1. Field of the Invention
This invention relates generally to controlling the pumping rate of a pump of a petroleum well. Specifically, one or more implementations of the invention relate to controlling the pumping rate of a progressing cavity pump in order to increase liquid production from a petroleum well while avoiding operation of the well in a pumped-off state.
2. Description of the Prior Art
Prior art pumping systems for recovering petroleum from underground formations have generally had pumping capacities in excess of the productivity rate of the petroleum formation. This results in a well state in which the well may be pumped dry, i.e., the well production is pumped off, thereby potentially causing damage to the pumping system.
It is well known in the art to provide control systems, such as those disclosed in U.S. Pat. Nos. 4,973,226; 5,064,348; and 5,167,490, to avoid a pumped-off state in a petroleum well in which oil is pumped from the well through the use of a downhole liquid pump actuated by a rod and reciprocated from the well surface by a prime mover. In addition to these reciprocating sucker rod type of pumps, progressing cavity pumps (PCP) are also presently in use in which a rotor is rotated inside a stator for pumping liquids. Progressing cavity pumps are advantageous, because the initial cost of the installation is low as compared to reciprocating pumps. However, the progressing cavity pump may also cause a pumped-off state resulting in potential damage to the pump. Such pump damage is expensive to repair, because the progressing cavity pump must be removed from the petroleum well.
U.S. Pat. No. 5,782,608 describes a method and apparatus for controlling the speed of a progressing cavity liquid well pump by driving the pump with a variable speed drive while measuring the amount of liquid production from the pump. One or more of the implementations described herein are improvements upon the method and apparatus disclosed in U.S. Pat. No. 5,782,608, which is incorporated herein by reference.
3. Identification of Objects of the Invention
An object of the invention is to accomplish one or more of the following:
Provide a system and method of controlling the pumping rate of a progressing cavity pump in order to increase liquid production from a petroleum well while avoiding operation of the well in a pumped-off state;
Provide a system and method of controlling the pumping rate of a progressing cavity pump by varying the speed of the pump, either upwardly or downwardly, by a variable speed drive while measuring the liquid production rate in order to increase liquid production from a petroleum well while avoiding operation of the well in a pumped-off state;
Provide a system and method of controlling the pumping rate of a progressing cavity pump by varying the speed of the pump, either upwardly or downwardly, by a variable speed drive while measuring the pump efficiency in order to increase liquid production from a petroleum well while avoiding operation of the well in a pumped-off state;
Provide a system and method of routinely challenging the current pumping rate of a progressing cavity pump by varying the speed of the pump, either upwardly or downwardly, by a variable speed drive in order to increase liquid production from the well while avoiding operation of the well in a pump-off state; and
Provide a system and method of controlling the pumping rate of a progressing cavity pump by varying the speed of the pump in order to remove sand along with the liquid production;
Other objects, features, and advantages of the invention will be apparent to one skilled in the art from the following specification and drawings.
The objects identified above, along with other features and advantages of the invention are incorporated in a system and method for controlling the pump speed of a progressing cavity pump in order to increase liquid production from a well while avoiding operation of the well in a pumped-off state. A controller is used to control a variable speed drive which drives a progressing cavity pump at a set pump speed for producing liquid production from the well. A flow measurement device, such as a flow meter, is used to measure the current flow rate of liquid production from the well.
The controller determines the difference between the current flow rate and a previous flow rate and further uses the determined difference to control the set speed of the pump. The controller increases the set pump speed by a step change when the difference indicates an increase in the current flow rate and decreases the set pump speed by a step change when the difference indicates a decrease in the current flow rate. Further, the controller increases the set pump speed by a step change when the difference indicates no change in current flow rate and the set pump speed was previously decreased and decreases the set pump speed by a step change when the difference indicates no change in current flow rate and the set pump speed was previously increased.
In an alternative implementation, a rod speed measurement device is also used to measure the current rod speed of the rotatable rod of the pump. The controller calculates the current pump efficiency as a function of the current rod speed and the current flow rate. The controller determines the difference between the current pump efficiency and a previous pump efficiency and further uses the determined difference to control the set speed of the pump as disclosed.
Additionally, the controller monitors several measured and calculated system parameters, such as rod speed difference, critical torque, torque limiting, low pump efficiency, high production, low production, low rod speed (i.e., low rpm), and no rod speed (i.e., no rpm), in order to detect if the system parameters are outside of their normal bounds. The controller indicates when the system parameters are outside of their normal bounds by setting an alarm or sending an alert. In an alternative implementation designed for sandy wells, the controller is responsive to the rod torque of the rotatable rod for controlling the set pump speed to remove sand along with the liquid production.
By way of illustration and not limitation, the invention is described in detail hereinafter on the basis of the accompanying figures, in which:
A preferred embodiment of the invention alleviates one or more of the deficiencies described in the prior art and incorporates at least one of the objects previously identified. Referring now to the drawings,
Referring now to
Referring now to
Preferably, the controller 50 and the variable speed drive 46 are in constant communication with each other through a data interface 66 in order to share system information, such as drive status, motor torque, rod torque, etc. If a torque measurement is not available from the variable speed drive 46, then the torque measurement is monitored and received by controller 50 via an analog input from the drive 46 or from any external torque measurement device 70. The controller 50 also preferably has a communication means, such as an antenna 68, data port for keyboard and display interface (not illustrated), or Internet connection (not illustrated), to communicate controller status, historical data, and system/controller configuration to a local or remote operator.
A flow meter 56, such as a turbine flow meter, is disposed in the flow outlet line 30 from the progressing cavity pump 10 in order to measure the flow rate and amount of liquid produced by the pump 10. The flow meter 56 transmits its measurement signal representative of liquid production flow rate through lines 58 and 64 to the controller 50. A rod string rpm sensor 60 is also provided to measure the speed of the rotating rod 24. The rpm sensor 60 is preferably a hall-effect sensor, however, a theoretical calculation of rod speed may be derived from the readings of other external devices. The rpm sensor 60 transmits its measurement signal representative of rod speed through lines 62 and 64 to the controller 50.
The controller 50 increases or decreases the speed of the primer mover/motor 28, and thus the speed of the pump 10, in varying amounts using the variable speed drive device 46. The controller 50 also receives measurement signals via signal wires 64 from the flow meter 56 representative of the liquid production and/or from the speed sensor 60 representative of the rotation speed of the rotatable rod 24. As previously stated, an objective of varying the speed of pump 10 in response to flow rate and rod speed measurements is to increase liquid production from a petroleum well 80 while avoiding operation of the well 80 in a pumped-off state. In other words, an object of the invention to provide improved control of pump 10 so as to operate and maintain a linear relationship between the liquid production rate and the pump speed (i.e., to operate and maintain the progressing cavity pump 10 on the linear portion 34 of the graph 32 as shown in
The controller 50 has a programmable settling period that allows the pumping system to reach a steady state or settle from a previous change in pump speed. After the settling period, the controller 50 commences the averaging of received measurements over a programmable sampling period. As discussed above, the controller 50 preferably receives a pump flow rate measurement from flow meter 56 via line 58 and 64 and a speed measurement from rpm speed sensor 60 via line 62 and 64. Other physical characteristics of the system, such as pressure, temperature, and rod torque, may be directly measured and received by the controller 50 for averaging over the sampling period or for other monitoring purposes. The controller 50 is preferably arranged and designed to use the raw measurements received to calculate additional characteristics of system performance. For example, in one implementation, the controller 50 calculates in real time the pump efficiency as the ratio of actual fluid displacement versus the theoretical fluid displacement. The actual fluid displacement is a calculated quantity comprising measured flow rate and measured pump speed. The theoretical fluid displacement is either calculated based upon the pump specifications or obtained from the pump manufacturer. In this way, the controller 50 can calculate an average pump efficiency over the sampling period based upon direct or indirect measurement of production flow rate and pump speed. Preferably, the controller 50 can receive and average at least one of the following measurements over the sampling period: the amount of production (i.e., flow), the rate of production (i.e., flow rate), and/or the pump efficiency (i.e., a calculated quantity of measured flow rate and pump speed).
Using the averaged measurements and calculated quantities thereof, the controller 50 directs a change in the motor speed of pump 10 to increase liquid production from the well 80 while avoiding an operation of the pump 10 and well 80 that will lead to a pumped-off well state.
After the settling period has expired, the controller 50 receives and averages a measured system characteristic or parameter, such as flow rate measured by flow meter 56, rod speed as measured by rpm speed sensor 60, and/or rod torque as measured by the drive 46 or the rod torque sensor 70. The measurements received by the controller 50 are averaged over the sampling period to filter out any short term variations or outlier readings. The controller 50 may also use any received measurements to calculate the quantities or values of additional characteristics representative of the physical state of the pump 10 and well 80. Solely as an example, and not to limit the scope of possible derivative calculations or system characteristics, the measured flow rate and measured rod speed may be used to calculate a pump efficiency, which is itself representative of the current state of the pump 10 and well 80. The controller 50 then determines the differential value between the averaged measurement or calculated characteristic or parameter over the sampling period and the corresponding measurement or calculated characteristic from the previous sampling period. If no previous sampling period measurement or calculated characteristic or parameter is available, then the controller 50 uses a predetermined value for the previous measurement or characteristic or parameter.
If the differential value indicates an increase in production pumped from the well 80, then the controller 50 follows the general control strategy as illustrated in
If the differential value indicates a decrease in the production pumped from the well 80, then the controller 50 follows the general control strategy as illustrated in
If the differential value indicates no change in production pumped from the well 80, then the controller 50 follows the general control strategy as illustrated in
After the speed of the pump 10 is set by the controller 50 in response to the differential value, the set pump speed with its step change, is saved as the previous set pump speed for future use by the controller 50 and the averaged system characteristic is also saved as the averaged system characteristic from the previous sampling period. The steps of allowing the system to settle at the set pump speed, measuring and averaging system characteristics, determining a difference in the averaged system characteristics between the current and previous sampling period, and adjusting the set pump speed in response to the determined difference are then repeated to increase liquid production from the well 80 and avoid operation of the well pump 10 in a pumped-off state.
As best illustrated in
While the controller 50 seeks to operate the pump 10 at a speed to optimize liquid production from the well 80, the controller 50 of an alternative implementation of the control strategy also includes an extensive violation detection module and violation action module for monitoring system characteristic or parameters received and processed by the controller 50. The violation detection and violation action modules serve to challenge the current operating speed of the pump in order to prevent the possibility of erroneous or misleading input measurement data. The parameter violation detection module is illustrated in
As shown in
As shown in
While the violation detection and action modules are illustrated as an integrated part of the alternative control strategy of
The Abstract of the disclosure is written solely for providing the United States Patent and Trademark Office and the public at large with a means by which to determine quickly from a cursory inspection the nature and gist of the technical disclosure, and it represents solely a preferred embodiment and is not indicative of the nature of the invention as a whole.
While some embodiments of the invention have been illustrated in detail, the invention is not limited to the embodiments shown; modifications and adaptations of the above embodiment may occur to those skilled in the art. Such modifications and adaptations are in the spirit and scope of the invention as set forth herein: