Method for Predicting the Life of Transformer based on Fiber Grating Temperature Measurement System

摘要

A method for predicting the life of a transformer includes: conducting a quasi-distributed description on an internal temperature of a transformer by using a fiber grating temperature measurement system; determining the position of an internal hottest spot of the transformer and conducting a life evaluation on an internal local region of the transformer; and according to the life loss of each position of the transformer, by combining the insulation characteristic of the transformer with the influence of the life of the position on the entire life of the transformer, predicting the life of the transformer scientifically and reasonably. The method can use the fiber grating temperature measurement system to calculate and evaluate the life loss of the internal insulation of the transformer and the rate of change thereof

主权项

1. A method for predicting the life of a transformer based on a fiber grating temperature measurement system, comprising the following steps:
1) providing a fiber grating temperature measurement system, wherein said fiber grating temperature measurement system comprises a transformer body, a terminal PC, a wavelength demodulator, a plurality of fiber grating sensors arranged inside said transformer body, and a wavelength demodulator comprising a broadband light source, a 3 dB coupler, an optical switch, a FP filter, a photoelectric conversion module, a sawtooth generator and a plurality of fibers; wherein in an operation process using said fiber grating temperature measurement system, light beams emitted by said broadband light source pass through said 3 dB coupler and then pass through said optical switch and then reach to each said fiber; each of said fibers is connected with said plurality of fiber grating sensors in series each having a different central reflection wavelength; wherein broadband light beams are reflected back as narrowband light beams of different peak wavelengths after projecting on each of the fiber grating sensors, and then said narrowband light beams enter into said FP filter and said photoelectric conversion module through said optical switch and said 3 dB coupler, so as to convert wavelength-encoded sensor signals into digital signals, and then said digital signals are send to said terminal PC for operation; wherein an internal temperature of said transformer body changes when said transformer body is working, and results in a change of to reflection wavelength of said fiber grating sensors; wherein at the same time, a single chip processor of said sawtooth generator provides a sawtooth voltage to a piezoelectric ceramics and changes a cavity length of said FP filter, so as to match with a wavelength of light beams passed through said FP filter; wherein when a wavelength of reflected light beams from said FP filter equals to a wavelength of reflected light beams from said fiber grating sensors, a photodetector outputs a maximum value, and a sweep voltage value of said piezoelectric ceramic is recorded; wherein a value of a scanning voltage and said wavelength of reflected light beams from said fiber grating at that time constitute a data pair; wherein according to a relationship of wavelength and temperature, after a change of wavelength is measured, a relative change of temperature is obtained, so as to achieve a purpose of temperature testing; and 2) recording locations of said fiber grating sensors during an arrangement process of said fiber grating temperature measurement system; wherein according to “GB 1094.7-2008 Power transformer—Part 7: guide rules for load of oil-immersed power transformers”, a six-degree principle is used to calculate an insulation aging rate in said transformer and to obtain a life loss thereof; wherein due to an influence on an operation of said transformer by insulation aging in different locations of an internal of said transformer are different, said life loss is corrected with respect to an internal insulation location of said transformer, so as to calculate said life loss of said transformer; wherein a relationship between aging rate and temperature is shown in the following table:Insulation of thermalInsulation of non-thermal-modifiedmodifiedθh (° C.)paper (V)paper (V)800.1250.036860.250.073920.50.145981.00.2821042.00.5361104.01.01168.01.8312216.03.2912832.05.813464.010.1140128.017.2 wherein during a certain period, said life loss of said transformer is L:L=∫t1t2Vt,orL=∑n=1NVn×tn; Wherein, Vn: relative aging rate of the n-th time interval: tn: a n-th time interval; n: an ordinal number of each time interval during the time being considered; N: a number of time interval of the time being considered; wherein said life loss of is transformer is: L′=max kL; Wherein a value of “k” is selected from the following table:leadingironpositionwirecoilcoreoil ductentrance of coolertop oilk value0.90.950.950.980.991 wherein a pointed assessment about an internal insulation aging degree of said transformer is given through this system, wherein based on a position of an internal partial insulation, an influence of said insulation aging degree at said position on said transformer is capable of being judged, so as to describe a life of said transformer scientifically and effectively.