Generator with dual cycloconverter for 120/240 VAC operation
First Claim
1. A generator system having at least first and second modes, the generator system producing a first alternating current output voltage when in the first mode and producing the first alternating current output voltage and a second alternating current output voltage when in the second mode, the second output voltage being twice the first output voltage, comprising:
- first and second voltage sources each having an output at which they produce the first output voltage; and
a switch coupling the outputs of the first and second voltage sources in parallel when the switch is in a first position and in series when the switch is in a second position, the first output voltage produced at the outputs of the first and second voltage sources when the switch is in the first position and the second output voltage produced across the series coupled outputs of the first and second voltage sources when the switch is in the second position with the first output voltage also produced at the outputs of the first and second voltage sources when the switch is in the second position.
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Accused Products
Abstract
A generator system in accordance with the invention has two modes of operation, such as 120 VAC and 240/120 VAC modes of operation. The generator system has a permanent magnet generator with two independent sets of windings that each generate a three phase AC voltage. One three phase AC voltage is coupled to a first or master cycloconverter and the second three phase AC voltage is coupled to a second or slave cycloconverter. Live outputs of each cycloconverter are coupled to each other through a switch, such as a relay and neutral outputs of each cycloconverter are coupled to ground. A controller controls the cycloconverters to provide a first voltage, illustratively 120 VAC, across their respective outputs having the same amplitude. When in the 120 VAC mode, the switch across the live outputs of the first and second cycloconverters is closed, shorting the live outputs of the first and second cycloconverters together and the controller operates the first and second cycloconverters so their output voltages are in phase with each other. When in the 240/120 VAC mode, the switch across the live outputs of the first and second cycloconverters is open and the controller operates the first and second cycloconverters so that their output voltages are 180 degrees out of phase. The permanent magnet generator has rotor position sensors that are used by a brushless DC motor drive to drive the permanent magnet generator as a brushless DC motor to start the engine of the generator system and also to develop cosine wave information for use in controlling the cycloconverters.
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Citations
95 Claims
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1. A generator system having at least first and second modes, the generator system producing a first alternating current output voltage when in the first mode and producing the first alternating current output voltage and a second alternating current output voltage when in the second mode, the second output voltage being twice the first output voltage, comprising:
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first and second voltage sources each having an output at which they produce the first output voltage; and a switch coupling the outputs of the first and second voltage sources in parallel when the switch is in a first position and in series when the switch is in a second position, the first output voltage produced at the outputs of the first and second voltage sources when the switch is in the first position and the second output voltage produced across the series coupled outputs of the first and second voltage sources when the switch is in the second position with the first output voltage also produced at the outputs of the first and second voltage sources when the switch is in the second position. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38)
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39. A generator system, comprising:
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an AC generator having an output coupled to a cycloconverter, the cycloconverter having a positive bank of naturally commutated switching devices and a negative bank of naturally commutated switching devices; a controller coupled to the naturally commutated switching devices of the positive and negative banks; a rotor position sensor for sensing the position of a rotor of the generator and generating a signal indicative of the position of the rotor, the rotor position sensor coupled to the controller; and the controller using the rotor position signal to develop control waves which it uses to control switching of the naturally commutated switching devices of the positive and negative banks. - View Dependent Claims (40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57)
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58. A generator system, comprising:
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an AC generator having an output coupled to a cycloconverter, the cycloconverter having a positive bank of naturally commutated switching devices and a negative bank of naturally commutated switching devices; a controller coupled to the naturally commutated switching devices of the positive and negative banks; the controller operating the positive and negative banks in a non-circulating mode, the controller enabling one of the positive and negative banks and disabling the other of the positive and negative banks based on the instantaneous output current of the cycloconverter; and a bandpass filter for filtering the instantaneous output current of the cycloconverter to reduce current ripple and ensure that a signal output by the bandpass filter at a fundamental frequency does not have any phase shift relative to the instantaneous output current, the signal output by the band pass filter coupled to an input of a comparator that generates a signal indicative of whether the instantaneous output current has transitioned from positive to negative or from negative to positive. - View Dependent Claims (59, 60, 61)
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62. A generator system, comprising:
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an AC generator having an output coupled to a cycloconverter, the cycloconverter having a positive bank of naturally commutated switching devices and a negative bank of naturally commutated switching devices; and each naturally commutated switching device including a silicon controlled rectifier/opto-silicon controlled rectifier combination.
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63. A method of controlling a generator system having at least first and second modes where the generator system produces a first alternating current output voltage when it is in the first mode and produces the first output voltage and a second alternating current output voltage when it is in the second mode, the second output voltage twice the first output voltage, comprising:
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coupling the outputs of the first and second voltage sources in parallel and operating the first and second voltage sources so that the voltages at the outputs of the first and second voltage sources are in phase when the generator system is in the first mode; and coupling the outputs of the first and second voltage sources in series and operating the first and second voltage sources so that the voltages at the outputs of the first and second voltage sources are one-hundred and eighty degrees out of phase when the generator system is in the second mode with the second output voltage produced across the series coupled outputs of the first and second voltage sources and the first output voltage produced at each of the outputs of the first and second voltage sources. - View Dependent Claims (64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78)
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- 79. A method of controlling a generator system having an AC generator with an output coupled to a cycloconverter, the cycloconverter having a positive bank of naturally commutated switching devices and a negative bank of naturally commutated switching devices, the method comprising developing control waves based upon the position of a rotor of the AC generator and using the control waves to control switching of the naturally commutated switching devices.
- 90. A method of controlling a generator system having an AC generator with an output coupled to a cycloconverter, the cycloconverter having a positive bank of naturally commutated switching devices and a negative bank of naturally commutated switching devices, the method comprising operating the positive and negative banks of the cycloconverter in a non-circulating mode and enabling one of the positive and negative banks and disabling the other of the positive and negative banks based on the instantaneous output current of the cycloconverter produced at an output of the cycloconverter transitioning between positive and negative or between negative and positive, and bandpass filtering the instantaneous output current of the cycloconverter to produce a filtered signal to reduce current ripple and ensure that a fundamental frequency component of the filtered signal does not have any phase-shift relative to the instantaneous output current, and comparing the filtered signal to at least one reference level to determine whether the instantaneous output current transitioned from positive to negative or from negative to positive.
Specification