The present application relates to an electric submersible motor, and more specifically, to motor windings of an electric submersible motor.
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 is perforated. Perforating involves creating holes in the casing thereby connecting the wellbore outside of the casing to the inside of the casing. Perforating involves lowering a perforating gun into the casing. The perforating gun has charges that detonate and propel matter thought the casing thereby creating the holes in the casing and the surrounding formation and helping 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 necessarily be relied upon. An artificial lift device can therefore be needed to drive downhole well fluids uphole, e.g., to surface. The artificial lift device is placed downhole inside the casing.
According to an embodiment an electric submersible pump device comprises an electric motor having motor windings; a pump coupled with the motor; and high temperature polymeric insulation surrounding at least a portion of the motor windings, the high temperature polymeric insulation comprising HN polyimide film and a high temperature fluoropolymer adhesive coating at least one side of the HN polyimide film.
In the following description, numerous details are set forth to provide an understanding of the present invention. However, it will be understood by those skilled in the art that the present invention may be practiced without many of these details and that numerous variations or modifications from the described embodiments are possible.
As used here, the terms “above” and “below”; “up” and “down”; “upper” and “lower”; “upwardly” and “downwardly”; 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 of the invention. However, when applied to equipment and methods for use in wells that are deviated or horizontal, such terms may refer to a left to right, right to left, or diagonal relationship as appropriate.
Electrical submersible pumping systems (herein referred to as ESPs) are used in a wide variety of environments, including wellbore applications for pumping production fluids, such as water or petroleum. The submersible pumping system includes, among other components, an induction motor used to power a pump, lifting those fluids to the surface. At times, it is desirable to operate the ESP system in high temperature applications, such as steam flood conditions. Production fluid recovery in such applications can expose the ESP motor to temperatures of 500° F. or greater. Temperatures at or exceeding that level may lead to undesirable levels of degradation of materials used in current ESP motor designs, in particular, the dielectric insulation layer used on the motor windings. Incorporating new higher temperature materials for the dielectric layer of the motor windings can allow improved resilience and improved levels of degradation that can lead to continuous operation of the motor in temperature environments at or exceeding 500° F. for an extended period of time.
The present application features a submersible pumping system that is deployed in a wellbore to pump fluids disposed in a subterranean environment. The system includes a submersible motor and pump powered by the motor. The submersible electric motor comprises a motor housing having a plurality of laminations stacked there within, a drive shaft longitudinally extending through the motor housing, and a plurality of electrical windings extending through slots in the laminations. The electrical windings are formed from magnet wire comprising an electrical conductor and a polymeric dielectric insulation surrounding the electrical conductor. The polymeric insulation layer is comprised of single or multiple layers of thin, high dielectric, high temperature tape that is continuously helically wrapped around the electrical conductor and is bonded to the electrical conductor and to itself through the use of high temperature adhesive. The unique design permits the use of the motor and the overall ESP system in high temperature environments or applications where the system is exposed to high temperature conditions.
Referring generally to
For this system 10, an electrical power cable 12 is coupled to an electrical submersible motor 14 in the wellbore environment 22 by an electrical connector 40. This electrical connector is commonly referred to as a “pothead”. The electrical power cable 12 provides typically the three phase power needed to power the electrical submersible motor 14 and may have different configurations and sizes depending on the application. For this system 10 the electrical power cable 12 and connector 40 are designed to withstand the high-temperature wellbore environment 22.
The electrical submersible pump system 10 may have a variety of configurations depending on the application. The system 10 typically comprises an electrical submersible motor 14, motor protector 16, pump intake 36, and submersible pump 13. The system is deployed into the wellbore 22 to extract fluids from within the wellbore 22 and to pump the fluids to surface. The well fluids 26 are extracted by the system 10 and delivered through the production tubing 30 from which the electrical submersible pump 13 is connected.
Internally, the electric motor 14 includes, as shown in
As shown in
An example of the polymeric insulation 54 referred to herein is commercially available from DuPont™ under the identification 150PRN411. The 150 indicating 1.5 mils thick overall tape thickness, the PRN indicating an HN polyimide film with the high temperature fluoropolymer adhesive, the 4 indicating 0.0004 inch thick high temperature adhesive on the bottom side of the tape, the first 1 indicating the thickness of the polyimide film and the second 1 indicating 0.0001 inch thick high temperature adhesive on the top side of the tape.
Another polymeric insulation 54 available from DuPont™ is CR polyimide film (Corona Resistant Film), identified as PRCR. The PRCR is used with the high temperature fluoropolymer adhesive referred to above.
The embodiments referred to above are meant to illustrate features of a number of embodiments of the inventive idea. The embodiments are in no way meant to limit the scope of the claims herein.