Voltage control of an HR-PMG without a rotor position sensor
First Claim
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1. An electrical power generation system comprising:
- an electric power source adapted for providing AC power;
a power converter connected to said electric power source;
a position estimator receiving a current feedback signal in Park vector format and providing a synchronous reference frame; and
a controller configured to provide a voltage command for controlling said power converter, said controller receiving said current feedback signal and a current reference in Park vector format and using said synchronous reference frame, said current feedback signal, and said current reference to produce said voltage command.
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Abstract
An electrical power system includes an electric power source, for example, an electrical machine, capable of supplying AC power to a load; a power converter connected to the electric power source; a position estimator for receiving a current feedback signal in Park vector format and providing a synchronous reference frame without the need, for example, of a rotor position sensor in the electrical machine; and a controller configured to provide a voltage command for controlling the power converter, the controller receiving the current feedback signal and a current reference in Park vector format and using the synchronous reference frame, the current feedback signal, and the current reference to produce the voltage command.
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Citations
24 Claims
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1. An electrical power generation system comprising:
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an electric power source adapted for providing AC power;
a power converter connected to said electric power source;
a position estimator receiving a current feedback signal in Park vector format and providing a synchronous reference frame; and
a controller configured to provide a voltage command for controlling said power converter, said controller receiving said current feedback signal and a current reference in Park vector format and using said synchronous reference frame, said current feedback signal, and said current reference to produce said voltage command. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10)
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11. An electrical power system comprising:
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an electric power source comprising a high reactance generator adapted for providing AC power;
a power converter connected to said electric power source;
a plurality of current sensors, said plurality of current sensors disposed for sensing an AC current between said electric power source and said power converter, and for providing a current feedback signal;
a position estimator receiving said current feedback signal in Park vector format and providing a synchronous reference frame, wherein said position estimator comprises;
a multiplier configured to multiply said current feedback signal in Park vector format by a negative estimate of a transformation angle θ
in Park vector format to provide a synchronous frame signal;
a PI-regulator configured to regulate said synchronous frame signal compared to zero to provide an estimated electrical frequency; and
an integrator configured to integrate said estimated electrical frequency so as to provide said negative estimate of said transformation angle θ
to said multiplier and to provide said transformation angle θ
to said controller, whereby said position estimator provides said synchronous reference frame to said controller;
a controller configured to provide a voltage command for controlling said power converter, said controller receiving said current feedback signal and a current reference in Park vector format and using said synchronous reference frame, said current feedback signal, and said current reference to produce said voltage command; and
a space vector modulation module, said space vector modulation module receiving said voltage command and providing control signals to said power converter. - View Dependent Claims (12, 13, 14, 15, 16, 17)
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18. An electrical power system comprising:
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an electric power source comprising a high reactance permanent magnet generator adapted for providing AC power at varying power factors;
a power converter connected to said electric power source;
a plurality of current sensors, said plurality of current sensors disposed for sensing an AC current between said electric power source and said power converter, and for providing a current feedback signal;
a position estimator receiving said current feedback signal in Park vector format and providing a synchronous reference frame, wherein said position estimator comprises;
a multiplier configured to multiply said current feedback signal in Park vector format by a negative estimate of a transformation angle θ
in Park vector format to provide a synchronous frame signal;
a first PI-regulator configured to regulate said synchronous frame signal compared to zero to provide an estimated electrical frequency; and
an integrator configured to integrate said estimated electrical frequency so as to provide said negative estimate of said transformation angle θ
to said multiplier and to output said transformation angle θ
, whereby said position estimator provides said synchronous reference frame;
a DC link voltage sensor for sensing a DC link voltage output of said power converter and providing a DC link voltage feed back signal;
a first comparator receiving said DC link voltage feed back signal and a DC link voltage command signal, and producing a DC link voltage error signal;
a second PI-regulator regulating said DC link voltage error signal to produce a DC link voltage angle component, wherein a current reference comprises an angle component and an amplitude component and said angle component of said current reference comprises said DC link voltage angle component and whereby said electrical power system controls said DC link voltage output of said power converter;
a current sensor disposed for sensing a DC current output of said power converter and providing a load current signal;
a feedforward function module configured to receive said load current signal and produce a feedforward angle component;
a combiner configured to combine said DC link voltage angle component and said feedforward angle component so that said angle component of said current reference comprises said feedforward angle component whereby a gain sensitivity of said angle component of said current reference is minimized;
a non-linear function generator configured to receive said load current signal and produce said amplitude component of said current reference, whereby said controller controls said DC current output of said power converter;
a controller configured to provide a voltage command for controlling said power converter, said controller receiving said current feedback signal and said current reference in Park vector format and using said synchronous reference frame, said current feedback signal, and said current reference to produce said voltage command, wherein said controller comprises;
a first conversion block for providing said current feedback signal in Park vector format in said synchronous reference frame;
a second conversion block for providing said current reference in Park vector format in said synchronous reference frame;
a second comparator using said current feedback signal and said current reference in said synchronous reference frame to provide a command; and
a third PI-regulator regulating said command to produce said voltage command; and
a space vector modulation module, said space vector modulation module receiving said voltage command and providing control signals to said power converter.
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19. A method for electrical power generation comprising steps of:
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supplying electric power from an electric power source comprising a high reactance generator adapted for providing AC power, wherein said electric power source is connected to a power converter;
sensing an AC current between said electric power source and said power converter using a plurality of current sensors to provide a current feedback signal;
using said current feedback signal in Park vector format to provide a synchronous reference frame by performing steps of;
receiving said current feedback signal in Park vector format;
multiplying said current feedback signal in Park vector format by a negative estimate of a transformation angle θ
in Park vector format to provide a synchronous frame signal;
regulating said synchronous frame signal compared to zero with a PI-regulator to provide an estimated electrical frequency; and
integrating said estimated electrical frequency so as to provide said negative estimate of said transformation angle θ
in the above step of multiplying and to provide said transformation angle θ
, whereby said synchronous reference frame is provided; and
controlling said power converter by using said synchronous reference frame, said current feedback signal, and a current reference to produce a voltage command and feeding said voltage command through a space vector modulation module to provide control signals to said power converter. - View Dependent Claims (20, 21, 22, 23, 24)
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Specification
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Current AssigneeHoneywell International Inc.
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Original AssigneeHoneywell International Inc.
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InventorsHuggett, Colin, Kalman, Gabor
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Granted Patent
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Time in Patent OfficeDays
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Field of Search
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US Class Current322/24
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CPC Class CodesH02P 2101/30 for aircraftH02P 9/00 Arrangements for controllin...H02P 9/009 Circuit arrangements for de...
