Control device for AC rotary machine and magnetic-pole-position correction amount calculation method

The invention claimed is: 1. A control device for AC rotary machine, comprising: a voltage-vector command generation device that generates a voltage command for controlling an AC rotary machine; a voltage application device that applies a voltage to the AC rotary machine, based on the voltage command; a current vector detection device that detects a detection-current vector whose component is a rotary machine current flowing through the AC rotary machine; a magnetic-pole-position correction amount calculation device that, at the time of correction-amount-generation operation of the AC rotary machine that is different to normal operation thereof, calculates a magnetic-pole-position correction amount for correcting a magnetic-pole-position error that corresponds to a difference between an estimated position that is an estimated magnetic-pole position of a rotor of the AC rotary machine corresponding to the voltage command, and a magnetic-pole position of the rotor when the AC rotary machine is driven based on the voltage command; wherein, at the time of the correction-amount-generation operation, the voltage-vector command generation device successively generates: a first said voltage command for causing a target current to flow through the AC rotary machine; and a second said voltage command that is a voltage command for applying a voltage to the AC rotary machine in a state that a current is flowing through the AC rotary machine according to the first voltage command, to calculate the magnetic-pole position correction amount in the state that the current is flowing through the AC rotary machine according to the first voltage command; and wherein, the magnetic-pole-position correction amount calculation device calculates the magnetic-pole-position correction amount, based on the first voltage command and the second voltage command, and on the detection-current vector that is detected when voltages according to the first voltage command and the second voltage command are applied, wherein the magnetic-pole-position correction amount calculation device calculates the magnetic-pole-position correction amount, based on an amplitude of a current resulting from converting the detection-current vector detected when the voltage application device applies the voltage to the AC rotary machine according to the second voltage command, into a magnetic-pole axis of the rotor and an axis perpendicular thereto using the magnetic-pole position. 2. The control device for AC rotary machine of claim 1 , further comprising a storage device in which the magnetic-pole-position correction amount associated with the detection-current vector is stored; wherein, at the time of the normal operation of the AC rotary machine, the voltage-vector command generation device generates the voltage command to be used for the normal operation, based on the detection-current vector detected by the current vector detection device, and on the magnetic-pole-position correction amount associated with that detection-current vector. 3. The control device for AC rotary machine of claim 2 , wherein, at the time the magnetic-pole-position correction amount is calculated, the voltage-vector command generation device changes plural times a position of the rotor of the AC rotary machine, and for each different position of the rotor, the voltage-vector command generation device successively generates a first said voltage command for causing a target current to flow through the AC rotary machine, and a second said voltage command for calculating the magnetic-pole-position correction amount in a state that a current is flowing through the AC rotary machine according to the first voltage command, such that their corresponding voltages are applied to the AC rotary machine; and the magnetic-pole-position correction amount calculation device calculates the magnetic-pole-position correction amount, based on the first voltage command and the second voltage command, and on the detection-current vector detected when the voltages according to the first voltage command and the second voltage command are applied, and then stores in the storage device, the magnetic-pole-position correction amount associated with the detection-current vector and the position of the rotor. 4. The control device for AC rotary machine of claim 2 , wherein, at the time the magnetic-pole-position correction amount is calculated, the voltage-vector command generation device changes plural times a position of the rotor of the AC rotary machine that is a three-phase AC rotary machine, and for each different position of the rotor, the voltage-vector command generation device successively generates the first voltage command for causing the target current to flow through the AC rotary machine, and the second voltage command for calculating the magnetic-pole-position correction amount in a state that the current is flowing through the AC rotary machine according to the first voltage command, such that their corresponding voltages are applied to the AC rotary machine, the second voltage command comprising voltage commands with phases having a phase difference of 120° to each other and a same frequency; and the magnetic-pole-position correction amount calculation device calculates the magnetic-pole-position correction amount, based on the first voltage command and the second voltage command, and on the detection-current vector detected when the voltages according to the first voltage command and the second voltage command are applied, and then stores in the storage device, the magnetic-pole-position correction amount associated with the detection-current vector and the position of the rotor. 5. The control device for AC rotary machine of claim 2 , wherein the first voltage command is a voltage command that causes a current necessary to induce magnetic saturation in the AC rotary machine to flow therethrough. 6. The control device for AC rotary machine of claim 2 , wherein the first voltage command is a voltage command that causes a current to flow in one direction through the AC rotary machine. 7. The control device for AC rotary machine of claim 1 , wherein the first voltage command is a voltage command that causes a current necessary to induce magnetic saturation in the AC rotary machine to flow therethrough. 8. The control device for AC rotary machine of claim 1 , wherein the first voltage command is a voltage command that causes a current to flow in one direction through the AC rotary machine. 9. The control device for AC rotary machine of claim 1 , wherein, when the rotary machine current caused by application of the voltage according to the first voltage command is flowing through the AC rotary machine, the voltage according to the second voltage command is applied to the AC rotary machine. 10. The control device for AC rotary machine of claim 1 , wherein the second voltage command is a voltage command for applying a bidirectional voltage having a phase difference of more than 90° but less than 270° in the AC rotary machine. 11. The control device for AC rotary machine of claim 10 , wherein the second voltage command is a voltage command for applying the bidirectional voltage having a phase difference of 180° in the AC rotary machine. 12. The control device for AC rotary machine of claim 1 , wherein the AC rotary machine is a three-phase AC rotary machine; and wherein the second voltage command comprises voltage commands with phases having a phase difference of 120° to each other and a same frequency. 13. The control device for AC rotary machine of claim 12 , wherein the voltage application device is a device that applies a voltage to the AC rotary