. Protrusions 60 may comprise the protruding ends of the wires or conductive elements used to form conductors 54.

Connectors 36 are constructed for engagement with plug connection ends 58 of adjacent stator sections 32.

Connectors 36 may be formed as part of one or more of the adjacent stator sections 32 or as independent connectors.

With reference to Figures 9-12, a preferred, exemplary embodiment of an independent connector 36 can be described.

Generally, each connector 36 is circular in shape and inclues a central opening 62 that is aligned with the interior openings 48 of stator sections 32. In other words, each connector 36 isgenerally"donut-shaped,"having a pair of axial side walls 64, an interior wall or surface 66 and an exterior wall or surface 68. Exterior wall 68 has a radius that permits the connector 36 to be slid into outer housing 24 of motor 20 adjacent the interior surface of outer housing 24.

As illustrated best in Figure 9 and the enlarged view of Figure 10, each exemplary connector 36 inclues a plurality of plug connectors 70 dispose along each of its axial sidewalls 64. Plug connectors 70 are arrange for engagement with the plug connectors 58 of adjacent stator sections 32. In the illustrated embodiment, each plug connector 70 inclues a plurality of recesses 72 arrange and sized to receive protrusions 60 of a corresponding stator section plug connector 58. Thus, adjacent stator sections can be electrically coupled together via an appropriate connector 36 dispose therebetween, as illustrated in Figure 3.

In the preferred embodiment, each connector 36 comprises a connector block 74 formed of an insulative material, such as a polymeric material. Exemplary insulationmaterials lnclude PEEK, kapton, and mylar.

Within each connector block 74, a plurality of conductive elements 76 are arrange in a generally axial direction, as best illustrated in Figures 11 and 12.

Conductive elements 76 may be made of copper or other appropriate, conductive materials to form conductive paths from one stator section 32 to another. The conductive elements 76 are arrange to be contacte by protrusions 60 when adjacent stator sections 32 are coupled to a given connector 36. For example, each conductive element may include a central solid body 78 (see Figure 12) having a socket 80 dispose at each axial end. Sockets 80 are sized to matingly receive protrusions 60 to form a conductive path.

Preferably, each socket 80 extends to a chamfered opening 82 formed in the axial side wall 64 at each conductive element 76. Chamfered openings 82 facilitate the insertion of protrusions 60 when stator sections 32 and connectors 36 are assemble.

Furthermore, end coils 38 preferably include ends 84 designed for coupling with a stator section 32. Ends 84 may be in the form of plug ends having a plurality of plug protrusions 86 (see Figure 2) arrange for insertion into a corresponding plug connector 70 of the axially outlying connector 36 at each end of stator assembly 22. The protrusions 86 form a conductive path with a plurality of corresponding conductive wires 88. Generally, the wires 88 (for each plug connector 70) are wrapped by an insulating material, such as a tape 90. Thus, each cluster of wrapped conductive wires 88 has a pair of plug connectors 84 that may be selectively plugged into the appropriate stator section via, for instance, the plug connectors 70 of each axially outlying connector 36. Connection of the end coils completes the windings of stator assembly 22. A continuous conductive path is formed between each stator section 32 via the intermediate connectors 36 and the end coils 38.

During assembly, the modular components, e. g. connectors 36, stator sections 32 and end coils 38, can be preassembled and slid into outer housing 24 as a unit.

Alternatively, the individual components can be assemble as they are moved into outer housing 24. Furthermore, the number of stator sections 32 and connectors 36 can be selected according to the desired length/horsepower for a given motor, provided the outer housing 24 is of an appropriate length to accommodate the selected number of modular components.

In the event of repair or servicing, the stator assembly 22 simply can be removed from outer housing 24 and uncoupled as necessary. For example, if a certain stator section 32 requires replacement, the surrounding components can be uncoupled, e. g. unplugged, and a replacement stator section 32 inserted. This modular concept greatly simplifies the assembly, servicing, repair, and stocking of replacement stator components for electric motor 20.

Referring generally to Figure 13, an exemplary use of motor 20 is illustrated. In this particular utilization, motor 20 is connecte as an integral component in a submergible pumping system 100. Submergible pumping system 100 may comprise a variety of components depending on the particular application or environment in which it is used.

However, system 100 typically inclues a submergible motor, such as motor 20, that drives a submergible pump 102 having a pump intake 103.

Additionally, a motor protector 104 is connecte between submergible pump 102 and motor 20 to isolate well fluid from internal motor oil within motor 20. A connector 106 is used to connect the submergible pumping system to a deployment system 108, e. g. production tubing, cable or coil tubing. Power is supplie to electric motor 20 by a power cable 109.

Submergible pumping system 100 is designed for deployment in a well 110 containing desirable production fluids, such as petroleum. In a typical application, a wellbore 112 is drilled and lined with a wellbore casing 114. System 100 is deployed within wellbore 112 to a desired location for pumping of the wellbore fluids.

Because of the relatively small diameter and space constraints in a wellbore environment, elongate motors, often thirty feet in length or more, are used. The abovedescribed modular approach to motor construction facilitates the assembly, servicing, repair and storage of replacement components for such motors.

It will be understood that the foregoing description is of a preferred embodiment of this invention, and that the invention is not limited to the specific form shown. For example, a variety of connection regions can be used to couple individual stator sections to one another ; a variety of component shapes and sizes may be utilized ; different motor styles and types may benefit from the modular construction described above ; other components may be combine with the modular stator sections ; single modular stator sections can be utilized with modular end coils ; various plug configurations and coupling structures can be used to combine components ; and the subject motor may be utilized in a variety of systems and environments. These and other modifications may be made in the design and arrangement of the elements without departing from the scope of the invention as expressed in the appende claims.