Power converter control method

The invention claimed is: 1. A power converter control method of controlling a direct AC-AC power converter which comprises: a rectifier circuit which inputs first AC voltages and outputs a rectified voltage; and a voltage source inverter which inputs said rectified voltage, applies three-phase second AC voltages to a load, and outputs three-phase load currents to said load, wherein a modulation factor of said voltage source inverter includes a DC component and an AC component which is an angular frequency which is a 6n multiple (n is a natural number) of a base fundamental angular frequency of said second AC voltage, and when a fundamental wave component, a (6n−1)th order component and a (6n+1)th order component of said load current are Iu 1 , Iu 6n−1 and Iu 6n+1 , respectively, and phase differences of said fundamental wave component, said (6n−1)th order component and said (6n+1)th order component of said load current from a fundamental wave component of said second AC voltage are (Φ 1 , Φ 6n−1 and Φ 6n+1 , respectively, a ratio of an amplitude of said AC component with respect to said DC component takes a ratio represented by −[ m 6n 2 +Iu h6n 2 +2 ·m 6n ·Iu h6n cos(θ−χ 6n )] 1/2 /[Iu 1 ·cos(Φ 1 )] ( m 6n =[Iu 6n−1 2 +Iu 6n+1 2 +2 ·Iu 6n−1 ·Iu 6n+1 ·cos(Φ 6n−1 −Φ 6n+1 )] 1/2 ), and a phase difference (Φ 6n ) of said AC component from the fundamental wave component of said second AC voltage takes an angle represented by tan −1 [{m 6n ·sin(χ 6n )+ Iu h6n ·sin(χ 6n )}/{ m 6n ·cos(χ 6n )+ Iu h6n ·cos(χ 6n )}] (χ 6n =tan −1 [{Iu 6n−1 ·sin(Φ 6n−1 )+ Iu 6n+1 ·sin(Φ 6n+1 )}/{ Iu 6n−1 ·cos(Φ 6n−1 )+ Iu 6n+1 ·cos(Φ 6n+1 )}], with relationship of Iu h6n <m 6n and θ: arbitrary. 2. The power converter control method according to claim 1 , wherein the ratio of said AC component with respect to said DC component is calculated in advance as a function of a plurality of operation states of said load before said load is actually operated, and said direct AC-AC power converter is controlled based on said function upon said actual operation. 3. The power converter control method according to claim 2 , wherein said operation states include a plurality of power states consumed by said load, and said ratio corresponding to said power states upon said actual operation is taken. 4. The power converter control method according to claim 1 , wherein Iu h6n =0 is true in all n. 5. The power converter control method according to claim 1 , wherein an amplitude of said AC component is increased in a predetermined range of said base fundamental angular frequency of said second AC voltage according to a sensitization amount which increases when said base fundamental angular frequency increases. 6. The power converter control method according to claim 5 , wherein Iu h6n =0 is true in all n. 7. A power converter control method of controlling a direct AC-AC power converter which comprises: a rectifier circuit which inputs first AC voltages and outputs a rectified voltage; and a voltage source inverter which inputs said rectified voltage, applies three-phase second AC voltages to a load, and outputs three-phase load currents to said load, wherein a voltage command to said voltage source inverter includes a DC component and an AC component of an angular frequency which is a 6n multiple (n is a natural number) of a base fundamental angular frequency of said second AC voltage, and when a fundamental wave component, a (6n−1)th order component and a (6n +1)th order component of said load current are Iu 1 , Iu 6n−1 and Iu 6n+1 , respectively, and phase differences of said fundamental wave component, said (6n−1)th order component and said (6n+1)th order component of said load current from a fundamental wave component of said second AC voltage are Φ 1 , Φ 6n−1 and Φ 6n+1 , respectively, a ratio of an amplitude of said AC component with respect to said DC component takes a ratio represented by −[ m 6n 2 +Iu h6n 2 +2 ·m 6n ·Iu h6n cos(θ−χ 6n )] 1/2 /[Iu 1 ·cos(Φ 1 )] ( m 6n =[Iu 6n−1 2 +Iu 6n+1 2 +2· Iu 6n−1 ·Iu 6n+1 ·cos(Φ 6n−1 −Φ 6n+1 )] 1/2 ), and a phase difference (Φ 6n ) of said AC component from the fundamental wave component of said second AC voltage takes an angle represented by tan −1 [{m 6n ·sin(χ 6n )+ Iu h6n ·sin(χ 6n )}/{ m 6n ·cos(χ 6n )+ Iu h6n ·cos(χ 6n )}] (χ 6n =tan −1 [{Iu 6n−1 ·sin(Φ 6n−1 )+ Iu 6n+1 ·sin(Φ 6n+1 )}/{ Iu 6n−1 ·cos(Φ 6n−1 )+ Iu 6n+1 ·cos(Φ 6n+1 )}], with relationship of Iu h6n <m 6n and θ: arbitrary. 8. The power converter control method according to claim 7 , wherein the ratio of said AC component with respect to said DC component is calculated in advance as a function of a plurality of operation states of said load before said load is actually operated, and said direct AC-AC power converter is controlled based on said function upon said actual operation. 9. The power converter control method according to claim 8 , wherein said operation states include a plurality of power states consumed by said load, and said ratio corresponding to said power states upon said actual operation is taken. 10. The power converter control method according to claim 7 , wherein Iu h6n =0 is true in all n. 11. The power converter control method according to claim 7 , wherein an amplitude of said AC component is increased in a predetermined range of said base fundamental angular frequency of said second AC voltage according to a sensitization amount which increases when said base fundamental angular frequency increases. 12. The power converter control method according to claim 11 , wherein Iu h6n =0 is true in all n.