Drift control system of a work machine and method thereof

We claim: 1. A drift control method for a machine, the machine including a controller, a cutting tool, a motor having a motor shaft for driving a machine function, a control valve, and an operator control for commanding a machine function, the drift control method comprising: sensing a neutral position of the operator control; storing a drift control function and a look-up table in the controller, the look-up table including electric current values relative to a load pressure on the motor; and performing the following steps while the operator control is sensed in the neutral position: storing a first position of the motor shaft or cutting tool in the controller; detecting a change in position of the motor shaft or cutting tool with a sensor; determining a direction as a function of the change in position; enabling the drift control function using the look-up table to execute the performing step if the operator control is in the neutral position; and hydraulically controlling the motor shaft or cutting tool to the first position. 2. The drift control method of claim 1 , further comprising: sensing the operator control is in a position different from the neutral position; and disabling the drift control function. 3. The drift control method of claim 1 , further comprising: continuously measuring the position of the motor shaft or cutting tool while the operator control is in the neutral position; and continuously adjusting the position of the motor shaft or cutting tool to remain substantially in the first position. 4. The drift control method of claim 1 , further comprising: providing a first solenoid to control rotation of the motor shaft in a clockwise direction and a second solenoid to control rotation in a counterclockwise direction; and energizing the first solenoid or the second solenoid based on a result of the determining step. 5. The drift control method of claim 4 , further comprising: actuating the control valve in one of two directions based on the energizing step; detecting a new position of the motor shaft or cutting tool after the actuating step; comparing the new position to the first position; determining a second direction if the new position is different from the first position; and hydraulically controlling the motor shaft or cutting tool from the new position to the first position. 6. The drift control method of claim 1 , wherein the hydraulically controlling step comprises hydraulically controlling motor shaft speed based on a magnitude of the change in position of the motor shaft. 7. The drift control method of claim 1 , wherein the hydraulically controlling step comprises hydraulically controlling motor shaft speed based on one or more of a magnitude of the change in position of the motor shaft, actual fluid temperature relative to a threshold temperature, and load pressure on a work line of the motor. 8. The method of claim 1 , wherein the storing the drift control function step includes storing a look-up table including a fluid temperature. 9. A method of controlling motor shaft drift due to fluid leakage of a machine, comprising: providing a controller, a control valve having a first solenoid and a second solenoid, a motor having a motor shaft for driving a machine function, a sensor, and an operator control for commanding the machine function; storing a look-up table in the controller, the look-up table including electric current values relative to a load pressure on the motor; detecting a neutral position of the operator control; sensing rotation of the motor shaft in a first rotational direction with the sensor; receiving a pressure signal from the sensing step; determining an output current from the look-up table based on the pressure signal; and electrically controlling the control valve based on the determined output current from the look-up table to rotate the motor shaft in a second rotational direction, where the first rotational direction is opposite the second rotational direction. 10. The method of claim 9 , wherein: the sensing step comprises sensing rotation of the motor shaft in the first rotational direction by an angular distance; and the electrically controlling step comprises electrically controlling the control valve to rotate the motor shaft in the second rotational direction by the angular distance. 11. The method of claim 10 , wherein the electrically controlling step comprises: comparing the angular distance to a threshold distance; and electrically controlling the control valve to rotate the motor shaft in the second rotational direction by the angular distance when the angular distance is greater than the threshold distance. 12. The method of claim 10 , wherein: the sensing step comprises sensing rotation of the motor shaft in the first rotational direction by a first angular distance; and the electrically controlling step comprises electrically controlling the control valve to rotate the motor shaft in the second rotational direction by a second angular distance, the second angular distance being equal to or within approximately 90% of the first angular distance. 13. The method of claim 9 , further comprising: continuously monitoring the motor shaft after the electrically controlling step; detecting rotational movement of the motor shaft in either the first or second direction; and commanding the control valve to control movement of the motor shaft in the direction opposite of the rotational movement. 14. A method of controlling motor shaft drift due to fluid leakage of a machine, comprising: providing a controller, a control valve having a first solenoid and a second solenoid, a motor having a motor shaft for driving a machine function, a sensor, and an operator control for commanding the machine function; detecting a neutral position of the operator control; sensing rotation of the motor shaft in a first rotational direction with the sensor; electrically controlling the control valve to rotate the motor shaft in a second rotational direction, where the first rotational direction is opposite the second rotational direction; storing a look-up table in the controller, the look-up table including electric current values relative to a load pressure on the motor and a fluid temperature; receiving a pressure signal from the sensing step; reading a current fluid temperature over a CAN link; determining an output current from the look-up table based on the pressure signal and current fluid temperature; and communicating the output current to a first solenoid or a second solenoid to execute the electrically controlling step. 15. The method of claim 14 , wherein: the sensing step comprises detecting a movement in a first direction of a cutting tool of the machine with the sensor; and the electrically controlling step comprises controllably moving the cutting tool in a second direction, wherein the first direction is opposite the second direction. 16. A method for controlling drift of a work machine, the work machine including a controller, a control valve having a first solenoid and a second solenoid, a motor having a motor shaft for driving a machine function, a motor shaft sensor, a pressure sensor, and an operator control for commanding the machine function, the method comprising: storing a drift control function and a look-up table in the controller, the look-up table including electric current values relative to a load pressure on the motor and a fluid temperature; enabling the drift control function if the operator control is in a neutral position; receiving a pressure si