Uninterruptible power supplies for use in a distributed network
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H02J-007/00
H02J-009/00
H02J-009/06
H01M-010/44
G01R-031/36
G06F-019/00
H02H-003/00
H02B-001/20
H02J-001/00
H02B-013/02
H01M-010/48
H01M-010/42
출원번호
US-0352317
(2012-01-17)
등록번호
US-9312726
(2016-04-12)
발명자
/ 주소
Heidenreich, James Joseph
Roybal, Ronald Jay
Le, Thanh Quoc
Bhatt, Pankaj H.
출원인 / 주소
Alpha Technologies Inc.
대리인 / 주소
Schacht, Michael R.
인용정보
피인용 횟수 :
3인용 특허 :
69
초록▼
A UPS module configured to be arranged between at least one AC line and a communications system comprising at least one load comprises a power system, a diagnostic system, and a communications module. The power system comprising a battery module, an inverter module, and a transformer module and is o
A UPS module configured to be arranged between at least one AC line and a communications system comprising at least one load comprises a power system, a diagnostic system, and a communications module. The power system comprising a battery module, an inverter module, and a transformer module and is operatively connected between the AC line and the at least one load. The diagnostic system generates battery diagnostic information, inverter diagnostic, utility diagnostic information, and transformer diagnostic information. The communications module transfers diagnostic information between the diagnostic system and the communications system.
대표청구항▼
1. A UPS module configured to be arranged between a utility power supply supplying a utility power signal and a cable television system comprising at least one load, comprising: a power system comprising a battery module, an inverter module, and a transformer module, where the power system is operat
1. A UPS module configured to be arranged between a utility power supply supplying a utility power signal and a cable television system comprising at least one load, comprising: a power system comprising a battery module, an inverter module, and a transformer module, where the power system is operatively connected between the utility power supply and the at least one load such that when the utility power signal is within predetermined line parameters, the power system operates in a line mode to supply power from the utility power supply to the at least one load through the transformer module, andsupply power from the utility power supply to the battery module through the transformer module and the inverter module, andwhen the utility power signal is not within predetermined line parameters, the power system in a standby mode to supply power from the battery module to the at least one load through the inverter module and the transformer module;a diagnostic system comprising a battery diagnostic module configured to generate battery diagnostic information based on at least one operating characteristic of at least one element of the battery module, where the battery diagnostic information comprises current status information indicative of performance of the battery module if the power system is operated in the standby mode when the battery diagnostic information is generated, andprojected status information indicative of projected performance of the battery module should the power system be operated in standby mode at some point in time after the diagnostic information is generated,an inverter diagnostic module configured to generate inverter diagnostic information based on at least one operating characteristic of at least one element of the inverter module, where the inverter diagnostic information is indicative of mean time between failure of the inverter module,a utility diagnostic module configured to generate utility diagnostic information based on at least one operating characteristic of at least one element of the utility power signal supplied by the utility power supply, anda transformer diagnostic module configured to generate transformer diagnostic information based on at least one operating characteristic of at least one element of the transformer module, where the transformer diagnostic information is indicative of mean time between failure of the transformer module; anda communications module operatively connected between the diagnostic module and the communications system to transfer battery diagnostic information, inverter diagnostic information, utility diagnostic information, and transformer diagnostic information between the diagnostic system and the cable television system. 2. The UPS module as recited in claim 1, in which the battery diagnostic module generates the battery diagnostic information based on at least one of voltage, current, internal battery temperature, ambient temperature, charge times, and discharge times associated with the battery module. 3. The UPS module as recited in claim 1, in which the inverter diagnostic module generates the inverter diagnostic information based on a temperature within the inverter module associated with an electrolytic capacitor within the inverter module. 4. The UPS module as recited in claim 1, in which the inverter diagnostic module generates the inverter diagnostic information based on an average daily temperature within the inverter module. 5. The UPS module as recited in claim 4, in which the inverter diagnostic information is at least partly expressed as inverter age in days. 6. The UPS module as recited in claim 5, in which: if the average daily temperature is greater than or equal to a baseline temperature, the inverter age in days is equal to an accumulated age in days of a last sample+2^[(sample temp−baseline temperature)/10]; andif the average daily temperature is less than the baseline temperature, the inverter age in days is equal to the accumulated age in days of the last sample plus 1 day. 7. The UPS module as recited in claim 1, in which the utility diagnostic module that generates the utility diagnostic information based on at least one of line surges, line sags, line outages, and line frequency deviation. 8. The UPS module as recited in claim 1, in which the transformer diagnostic module that generates the transformer diagnostic information based on a temperature of a resonant capacitor within the transformer module. 9. The UPS module as recited in claim 8, in which the inverter diagnostic module generates the transformer diagnostic information based on a temperature profile of the resonant capacitor. 10. A method of providing uninterruptible power to at least one load of a cable television system from utility power signal supplied by a utility power supply, the method comprising the steps of: providing a power system comprising a battery module, an inverter module, and a transformer module;arranging the power system between the utility power supply and the at least one load;when the utility power signal is within predetermined line parameters, operating the power system in a line mode to supply power from the utility power supply to the at least one load through the transformer module, andsupply power from the utility power supply to the battery module through the transformer module and the inverter module;when the utility power signal is not within predetermined line parameters, operating the power system to supply power from the battery module to the at least one load through the inverter module and the transformer module;generating battery diagnostic information based on at least one operating characteristic of at least one element of the battery module, where the battery diagnostic information comprises current status information indicative of performance of the battery module if the power system is operated in the standby mode when the battery diagnostic information is generated, andprojected status information indicative of projected performance of the battery module should the power system be operated in standby mode at some point in time after the diagnostic information is generated;generating inverter diagnostic information based on at least one operating characteristic of at least one element of the inverter module, where the inverter diagnostic information is indicative of mean time between failure of the inverter module;generating utility diagnostic information based on at least one operating characteristic of at least one element of the utility power signal supplied by the utility power supply;generating transformer diagnostic information based on at least one operating characteristic of at least one element of the transformer module, where the transformer diagnostic information is indicative of mean time between failure of the transformer module; andtransferring the battery diagnostic information, the inverter diagnostic information, the utility diagnostic information, and the transformer diagnostic information between the diagnostic module and the cable television system. 11. The method as recited in claim 10, in which the battery diagnostic information is generated based on at least one of voltage, current, internal battery temperature, ambient temperature, charge times, and discharge times associated with the battery module. 12. The method as recited in claim 10, in which the inverter diagnostic information is generated based on a temperature within the inverter module associated with an electrolytic capacitor within the inverter module. 13. The method as recited in claim 10, in which the inverter diagnostic information is generated based on an average daily temperature within the inverter module. 14. The method as recited in claim 13, further comprising the steps of: if the average daily temperature is greater than or equal to a baseline temperature, calculating an inverter age in days as an accumulated age in days of a last sample+2^[(sample temp−baseline temperature)/10]; andif the average daily temperature is less than the baseline temperature, calculating the inverter age in days as the accumulated age in days of the last sample plus 1 day. 15. The method as recited in claim 10, in which the utility diagnostic information is generated based on at least one of line surges, line sags, line outages, and line frequency deviation. 16. The method as recited in claim 10, in which the transformer diagnostic information is generated based on a temperature of a resonant capacitor within the transformer module. 17. The method as recited in claim 16, in which the inverter diagnostic information is generated based on a temperature profile of the resonant capacitor. 18. A UPS module configured to be arranged between a utility power supply supplying a utility power signal and a cable television system comprising at least one load, comprising: a power system comprising a battery module, an inverter module, and a transformer module, where the power system is operatively connected between the utility power supply and the at least one load such that when the utility power signal is within predetermined line parameters, the power system operates in a line mode to supply power from the utility power supply to the at least one load through the transformer module, andsupply power from the utility power supply to the battery module through the transformer module and the inverter module, andwhen the utility power signal is not within predetermined line parameters, the power system in a standby mode to supply power from the battery module to the at least one load through the inverter module and the transformer module;a diagnostic system comprising a battery diagnostic module configured to generate battery diagnostic information based on at least one of voltage, current, internal battery temperature, ambient temperature, charge times, and discharge times associated with the battery module, where the battery diagnostic information comprises current status information indicative of performance of the battery module if the power system is operated in the standby mode when the battery diagnostic information is generated, andprojected status information indicative of projected performance of the battery module should the power system be operated in standby mode at some point in time after the diagnostic information is generated,an inverter diagnostic module configured to generate inverter diagnostic information based on a temperature within the inverter module associated with an electrolytic capacitor within the inverter module, where the inverter diagnostic information is indicative of mean time between failure of the inverter module,a utility diagnostic module configured to generate utility diagnostic information based on at least one of line surges, line sags, line outages, and line frequency deviation of utility power signal supplied by the utility power supply, anda transformer diagnostic module configured to generate transformer diagnostic information based on a temperature of a resonant capacitor within the transformer module, where the transformer diagnostic information is indicative of mean time between failure of the transformer module; anda communications module operatively connected between the diagnostic module and the communications system to transfer battery diagnostic information, inverter diagnostic information, utility diagnostic information, and transformer diagnostic information between the diagnostic system and the cable television system. 19. The UPS module as recited in claim 18, in which: if the average daily temperature is greater than or equal to a baseline temperature, an inverter age in days is equal to an accumulated age in days of a last sample+2^[(sample temp−baseline temperature)/10]; andif the average daily temperature is less than the baseline temperature, the inverter age in days is equal to the accumulated age in days of the last sample plus 1 day. 20. The UPS module as recited in claim 18, in which the inverter diagnostic module generates the transformer diagnostic information based on a temperature profile of the resonant capacitor.
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