Capacitor balancing control in an HVDC MMC

The invention claimed is: 1. A power conversion device comprising: a power converter including at least one arm having a plurality of converter cells connected to each other in cascade, each of the converter cells including: a first input/output terminal on a high potential side; a second input/output terminal on a low potential side; a plurality of switching elements; a power storage element having a positive electrode terminal and a negative electrode terminal, holding a positive voltage between the positive and negative electrode terminals, and electrically connected to the first input/output terminal and the second input/output terminal through the switching elements; and a voltage detector to detect a voltage of the power storage element; and a control device to perform phase shift pulse width control for the converter cells included in the at least one arm, wherein the control device calculates an evaluation value representing a degree of variations in positive voltage of the power storage elements in the converter cells included in the at least one arm, and when the evaluation value exceeds a threshold value, performs phase shift pulse width control for at least one of the converter cells such that at least one of the following is implemented: (i) when current in a first direction that is a direction from the first input/output terminal to the second input/output terminal flows through at least one first converter cell with a positive voltage of the power storage element greater than a mean value, reducing a time for a positive voltage output caused by a first switching state of the switching elements in which the positive electrode terminal of the power storage element is connected to the first input/output terminal and the negative electrode terminal of the power storage element is connected to the second input/output terminal; (ii) when current in a second direction opposite to the first direction flows through the first converter cell, increasing a time for the positive voltage output caused by the first switching state; (iii) when current in the first direction flows through at least one second converter cell with a positive voltage of the power storage element smaller than a mean value, increasing a time for the positive voltage output caused by the first switching state; or (iv) when current in the second direction flows through the second converter cell, reducing a time for the positive voltage output caused by the first switching state. 2. The power conversion device according to claim 1 , wherein the control device generates a final voltage command value for each converter cell by adding, to a voltage command value common to the converter cells, an individual voltage command value for each converter cell in accordance with a deviation between a positive voltage of the power storage element and a command value thereof, and when the evaluation value exceeds the threshold value, the control device sets a gain in generating the individual voltage command value to a larger value than when the evaluation value is equal to or smaller than the threshold value. 3. The power conversion device according to claim 1 , wherein when the evaluation value exceeds the threshold value, the control device changes a sign, a phase, or a frequency of a carrier signal in generating a pulse width modulation signal to be output to each of the converter cells. 4. The power conversion device according to claim 1 , wherein when the evaluation value exceeds the threshold value, the control device reverses a sign of a carrier signal in generating a pulse width modulation signal to be output to each of the converter cells. 5. The power conversion device according to claim 1 , wherein when the evaluation value exceeds the threshold value, the control device interchanges a phase of a carrier signal in generating a pulse width modulation signal to be output to a converter cell with a maximum positive voltage of the power storage element and a phase of a carrier signal in generating a pulse width modulation signal to be output to a converter cell with a minimum positive voltage of the power storage element. 6. The power conversion device according to claim 1 , wherein when the evaluation value exceeds the threshold value, the control device interchanges a phase of a carrier signal in generating a pulse width modulation signal to be output to a converter cell with a maximum positive voltage of the power storage element and a phase of a carrier signal in generating a pulse width modulation signal to be output to any other converter cell. 7. The power conversion device according to claim 1 , wherein when the evaluation value exceeds the threshold value, the control device interchanges a phase of a carrier signal in generating a pulse width modulation signal to be output to a converter cell with a minimum positive voltage of the power storage element and a phase of a carrier signal in generating a pulse width modulation signal to be output to any other converter cell. 8. The power conversion device according to claim 1 , wherein when the evaluation value exceeds the threshold value, the control device changes a frequency of a pulse width modulation signal to be output to each of the converter cells. 9. A power conversion device comprising: a power converter including at least one arm having a plurality of converter cells connected to each other in cascade, each of the plurality of converter cells including: a first input/output terminal on a high potential side; a second input/output terminal on a low potential side; a plurality of switching elements; a power storage element having a positive electrode terminal and a negative electrode terminal, holding a positive voltage between the positive and negative electrode terminals, and electrically connected to the first input/output terminal and the second input/output terminal through the switching elements; and a voltage detector to detect a voltage of the power storage element; and a control device to perform phase shift pulse width control for the converter cells included in the at least one arm, wherein the control device calculates an evaluation value representing a degree of variations in voltage of the power storage elements in the converter cells included in the at least one arm, when the evaluation value exceeds the threshold value, the control device controls a converter cell with a maximum positive voltage of the power storage element to a bypass state in which current does not flow into the power storage element or flow out of the power storage element, when the evaluation value has been changed to a value that does not exceed the threshold value, the control device controls the converter cell changed to the bypass state to be returned back from the bypass state, and when the evaluation value remains to exceed the threshold value and the converter cell changed to the bypass state does not have a maximum positive voltage of the power storage element, the control device controls the converter cell changed to the bypass state to be returned back from the bypass state, and instead controls another converter cell with a maximum positive voltage of the power storage element to the bypass state. 10. The power conversion device according to claim 9 , wherein each of the converter cells further includes a bypass switch having one end connected to the first input/output terminal and the other end connected to the second input/output terminal, and the bypass state includes a closed state of the bypass switch. 11. A power conversion device comprising: a power converter including at least one arm having a plurality of converter cells connected to