Creep life management system for a turbine engine and method of operating the same
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01M-015/14
F01D-017/04
F01D-021/00
출원번호
US-0585194
(2012-08-14)
등록번호
US-9494490
(2016-11-15)
발명자
/ 주소
Tralshawala, Nilesh
Miller, Harold Edward
Badami, Vivek Venugopal
Vittal, Sameer
Sexton, Daniel White
출원인 / 주소
General Electric Company
대리인 / 주소
Armstrong Teasdale LLP
인용정보
피인용 횟수 :
2인용 특허 :
3
초록▼
A creep life management system includes at least one sensor apparatus coupled to a first component. The at least one sensor apparatus is configured with a unique identifier. The creep life management system also includes at least one reader unit coupled to a second component. The at least one reader
A creep life management system includes at least one sensor apparatus coupled to a first component. The at least one sensor apparatus is configured with a unique identifier. The creep life management system also includes at least one reader unit coupled to a second component. The at least one reader unit is configured to transmit an interrogation request signal to the at least one sensor apparatus and receive a measurement response signal transmitted from the at least one sensor apparatus. The creep life management system further includes at least one processor programmed to determine a real-time creep profile of the first component as a function of the measurement response signal transmitted from the at least one sensor apparatus.
대표청구항▼
1. A method of operating a turbine engine, the turbine engine including a plurality of rotatable components, at least one stationary component, and a creep life management system including a processor, an alarm component, a first portion coupled to the plurality of rotatable components, thereby defi
1. A method of operating a turbine engine, the turbine engine including a plurality of rotatable components, at least one stationary component, and a creep life management system including a processor, an alarm component, a first portion coupled to the plurality of rotatable components, thereby defining a plurality of first portions, and a second portion coupled to the at least one stationary component, said method comprising: rotating the plurality of rotatable components with respect to the at least one stationary component;interrogating each respective first portion of the plurality of first portions by the second portion;transmitting from each respective first portion of the plurality of first portions a response signal in response to the interrogation by the second portion, wherein each respective response signal is representative of a measurement value of a respective rotatable component of the plurality of rotatable components;receiving each respective response signal at the second portion;determining, using the processor, a unique creep profile for each respective rotatable component of the plurality of rotatable components that is at least partially based on the respective response signal;determining, using the processor, a real-time remaining useful life (RUL) estimation for each respective rotatable component as a function of the response signal transmitted from each respective first portion;comparing, using the processor each RUL estimation for each respective rotatable component to each other to determine a prioritized order of maintenance activities for the plurality of rotatable components;receiving at the alarm component an alert signal transmitted by the processor, the alert signal related to at least one response signal transmitted from the plurality of sensor apparatuses; andperforming an alert action, by the alarm component, in response to receiving the alert signal from the processor. 2. The method in accordance with claim 1, wherein determining, using the processor, a unique creep profile for each respective rotatable component comprises: determining the measurement value of at least one of a temperature, a strain, and a creep rate for each respective rotatable component of the plurality of rotatable components in real-time from the response signal; anddetermining a stage of creep for each respective rotatable component of the plurality of rotatable components from the measurement value. 3. The method in accordance with claim 2, wherein performing an alert action comprises alerting an operator when a real-time measurement value of at least one of the plurality of rotatable components at least one of approaches a predetermined value, attains the predetermined value, and exceeds the predetermined value. 4. The method in accordance with claim 3 further comprising facilitating operation of a condition-based maintenance system by at least one of: directing an operator of the turbine engine to increase monitoring of the plurality of rotatable components via the creep life management system; anddirecting an operator of the turbine engine to schedule an inspection of the plurality of rotatable components. 5. The method in accordance with claim 1, wherein determining, using the processor, a real-time remaining useful life (RUL) estimation comprises determining real-time component cumulative damage using component temperature and strain history. 6. The method in accordance with claim 5, wherein determining, using the processor, and real-time RUL estimation comprises: comparing each RUL estimation for each first component of the plurality of first components to at least one predetermined RUL parameter, thereby at least partially determining a prioritized order of maintenance activities for the plurality of first components; anddisplaying to an operator a comparative operational history of the plurality of rotatable components, thereby facilitating identification of operating conditions that facilitate extensions of a useful life of the plurality of first components. 7. The method in accordance with claim 1, wherein determining, using the processor, a unique creep profile comprises determining at least one of a historical temperature profile, a historical strain profile, and a historical creep profile for each respective rotatable component of the plurality of rotatable components. 8. The method in accordance with claim 1 further comprising: importing at least one of a historical temperature profile, a historical strain profile, a historical creep profile, and an RUL estimation for the plurality of rotatable components into at least one physics-based model of the turbine engine; andat least one of enhancing and calibrating the at least one physics-based model. 9. A creep life management system for a turbine engine, said system comprising: a plurality of sensor apparatuses, each respective sensor apparatus of said plurality of sensor apparatuses coupled to a respective rotatable component of a plurality of rotatable components of the turbine engine, wherein said each respective sensor apparatus comprises a unique identifier;at least one reader unit coupled to a stationary component of the turbine engine, said at least one reader unit configured to transmit an interrogation request signal to said each respective sensor apparatus and receive a measurement response signal transmitted from said each respective sensor apparatus;an alarm component, andat least one processor programmed to: determine a real-time creep profile for each respective rotatable component as a function of the measurement response signal transmitted from said each respective sensor apparatus;determine a real-time remaining useful life (RUL) estimation for each respective rotatable component as a function of the measurement response signal transmitted from said each respective sensor apparatus; andcompare each RUL estimation for each respective rotatable component to each other to determine a prioritized order of maintenance activities for the plurality of rotatable components,wherein said alarm component is configured to: receive from said at least one processor an alert signal related to at least one measurement response signal transmitted from said plurality of sensor apparatuses; andperform an alert action in response to receiving the alert signal from the at least one processor. 10. The creep life management system in accordance with claim 9, wherein said at least one processor programmed to determine a real-time creep profile is programmed to determine at least one of a historical temperature profile, a historical strain profile, and a historical creep profile for at least one of the plurality of rotatable components. 11. The creep life management system in accordance with claim 9, wherein said alarm component configured to perform an alert action in response to receiving the alert signal from the at least one processor is configured to alert an operator when a measured real-time strain value of at least one of the plurality of rotatable components at least one of approaches a predetermined value, attains the predetermined value, and exceeds the predetermined value. 12. The creep life management system in accordance with claim 9, wherein said at least one processor is further programmed to: compare each RUL estimation for each rotatable component of the plurality of rotatable components to at least one predetermined RUL parameter. 13. The creep life management system in accordance with claim 9 further comprising at least one of: a first plurality of antennas coupled to said at least one reader unit; anda plurality of sensor apparatus comprising a second plurality of antennas, wherein each of said first plurality of antennas and said second plurality of antennas are positioned such that:a distance between each of said first plurality of antennas is at least one of:at least ¼ of one wavelength; andat least a spatial coherence distance associated with a wireless channel defined by at least one of said first plurality of antennas and at least one of said second plurality of antennas; anda distance between each of said second plurality of antennas is at least one of:at least ¼ of one wavelength; andat least a spatial coherence distance associated with the wireless channel defined by said at least one of said first plurality of antennas and at least one of said second plurality of antennas. 14. The creep life management system in accordance with claim 9, wherein: said plurality of sensor apparatuses and said at least one reader unit are coupled in wireless communication; andsaid each respective sensor apparatus comprises at least one of a strain measurement sensor and a temperature measurement sensor. 15. The creep life management system in accordance with claim 1, wherein said at least one processor is further programmed to determine a real-time component cumulative damage using component temperature and strain history. 16. A turbine engine comprising: a plurality of rotatable components;at least one stationary component; anda creep life management system comprising: a plurality of sensor apparatuses, each respective sensor apparatus of said plurality of sensor apparatuses coupled to a respective rotatable component of said plurality of rotatable components, wherein said each respective sensor apparatus comprises a unique identifier;at least one reader unit coupled to said at least one stationary component, said at least one reader unit configured to transmit an interrogation request signal to said each respective sensor apparatus and receive a measurement response signal transmitted from said each respective sensor apparatus;an alarm component; andat least one processor programmed to: determine a real-time creep profile for each respective rotatable component as a function of the measurement response signal transmitted from said each respective sensor apparatus;determine a real-time remaining useful life (RUL) estimation for each respective rotatable component as a function of the measurement response signal transmitted from said each respective sensor apparatus; andcompare each RUL estimation for each respective rotatable component to each other to determine a prioritized order of maintenance activities for the plurality of rotatable components,wherein said alarm component is configured to: receive from said at least one processor an alert signal related to at least one measurement response signal transmitted from said plurality of sensor apparatuses; andperform an alert action in response to receiving the alert signal from the at least one processor. 17. The turbine engine in accordance with claim 16, wherein: said each respective sensor apparatus comprises a sensor antenna; andsaid at least one reader unit comprises a plurality of reader antennas, wherein each respective reader antenna is communicatively coupled to one or more of each said sensor antenna in one of a one-to-many relationship and a one-to-one relationship. 18. The turbine engine in accordance with claim 16, wherein: said each respective sensor apparatus comprises a sensor antenna; andsaid at least one reader unit comprises one reader antenna, wherein said reader antenna is communicatively coupled to each said sensor antenna in a one-to-many relationship. 19. The turbine engine in accordance with claim 16, wherein: said each respective sensor apparatus of said plurality of sensor apparatuses are coupled to said at least one reader unit in wireless communication; andsaid each respective sensor apparatus of said plurality of sensor apparatuses comprises at least one of a strain measurement sensor and a temperature measurement sensor. 20. The turbine engine in accordance with claim 16, wherein said plurality of sensor apparatuses and said plurality of rotatable components are positioned within at least one of a compressor section and a turbine section of said turbine engine.
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이 특허에 인용된 특허 (3)
Kulkarni,Anand A.; Subramanian,Ramesh, Electrical assembly for monitoring conditions in a combustion turbine operating environment.
Tollison, Brian Lee; Kottilingam, Srikanth Chandrudu; Cui, Yan; Germann, Bryan Joseph, Methods of forming a passive strain indicator on a preexisting component.
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