Power conversion device with individual cell and arm balancing

The invention claimed is: 1. A power conversion device comprising: a power converter including a plurality of arms each having a plurality of converter cells connected to each other in cascade, each of the arms being electrically connected to a corresponding phase of an AC circuit, each of the converter cells including: a pair of input/output terminals; a plurality of switching elements; a power storage element electrically connected to the input/output terminals through the switching elements; and a voltage detector to detect a voltage of the power storage element, the power conversion device further comprising: an AC current detector to detect AC current flowing through an AC line connecting the AC circuit and the power converter; and a control device to control the power converter, the control device including: an AC current controller to perform AC current control in accordance with a deviation between the detected AC current and an AC current command value; an individual voltage controller to perform individual voltage control in accordance with a deviation between a voltage of each individual power storage element and an individual voltage command value; and a control changer to calculate an evaluation value indicating a degree of variations in voltage of the power storage elements in the power converter as a whole, wherein when the evaluation value is greater than a threshold value, the control changer changes control of the power converter such that an effective value of arm current flowing through each of the arms increases as compared with when the evaluation value is not greater than the threshold, while the AC current control and the individual voltage control are being performed. 2. The power conversion device according to claim 1 , further comprising a plurality of arm current detectors to detect respective arm currents flowing through the arms, wherein the control device further includes a circulating current controller to perform circulating current control in accordance with a deviation between circulating current calculated based on the detected arm currents and a circulating current command value calculated based on a mean value of voltages of the power storage elements in the converter cells, and when the evaluation value is greater than the threshold value, the control changer outputs, to the circulating current controller, an instruction to change an absolute value of the circulating current command value to a greater value. 3. The power conversion device according to claim 2 , wherein when the evaluation value is greater than the threshold value, the control changer outputs, to the circulating current controller, an instruction to intermittently change an absolute value of the circulating current command value to a greater value. 4. The power conversion device according to claim 2 , when the evaluation value is greater than the threshold value, the control changer outputs, to the circulating current controller, an instruction to alternately repeat adding an amount of change to an original circulating current command value and subtracting an amount of change from an original circulating current command value. 5. The power conversion device according to claim 1 , further comprising a phase modifier connected to the AC line through a switch between the AC current detector and the power converter, wherein when the evaluation value is greater than the threshold value, the control changer outputs an instruction to close the switch. 6. The power conversion device according to claim 1 , further comprising a transformer with a function of changing a tap, the transformer being connected between the AC current detector and the power converter, wherein when the evaluation value is greater than the threshold value, the control changer outputs an instruction to change the tap of the transformer to increase AC current on the power converter side. 7. The power conversion device according to claim 1 , wherein when the evaluation value is greater than the threshold value, the control changer outputs, to the AC current controller, an instruction to change the AC current command value so as to include a negative phase sequence current component, and the AC current controller performs AC current control in accordance with a deviation between the detected AC current and the changed AC current command value. 8. A power conversion device comprising: a power converter including a plurality of arms each having a plurality of converter cells connected to each other in cascade, each of the arms being electrically connected to a corresponding phase of an AC circuit, each of the converter cells including: a pair of input/output terminals; a plurality of switching elements; a power storage element electrically connected to the input/output terminals through the switching elements; and a voltage detector to detect a voltage of the power storage element, the power conversion device further comprising: an AC current detector to detect AC current flowing through an AC line connecting the AC circuit and the power converter; and a control device to control the power converter, the control device including: an AC current controller to perform AC current control in accordance with a deviation between the detected AC current and an AC current command value; an individual voltage controller to perform individual voltage control in accordance with a deviation between a voltage of each individual power storage element and an individual voltage command value; and a control changer to calculate an evaluation value indicating a degree of variations in voltage between the individual power storage elements, wherein when the evaluation value is greater than a threshold value, the control changer changes control of the power converter such that an effective value of arm current flowing through each of the arms increases as compared with when the evaluation value is not greater than the threshold, while performing the AC current control and the individual voltage control.