Journal of Babylon niversity/engineering Sciences/ No.()/ ol.(1): 13 Effect of nbalance oltage on the peration and Performance of a Three Phase Distribution Transformers Mohammed k. Edan Abstract- Three phase supply system is found to be quite balanced in both magnitude and displacement at the generation levels but it is not so at distribution end. oltage unbalance which is a common and global phenomenon is found to be very effective in deteriorating the operation and performance of electrical apparatus. Present paper is an attempt to analyze the operation of three phase distribution transformers with unbalance voltage conditions. MATLAB programming based upon symmetrical component approach is adopted to estimate the performance of a three-phase transformer under unbalanced condition. Both under voltage unbalance as well as over voltage unbalance have been considered for analysis purpose. Numerical details study in case of distribution transformer with primary delta connection and secondary star connection with solidly grounded neutral is presented in this paper. The degree of voltage unbalance is represented by the voltage unbalance factor (F) derived from symmetrical component. Key words: Transformer, Abnormal operation, symmetrical components, oltage unbalance factor الخلاصة نظام تجهیز القدرة ثلاثي الطور یكون متزن القیمة و ال ازویة عند التولید ولكن قد لایكون كذلك عند التوزیع. عدم ات ازن الفولتیة من الظواهر الشاي عة التي تؤثر على تدهور عمل و اداء المعدات الكهرباي یه. یقدم هذا البحث محاولة لتحلیل عمل محولات التوزیع ثلاثیة الطور في حالة عدم ات ازن الفولتیة. تم انشاء برنامج باستخدام لغة البرمجة Matlab بالاعتماد على المركبات المتماثلة لتخمین اداء عمل المحولات ثلاثیة الطور في حالة عدم الات ازن. حالة عدم ات ازن الفولتیة الناتج عن ارتفاع الفولتیة وكذلك انخفاض الفولتیة كلاهما تمت د ارسة تا ثیره. قدم البحث د ارسة عددیة موسعة لمحولة ثلاثیة الطور مؤرضة تا ریضا مباش ار. استخدم عامل عدم ات ازن الفولتیة المشتق من المركبات المتماثلة لبیان مقدار عدم ات ازن الفولتیة. 1. Introduction oltage unbalance is the deviation of individual phase voltage magnitudes from the normal/rated values, with the individual phase voltages being not equal to each other either in magnitude and/or in phase displacement. The presence of inequality among the phase voltages can be attributed to the unsymmetrical impedances of transmission and distribution lines, unbalanced or unstable power utilities, unbalanced three phase loads, open delta transformer connections, blown fuses of a three-phase capacitor banks, uneven spread of single-phase loads across the three phases, singlephase traction loads, weak rural power electric systems with long transmission lines, or even unidentified/ uncleared single-phase-to-ground faults [ Giridhar Kini, Ramesh C. Bansal, and R. S. Aithal 7]. oltage unbalance can affect customer equipment, in particular, three phase induction motors can suffer from temperature rise due to the currents in the windings resulting from negative sequence voltage. Reduced torque and lower full-load speed can also result from voltage unbalance, possible resulting in the motor not being able to adequately fulfill its function. ther affects are an increase in noise and vibration [Neil Browne, Darren Spoor, and Justin Byrnes 8]. oltage unbalance can also affect performance of the network. It can result in increased voltage drop on conductors, resulting in the need for larger conductors. It can cause different losses on each phase of transformers, resulting in a rise in hot spot temperature. nbalance can increase the generation of triplen harmonics, possibly
overloading harmonic filters and capacitor banks [Z. Emin and D. Crisford 6]. In the most practical studies, the method of measuring the voltage unbalanced level is either the percent voltage unbalance (P) defined by the (National Electrical Manufactures Association) NEMA or the voltage unbalance factor (F) defined by the (International Electrotechnical Commission) IEC. Both of them are positive real quantities which can show the level of voltage unbalance. The P is a method calculated by the sampled data of the ratio of the maximum deviation of the average voltage to the average of the three voltages. As for the F, it is described by the ratio of the negative sequence to the positive sequence voltage [Guilin Zheng and Yan Xu 1].. Types of oltage nbalance There may be different type of unbalance in a supply system and exists definite possibility of voltage variations above and below the rated value. Thus voltage unbalance can be classified into overvoltage unbalance () under-voltage unbalance () unbalance. is a condition when the three phase voltages are not equal to each other, in addition positive sequence component is greater than the rated value while is a condition where the three phase voltages are not equal to each other, and in addition the positive-sequence component is lesser than the rated value. There are many possible voltage unbalance in a power system, here we will study the following six causes, (1) single phase under voltage unbalance (1Φ-), () two phases under voltage unbalance (Φ-), (3) three phases under voltage unbalance (3Φ-), (4) single phase over voltage unbalance (1Φ-), () two phases over voltage unbalance (Φ-), (6) three phases over voltage unbalance (3Φ-) [Knwararjit Singh Sandhu and innet Chaudhary 9]. 3. nbalance in Three-Phase Distribution Networks To study the unbalanced operation of a power system, the symmetrical components theory is used. According to Stokvis-Fortescue theorem, every threephase asymmetrical system of phasors can be decomposed into three symmetrical systems of positive, negative and zero sequence respectively. Every sequence system contains three phasors characterized by equal magnitudes; in the case of positive and negative sequences, components are rotated between them with 1 electrical degrees in counter-clockwise direction and negative clockwise direction, respectively. In the case of zero sequence components, there is no rotation between phasors [ Chindriş, A. Cziker, Anca Miron, H.Bălan,and A. Sudria 7]. If an asymmetrical system of line voltages is taken into consideration, the relationship between the initial system and the symmetrical sequence systems can be written as follows [E. Seiphetlho and A. P. J. Rens 1]: (1) Where a, b and c are the unbalanced phase voltage Phasors p, n and the positive, negative and zero-sequence voltage phasors respectively (fundamental frequency components). In the same way, if an asymmetrical system of line currents is taken into consideration, the relationship between the initial system and the symmetrical sequence systems can be written as follows [E. Seiphetlho and A. P. J. Rens 1]:
Journal of Babylon niversity/engineering Sciences/ No.()/ ol.(1): 13 Where I a, I b and I c are the unbalanced phase current Phasors I p, I n and I the positive, negative and zero-sequence currents phasors respectively (fundamental frequency components). Where = -.+ j.866 These sequence systems are not only theoretical, they correspond to the reality: the positive sequence components are created by the synchronous or asynchronous generators while the negative and zero sequence components appear at the place of unbalance. Each of them can be separately measured and influence in a different way in power systems. For example, in the case of motors, the positive sequence components produce the useful torque while the negative sequence components produce fields that create braking torques. n other hand, the zero sequence components is the one that get involved in the cases of interferences between the electric and the telecommunication transmission lines [M. Chindriş, A. Cziker, Anca Miron, H.Bălan, and A. Sudria 7]. 4. nbalance Definition The two general definitions for voltage unbalance as described are; 4.1 NEMA Definition The voltage unbalance percentage (P) at the terminal of a machine as given by the National Electrical Manufacturer Association Motor and Generator Standard (NEMA MGI) used in most studies is[k.s. Sandhu and ineet Chaudhary 8, P.Pillay and M.Manyage 1]: () 4. Symmetrical Component Definition The voltage unbalance factor (F) is defined by International Electro technical Commission (IEC) as the ratio of negative-sequence voltage component to the positive-sequence voltage component [P.Pillay and M.Manyage 1, J. M. Apsley 1]. (3) (4) Where n and p are the magnitude of negative and positive sequence voltage components respectively are obtained by symmetrical component transformation.. Transformer Modeling nder nbalance Condition Steady state analysis of a transformer operating with unbalanced voltage is possible using symmetrical component approach. This requires the development of positive-, negative- and zero sequence equivalent circuit representation. It possible to assume for a transformer that X 1 =X = leakage impedance. As the transformer is a static device, the positive or negative sequence impedances do not change with phase sequence of the applied balanced voltages. The zero sequence impedance can,
however, vary from an open circuit to a low value depending on the transformer winding connection, method of neutral grounding [J. C. Das ]. The positive and negative sequence equivalent circuit representation of any transformer connection is shown in Fig.1 and Fig. respectively. The zero sequence equivalent representation of transformer is dependent on the type of transformer winding connection.the zero sequence representation for a deltastar transformer with the star neutral solidly grounded is constructed as shown in Fig. 3(a). The grounding of the star neutral allows the zero sequence currents to return through the neutral and circulate in the windings to the source of unbalance. n the delta side, the circuit is open, as no zero sequence currents appear in the lines, though these currents circulate in the delta windings to balance the ampere turns in the star windings. The circuit is open on the delta side line, and the zero sequence impedance of the transformer seen from the delta side is an open circuit [J. C. Das ]. If the star winding neutral is left isolated, Fig.3 (b), the circuit will be open on both sides, presenting infinite impedance [John J. Winders and Jr ]. In a star star transformer connection, with both neutrals isolated, no zero sequence currents can flow. The zero sequence equivalent circuit is open on both sides and presents infinite impedance to the flow of zero sequence currents [John J. Winders, Jr, A. C. Franklin, and D. P. Franklin 1983]. For delta delta connection, no zero currents will pass from one winding to another. n the transformer side, the windings are shown connected to the reference bus, allowing the circulation of currents within the windings [A. C. Franklin and D. P. Franklin 1983]. In star star connected transformer, with both neutrals grounded the zero sequence equivalent circuit representation shown in Fig.4 [John J. Winders and Jr, A. C. Franklin, and D. P. Franklin 1983]. Where per phase values are defined as: pp positive-sequence voltage np negative-sequence voltage s zero-sequence voltage R Tp primary resistance X Tp primary reactance R Ts secondary resistance referred to primary X Ts secondary reactance referred to primary X m magnetizing reactance Z p positive-sequence impedance of transformer Z n negative-sequence impedance of transformer Z zero-sequence impedance of transformer I pp primary positive-sequence current phasor I ps secondary positive-sequence current phasor I np primary negative-sequence current phasor I ns secondary negative-sequence current phasor I p primary positive-sequence current phasor I s secondary positive-sequence current phasor Let as, bs, and cs be the phase secondary voltages of a delta-star transformer with the star neutral soldely grounded. The corresponding zero-, positive and negative-sequence components ( s, ps and ns ) of the voltages are given by equation[e. Seiphetlho and A. P. J. Rens 1] :
Journal of Babylon niversity/engineering Sciences/ No.()/ ol.(1): 13 () The corresponding zero-, positive and negative-sequence components (I s,i ps and I ns ) of the currents are given by equation[m. Chindriş, A. Cziker, Anca Miron, H.Bălan, and A. Sudria 7]: (6) Analysis of equivalent circuits the positive and negative primary phase voltages and currents can be determined from equations [Knwararjit Singh Sandhu, innet Chaudhary 9, A. C. Franklin, D. P. Franklin 1983]: pp np n ( Z Z ( Z Z Z Z )) /(( Z Z )) (7) ( ps LP Ts m Tp Tp m LP m n ( Z Z ( Z Z Z Z )) /(( Z Z )) (8) ( ns Ln Ts m Tp Tp m Ln m (9) Where n is the transformer voltage ratio. The values of n are dependent on transformer connection as shown in Table 1 where N p represents the primary turn number while N s has the same meaning for the secondary winding [M. Chindriş, A. Cziker, Anca Miron, H.Bălan, and A. Sudria 7]. The primary is delta connected. The primary phase voltages and currents can be calculated by as [K.S. Sandhu and ineet Chaudhary 8]: (1) pa pb pc a pp * a * pp pp np a a * * np np (11) (1) The transformer input, output power and primary and secondary power factor can be expressed in terms of symmetrical components of the voltage and currents as [E. Seiphetlho and A. P. J. Rens 1]: Input active power: ] (13)
Input reactive power: ] (14) Where (*) indicates the conjugate value. Primary power factor: p. f 1 Q cos [tan ( in )] (1) P in utput active power: ] (16) utput reactive power: ] (17) Secondary power factor: p. f 1 Q cos [tan ( ot )] (18) P Total losses in watts: ot Total losses = P in - P ot (19) Efficiency of the transformer is defined as: 6. System under study To facilitate the analysis of unbalance and to understand the effect of unbalance voltage on operation of distribution transformer, a system content of three phase distribution transformer with delta primary winding connected and star secondary winding with solidly grounding neutral. The transformer is loading with unbalance impedances as shown in figure (). The transformer and load have the following parameters: - rated primary voltage p =11 Kv, rated secondary voltage s =41, transformer turn ratio N=4.9, transformer rated power S T = KA. - Primary impedance Z Tp = (17.4 + j 4.3) Ω, secondary impedance reffered to primary Z Ts = (13.4 + j 4.3) Ω. - Load impedance reffered to primary Z La = (131 + j 9) Ω, Z Lb = (11 + j 6) Ω, Z Lc = (18 + j 4) Ω. All parameters are on per phase basis 7. Results and Discussion To study the effects of voltage unbalance on performance of distribution transformer, three causes of unbalancing the secondary voltage included under and over voltage are applied on the system under study. ()
Journal of Babylon niversity/engineering Sciences/ No.()/ ol.(1): 13 Case 1: effect of three phase voltage unbalance. (a) ver voltage unbalance. It can be seen from table that both efficiency and secondary power factor increase with increasing of unbalance factor. (b) nder voltage unbalance.it is observed from the results listed in table that at under voltage unbalance in secondary voltage. The secondary power factor and transformer efficiency are decreased with increase of unbalance factor (F). It also can be observed from table 3 for under and over voltage cases that the change in F is little effect on primary power factor. The efficiency and total losses at over and under three phase voltage unbalance are 3-D plotted with unbalance factor in figures 6 and 8. The secondary and primary power factors are 3-D plotted with F in figures 7 and 9. Case : effect of single phase voltage unbalance. (a) ver voltage unbalance. For over voltage unbalance occurs in phase a. It can be seen from the results listed in table 4 that the secondary power factor and transformer efficiency decrease with increasing of F. For over voltage unbalance occurs in phase b the transformer efficiency increases with increasing of F, while the secondary power factor decreases with increasing of F as shown in table 6. For under voltage unbalance occurs in phase c the transformer efficiency and secondary power factor increase with increasing of F, as shown in table 8. The efficiency and total losses for single phase over voltage unbalance occurs in phase b is 3-D plotted with F in figure 1.The secondary and primary power factor is 3-D plotted with F in figure11. (b) nder voltage unbalance For under voltage unbalance occurs in phase a. It can be seen from the results listed in tables 4 that the power factor and efficiency increase with increasing of F. For under voltage unbalance occurs in phase b. The transformer efficiency decreases with increasing of F until F value 6.418% and return to increases with increasing o F as shown in table 6.The secondary power factor increases with increasing of F as shown in table 6. For under voltage unbalance occurs in phase c. The transformer efficiency and secondary power factor decreases with increasing of F, as shown in table 8. The efficiency and total losses for single phase under voltage unbalance occurs in phase b is 3-D plotted with F in figure 1.The secondary and primary power factor is 3-D plotted with F in figure 13. Case 3: effect of two phase voltage unbalance. For unbalance voltage occurs in phase a and c. It can be seen from the results listed in table 1 that the secondary positive sequence voltage is fixed at SP =39.64 volt with different F values. It also can be observed that the efficiency and power factor decrease with increase of F. The maximum changes in efficiency and secondary power factor are.843% and.9% respectively. The efficiency and total losses are 3-D plotted with F in figure 14.The secondary and primary power factor is 3-D plotted with F in figure 1. For unbalance voltage occurs in phase a and b. It can be seen from result listed in table 1 that the positive sequence voltage of the secondary voltage is fixed at the
same above value. It also can be seen from results in table 1 that the efficiency and power factor decrease with increase of F. The maximum changes in efficiency and secondary power factor are 1.916% and.16% respectively. The efficiency and total losses are 3-D plotted with F in figure 16. The secondary and primary power factor is 3-D plotted with F in figures 17. It can be seen from tables 1, 1 that the negative sequence voltage component has little effect on the power factor. In other word the transformer power factor affected by the positive sequence voltage component. 8. Conclusion This paper presents analysis and control the operation of three-phase distribution transformer operating with unbalanced condition. From the results of this paper it can be concluded the following: 1- The operating characteristics of a three phase distribution transformer will not be as good as in the balance case, but most customers do not know that the unbalance may cause a higher power factor. It is worth that customers usually use capacitors to improve the power factor, but due to ignorance of voltage unbalance, they may over compensate the power factor, thus result in over voltage. - The negative sequence voltage component has little effect on the secondary power factor. 3-The values of efficiency and secondary power factor dependent on over or under voltage unbalance for three phase unbalance. For two and single phase voltage unbalance the values of efficiency and secondary power factor dependent on same reason of the three phase unbalance,further dependent on at which phase or phases the unbalance voltage occurs. 4-The voltage unbalance may causes decrease of transformer efficiency and increase transformer losses. 9. References A. C. Franklin and D. P. Franklin, 1983, The J & P Transformer Book, Butterworth. E. Seiphetlho and A. P. J. Rens, 1, n the Assessment of oltage nbalance, Proceeding of 14 th International Conference on Harmonics and Quality of Power, page 1-6.IEEE Publisher. Guilin Zheng and Yan Xu, 16- August 1, An Intelligent Three-Phase oltage nbalance Measuring Instrument Based on the ATT7C, Proceedings of the 1 IEEE International Conference on Automation and Logistics,, Hong Kong and Macau. J. C. Das,, Power System Analysis Short-Circuit Load Flow and Harmonics, Marcel Dekker, Inc. J. M. Apsley, March-April 1, De-rating of multiphase induction machines due to supply unbalance, IEEE Transaction on Industry Application, olume 46, Issue. John J. Winders and Jr,, Power Transformers Principles and Applications, Marcel Dekker, Inc. Knwararjit Singh Sandhu and innet Chaudhary, February 9, Steady State Modelling of Induction Motor perating With nbalanced Supply System, Wseas Transaction on Circuit and Systems, Issue, olume 8. K.S. Sandhu and ineet Chaudhary, December 8, MATLAB & PSIM Based Analysis of Three- Phase Induction Motor peration with nbalanced Supply System, Electrical Conference paper.
Journal of Babylon niversity/engineering Sciences/ No.()/ ol.(1): 13 M. Chindriş, A. Cziker, Anca Miron, H.Bălan, and A. Sudria, 9-11 ctober 7, Propagation of nbalance in Electric Power Systems,9 th International Conference Power Quality and tilisation. Barchelona. Neil Browne, Darren Spoor, and Justin Byrnes, 8, oltage nbalance in an rban Distribution Network - A Case Study, 13th International Conference on Harmonics and Quality of Power, page 1-6.IEEE Publisher. P. Giridhar Kini, Ramesh C. Bansal, and R. S. Aithal, August 7, A Novel Approach Toward Interpretation and Application of oltage nbalance Factor, IEEE Transaction on Industrial Electronics, ol.4, No.4. Z. Emin and D. Crisford, July 6, Negative phase sequence voltages on e and w transmission system, IEEE Trans. Power Delivery., vol. 1, no. 3, pp. 167 161. P.Pillay and M.Manyage, Definition of oltage nbalance, May 1, IEEE Power Engineering Review, vol.1, No., pp 49-1. Table (1) Transformer ratio dependent on its connection n Connection n Connection Dy Yy Dd Dz Yd Yz Table () results of transformer secondary circuit for 3 phases under and over voltage unbalance F% as bs cs Ias Ibs Ics sp sn so PF Total losses Watts. 39.64 39.64 39.64 31.781 4.46 431.634 39.64...867 ٢١٧٩٥ 91.697 1.64 37.169 31.664.16 39.3644 4.83 4.373 31.664 3.687 3.687.86 ٢٢٠٢٦ 9.9961 3.37 3.4334.93 1.4316 36.67 391.18 379.841.93 7.174 7.174.863 ٢٢١٠٣ 9.83.448 33.3499 14.986 19.8473 33.937 376.861 3.819 14.986 1.861 1.861.866 ٢٢٠٢٨ 89.691 6.998 31.664 6.647 181.69 31.3 361.9614 36.378 6.647 14.4348 14.4348.88 ٢١٨٠١ 88.8 9.1161 9.183 197.937 166.678 98.9 347.3367 3.646 197.937 18.43 18.43.8 ٢١٤٢٢ 88.16 1.4 41.6838 47.9343 4.1847 314.7918 43.849 47.936 47.9343 3.687 3.687.8691 1413 9.3839.696 44.891 6.68 68.7691 318.864 449.797 484.1767 6.61 6.9188 6.9188.878 1134 9.9871 3.9731 46.89 64.61 83.33 31.761 464.3344 1.4499 64.9494 1.68 1.68.874 47 93.6381.173 48.976 7.9361 97.9378 34.899 478.991 36.73 73.833 14.131 14.131.8739 1968 94.696 6.36 1.9 81.7 31. 37.36 493.838 6.996 81.617 17.7436 17.7436.87 18647 94.881 7.3641 3.143 89.639 37.166 39.7173 8.8 89.693 89.91 1.3 1.3.876 1713 9.47 8.4786 4.1847 97.9378 341.691 331.74.833 61.4 97.9378.69.69.8778 1917 96.11 Efficiency % Table (3) results of transformer primary circuit for 3 phases under and over voltage unbalance F ap bp cp Iap Ibp Icp pp pn PF %. 116 116 116 9.173 9.173 9.173 116..8184 1.64 114 111 1198 8.9649 8.879 8.78 11 17.4.8184 3.174 11146 184 14 8.741 8.898 8.691 184 348.989.818.13 1893 148 9986 8.49 8.318 7.8174 1439 3.3634.8186 6.947 164 16 943 8.3389 8.166 7.3661 134 697.8179.8189 9.94 1389 9677 8879 8.1331 7.7346 6.913 968 87.73.819 1.446 11911 16 113 9.3846 9.4686 9.661 161 174..8184.6794 11 1476 178 9.63 9.774 1.833 1483 334..818 3.9484 148 188 13338 9.839 1.76 1.363 1888 8.9.818.14 171 1396 13897 1.494 1.379 1.9894 1394 683.3.8186 6.61 1973 1379 1447 1.636 1.6746 11.447 13699 87.8.8188 7.3183 1331 1413 116 1.4784 1.9777 11.8961 141 13..8189 8.49 1347 143 169 1.6673 11.746 1.344 14493 11..8191
Table (4) results of transformer secondary circuit for 1 phase under and over voltage unbalance in phase a F% as bs cs Ias Ibs Ics sp sn so PF Total Efficiency% losses Watts. 39.64 39.64 39.64 31.781 4.46 431.634 39.64...867 179 91.697.71.16 39.64 39.64 93.81 4.46 431.634 34.7389 4.861 4.861.869 1819 9.637 4.96 1.4316 39.64 39.64 74.86 4.46 431.634 9.8774 9.79 9.79.877 1 93.714 6.481 19.8473 39.64 39.64.899 4.46 431.634.16 14.844 14.844.874 11994 94.844 8.838 181.69 39.64 39.64 36.939 4.46 431.634.14 19.448 19.448.874 8748 96.873 11.93 166.678 39.64 39.64 17.978 4.46 431.634 1.931 4.373 4.373.876 1 97.439 1.9886 4.1847 39.64 39.64 331.74 4.46 431.634 44.4618 4.861 4.861.86 84 9.848 3.8997 68.7691 39.64 39.64 3.7 4.46 431.634 49.333 9.79 9.79.8638 8383 9.31.7377 83.33 39.64 39.64 369.663 4.46 431.634 4.1847 14.844 14.844.861 31693 89.31 7.67 97.9378 39.64 39.64 388.64 4.46 431.634 9.46 19.448 19.448.864 314 88.669 9.1 31. 39.64 39.64 47.84 4.46 431.634 63.976 4.373 4.373.887 3834 88.733 1.87 37.166 39.64 39.64 46.4 4.46 431.634 68.7691 9.1687 9.1687.871 41687 87.444 1.436 341.691 39.64 39.64 44. 4.46 431.634 73.636 34.3 34.3.8 44 87.69 Table () results of transformer primary circuit for 1 phase under and over voltage unbalance in phase a F% ap bp cp Iap Ibp Icp pp pn PF. 116 116 116 9.173 9.173 9.173 116..8184.71 1118 1139 1139 8.7978 9.64 9.119 11419 36..8184 4.33 171 114 1149 8.43 8.938 9.3 1118 47.8186 6.441 141 1139 1131 8.1 8.863 8.993 1946 7.8188 8.7779 9769 111 1117 7.6778 8.718 8.948 179 94.1.8191 11. 998 1197 11117 7.343 8.6143 8.8888 1473 117.1.8196 1.9763 117 11778 11774 9.477 9.964 9.173 1189 3.8184 3.87 198 119 11896 9.91 9.48 9.376 118 47.818.7 137 13 11 1.966 9.4 9.339 136 7.8187 7.46 1341 1168 11 1.671 9.681 9.37 161 94.1.8189 9.133 1413 134 181 11.48 9.88 9.4433 1838 117.1.819 1.783 14484 1443 1416 11.4 9.994 9.16 1374 141.1.819 1.393 1496 18 13 11.793 1.17 9.91 13311 164.1.8199 Table (6) results of transformer secondary circuit for 1 phase under and over voltage unbalance in phase b F% as bs cs Ias Ibs Ics sp sn so PF Total Efficiency % losses Watts. 39.64 39.64 39.64 31.781 4.46 431.634 39.64...867 179 ٩١.٦٩٧٢.71 39.64.16 39.64 31.781 394.867 431.634 34.7389 4.861 4.861.8684 1373 ٩١.٥٢١٤ 4.96 39.64 1.4316 39.64 31.781 369.738 431.634 9.8774 9.79 9.79.869 78 ٩١.٤١٧٦ 6.481 39.64 19.8473 39.64 31.781 343.68 431.634.16 14.844 14.844.877 19 ٩١.٣٩٣٩ 8.838 39.64 181.69 39.64 31.781 318.873 431.634.14 19.448 19.448.8718 199 ٩١.٤٦١٣ 11.93 39.64 166.678 39.64 31.781 9.4941 431.634 1.931 4.373 4.373.873 1799 ٩٢.٥٦٢٣ 1.9886 39.64 4.1847 39.64 31.781 446.3 431.634 44.4618 4.861 4.861.8661 91.9344 3.8997 39.64 68.7691 39.64 31.781 471.6467 431.634 49.333 9.79 9.79.861 137 9.3.7377 39.64 83.33 39.64 31.781 497.399 431.634 4.1847 14.844 14.844.864 9.63 7.67 39.64 97.9378 39.64 31.781.833 431.634 9.46 19.448 19.448.863 184 9.9388 9.1 39.64 31. 39.64 31.781 48.464 431.634 63.976 4.373 4.373.861 138 93.348 1.87 39.64 37.166 39.64 31.781 74.196 431.634 68.7691 9.1687 9.1687.861 798 93.789 1.436 39.64 341.691 39.64 31.781 99.619 431.634 73.636 34.3 34.3.863 4 94.463 Table (7) results of transformer primary circuit for 1 phase under and over voltage unbalance in phase b F% ap bp cp Iap Ibp Icp pp pn PF. 116 116 116 9.173 9.173 9.173 116..8184.71 1118 1139 1139 8.7978 9.64 9.119 11419 36..8184 4.33 171 114 1149 8.43 8.938 9.3 1118 47.8186 6.441 141 1139 1131 8.1 8.863 8.993 1946 7.8188 8.7779 9769 111 1117 7.6778 8.718 8.948 179 94.1.8191 11. 998 1197 11117 7.343 8.6143 8.8888 1473 117.1.8196 1.9763 117 11778 11774 9.477 9.964 9.173 1189 3.8184 3.87 198 119 11896 9.91 9.48 9.376 118 47.818.7 137 13 11 1.966 9.4 9.339 136 7.8187 7.46 1341 1168 11 1.671 9.681 9.37 161 94.1.8189 9.133 1413 134 181 11.48 9.88 9.4433 1838 117.1.819 1.783 14484 1443 1416 11.4 9.994 9.16 1374 141.1.819 1.393 1496 18 13 11.793 1.17 9.91 13311 164.1.8199
Journal of Babylon niversity/engineering Sciences/ No.()/ ol.(1): 13 Table (8) results of transformer secondary circuit for 1 phase under and over voltage unbalance in phase c F% as bs cs Ias Ibs Ics sp sn so PF Total Efficiency % losses Watts. 39.64 39.64 39.64 31.781 4.46 431.634 39.64...867 179 91.697.71 39.64 39.64.16 31.781 4.46 4.373 34.7389 4.861 4.861.8643 64 91.181 4.96 39.64 39.64 1.4316 31.781 4.46 379.841 9.8774 9.79 9.79.8613 337 9.4 6.481 39.64 39.64 19.8473 31.781 4.46 3.819.16 14.844 14.844.883 386 89.864 8.838 39.64 39.64 181.69 31.781 4.46 36.378.14 19.448 19.448.81 3687 89.4 11.93 39.64 39.64 166.678 31.781 4.46 3.646 1.931 4.373 4.373.819 339 89.7 1.9886 39.64 39.64 4.1847 31.781 4.46 47.936 44.4618 4.861 4.861.87 7 9.476 3.8997 39.64 39.64 68.7691 31.781 4.46 484.1767 49.333 9.79 9.79.877 19361 93.4.7377 39.64 39.64 83.33 31.781 4.46 1.4499 4.1847 14.844 14.844.87 17771 94.7 7.67 39.64 39.64 97.9378 31.781 4.46 36.73 9.46 19.448 19.448.8777 1933 94.841 9.1 39.64 39.64 31. 31.781 4.46 6.996 63.976 4.373 4.373.88 13847 9.6931 1.87 39.64 39.64 37.166 31.781 4.46 89.693 68.7691 9.1687 9.1687.881 1113 96.6 1.436 39.64 39.64 341.691 31.781 4.46 61.4 73.636 34.3 34.3.884 8931 97.4361 Table (9) results of transformer primary circuit for 1 phase under and over voltage unbalance in phase c F% ap bp cp Iap Ibp Icp pp pn PF. 116 116 116 9.173 9.173 9.173 116..8184.71 1139 1139 1118 9.64 9.119 8.7978 11419 36..8184 4.33 114 1149 171 8.938 9.3 8.43 1118 47.8186 6.441 1139 1131 141 8.863 8.993 8.1 1946 7.8188 8.7779 111 1117 9769 8.718 8.948 7.6778 179 94.1.8191 11. 1197 11117 998 8.6143 8.8888 7.343 1473 117.1.8196 1.9763 11778 11774 117 9.964 9.376 9.477 1189 3.8184 3.87 119 11896 198 9.48 9.339 9.91 118 47.818.7 13 11 137 9.4 9.37 1.966 136 7.8187 7.46 1168 11 1341 9.681 9.4433 1.671 161 94.1.8189 9.133 134 181 1413 9.88 9.16 11.48 1838 117.1.819 1.783 1443 1416 14484 9.994 9.91 11.4 1374 141.1.819 1.393 18 13 1496 1.17 9.6683 11.793 13311 164.1.8199 Table (1) results of transformer secondary circuit for phases voltage unbalance in phase a and c F% as bs cs Ias Ibs Ics sp sn so PF Total Efficiency% losses Watts. 39.64 39.64 39.64 31.781 4.46 431.634 39.64...867 179 91.697 1.1 43.79 39.64 3.4498 317.484 4.46 44.134 39.64.3963.3963.869 988 91.437.3 47.91 39.64 31.99 3.893 4.46 416.6763 39.64 4.797 4.797.8646 4147 9.86 3.4. 39.64 7.1487 38.964 4.46 49.199 39.64 7.189 7.189.8633 71 9.3831 4. 6.6 39.64.9981 333.74 4.46 41.7 39.64 9.83 9.83.86 636 89.976.7 6.331 39.64 18.8476 339.18 4.46 394.41 39.64 11.9816 11.9816.866 7414 89.89 6.8 64.37 39.64 14.697 344.146 4.46 386.768 39.64 14.378 14.378.893 843 89.117 7.9 68.643 39.64 1.46 349.97 4.46 379.91 39.64 16.7743 16.7743.88 94 88.84 Table (11) results of transformer primary circuit for phases voltage unbalance in phase a and c F ap bp cp Iap Ibp Icp pp pn PF %. 116 116 116 9.173 9.173 9.173 116..8184.9939 117 1167 11 9.47 9.19 9.849 116 11.841.8184 1.9878 118 1166 1144 9.3183 9.8 8.996 116 31.69.8184.9818 1196 11664 1134 9.391 9.74 8.98 116 347.33.818 3.977 17 1167 114 9.4646 9.473 8.81 116 463.384.818 4.9696 117 11676 1114 9.383 9.68 8.73 116 79..8186.963 19 11683 11 9.614 9.897 8.6441 116 69.76.8187 6.974 136 1169 196 9.6868 9.31 8.63 116 81.917.8189
Table (1) results of transformer secondary circuit for phases voltage unbalance in phase a and b F% as bs cs Ias Ibs Ics sp sn so PF Total losseswatts Efficiency %. 39.64 39.64 39.64 31.781 4.46 431.634 39.64...867 179 91.697 1.1 43.79 3.4498 39.64 317.484 413.1767 431.634 39.64.3963.3963.8671 619 91.3844.3 47.91 31.99 39.64 3.893 4.8931 431.634 39.64 4.797 4.797.8669 341 91.843 3.4. 7.1487 39.64 38.964 398.696 431.634 39.64 7.189 7.189.8666 418 9.797 4. 6.6.9981 39.64 333.74 391.36 431.634 39.64 9.83 9.83.8664 49 9.33.7 6.331 18.8476 39.64 339.18 384.44 431.634 39.64 11.9816 11.9816.866 633 9.66 6.8 64.37 14.697 39.64 344.146 376.789 431.634 39.64 14.378 14.378.869 6316 9.14 7.9 68.643 1.46 39.64 349.97 369.473 431.634 39.64 16.7743 16.7743.866 697 89.7817 Table (13) results of transformer secondary circuit for phases voltage unbalance in phase a and b F ap bp cp Iap Ibp Icp pp pn PF %. 116 116 116 9.173 9.173 9.173 116..8184.9939 117 1167 11 9.47 9.19 9.849 116 11.841.8184 1.9878 118 1166 1144 9.3183 9.8 8.996 116 31.69.8184.9818 1196 11664 1134 9.391 9.74 8.98 116 347.33.818 3.977 17 1167 114 9.4646 9.473 8.81 116 463.384.818 4.9696 117 11676 1114 9.383 9.68 8.73 116 79..8186.963 19 11683 11 9.614 9.897 8.6441 116 69.76.8187 6.974 136 1169 196 9.6868 9.31 8.63 116 81.917.8189 Z P Fig.1 Per-phase positive sequence representation Z n + - + pp np - R Tp I pp R Tp I np jx Tp R c R Ts Fig. Per-phase negative sequence representation I ps jx Ts I pm jx m ps jx Tp R c R Ts I ns jx Ts I nm jx m ns + - + - I p= N o Z R Tp jx Tp (b) R Ts I s = jx Ts s Fig.3 (a) Derivations of equivalent zero sequence circuit for a delta star transformer, star neutral solidly grounded; (b) zero sequence circuit of a delta star transformer, star neutral isolated. + - Primary Secondary I R Tp jx Tp R Ts jx Ts I I + p I p R c I s I pm jx m s R Tp jx Tp R Ts jx Ts + Z - I p= N o I s s - Fig.4 Per-phase zero sequence representation of a wye wye transformer, both neutrals grounded. Z
Journal of Babylon niversity/engineering Sciences/ No.()/ ol.(1): 13 (a) Primary Secondary I ap a ab ac I bp b c bc I CP Primary Secondary I as Z ac Z a Z ab Z c Z b Z bc I bc I cs Fig. system under study Z La Z Lb Z Lc 97.8194 Efficiency (%) 96 9 94 93 9 primary Power Factor.819.819.8188.8186.8184 91. 1.8 x 1 4 Total losses 1.6 1.4 1 oltage nbalance Factor (%).818.87.87.86 Secondary Power Factor.86.8 1 oltage nbalance Factor (%) Fig.6. 3-D plot of F, total losses and efficiency for 3-phases over voltage unbalance Fig.9. 3-D plot of F, secondary and primary power factor for 3-phases under voltage unbalance Primary Power Factor.8194.819.819.8188.8186.8184 Efficiency (%) 94. 94 93. 93 9. 9.818.88.88.87 Secondary Power Factor.87.86 1 oltage nbalance Factor (%) 91..3. x 1 4 Total losses.1 1 1 oltage nbalance Factor (%) Fig.7. 3-D plot of F, secondary and primary power factor for 3-phases over voltage unbalance Fig.1. 3-D plot of F, total losses and efficiency for 1-phase over voltage unbalance in phase b
Total losses...18.16.14 9 x 1 4 91 Efficiency (%) 9 89 88 1 oltage nbalance Factor (%) Fig.8. 3-D plot of F, total losses and efficiency for 3-phases under voltage unbalance 93 Primary Power Factor.8.8.819.819.818.818.87.86 Secondary Power Factor.86 1 1 oltage nbalance Factor (%) Fig.11. 3-D plot of F, secondary and primary power factor for 1-phase over voltage unbalance in phase b.819 Efficiency (%) 9. 9 91. Secondary Power Factor.8188.8186.8184 91. x 1 4 Total losses 1.8 1.6 1 1 oltage nbalance Factor (%).818.87.87.86 Primary Power Factor.86.8 8 6 4 oltage nbalance Factor (%) Fig.1. 3-D plot of F, total losses and efficiency for 1-phase under voltage unbalance in phase b Fig.1. 3-D plot of F, secondary and primary power factor for ٢-phase voltage unbalance in phase a and c Secondary Power Factor.874.87.87.868.866.81.8 Primary Power Factor.819.818 1 1 oltage nbalance Factor (%) Fig.13. 3-D plot of F, secondary and primary power factor for 1-phase under voltage unbalance in phase b Total losses.7.6..4.3..1 9 x 1 4 91 Efficiency(%) 9 89 4 6 oltage nbalance Factor (%) Fig.16. 3-D plot of F, total losses and efficiency for -phases voltage unbalance in phase a and b 8
Journal of Babylon niversity/engineering Sciences/ No.()/ ol.(1): 13 x 1 4.819 Total losses 3.8.6.4. Secondary Power Factor.8188.8186.8184 9 91 Efficiency(%) 9 89 88 8 6 4 oltage nbalance Factor (%).818.868.867 Primary Power Factor.866.86 8 6 4 oltage nbalance Factor (%) Fig.14. 3-D plot of F, total losses and efficiency for -phases voltage unbalance in phase a and c Fig.17. 3-D plot of F, secondary and primary power factor for -phases voltage unbalance in phase a and b