An electric alternator having a rotor, stator and at least one winding in the stator adapted to conduct a current, the machine also having and first and second magnetic circuits around different portions of the winding which may be configured relative to one another to control generated output volta
An electric alternator having a rotor, stator and at least one winding in the stator adapted to conduct a current, the machine also having and first and second magnetic circuits around different portions of the winding which may be configured relative to one another to control generated output voltage of the winding.
대표청구항▼
What is claimed is: 1. A method of controlling an output voltage in a machine operable as an electric alternator/generator, the machine comprising a rotor and stator assembly, the assembly having a stator including at least a first winding, the assembly also having first and second magnetic circuit
What is claimed is: 1. A method of controlling an output voltage in a machine operable as an electric alternator/generator, the machine comprising a rotor and stator assembly, the assembly having a stator including at least a first winding, the assembly also having first and second magnetic circuits and a saturation control device, the first magnetic circuit including the rotor and encircling at least a first portion of the first winding, the second magnetic circuit encircling at least a second portion of the first winding remote from the first magnetic circuit, the first and second magnetic circuits coupled when current flows in the first winding, the second magnetic circuit including a portion which is selectively magnetically saturable, the saturation control device being operatively associated with the magnetically saturable portion of the second circuit and operable to controllably vary a saturation level of said saturable portion, the method comprising: reducing the saturation of the magnetically saturable portion as an output current of the machine reduces towards zero during a low or no-load condition; preventing an output voltage of the machine from rising above a threshold value during the low/no-load condition by allowing sufficient flux to leave the first magnetic circuit and circulate through the magnetically saturable portion when in an unsaturated condition to induce a reducing voltage in second portion of the first winding subtractive from the output voltage. 2. The method of claim 1 wherein the step of preventing includes allowing some of the first magnetic circuit to circulate into the magnetically saturable portion by selecting relative permeabilities of the stator so as to direct sufficient flux through the saturable portion to induce a sufficient reducing voltage to limit the output voltage to said threshold value. 3. The method of claim 2, wherein a relative dimension of at least one stator portion remote from the first circuit is selected to reduce a permeability of the stator relative to the first magnetic circuit and thereby promote flux circulation through the magnetically saturable portion when unsaturated in the low/no-load condition. 4. The method of claim 3, wherein the at least one stator portion is the magnetically saturable portion. 5. The method of claim 2, wherein at least one material of at least one stator portion remote from the first circuit is selected to reduce a permeability of the stator relative to the first magnetic circuit and thereby promote flux circulation through the magnetically saturable portion when unsaturated in the low/no-load condition. 6. The method of claim 5, wherein the at least one stator portion is the magnetically saturable portion. 7. A method of providing an electric alternator, the method comprising: providing an alternator having a rotor, a stator and at least a first winding providing alternator output power, the stator having a plurality of first slots and second slots circumferentially around the stator, the first slots located closer to the rotor than the second slots, the first slots having a portion of the first winding disposed therein, the second slots having another portion of the first winding disposed therein, the stator defining a first magnetic circuit path around the first slots and a second magnetic path around the second slots, the first magnetic circuit path in use conducting rotor magnetic flux to induce a first voltage in the first winding, the second magnetic circuit path in use conducting rotor magnetic flux to induce a second voltage in the first winding, the second voltage opposite in direction to the first voltage, the stator having first and second magnetic permeabilities associated with the first and second magnetic circuit paths; determining a maximum allowable output voltage of the alternator mode when operating under a low or no-load condition; configuring the stator by selecting relative permeabilities of the first and second magnetic circuits such that in use the induced second voltage is sufficient large relative to the induced first voltage so as to prevent the first voltage from exceeding the maximum allowable output voltage. 8. The method of claim 7, wherein the step of configuring includes adjusting the relative dimensions of stator portions defining the first and second magnetic circuit paths. 9. The method of claim 7, wherein the step of configuring includes adjusting the relative materials of stator portions defining the first and second magnetic circuit paths. 10. The method of claim 7, wherein the second circuit branches from the first circuit, and the method further comprises the step of diverting a portion of the magnetic flux circulating the first circuit to the second circuit. 11. An electric alternator comprising a rotor, a stator and at least a first stator winding providing alternator output power to a load, the stator having a plurality of first slots and second slots circumferentially around the stator, the first slots located closer to the rotor than the second slots, the first slots having a portion of the first winding disposed therein, the second slots having another portion of the first winding disposed therein and wound oppositely relative to the portion in the first slots, the stator defining a first magnetic circuit path around the first slots and a second magnetic circuit path around the second slots, the second path outside of the first magnetic circuit path, the first magnetic circuit path adapted to conduct rotor magnetic flux to induce a first voltage in the first winding, the second magnetic circuit path adapted to conduct rotor magnetic flux to induce a second voltage in the first winding, the second voltage opposite in direction to the first voltage, the stator having first and second magnetic permeabilities associated with the first and second magnetic circuit paths, the relative permeabilities selected such that in use the induced second voltage is sufficiently large relative to the induced first voltage so as to prevent the first voltage from exceeding a pre-determined maximum allowable output voltage. 12. The alternator of claim 11 wherein the pre-determined maximum allowable output voltage is substantially equal to a full load output voltage of the first winding. 13. The alternator of claim 11 further comprising a second winding disposed in the second slots, the second winding coiled around a stator portion remote from the first magnetic circuit and defining a portion of the second magnetic circuit, the second winding connected to a current source and in use adapted to selectively energize the second winding to saturate said stator portion, said stator portion being unsaturated in a "no-load" condition when substantially no current is drawn from the first winding by the load, and wherein during in this "no-load" condition the induced second voltage is sufficiently large relative to the induced first voltage so as to prevent the first voltage from exceeding a pre-determined maximum allowable output voltage.
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