IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
US-0094222
(2005-03-31)
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등록번호 |
US-7368836
(2008-05-06)
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발명자
/ 주소 |
- Kammeter,John B.
- Stant,Vernon Lee
- Schlueter,Gregory Scott
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출원인 / 주소 |
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대리인 / 주소 |
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인용정보 |
피인용 횟수 :
0 인용 특허 :
9 |
초록
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A method and device for connecting a load to an AC power source is arranged to ensure that the volt-second ratings of magnetic devices in the load are not exceeded, in order to limit in-rush currents resulting from saturation of the magnetic devices. In the case where the load is being disconnected
A method and device for connecting a load to an AC power source is arranged to ensure that the volt-second ratings of magnetic devices in the load are not exceeded, in order to limit in-rush currents resulting from saturation of the magnetic devices. In the case where the load is being disconnected from a first AC source and connected to a second AC source, the volt-seconds of the load can be measured and/or calculated during disconnect, in order to delay connection of the load to the second AC source by an amount sufficient to prevent saturation of magnetic devices and thereby ensure volt-second synchronization of the sources.
대표청구항
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We claim: 1. A method of connecting a load to a source, comprising the steps of: determining delay intervals based on volt-second characteristics of a load; and connecting an AC source to the load following said delay intervals, wherein said load is disconnected from disconnecting source S1 and con
We claim: 1. A method of connecting a load to a source, comprising the steps of: determining delay intervals based on volt-second characteristics of a load; and connecting an AC source to the load following said delay intervals, wherein said load is disconnected from disconnecting source S1 and connected to connecting source S2 after said delay intervals, and wherein said volt-seconds are determined based on current and voltage measurements during disconnection of source S1 from said load, and wherein said volt-seconds are determined, for delay times Td1, Td2, and Td3, according to the equality VSd+VSc1+VSc2+VSc3=2*Aoc/Wc, where: Td1 is the delay from the load disconnection point to the reconnection in first �� cycle of the connecting source that occurs after disconnection; Td2 is the delay from the load disconnection to the reconnection in second �� cycle of the connecting source that occurs after disconnection; Td3 is the delay from the first cross over of the third �� cycle to the reconnection in third �� cycle of the connecting source that occurs after disconnection; VSc1=volt-seconds of the first �� cycle of the connecting source after load reconnection to the end of the �� cycle; VSc2=volt-seconds of the second �� cycle of the connecting source after load reconnection to the end of the �� cycle; VSc3=volt-seconds of the third �� cycle of the connecting source after load reconnection to the end of the �� cycle; Aoc=peak value, in volts, of the sine wave form of the connecting source; Wc=omega=2*(PI)*Foc; Foc=connecting source frequency; Aod=peak value, in volts, of the sine wave form of the disconnecting source; Wd=omega=2*(PI)*Fod; Fod=disconnecting source frequency. 2. A method as claimed in claim 1, wherein the step of determining the delay times comprises the step of determining the volt-seconds during the first half cycle before disconnection from a first AC source. 3. A method as claimed in claim 2, wherein a controller samples the �� cycle voltage wave from cross-over to time Tdis1 and then calculate the volt-seconds, as; VSd=volt-seconds=Tint*{ΣV1+. . . (V2+V3)/2+(Vn-1+Vn)/2}+Vsde, wherein: Tint=sampling interval in seconds; V1, V2. . . Vn=Sampled voltage amplitudes; VSde=The error due to measurement or calculation which is somewhere constant and can be stored by controller learning algorithms; the S1 volt-seconds must be normalized to S2 volt-seconds with respect to differences in Aox and Wx amplitudes; and VSdn=(Aoc/Aod)*(Fod/Foc)*VSd, where a. Aod=peak amplitude of the connecting source; b. Foc=Frequency of connecting source; and c. VSdn=normalized VSd. 4. A method as claimed in claim 1, wherein the step of determining the volt-seconds during the half cycle before disconnection comprises the steps of using current sensors to determine the direction of the current, voltage samples to measure Aod and Wd and the various time periods, and the following calculation of the volt-seconds VSd: VSd=Aod/Wd*(-cos (Wd*Finish time)+cos (Wd*start time)); Aod=the peak value, in volts, of the sine wave form of the disconnecting source; and Wd=omega=2*(pi)*Fod; and Fod=disconnecting source frequency. 5. A method as claimed in claim 4, wherein: VSd=Aod/Wd*(-cos (Wd*Tdis1)+cos (0))+VSde=Aod/Wd*(-cos (Wd*Tdis1)+1)+Vsde, and wherein: Tdis1=is the time from the initial �� cycle zero cross-over to the load disconnection point; VSde=the error due to measurement or calculation. 6. A method as claimed in claim 1, wherein connecting source S2 leads disconnecting source S1, the step of connecting source S2 comprises the step of gating semiconductor devices, and time delays for the first three half cycles of the load reconnection are calculated as follows: VSdn+VSc1-VSc2+VSc3=2*Aoc/Wc, where: VSc1=volt-seconds of the first �� cycle of the connecting source after load reconnection to the end of the �� cycle; VSc2=volt-seconds of the second �� cycle of the connecting source after load reconnection to the end of the �� cycle; VSc3=volt-seconds of the third �� cycle of the connecting source after load reconnection to the end of the �� cycle; Aoc=peak value, in volts, of the sine wave form of the connecting source; Wc=omega=2*(PI)*Foc; Foc=connecting source frequency. 7. A method as claimed in claim 6, wherein Wc=omega=2*(pi)*Foc, where Foc=connecting source frequency. 8. A method as claimed in claim 6, wherein VSdn, VSc1, nd VSc3 have the same sign and VSc2 has an opposite sign. 9. A method as claimed in claim 6, wherein Td1=0, so that semiconductors used to connect source S2 are gated on as quickly as possible after semiconductors used to connect source S1 are gated off. 10. A method as claimed in claim 6, wherein for values of Tdis1>=1/(2*Fod)-Tps, Td1 is ignored and VSc1=0, where Tps=(phase shift betw sources)/(2*PI()*Fo). 11. A method as claimed in claim 6, Td3=(1/Wc)*ACos [(Wc/Aoc)*(VSc3-1] and, to keep transition times short, Td3 should equal zero so that VSc3=2*Aoc/Wc. 12. A method as claimed in claim 6, wherein: VSc2=-[2*Aoc/Wc.]+{VSdn+VSc1+VSc3}; VSc2=Aod/Wd*(-cos(Wc*Tdis2)+cos(Wc*Tx)+2); and Tx=Tps+Tdis+Td2-0.5/Foc. 13. A method as claimed in claim 12, wherein Cos(Tdis2)=1 for all categories of semiconductor except those that remain conducting until pulses and/or level stops and an external mechanism reduces current flowing though the semi-conductor to a specified small value. 14. A method as claimed in claim 12, wherein Tx=(1/W2)*ACos[(W2/Ao2)*VSc2-2+cos(Wc*Tdis2 )], and Td2=Tx+0.5/Foc-Tps-Tdis. 15. A method as claimed in claim 1, wherein source S2 lags source S1, the step of connecting source S2 comprises the step of gating semiconductor devices, there is no reconnect in the first half cycle of the connecting source, and time delays Td1 and Td3 are assigned values to ensure no conduction in a first half cycle of source S2 and full conduction in a third half cycle of S2. 16. A method as claimed in claim 1, wherein, for low values of phase shift between source S1 and S2 and a high-speed connect-disconnect time, if the connecting source S2 lags the disconnecting source S1 by 15 degrees or less, a 2 to 4 millisecond transition time between disconnection and reconnection is applied. 17. A method as claimed in claim 1, wherein, for low values of phase shift between source S1 and S2 and a high-speed connect-disconnect time, if the connecting source S2 leads the disconnecting source S1 by 8 degrees or less, a 2 to 4 millisecond transition time between disconnection and reconnection is applied. 18. A method as claimed in claim 1, wherein the step of connecting source S2 comprises the step of controlling electro-mechanical switching devices capable of disconnecting from source S1 for a predetermined length of time, holding the load disconnected for said time intervals, and then reconnecting to source S2, and wherein said controller is arranged to store device parameters so that disconnect and reconnect times can be predicted. 19. A method as claimed in claim 18, wherein the following parameters are recorded and stored for each disconnect and reconnect period: Applied connect and disconnect voltage; Temperature; Number of disconnects and reconnects; and Power factor of the load. 20. A method as claimed in claim 18, wherein if the connecting source lags the disconnecting source, Td2=N+Tps, where N=an integer>= the number of S2 cycles required to reconnect the load and the controller predicts N based on measured parameters. 21. A method as claimed in claim 18, wherein if the connecting source leads the disconnecting source, Td2=N+Tps+(1/fc)-(2*Tdis1), where N=an integer>=the number of S2 cycles required to reconnect the load, and the controller predicts N based on measured parameters. 22. A method as claimed in claim 18, wherein a controller calculates or refers to a look-up table to determine the delay for each cycle from the first full cycle after reconnect is initiated until the load is fully reconnected after the twentieth cycle. 23. A method of connecting a load to a source, comprising the steps of: determining delay intervals based on volt-second characteristics of a load; and connecting an AC source to the load following said delay intervals, wherein when a magnetic device is randomly disconnected from a source without any knowledge of the applied volt-seconds before disconnection, minimization of the in-rush current is accomplished by: reconnection of the load to the source so that there is only 5% of the rated cycle volt-seconds applied for the first two �� cycles; after the first two �� cycles, 5% more volt-seconds are added for each subsequence two �� cycles; and after 20 cycles (40 �� cycles) the applied volt-seconds will be 100. 24. A method as claimed in claim 23, wherein VSrs=Aoc/Wc*(-cos (Finish time)+cos (start time)), and: VSrs=volt-seconds of an �� cycle sine wave; Aoc=the peak value, in volts, of the sine wave form of the connecting source; Wc=omega=2*(pi)*Fc; Fc= connecting source frequency; and the finish time is 1/(2*Fc). 25. A method as claimed in claim 24, wherein VSrs=Aoc/Wc*(1+cos (Wc*Td)); Td=delay period from the start of the �� cycle; VSrs should be N*5%*2*Aoc/Wc; N ranges from 1 to 20 cycles; Td=1/Wc*ACos[N*0.1-1]; Td=1/Wc*ACos[-0.9]=7.136 Ms for the first cycle; Td=1/Wc*ACos (1.8-1)=1.70 Ms for the eighteenth cycle; and Td=0 for the twentieth cycle. 26. A device for connecting a load to a source, comprising: means for determining delay intervals based on volt-second characteristics of a load; and means for connecting an AC source to the load following said delay intervals, wherein said load is disconnected from disconnecting source S1 and connected to connecting source S2 after said delay intervals, and wherein said volt-seconds are determined based on current and voltage measurements during disconnection of source S1 from said load, and wherein said volt-seconds are determined, for delay times Td1, Td2, and Td3, according to the equality VSd+VSc1+VSc2+VSc3=2*Aoc/Wc, where: Td1 is the delay from the load disconnection point to the reconnection in first �� cycle of the connecting source that occurs after disconnection; Td2 is the delay from the load disconnection to the reconnection in second �� cycle of the connecting source that occurs after disconnection; Td3 is the delay from the first cross over of the third �� cycle to the reconnection in third �� cycle of the connecting source that occurs after disconnection; VSc1=volt-seconds of the first �� cycle of the connecting source after load reconnection to the end of the �� cycle; VSc2=volt-seconds of the second �� cycle of the connecting source after load reconnection to the end of the �� cycle; VSc3=volt-seconds of the third �� cycle of the connecting source after load reconnection to the end of the �� cycle; Aoc=peak value, in volts, of the sine wave form of the connecting source; Wc=omega=2*(PI)*Foc; Foc=connecting source frequency; Aod=peak value, in volts, of the sine wave form of the disconnecting source; Wd=omega=2*(PI)*Fod; Fod=disconnecting source frequency.
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