Inernaional Conference on Advanced Maerial Science and Environmenal Engineering (AMSEE 06) Faul Diagnosis Sysem Idenificaion Based on Impedance Maching Balance ransformer Yanjun Ren* and Xinli Deng Chongqing Radio & V Universiy, Chongqing 40005, China *Corresponding auhor ha is high volage side is conneced ino a sar connecion, he low volage side is conneced ino riangle juncion and he iron core limb winding in B phase of low volage side exend supporing arms, called balance winding. From he figure, we can see ha he core limb in A phase and C phase of impedance maching ransformer winds wo windings and ha in B phase winds four windings. In accordance o he principle of he muli-winding ransformer circui, magneic circui and equivalen circui, he linear model of impedance maching balance ransformer in equaion () can be obained hrough a series of simplified processing [7]. In equaion (), K=/N and x is he shor circui reacance of high volage side, oher noaions see he reference [8]. Absrac Impedance maching balance ransformer is ofen used as he main elecrified railway racion subsaion ransformer. In order o solve he problem ha radiional faul diagnosis mehod could no accuraely idenify he inernal or exernal failure, i is proposed an idenificaion algorihm of recursive leas square parameer esimaion online o disinguish he inernal faul from exernal faul, which is based on ha he winding resisance and shor circui reacance values have no been changed in normal operaion for impedance maching balance ransformer or exernal faul, bu hey have been changed for inernal faul. he curves of simulaion proved ha he proposed algorihm could effecively disinguish inernal faul from exernal faul. he research resuls show he feasibiliy o idenify wo sors of differen fauls. Keywords-sysem idenificaion; impedance maching balance ransformer; faul diagnosis ia ua I. INRODUCION Impedance maching balance ransformer wih ransformaion and commuaion is he main elecrified railway racion subsaion ransformer[]. ransformer s sable operaion is direcly relaed o he safey of high-speed rail, so i is very imporan o accuraely disinguish possible faul ypes and design differen proecion devices[]. ransformers of elecrified railway power supply sysem work under poor condiions. Currenly, microcompuer proecion devices in operaion are almos designed based on he principle of differenial proecion. In general, i is difficul o disinguish o be inernal failure or exernal faul, which may lead o proecion ripping or malfuncion and hen endanger he safe operaion of elecrified railway sysem[3]. Based on ha he winding resisance and shor circui reacance values could no been changed in normal operaion for impedance maching balance ransformer or exernal faul while he winding resisance and shor circui reacance values would changed dramaically, he winding resisance and shor circui reacance values of ransformer could be online idenified[4]. By comparing he idenificaion values wih he normal parameer values, we can deermine wheher he impedance maching balance ransformer proecion acion is required[5]. II. ub u ib i ib i ub ia ua N u uc ic 3 N N 3 uc N N FIGURE I. HE WINDING OF IMPEDANCE MACHING BALANCE RANSFORMER From he equaion (), we can see ha ua, ub and uc are he volage values of hree phases a he high volage side. ia, ib and ic are he curren values of windings a he high volage side. u, u and i, i are he volage values and curren values of wo phases a he low volage side respecively, which are direcly reasured as he inpu and oupu of he ransformer s parameer idenificaion model. he winding resisance R and shor circui reacance x values a he high volage side as he parameers o be idenified can consiue he grey box model of sysem idenificaion, which can respecively consruc A, B and C phases idenificaion mahemaical models of impedance maching balance ransformer hrough discreizaion. his paper only wih A- phase winding for example analyses he relevan faul diagnosis. IDENIFICAION MAHEMAICAL MODEL OF IMPEDANCE MACHING BALANCE RANSFORMER Figure I shows he winding resisance of impedance maching balance ransformer[6]. According o he operaional principle of impedance maching balance ransformer, we know 06. he auhors - Published by Alanis Press 70
3 3 ua ub Ku RiA RiB R 3 3 x dia i i K 3 3 d 5 3x 6 3 3x di B di 8 3 d 4K d 7 4 3x di 4K d K R u B u u RiB i i 3 3 K d i i 3 3K 3 3 u C u B Ku RiC Ri B R 3 3 x dic i i K 3 3 d 5 3x 6 3 3x di B di 8 3 d 4K d 7 4 3x di 4K d x dib 5 7 3 3 x d K d For online real-ime deecion he winding resisance and shor reacance values of ransformer, winding parameer idenificaion model of ransformer A-phase is as follows. z A n 3 ua n ua n ub n ub n u n u n K ia n ia n ib n ib n h A n 3 3 i n i n 3 i n i n, 3K 3K ia A 5 3 B B n i n i n i n 8 3 6 3 3 i n in 7 4 3 i n in 4K 4K A Rx, () III. FAUI DIAGNOSIS MEHOD OF IMPEDANCE MACHING BALANCE RANSFORMER BASED ON RLS A. Forgeing Facor Algorihm of Recursive leas Square Parameer Esimaion he characerisics of he leas square echnique is direcly o use all he observed daa have been obained o compue and process[9]. herefore, he parameers of sysem model need o been re-esimaed if having he new observaion daa every ime, which means ha all he obained observed daa o esimae he parameers of he model needs o be sored. And he complexiy of solving he marix equaion ˆ ( H H ) H Z resuls in he difficulies of L L L L L L online idenificaion. he soluion of his problem is o be urned ino recursive leas square algorihm. he basic idea is as follows. ( k) = ( k ) + correcion erm (3) he characerisic of he mehod is o revise he las ime esimaed resuls wih new obained observaional daa and hen recursively esimae he nex ime parameer resuls[0]. However, here will be daa sauraion phenomenon as he increase of daa when he mehod applies o online real-ime idenificaion. In oher words, as he growh of k, gain marix K (k) will gradually ends o zero so ha i could no revise ( k). Forgeing facor mehod can solve daa sauraion phenomenon effecively. he basic idea is ha he old daa adds forgeing facor o reduce he amoun of old daa informaion and increase he amoun of new daa informaion. Forgeing facor recursive leas square algorihm is as equaion (4). ˆ ˆ ( k ) k K ( k )[ z( k ) h ( k ) ˆk ] K ( k ) P k h( k ) h ( k ) P k h k P ( k ) [ I K k h ( k )] P k (4) Where is forgeing facor, 0, is no usually less han 0.9. 0.95 will be seleced if he process is linear[]. he large forgeing facor will reduce he racking performance of he algorihm, and he sysem will be easily affeced by noise wih he small forgeing facor. B. he Process of Parameer Idenificaion and Iniial Value Selecion aking A-phase as an example, he process of parameer idenificaion can be analyzed by means of idenificaion model (4). According o he measured daa, A z n, A h n, A can be obained. Subsiuing recursive leas square algorihm equaion, we can idenify he parameers. Figure II shows he program flow diagram of he algorihm. In figure II 0 is he iniial value of idenificaion parameer, idenificaion parameer value a k is he hreshold. he simulaion program of algorihm can be wrien using MALAB[]. ik is he 7
o be idenified will be analyzed in various operaing condiions. (0) P(0) za( k), h A( k) K( k), P( k), ( k) ik 0 A. Normal Operaion Figure III and figure IV shows he idenificaion curve graph of he winding resisance value R and shor circui reacance value x a he high volage side when he impedance maching balance ransformer is in normal operaion. In accordance o he parameers idenificaion curve, we can see ha when he impedance maching balance ransformer is in normal operaion, he resisance idenificaion value of he winding a he high volage side has a cerain oscillaion a 0.00s ago bu hen quickly converge near.374s. A he same ime, he shor circui reacance idenificaion value a he high volage side has a grea change a firs and hen ends o be sable. We also can see ha he winding resisance value R and shor circui reacance value x have been changed lile in normal operaion for impedance maching balance ransformer a he high volage side. FIGURE II. HE PROGRAM FLOW DIAGRAM OF HE RLS ALGORIHM In order o improve he proecion sensiiviy and rapidiy of impedance maching balance ransformer, he iniial value of he algorihm is, where is sufficienly large P 0 0 I real number, is he parameer values of impedance maching balance ransformer given by manufacurers, he forgeing facor is 0.95. IV. HE SIMULAION AND ANALYSIS he simulaion employs a impedance maching balance ransformer, whose capaciy is 5MVA, raed volage is U N U N 00 3 7.5 KV and he shor circui reacance is.7+j5.06, namely, ra.36, x 5.06. During normal operaion, he error of original and secondary side volage ransformer is %, he error of original and secondary side curren ransformer is 0% and he errors of all he resisance and reacance parameers are 0.5%. he original parameers ra, x given by he model of impedance maching balance ransformer are used as he iniial value of parameer values o be idenified in simulaion. Using elecromagneic ransien simulaion program (EMP) we can ge he real-ime volage and curren sampling values of he impedance maching balance ransformer windings on boh sides. And hen hese values are used as he inpu and oupu of he idenificaion model. he parameer values o be idenified a every sampling ime can be calculaed by wriing he program of recursive leas square algorihm in MALAB simulaion sofware. Nex he changes of impedance maching balance ransformer parameer values FIGURE III. HE IDENIFICAION CURVE FOR RESISANCE FIGURE IV. HE IDENIFICAION CURVE FOR SHOR CIRCUI REACANCE B. Exernal Phase Winding Shors o Ground Earh shor circui of exernal phase winding a he secondary side (exernal faul) suddenly occurred a 0.00s, when he impedance maching balance ransformer is in normal operaion. Under he circumsance, he idenificaion curve graph of he winding resisance value R and shor circui 7
reacance value x of impedance maching balance ransformer a he high volage side is shown as figure V and figure VI. FIGURE VII. HE IDENIFICAION CURVE FOR RESISANCE IN INERNAL faul FIGURE V. HE IDENIFICAION CURVE FOR RESISANCE IN EXERNAL faul FIGURE VIII. HE IDENIFICAION CURVE FOR SHOR CIRCUI REACANCE IN INERNAL FAUL FIGURE VI. HE IDENIFICAION CURVE FOR SHOR CIRCUI REACANCE IN EXERNAL FAUL As shown in figure 5 and figure 6, he winding resisance value R and shor circui reacance value x a he high volage side have oscillaion when Exernal phase winding shors o ground a 0.00s, bu hen he values end o be sable and almos equal o hem in normal operaion. C. A Phase Winding a he High Volage Side Shors o Ground Single phase earh faul of A-phase winding a he high volage side (inernal faul) suddenly occurred a 0.00s when he impedance maching balance ransformer is in normal operaion. Under he circumsance, he idenificaion curve graph of he winding resisance value R and shor circui reacance value x of impedance maching balance ransformer a he high volage side is shown as figure VII and figure VIII. As shown in figure VII and figure VIII, he winding resisance and shor circui reacance idenificaion values a he high volage side remain unchanged in normal operaion for impedance maching balance ransformer. he values change dramaically and will never converge when Single phase earh faul of A-phase winding a he high volage side occurred a 0.00s. he paper will no explain he iner-phase shor circui faul and iner-run shor circui faul of phase winding for impedance maching balance ransformer, however, he resuls is similar o he above menioned. he simulaion resuls show ha he winding resisance and shor circui reacance values have no been significanly changed in normal operaion for impedance maching balance ransformer or exernal faul, bu hey have been dramaically changed for inernal faul. V. CONCLUSION In order o solve he puzzle ha he exising faul diagnosis mehods could no accuraely idenify he ypes of faul for impedance maching balance ransformer, he paper proposed a faul diagnosis mehod exploiing recursive leas square algorihm o idenify he inernal failure and exernal faul based on operaional feaure of impedance maching balance ransformer. he simulaion resuls in MALAB indicae ha he proposed mehod could effecively make an accurae diagnosis of he inernal and exernal faul. REFERENCES [] IEEEGuide for Proecive Relay Applicaions o Power ransformers, 000. 73
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