초록 ▼

In the present invention, several polyphase devices are connected together: an inverter, and electrical rotating machine, and a resistive load or braking resistor. The purpose of the resistive load is to dissipate excess electrical power which may be produced when the inverter acts to slow down the

In the present invention, several polyphase devices are connected together: an inverter, and electrical rotating machine, and a resistive load or braking resistor. The purpose of the resistive load is to dissipate excess electrical power which may be produced when the inverter acts to slow down the rotating machine, causing the rotating machine to act as a generator. In common art, this resistive load is a single DC resistor coupled to the DC link of the inverter via a separate resistor control transistor. In the present invention, the resistive load is a mesh connected array of resistors, and is electrically connected to the same inverter output terminals that the rotating machine is connected to. When it is desired that the resistors absorb energy, for example from a braking operation, then the harmonic content of the inverter output is adjusted, thus placing voltage differences across the resistor array and causing current to flow in the resistors.

대표청구항 ▼

The invention claimed is: 1. Apparatus for dissipating regenerated power, comprising: a) an inverter comprising a plurality (N) of terminals, for the synthesis of N different phases of alternating current (AC) waveform of variable harmonic content, where N is greater than three; b) an AC motor, ope

The invention claimed is: 1. Apparatus for dissipating regenerated power, comprising: a) an inverter comprising a plurality (N) of terminals, for the synthesis of N different phases of alternating current (AC) waveform of variable harmonic content, where N is greater than three; b) an AC motor, operable as both a motor and as a generator of regenerative power, comprising N electrical phases connected to said inverter terminals in a first mesh connection, said first mesh characterized in that: each motor phase is electrically connected to a first inverter terminal and a second inverter terminal L inverter terminals distant from the first inverter terminal in order of electrical phase angle, where L is the skip number, and the phase angle difference between the pair of inverter terminals to which each motor phase is connected is identical for each motor phase; c) a regenerated power sink comprising at least three elements and connected to said inverter in a second mesh connection wherein said second mesh connection differs in number of phases or step value from said first mesh connection; d) a detector for detecting said regenerated power; e) a controller; for adjusting the phase angles of said AC waveform to comprise harmonic content that creates a voltage difference across both mesh connections when regenerative power is detected; and to comprise harmonic content that creates a voltage difference across the motor mesh connection and a substantially zero voltage difference across the regenerative power sink mesh connection when regenerative power is not detected. 2. The apparatus of claim 1 wherein N is a multiple of three; wherein said regenerated power sink comprises three elements; wherein said second mesh connection comprises a delta connection; and a phase difference across each element is substantially zero when said output drive waveform consists of third harmonic, and is not zero in the presence of said additional harmonic components. 3. The apparatus of claim 1 wherein said motor has 15 phases; wherein N is 15; wherein said output drive waveform consists of third harmonic; wherein L is 6; wherein said second mesh connection characterized in that: each motor phase is electrically connected to a first inverter terminal and a second inverter terminal 5 inverter terminals distant from the first inverter terminal in order of electrical phase angle; and wherein said controller causes the output drive waveform to comprise fundamental. 4. The apparatus of claim 1 in which said regenerated power sink is selected from the group consisting of: a resistor array, a battery array, a potential energy storage unit, or a means of returning power to an AC mains supply. 5. A method for directing regenerated power to a sink comprising the steps of: a) synthesizing in an inverter N phases of an AC waveform current; b) connecting a motor comprising N phases to the inverter according to a mesh connection operable to have a phase angle difference across each motor phase of substantially not zero during synthesis of either a first or a second waveform by the inverter; c) connecting a power sink comprising at least three elements to the inverter according to a second mesh connection operable to produce a phase angle difference across each element of substantially zero during synthesis of the first waveform synthesized by the inverter, and operable to produce a phase angle difference across each element of substantially not zero during synthesis of the second waveform by the inverter; d) detecting when the motor is in regenerative mode; e) activating the sink by controlling the inverter to synthesize the second waveform during the period in which the motor is in regenerative mode, f) de-activating the sink by controlling the inverter to synthesize the first waveform during the period in which the motor is not in regenerative mode. 6. The method of claim 5 wherein the first waveform comprises harmonics that are equal to or multiples of the number of elements in the sink divided by a skip number L of the sink mesh connection, and wherein said step of activating said sink comprises controlling the inverter to introduce varying degrees of fundamental waveform into the first waveform, depending on the amount of regenerated power detected, to form the second waveform. 7. The method of claim 5 in which said regenerated power sink is selected from the group consisting of: a resistor array, a battery array, a potential energy storage unit, or a means of returning power to an AC mains supply.