非晶合金铁芯Word格式.docx

1、rio FreireIIDepartamento de Engenharia Eltrica, Universidade Federal de Campina Grande - UFCG, Rua Aprgio Veloso, 882, CEP 58429-900, Campina Grande, PB, BrasilIICompanhia de Energia Eltrica do Estado de Tocantins, Palmas, TO, BrasilABSTRACTIn this paper are presented some considerations about the p

2、erformance of single wire earth return amorphous alloy core transformers in comparison with conventional silicon steel sheets cores transformers used in rural electric energy distribution network. It has been recognized that amorphous metal core transformers improve electrical power distribution eff

3、iciency by reducing transformer core losses. This reduction is due to some electromagnetic properties of the amorphous alloys such as: high magnetic permeability, high resistivity, and low coercivity. Experimental results obtained with some single-phase, 60Hz, 5kVA amorphous core transformers instal

4、led in a rural area electric distribution system in Northern Brazil have been confirming their superior performance in comparison to identical nominal rated transformers built with conventional silicon steel cores, particularly with regard to the excitation power and to the no-load losses.Keywords:a

5、morphous alloy, core losses, energy efficiency, transformer1. IntroductionSingle wire earth return （SWER） core transformers are characterized by having only one bushing on the high voltage side and two or more bushings on the low voltage side. Generally, these transformers are designed and construct

6、ed to be used in rural electricity distribution. Usually SWER core transformers are low-cost equipment and have apparent power of 5, 10 and 15kVA.The distribution of electricity power in rural areas has generally high cost of operation for the concessionary companies due to the seasonality of their

7、loads. Under these conditions, the losses in the cores of the transformers manufactured with conventional grain oriented silicon steel become significant when these transformers operate in conditions of light load or no load. In such circumstances, part of the total current absorbed by the electric

8、system is used in the magnetizing core transformers process. However, these losses can be reduced, which can be achieved by replacing the conventional by transformers for amorphous metal-based transformers, because it has been recognized that amorphous metal core transformers improve electrical powe

9、r distribution efficiency by reducing excitation current and core losses1. This reduction is due to some electromagnetic properties of the amorphous alloys such as: high magnetic permeability, high resistivity, and low coactivity2.In this paper are presented some experimental results obtained with S

10、WER, 60kVA amorphous core transformers installed in a rural area electric distribution system, distant 50km from Palmas （capital of the state of Tocantins）, located in the Amazon region of Brazil.From these results it can be observed the superior performance of amorphous core transformers in compari

11、son to identical transformers manufactured with conventional cold-rolled grain-oriented （CRGO） silicon steel cores, particularly with regard to the excitation current and to the no-load losses. Before being installed, all transformers were submitted to test as stated at Brazilian Standards.2. From A

12、cademic Research to Electric Distribution SystemsChronologically, the development of amorphous alloys potentially applicable in transformer cores began in 1975. However, the introduction of these materials in the market only happened in 1976, with the first amorphous metal distribution transformer （

13、AMDT）, built at MITs Lincoln Laboratory （USA）. In that opportunity, a 30kVA transformer prototype, with an amorphous material core, was compared to a conventional silicon steel core transformer of equal nominal rated power. Once the comparative tests were carried out, the results obtained were favor

14、able to AMDT, particularly in the aspects relative to the losses and the excitation current: there was a reduction of 60% in the total losses （87.5% in the core losses and 21% in the copper losses） and the excitation current was reduced from 2.5 to 0.12A. However, in what concerns the weight, AMDT p

15、resented an increase of 15% in comparison to the conventional silicon steel core transformer3.In the early 1980s, EPRI （Electric Power Research Institute, USA） and General Electric launched a project in which 25 units of pre-prototype 25kVA, 15kV amorphous metal core distribution transformers （AMDT）

16、 were tested for two years, followed by designing and testing 1000 units of the same size AMDTs on their distribution systems. The purpose of the field trial was to confer the long-term stability of core loss in amorphous metal transformers under actual operation conditions. Ten years later, there w

17、as an estimated 60000 to 70000AMDT installed throughout the world.In Brazil, the first studies and experimental tests had their origin in laboratories of some different institutions, in the early 1990s4, passing, soon after, to assembly by industrial manufacturers5.3. Experimental ProcedureInFigure1

18、are shown some units of 5kVA SWER transformers with amorphous alloy core （Fe78B13Si9） manufactured by Brazilian industries ITB. Seventeen of these transformers were submitted to open circuit and short circuit tests in the laboratory of the factory, in January 2009.The following are listed the main e

19、lectric characteristics of transformers under test: Rated powerkVA=5; Phases1; Frequency60Hz; High voltage side （kV）: 20.90 to 18.19; Low voltage side （V）: 440/220; Rated current in high voltage side: 0.25A; Rated current in low voltage side: 11.36 Subtractive polarity.All routine tests carried out

20、in accordance with specific Brazilian Standards. But because the main interest is directly related to the energy efficiency in this paper are only presented two tests: no-load and short circuit.4. ResultsTableare presented the comparative values concerning losses and excitation current in single-pha

21、se 5kVA transformers with maximum tension 24.2 and 36.2kV, according to Brazilian Standard NBR 54406.The no-load losses and the excitation current measurements were performed at nominal frequency, applying rated voltage to the low voltage winding and leaving the high voltage in open circuit, as requ

22、ired by Brazilian Standard NBR 53567.2are presented in graph form, the results of comparative tests between seventeen transformers with amorphous alloy core and seventeen transformers with CRGO silicon steel core, all with the same nominal power rating （5kVA）.5. DiscussionSince the excitation curren

23、t is small, the Joule losses in the windings are negligible; the losses resulting from the process of magnetization and demagnetization of the core are significant. In analytical terms, these losses are characterized as hysteresis, eddy currents and anomalous losses.The hysteresis loss is directly p

24、roportional to the frequency of supply voltage and eddy current loss is directly proportional to the square of the frequency of the source. This is the reason why this test should be conducted at nominal frequency.Physically, the reason for the excitation current is small compared to the nominal cur

25、rent of the winding, due to the fact that the no-load transformer can be represented by a high-impedance load with respect to the power supply. And this impedance will be greater the larger the magnetic permeability and electrical resistivity of core material.In the specific case of amorphous Fe78B1

26、3Si9used in the cores of transformers these values are higher than the values for GO FeSi alloys used in conventional transformers. Therefore, the maximum relative magnetic permeability of amorphous Fe78B13Si9, 60Hz, is around 70000, while the value of this quantity for the GO FeSi at 60Hz, is aroun

27、d 40000. Since the value of the electrical resistivity of amorphous Fe78B13Si9is between 130 to 135.m, while the value of this magnitude for the GO FeSi is around 10 to 47.m. Note that the high value of relative permeability provides a better magnetic coupling and the high value of electrical resist

28、ivity results in smaller eddy current losses in the core.Note also that although both transformers have values of excitation current and load loss values below the Brazilian Standard NBR5440 recommended, it appears that the values of the excitation current （0.13A） and no-load losses （8W） for transfo

29、rmers with amorphous core transformers are lower than values of the conventional transformers, that are 0.36A and 36W, respectively.The measurement of short circuit losses was performed at nominal frequency, connecting the high voltage terminals to the source and at the same time keeping the low vol

30、tage windings short-circuited, as shown inFigure3.are presented the comparative values concerning short-circuit test in single-phase 5kV, according to Brazilian Standard NBR54406.As can be seen in2, there are virtually no differences between the values obtained in short-circuit test for both types o

31、f transformers. This, in fact, was expected, since the active losses relate to the Joule effect in the windings and has no dependence on the magnetic material core and short-circuit current depends on the impedance of a short circuit.After submitted to routine tests in the laboratory, the seventeen 5kVA SWER amorphous core transformers were installed in a rural area electric distribution system in Northern Brazil,