IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0878418
(2007-07-24)
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등록번호 |
US-7450405
(2008-11-11)
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발명자
/ 주소 |
- Ponnaluri,Srinivas
- Serpa,Leonardo
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출원인 / 주소 |
|
대리인 / 주소 |
Buchanan Ingersoll & Rooney PC
|
인용정보 |
피인용 횟수 :
7 인용 특허 :
4 |
초록
▼
A method is disclosed for operating a converter circuit, with the converter circuit having a converter unit with a plurality of drivable power semiconductor switches and an LCL filter connected to each phase connection of the converter unit, in which the drivable power semiconductor switches are dri
A method is disclosed for operating a converter circuit, with the converter circuit having a converter unit with a plurality of drivable power semiconductor switches and an LCL filter connected to each phase connection of the converter unit, in which the drivable power semiconductor switches are driven by means of a drive signal which is formed from a hysteresis power value, from a hysteresis wattless-component value and from a selected flux sector. An apparatus for carrying out the method is also disclosed.
대표청구항
▼
What is claimed is: 1. A method for operating a converter circuit, with the converter circuit having a converter unit with a plurality of drivable power semiconductor switches and an LCL filter connected to each phase connection of the converter unit, in which the drivable power semiconductor switc
What is claimed is: 1. A method for operating a converter circuit, with the converter circuit having a converter unit with a plurality of drivable power semiconductor switches and an LCL filter connected to each phase connection of the converter unit, in which the drivable power semiconductor switches are driven by means of a drive signal which is formed from a hysteresis power value, from a hysteresis wattless-component value and from a selected flux sector, wherein the hysteresis power value is formed from a difference power value by means of a first hysteresis regulator, wherein the difference power value is formed from the subtraction of an estimated power value and of a damping power value from a reference power value, with the damping power value being formed from a sum, weighted by a variable damping factor, of a multiplication of an α component of the space vector transformation of filter capacitance currents (icfα) of the LCL filters by an α component of the space vector transformation of phase connection currents (ifiβ) and a multiplication of a β component of the space vector transformation of filter capacitance currents (icfβ) of the LCL filters by a β component of the space vector transformation of phase connection currents (ifiβ), wherein the hysteresis wattless component value is formed from a difference wattless component value by means of a second hysteresis regulator, wherein the difference wattless component value is formed from the subtraction of an estimated wattless component value and of a damping wattless component value from a reference wattless component value with the damping wattless component value being formed from a difference, weighted by the variable damping factor of a multiplication of the β component of the space vector transformation of filter capacitance currents (icfβ) of the LCL filters by the α component of the space vector transformation of phase connection currents (ifiα) and a multiplication of the α component of the space vector transformation of filter capacitance currents (icfα) of the LCL filters by the β component of the space vector transformation of phase connection currents (ifiβ). 2. The method as claimed in claim 1, wherein the estimated power value and the estimated wattless component are each formed from an α component of the space vector transformation of filter output currents (ifgα), from a β component of the space vector transformation of filter output currents (ifgβ), from an α component of the space vector transformation of filter output fluxes (ψLα) and from a β component of the space vector transformation of filter output fluxes (ψLβ). 3. The method as claimed in claim 2, wherein the α component of the space vector transformation of filter output fluxes (ψLα) is formed from an α component of the space vector transformation of estimated filter capacitance fluxes ((ψCfα) and from the α component of the space vector transformation of filter output currents (ifgα), and wherein the β component of the space vector transformation of filter output fluxes (ψLβ) is formed from a β component of the space vector transformation of estimated filter capacitance fluxes (ψCfβ) and from the β component of the space vector transformation of filter output currents (ifgβ). 4. The method as claimed in claim 3, wherein the α component of the space vector transformation of estimated filter capacitance fluxes (ψcfα) is formed from an instantaneous DC voltage value of a capacitive energy store connected to the converter unit, from the drive signal and from the α component of the space vector transformation of phase connection currents (ifiα), and wherein the β component of the space vector transformation of estimated filter capacitance fluxes (ψCfβ) is formed from the instantaneous DC voltage value (udc) of the capacitive energy store connected to the converter unit, from the drive signal and from the β component of the space vector transformation of phase connection currents (ifiβ). 5. The method as claimed in claim 3, wherein a compensation wattless component value is additionally added in order to form the difference wattless component value, with the compensation wattless component value being formed by low-pass filtering of an estimated filter capacitance wattless component value. 6. The method as claimed in claim 5, wherein the estimated filter capacitance wattless component value is formed from the α component of the space vector transformation of the filter capacitance currents (iCfα), from the β component of the space vector transformation of the filter capacitance currents (icfβ), from the α component of the space vector transformation of the estimated filter capacitance fluxes (ψCfα) and from the β component of the space vector transformation of the estimated filter capacitance fluxes (ψCfβ). 7. The method as claimed in claim 3, wherein at least one compensation harmonic power value relating to the fundamental of the filter output currents is additionally added in order to form the difference power value, and wherein at least one compensation harmonic wattless component value relating to the fundamental of the filter output currents is additionally added in order to form the difference wattless component value. 8. The method as claimed in claim 7, wherein the compensation harmonic power value and the compensation harmonic wattless component value are each formed from the α component of the space vector transformation of the filter output currents (ifgα), from the β component of the space vector transformation of the filter output currents (ifgβ), from the α component of the space vector transformation of the filter output fluxes (ψLα), and from the β component of the space vector transformation of the filter output fluxes (ψLβ), and from the fundamental angle relating to the fundamental of the filter output currents. 9. An apparatus for carrying out a method for operating a converter circuit, with the converter circuit having a converter unit with a plurality of drivable power semiconductor switches and an LCL filter connected to each phase connection of the converter unit, having a control device which is used for producing a hysteresis power value, a hysteresis wattless component value and a selected flux sector and is connected to the drivable power semiconductor switches via a drive circuit in order to form a drive signal, wherein the control device has a first calculation unit for forming the hysteresis power value, the hysteresis wattless component value and the selected flux sector, with the first calculation unit having a first hysteresis regulator for forming the hysteresis power value from a difference power value, a second hysteresis regulator for forming the hysteresis wattless component value from a difference wattless component value and a vector allocator for forming the selected flux sector, a first adder for forming the difference power value from the subtraction of an estimated power value and of a damping power value from a reference power value, a second adder for forming the difference wattless component value from the subtraction of an estimated wattless component value and of a damping wattless component value from a reference wattless component value, a second calculation unit for forming the damping power value and the damping wattless component value, with the damping power value being formed from a sum, weighted by a variable damping factor, of a multiplication of an α component of the space vector transformation of filter capacitance currents (icfα) of the LCL filters by an α component of the space vector transformation of phase connection currents (ifia), and a multiplication of a β component of the space vector transformation of filter capacitance currents (iCfβ) of the LCL filter by a β component of the space vector transformation of phase connection currents (ifiβ), and the damping wattless component value being formed from a difference, weighted by the variable damping factor, of a multiplication of the β component of the space vector transformation of filter capacitance currents (icfβ) of the LCL filters by the α component of the space vector transformation of phase connection currents (ifiα) and a multiplication of the α component of the space vector transformation of filter capacitance currents (iCfα) of the LCL filters by the β component of the space vector transformation of phase connection currents (ifiβ). 10. The apparatus as claimed in claim 9, wherein the control device has a third calculation unit for forming the estimated power value and the estimated wattless component value in each case from an α component of the space vector transformation of filter output currents (ifgα) from a β component of the space vector transformation of filter output currents (ifgβ), from an α component of the space vector transformation of filter output fluxes (ψLα) and from a β component of the space vector transformation of filter output fluxes (ψLβ). 11. The apparatus as claimed in claim 10, wherein the control device has a fourth calculation unit for forming the α component of the space vector transformation of filter output fluxes (ψLα) and the β component of the space vector transformation of filter output fluxes (ψLβ), with the α component of the space vector transformation of filter output fluxes (ψLα) being formed from an α component of the space vector transformation of estimated filter capacitance fluxes (ψCfα) and from the α component of the space vector transformation of filter output currents (ifgα), and with the β component of the space vector transformation of filter output fluxes (ψLβ) being formed from a β component of the space vector transformation of estimated filter capacitance fluxes (ψCfβ) and from the β component of the space vector transformation of filter output currents (ifgβ). 12. The apparatus as claimed in claim 11, wherein the control device has a fifth calculation unit for forming the α component of the space vector transformation of estimated filter capacitance fluxes (ψCfα) and the β component of the space vector transformation of estimated filter capacitance fluxes (ψCfβ) with the α component of the space vector transformation of estimated filter capacitance fluxes ((ψCfα) being formed from an instantaneous DC voltage value of a capacitive energy store connected to the converter unit, from the drive signal and from the α component of the space vector transformation of phase connection currents (ifiα), and with the β component of the space vector transformation of estimated filter capacitance fluxes (ψCfβ) being formed from the instantaneous DC voltage value of the capacitive energy store connected to the converter unit from the drive signal and from the β component of the space vector transformation of phase connection currents (ifiβ). 13. The apparatus as claimed in claim 11, wherein the second adder is additionally supplied with a compensation wattless component value in order to form the difference wattless component value, with the compensation wattless component value being formed by low-pass filtering of an estimated filter capacitance wattless component value by means of a low-pass filter. 14. The apparatus as claimed in claim 13, wherein the control device has a sixth calculation unit for forming the estimated filter capacitance wattless component value from the α component of the space vector transformation of the filter capacitance currents (iCfα), from the β component of the space vector transformation of the filter capacitance currents (iCfβ), from the α component of the space vector transformation of the estimated filter capacitance fluxes (ψCfα), and from the β component of the space vector transformation of the estimated filter capacitance fluxes (ψCFβ). 15. The apparatus as claimed in claim 11, wherein the first adder is additionally supplied with at least one compensation harmonic power value relating to the fundamental of the filter output currents in order to form the difference power value, and wherein the second adder is additionally supplied with at least one compensation harmonic wattless component value relating to the fundamental of the filter output currents in order to form the difference wattless component value. 16. The apparatus as claimed in claim 15, wherein the control device has a seventh calculation unit for forming the compensation harmonic power value and the compensation harmonic wattless component value in each case from the α component of the space vector transformation of the filter output currents (ifgα), from the β component of the space vector transformation of the filter output currents (ifgβ), from the α component of the space vector transformation of the filter output fluxes (ψLα), from the β component of the space vector transformation of the filter output fluxes (ψLβ), and from the fundamental angle relating to the fundamental of the filter output currents.
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