The present invention is directed to downhole pump systems, and more particularly a sensor data system for a linear motor downhole pump.
Often there is not enough pressure for wells to produce at commercially viable levels without assistance in lifting formation fluids to the surface. Artificial lift devices are therefore used to pump oil or other liquids from underground or subsurface to ground or surface level.
A common approach for moving production fluids to the surface includes the use of a submersible pump. These pumps are installed in the well itself, typically at the lower end of the production tubing. One type of such a submersible pump generally comprises a cylindrical housing and an inner reciprocating piston, which reside at the base of the production line. The pump has an inlet at the bottom end of the piston and an outlet at the top end. The pump forces a first volume of fluid upward within the production tubing during an upstroke and a second volume of fluid upward within the tubing during the pumps downstroke. The piston is reciprocated axially within the well bore by a linear magnetic motor.
Linear magnetic motors include a stator assembly and a shaft that is driven to move linearly (that is, as a straight line translation) with respect to the stator assembly. The shaft member is at least partially surrounded by the stator and is held in place relative to the stator assembly by a bearing. The shaft generates a magnetic field by virtue of having a series of built in permanent magnets. The stator generates magnetic fields through a series of annular magnetic coils or windings. By timing the flow of current in the coils with respect to the position and/or momentum of the shaft, the interaction of magnetic forces from the shaft and from the stator will actuate the shaft to move linearly either up or down.
The motor is powered by an electrical cable extending from the surface to the bottom of the well. The power supply generates the magnetic field within the coils of the motor, which in turn imparts an oscillating force on the shaft of the motor. The shaft thereby is translated in an up and down or linear fashion within the well. The shaft is connected, through a linkage, to the piston of the pump and thus imparts translational or lineal movement to the pump piston. The linear electric motor thus enables the piston of the pump to reciprocate vertically, thereby enabling fluids to be lifted with each stroke of the piston towards the surface of the well.
U.S. Pat. No. 5,831,353 discloses a motor-pump assembly having a positive displacement pump and a brushless DC linear motor for driving the pump in a reciprocating manner to allow the fluids in the production tube to be lifted to the upper ground level. A motor controller is provided for controlling the linear motor and supplies the motor with a certain number of direct current pulses. A coupling arrangement connects the pump to the motor.
With parenthetical reference to the corresponding parts, portions or surfaces of the disclosed embodiment, merely for purposes of illustration and not by way of limitation, an oil well installation (15) is provided comprising tubing (17) arranged in a well (18) and forming a flow channel to a surface level for fluids originating from below the surface level; a pump (19) disposed in the well; a linear actuator (20) disposed in the well and configured to actuate the pump; a cable (24) supplying electric power from the surface level to the linear actuator; a surface controller (50) connected with the linear actuator and configured to control the linear actuator; multiple downhole sensors (30, 31, 32, 33, 34 and 35) configured to sense multiple different operating parameters of the linear actuator and/or the pump; a downhole signal processor (40) communicating with the sensors and configured to receive sensor data from the sensors and to output serial data; a communication cable (23) between the sensor processor and the surface controller, the communication cable having at least two paired transmission lines (25, 26); a downhole differential signal driver (41) configured to receive the serial data and to output data signals to the paired transmission lines; and a surface receiver (27) connected to the communication cable and configured to receive the signals from the differential signal driver via the paired transmission lines.
The multiple sensors may be selected from a group consisting of a temperature sensor (32, 33), a position sensor (34), a vibration sensor (35), an inclination sensor (35) and a pressure sensor (30, 31). The multiple sensors may be selected from a group consisting of a motor stator thermocouple (33), a pump inlet temperature transducer (32), a pump inlet pressure transducer (31), a pump outlet pressure transducer (30), and a synchronous serial interface encoder (34) configured to sense position of a shaft (22) of the actuator.
The linear actuator may comprise a brushless permanent magnet motor and the sensors may comprise a motor position encoder (34) configured to sense position of a shaft (22) of the actuator and an operating sensor selected from a group consisting of a temperature sensor (32, 33), a vibration sensor (35), an inclination sensor (35) and a pressure sensor (30, 31), and wherein the serial data comprises position data from the encoder and operating data from the operating sensor. The surface controller may comprise a clock (28) communicating with the signal processor and the serial data from the signal processor may comprise a synchronous serial data output. The installation may further comprise an analog to digital converter (43) communicating with at least one of the sensors and a multiplexer (42) configured to receive sensor signals from at least two of the sensors and to output a serial data signal. The actuator may comprise a stator (21) having an inner opening and a shaft (22) disposed in the opening and configured and arranged to reciprocate linearly in an actual direction relative to the stator under the effect of the magnetic field generated by the stator. The pump may comprise an inlet (51), an outlet (52) and a piston (70) coupled to the actuator shaft.
At the outset, it should be clearly understood that like reference numerals are intended to identify the same structural elements, portions or surfaces consistently throughout the several drawing figures, as such elements, portions or surfaces may be further described or explained by the entire written specification, of which this detailed description is an integral part. Unless otherwise indicated, the drawings are intended to be read (e.g., crosshatching, arrangement of parts, proportion, degree, etc.) together with the specification, and are to be considered a portion of the entire written description of this invention. As used in the following description, the terms “horizontal”, “vertical”, “left”, “right”, “up” and “down”, as well as adjectival and adverbial derivatives thereof (e.g., “horizontally”, “rightwardly”, “upwardly”, etc.), simply refer to the orientation of the illustrated structure as the particular drawing figure faces the reader. Similarly, the terms “inwardly” and “outwardly” generally refer to the orientation of a surface relative to its axis of elongation, or axis of rotation, as appropriate.
Referring now to the drawings, and more particularly to
More specifically, production fluid migrates from the subsurface formation through perforations in casing 16 and collects in well bore 18. Pump 19 generally comprises cylindrical housing 69 and inner reciprocating piston 70. Linear actuator 20 is disposed below pump 19 in well bore 18. Linear actuator 20 includes stator 21 and shaft 22, which is connected to piston 70 by actuator rod 64. Linear actuator 20 is powered by electric cable 24 extending from a motor driver in controller cabinet 50 at the surface to the bottom of well bore 18. The power supply generates a magnetic field within coils of stator 21, which in turn imparts an oscillating force on magnetic shaft 22 and actuator rod 64. Shaft 22 and actuator rod 64 are thereby translated in an up and down or linear fashion within well bore 18, which thus imparts linear movement to pump piston 70. This enables piston 70 of pump 19 to reciprocate vertically, thereby enabling fluids to be lifted with each stroke of piston 70 towards the surface of well 18. Pump inlet 51 is disposed at the bottom end of pump housing 69 and pump outlet 52 is disposed at the top end of piston 70. Pump 19 forces a first volume of fluid upward within production tubing 17 during an upstroke of piston 70 in pump housing 69 and a second volume of fluid upward within pump housing 69 during a downstroke of piston 70 in pump housing 69.
In this embodiment, actuator 20 is a three-phase permanent magnet linear DC electric motor having stationary stator 21 and sliding shaft 22. Motor 20 receives power from three-phase power line 24 from motor driver 50. With references to
As shown in
Down-hole pump 19 includes a standing valve, a traveling valve, piston or plunger 70, inlet 51, and outlet 52. As piston 70 of pump 19 is forced up and down by motor 20, oil and other fluid is drawn into inlet 51, and pushed up out of outlet 52. Outlet 52 is coupled to production tubing 17 leading to the surface of the oil well.
As shown in
Position sensors 34 are Hall Effect Devices (HEDs) configured to sense the position and speed of linear motor shaft 23 relative to stator 21. As shown, sensors 34 are positioned within data processing system 36 at spaced axial locations proximate to shaft 22. As discussed below, sensors 34 are inputs to a synchronous serial interface (SSI) encoder for sensing the position of the linear motor shaft.
Sensor 33 is a temperature sensor for monitoring the temperature of motor 20. In this embodiment, sensor 33 comprises a K-type (chromel/alumel) thermocouple positioned between motor windings in steel stator 21. Thermocouple 33 is connected to thermocouple electrical interface 45, which outputs digital motor temperature data. In this embodiment, interface 45 is a cold-junction compensated thermocouple-to-digital converter.
Sensor 35 is a microelectromechanical system (MEMS) that provides angular inclination digital data and vibration digital data. Thus, the angle at which motor 20 is mounted may be measured by inclinometer 35.
Sensor 30 is a pressure transducer that provides pressure readings at outlet 52. Sensor 31 is a pressure transducer that provides pressure readings at inlet 51. Pressure sensor 31 provides oil or fluid pressure at inlet 51 which may be used to determine the depth of oil remaining in the oil well. Sensor 32 is a temperature transducer that provides temperature readings at pump inlet 51. The outputs from transducers 30, 31 and 32 are received by single transducer interface 47 having analog-to-digital converter 43 and multiplexer 42. Thus, transducer interface 47 outputs a serial digital signal. System 15 may contain other and/or alternate sensors for monitoring pump operation, motor operation, and/or deep oil well conditions. The data interfaces may be implemented using alternative protocols for either analog or digital signal transfer.
As shown in
In this embodiment, signal processor unit 40 is a digital signal processor (DSP) chip or CPU having multiplexor 44. Processor 40 may include data sampling and storage mechanisms for receiving and storing sensory data and may include data storage for storing operational parameters as well as sensory data logs. In particular, in this embodiment processor 40 is a single chip embedded microcontroller incorporating a 32 bit DSP processing unit along with memory, oscillator, clock, watchdog and I/O in a 100 pin surface mount package. It incorporates 16 channel, 12 bit A/D converter 43 that interfaces with the analog sensor data inputs as well as digital inputs to accept the digital sensor data. The digital signal processor also has serial output 48 to directly interface with SSI serial bus drivers 41 for exchange of data with surface controller 50. Processor 40 accepts the sensor data inputs from the various system sensors, reformats the data in the SSI format and transmits the data with the appropriate timing via the SSI bus to surface controller 50. The DSP also monitors the encoder data integrity, power supplies and a separate motor temperature switch and sets fault bits in the SSI data words if the parameters fall outside of acceptable levels. The DSP also continuously monitors the states of the HED devices sensing the motor shaft and through DSP algorithms continually calculates and updates the motor shaft position.
Processor 40 communicates with thermocouple 33 via thermocouple interface 45, communicates with outlet pressure transducer 30, inlet pressure transducer 31 and inlet temperature transducer 32 via transducer interface 47, communicates directly with shaft position sensors 34, and communicates directly with MEMS sensor 35. As shown, analog signals from outlet pressure transducer 30, inlet pressure transducer 31 and inlet temperature transducer 32 are converted by interface 47 into digital signals and multiplexed into a single line. Digital signals from MEMS 35 are communicated to processor 40. In addition, signals from shaft position sensors 34 are provided to processor 40. Processor 40 is configured to receive such data inputs and to provide a serial SSI output signal 48 to differential signal driver 41. Data is transmitted by synchronizing the transmission at the receiving and sending ends using a common clock signal from clock 28 located in cabinet 50 at the surface of well bore 18.
Differential signal driver 41 transmits such data electrically via two complementary signals sent on paired wires 25 and 26 of communication cable 23 to receiver 27 in cabinet 50 above ground. Differential signaling improves the resistance to electromagnetic interference, making it a reliable communication channel over long transmission lengths and harsh external environments. At the surface end of cable 23, receiver 27 reads the difference between the two signals. In this embodiment, high voltage differential signals are employed.
Thus, the encoder output signal is converted to a digital data word for transmission over a differential serial data bus. SSI encoder system 36 embeds position data in a digital data word for transmission to controller 50. This allows for additional data such as sensor 30-33 and 35 outputs to be embedded and transmitted over to the digital bus in addition to HED derived motor position data from position sensor 34. The digital word provides the bandwidth required for operation of motor 20 at desired speeds while differential signal driver 41 maintains signal integrity and noise immunity over long transmission distances from the bottom of well bore 18 to the surface and controller 50. Additional data from sensors 30, 31, 32, 33 and 35 are embedded in the transmission. By integrating additional signals from downhole motor 20 and pump 19, an integrated subsurface communication system is provided.
While the presently preferred form of the system has been shown and described, and several modifications thereof discussed, persons skilled in this art will readily appreciate that various additional changes and modifications may be made without departing from the scope of the invention, as defined and differentiated by the following claims.
Filing Document | Filing Date | Country | Kind |
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PCT/US2016/040078 | 6/29/2016 | WO | 00 |
Number | Date | Country | |
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62189957 | Jul 2015 | US |