Control circuit for multiphase inverter apparatus
First Claim
1. A control circuit for controlling a power converting apparatus producing a three-phase power output from input direct current power by opening and closing switches coupled to the input direct current power the control circuit comprising:
- current detecting means for detecting output currents of each phase of a three-phase power converting apparatus;
three-phase current command generating means for generating three current command values;
adding/subtracting means for calculating current deviations between respective current command values and output currents;
voltage detecting means for detecting a voltage of each phase of a three-phase power supply, each phase being connected, via a respective reactor, to the power converting apparatus and for producing power supply voltage vectors from the voltages of each of the phases of the three-phase power supply that is detected; and
switching command generating means for producing a current deviation vector from the current deviations, establishing an allowable region for the current deviation vector, and determining whether the current deviation vector is located within the allowable region, obtaining moving directions for the current deviation vector with respect to each of a plurality of output voltage vectors of the power converting apparatus, based upon the output voltage vectors, and selecting and outputting, from the plurality of output voltage vectors, at least one output voltage vector producing a moving direction for moving the current deviation vector toward and into the allowable region for controlling opening and closing of the switches.
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Accused Products
Abstract
In a control circuit for a power converting apparatus, such as a three-phase inverter, unnecessary switching operations of switching elements are avoided. The control circuit includes current sensors for detecting inverter currents; a three-phase current command generating circuit for generating a current command value; adders/substracters for calculating current deviation between the current command value and the inverter current; a voltage detecting circuit for detecting voltages of three-phase power supplies; and a pulse width modulation (PWM) pattern selector circuit obtaining a current deviation vector from the current deviation, setting an allowable range region with respect to the current deviation vector, when the current deviation vector is not located within the allowable range region, obtaining a moving direction of the current deviation vector as to output voltage vectors of the power converting apparatus based upon the power supply voltage vector, and outputting an output voltage vector in which the moving direction of the current deviation vector, among moving directions, is directed to the allowable range region.
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Citations
10 Claims
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1. A control circuit for controlling a power converting apparatus producing a three-phase power output from input direct current power by opening and closing switches coupled to the input direct current power the control circuit comprising:
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current detecting means for detecting output currents of each phase of a three-phase power converting apparatus;
three-phase current command generating means for generating three current command values;
adding/subtracting means for calculating current deviations between respective current command values and output currents;
voltage detecting means for detecting a voltage of each phase of a three-phase power supply, each phase being connected, via a respective reactor, to the power converting apparatus and for producing power supply voltage vectors from the voltages of each of the phases of the three-phase power supply that is detected; and
switching command generating means for producing a current deviation vector from the current deviations, establishing an allowable region for the current deviation vector, and determining whether the current deviation vector is located within the allowable region, obtaining moving directions for the current deviation vector with respect to each of a plurality of output voltage vectors of the power converting apparatus, based upon the output voltage vectors, and selecting and outputting, from the plurality of output voltage vectors, at least one output voltage vector producing a moving direction for moving the current deviation vector toward and into the allowable region for controlling opening and closing of the switches. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10)
the power converting apparatus controlled is a three-phase inverter including a plurality of switching elements; and
said switching command generating means selects, from the plurality of output voltage vectors, an output voltage vector providing a moving direction of the current deviation toward and into the allowable region to remain in the allowable region longest, and a value obtained by multiplying (i) duration of the current deviation vector within the allowable region, by (ii) a weighting coefficient, the weighting coefficient corresponding to a total switching time of said plurality of switching elements, the total switching time being required for changing switching mode of said plurality of switching elements.
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4. The control circuit for controlling a power converting apparatus as claimed in claim 1 wherein said switching command generating means calculates an evaluation function, and selects, from the plurality of output voltage vectors, an output voltage vector based upon the evaluation function, the evaluation function being calculated by multiplying (i) duration of the current deviation vector within the allowable region when a zero voltage vector is output, by (ii) a weighting coefficient corresponding to total switching time of the switches, the total switching time being required for changing switching mode of the switches.
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5. The control circuit for controlling a power converting apparatus as claimed in claim 1 wherein the allowable region for the current deviation vector is represented on graph by a hexagonal area.
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6. The control circuit for controlling a power converting apparatus as claimed in claim 5 wherein respective edges of the hexagonal area intersect respective voltage vectors output from the power converting apparatus at right angles.
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7. The control circuit for controlling a power converting apparatus as claimed in claim 5 wherein respective edges of the hexagonal area intersect respective voltage vectors output from the power converting apparatus at an angle of 60°
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8. The control circuit for controlling a power converting apparatus as claimed in claim 1 wherein, when the current deviation vector, after movement, is not in the allowable region, said switching command generating means does not change a switching command output if a presently output switching command causes the current deviation vector to move in a direction toward the allowable region.
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9. The control circuit for controlling a power converting apparatus as claimed in claim 1 wherein said switching command generating means calculates an evaluation function, and selects a switching mode based upon the evaluation function, the evaluation function being calculated by multiplying (i) duration of the current deviation vector in the allowable region when a zero voltage vector is output, by (ii) a weighting coefficient determined by unbalanced switching times for each of the phases, for changing the switching mode.
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10. The control circuit for a power converting apparatus as claimed in claim 1 wherein said switching command generating means acquires the moving direction of the current deviation vector based upon a rate of change of a current command.
Specification