Systems and Methods for Detecting Pump-Off Conditions and Controlling a Motor to Prevent Fluid Pound

What is claimed is: 1 . A system comprising: an electric submersible pump (ESP) installed in a well; an electric drive positioned at the surface of the well; and a power cable coupled between the electric drive and the ESP; wherein the electric drive includes one or more current sensors coupled to an output of the electric drive, wherein the sensors measure one or more currents of AC output power provided by the electric drive to the linear motor; wherein the electric drive includes a controller that receives instantaneous current measurements from the current sensors, determines an instantaneous current vector for each of one or more phases of the AC output power based on the measured instantaneous currents, and determines an instantaneous force based on the instantaneous current vectors; wherein during a power stroke of the linear motor, the controller calculates the instantaneous force generated by the motor at each of a plurality of points in time in dependence on the instantaneous current vectors at the corresponding points in time and for one or more of the points in time, wherein the controller determines whether a pump-off condition exists and re-initializes the linear motor in response to determining that the pump-off condition exists; wherein the controller determines whether the pump-off condition exists at the corresponding point in time by determining whether the instantaneous force generated by the motor at the corresponding point in time is less than a predetermined percentage of the instantaneous force generated by the motor at a preceding point in time; and wherein the controller determines the instantaneous force for each point in time by measuring instantaneous current vectors of each of three phases of the output power for the corresponding point in time and computes the instantaneous force as a root-mean-square of the instantaneous current vectors multiplied by a constant power factor. 2 . A method for controlling a linear motor, the method comprising: driving a linear motor; during a power stroke of the linear motor, measuring current drawn by the motor at each of a plurality of points in time and calculating an instantaneous force generated by the motor at each of the plurality of points in time in dependence on the corresponding current drawn by the motor; at each of the points in time after a first one of the points in time, determining whether a pump-off condition exists, re-initializing the linear motor if the pump-off condition exists, and continuing to drive the linear motor if the pump-off condition does not exist; and wherein determining whether the pump-off condition exists at the corresponding point in time includes determining whether the instantaneous force generated by the motor at the corresponding point in time is less than a predetermined percentage of the instantaneous force generated by the motor at a preceding point in time. 3 . The method of claim 2 , wherein determining the instantaneous force for each point in time includes measuring instantaneous current vectors of each of three phases of power drawn by the linear motor at the corresponding point in time and computing the instantaneous force as a root-mean-square of the instantaneous current vectors multiplied by a constant power factor. 4 . The method of claim 2 , wherein determining whether the pump-off condition exists at the corresponding point in time includes determining whether: the instantaneous force generated by the motor at the corresponding point in time is less than 35% of the instantaneous force generated by the motor at the preceding point in time; and the linear motor is not in an acceleration phase of the power stroke. 5 . The method of claim 2 , further comprising re-initializing the linear motor when the instantaneous force generated by the motor at the corresponding point in time in an acceleration phase of the linear motor is less than a minimum force recorded during a dwell time of the linear motor. 6 . The method of claim 2 , further comprising stepping the linear motor through a remainder of the power stroke in a controlled mode prior to re-initializing the linear motor. 7 . The method of claim 2 , further comprising, after determining that the pump-off condition exists, delaying for a predetermined amount of time prior to beginning re-initialization of the linear motor. 8 . The method of claim 2 , wherein determining whether the pump-off condition exists at the corresponding point in time includes: determining whether the instantaneous force generated by the motor at the corresponding point in time is between 35% and 75% of the instantaneous force generated by the motor at the preceding point in time and the linear motor is not in an acceleration phase of the power stroke; if the instantaneous force generated by the motor at the corresponding point in time is between 35% and 75% of the instantaneous force generated by the motor at the preceding point in time and the linear motor is not in an acceleration phase of the power stroke, incrementing a low-force violations counter and re-initializing the linear motor if the low-force violations counter reaches a threshold count. 9 . A system comprising: a linear motor; and an electric drive coupled to provide output power to the linear motor, thereby driving the linear motor; wherein the electric drive measures a current of the output power and, during a power stroke of the linear motor, calculates an instantaneous force generated by the motor at each of a plurality of points in time in dependence on the current drawn by the motor at the corresponding points in time; wherein, for one or more of the points in time, the electric drive determines whether a pump-off condition exists and re-initializes the linear motor in response to determining that the pump-off condition exists; and wherein the electric drive determines whether the pump-off condition exists at the corresponding point in time by determining whether the instantaneous force generated by the motor at the corresponding point in time is less than a predetermined percentage of the instantaneous force generated by the motor at a preceding point in time. 10 . The system of claim 9 , wherein the electric drive determines the instantaneous force for each point in time by measuring instantaneous current vectors of each of three phases of the output power for the corresponding point in time and computes the instantaneous force as a root-mean-square of the instantaneous current vectors multiplied by a constant power factor. 11 . The system of claim 9 , wherein the electric drive determines whether the pump-off condition exists at the corresponding point in time by determining whether: the instantaneous force generated by the motor at the corresponding point in time is less than 35% of the instantaneous force generated by the motor at the preceding point in time; and the linear motor is not in an acceleration phase of the power stroke. 12 . The system of claim 9 , wherein the electric drive re-initializes the linear motor when the instantaneous force generated by the motor at the corresponding point in time in an acceleration phase of the linear motor is less than a minimum force recorded during a dwell time of the linear motor. 13 . The system of claim 9 , wherein in response to determining that the pump-off condition exists, the electric drive steps the linear motor through a remainder of the power stroke in a controlled mode prior to re-initializing the linear motor. 14 . The system of claim 9 , wherein the electric drive, after determining that the pump-off condition exists, positions the