Evaluation of Distribution System Losses Due to Unbalanced Load in Transformers a Case Study of Guinness 15MVA, 33/11KV, Injection Substation and its Associated 11/0.415kv Transformers in Benin City, Nigeria

DOI : 10.17577/IJERTV2IS3018

Download Full-Text PDF Cite this Publication

Text Only Version

Evaluation of Distribution System Losses Due to Unbalanced Load in Transformers a Case Study of Guinness 15MVA, 33/11KV, Injection Substation and its Associated 11/0.415kv Transformers in Benin City, Nigeria

Egwaile J. O; Onohaebi S.O; Ike S. A;

Department of Electrical/Electronic Engineering, University of Benin, Benin City, Nigeria.

Abstract

Distribution network losses can vary significantly depending on the load unbalance. Here, an analysis of distribution system losses is presented that considers load unbalance and the effect on the copper losses of a power distribution transformer. The study was carried by analyzing the load readings taken from all the public 11/0.415kv transformers fed from the Guinness injection substation. Comparison was made between the transformer copper losses calculated from the existing unbalanced load condition and the losses that would have resulted if the loads on the transformer were equally distributed among the phases

The result shows that high levels of load unbalance produced greater losses in the transformers, and the total transformer copper losses on both feeders considered can be reduced by about 6% if steps are taken to balance the loads on the phases of the transformer. This will ultimately lead to economic savings, and increase in the systems availability and reliability.

Keywords: Distribution networks, transformer, losses, load unbalance, three-phase load.substation, phase currents

1.0 Introduction

Energy efficiency, in limited energy resources scenario, is considered as a source of energy in a distribution system. [1]. This is particularly important in a country like Nigeria whose distribution System is faced with low voltage and high loss, these two problems of high voltage drop and losses in the distribution network varies with the pattern of loading on the distribution network. [2]. Since system losses represent a considerable cost for utilities and energy consumers, its evaluation and reduction have been recognized as of interest by researchers. There are many distribution network devices responsible for energy loss, these includes losses along distribution feeders, losses in transformer windings and losses associated with unbalanced loads connected to transformers.

Unbalanced load is a common occurrence in three- phase distribution systems. However, it can be harmful to the operation of the network components, its reliability and safety. Thus, a distribution system unbalance phenomenon has been the focus of research in recent decades [3]-[5]. Therefore, considering the importance of loss analysis, the objectives of this work is to evaluate losses due to unbalanced loading in a transformer. Transformers are the link between the generators of the power system and the transmission lines and between lines of different voltage levels.[13]. Transformers power losses can be divided into two main components: no-load losses (hysteresis and eddy current losses) and load losses (ohmic heat losses and conductor eddy current losses). There are, however, other two types of losses namely extra losses created by harmonic and unbalanced currents flowing in the transformer winding, respectively.

2.1 Transformer Losses

Three-phase power transformers are invariably used in transmission, sub transmission and distribution substations for essentially voltage transformation. The power transformer is a complex static electromagnetic machine with windings and a non-linear iron core .[6]. We will first present the transformer equivalent circuit in actual physical units then relate the losses in a transformer to these units.

Figure 1.0: Basic transformer equivalent circuit

An ideal transformer would have no energy losses, and would be 100% efficient. In practical transformers, energy is dissipated in the windings, core, and surrounding structures. Larger transformers are generally more efficient, and those

rated for electricity distribution usually perform better than smaller ones.[7]

Transformer losses are produced by the electrical current flowing through the coils and the magnetic field

alternating in the core. The losses associated with the coils are called load losses, while the losses produced in the core are called no-load losses.

The no-load losses are basically the power required to keep the core energized. These are commonly referred to as core losses, and they exist whenever the unit is energized. No-load losses depend primarily upon the voltage and frequency, so under operational conditions they vary only slightly with system variations.

Load losses, as the terminology might suggest, result from load currents flowing through the transformer. The two components of the load losses are the I2R losses and the stray losses. I2R losses are based on the measured dc (direct current) resistance, the value of which is due to the winding conductors and the current at a given load. The stray losses is a term given to the accumulation of the additional losses experienced by the transformer, which includes winding eddy losses and losses due to the effects of leakage flux entering the internal metallic structures.

Auxiliary losses refer to the power required to run auxiliary cooling equipment, such as fans and pumps;

they are not normally included in the total losses as defined below.

Total losses in a transformer can be summed up as shown in equation 1.1

PTL = PNL + PL 1.1

Where

PTL = Total Losses PNL = No load Losses PL = Load Losses

2.1.1 No Load Losses

Early transformer developers realized that cores constructed from solid iron resulted in prohibitive eddy current and hysteresis loss (as high as 99% of the no-load losses), and their design mitigated this effect with cores consisting of stack layers of laminations, a principle that has remained in use.[8][9]. The no-load loss can be significant, so that even an idle transformer constitutes a drain on the electrical supply and a running cost.

  1. Hysteresis losses: Each time the magnetic field is reversed, a small amount of energy is lost due to hysteresis within the core. According to Steinmetz's formula [11][12], the heat energy due to hysteresis is given by

    , and, 1.2

    hysteresis loss is thus given by

    1.3

    where, f is the frequency, is the hysteresis coefficient and max is the maximum flux density, the empirical exponent of which varies from about

    1.4 to 1 .8 but is often given as 1.6 for iron.[11]

  2. Eddy current losses: Ferromagnetic materials are also good conductors and a core made from such a material also constitutes a single short- circuited turn throughout its entire length. Eddy currents therefore circulate within the core in a plane normal to the flux, and are responsible for resistive heating of the core material. The eddy current loss is a complex function of the square of supply frequency and inverse Square of the material thickness. Eddy current losses can be reduced by making the core of a stack of plates electrically insulated from each other, rather than a solid block; all transformers operating at low frequencies use laminated or similar cores[10][12]. Referring to equivalent circuit of figure 1.0, Core loss and reactance is represented by the following shunt leg impedances of the model:

  • Core or iron losses: RC

  • Magnetizing reactance: XM.

    RC and XM are sometimes collectively termed the

    magnetizing branch of the model.

    2.1.2. Transformer load losses [7]

    These losses are commonly called copper losses or short circuitlosses. Load losses vary according to the

    transformer loading; they are composed of Ohmic heat losses, sometimes referred to as copper losses, since this resistive component of load losses dominates. These losses occur in transformer windings and are caused by the resistance of the conductors. The magnitude of these losses increases with the square of the load current and are proportional to the resistance of the windings. They can be reduced by increasing the cross section of conductor or by reducing the winding length. Using copper as the conductor maintains the balance between weight, size, cost and resistance; adding an additional amount to increase conductor diameter, consistent with other design constraints, reduces losses.

    Referring to equivalent circuit of figure 1.0 above, Winding joule losses and leakage reactance are

    represented by the following series loop impedances of the model:

    • Primary winding: RP, XP

    • Secondary winding: RS, XS.

Mathematically copper loss in a transformer is given by:

Copper losses = I2R 1.4

Where I is the load current and R is resistance of the transformer winding.

There is, however, another type copper loss created as a result unbalanced currents flowing in the phases of the transformer.

For a three phase transformer, let the secondary load currents flowing in each of the phases be

IR, IY, and IB respectively. Thus total load current =

and its associated 11/0.415kV transformers in Benin City, Nigeria

    1. Network Overview

      Guinness Injection substation is located along the Benin Agbor road, immediately after Guinness Nigeria Limited Brewery premises. The substation is fed by the Ikpoba Dam 33kv feeder which radiates from the Benin 132/33kv transmission station along Benin/Sapele road, Benin City. The one line diagram showing the source of power for the Guinness injection substation is shown in figure 1.1

      132KV BUS

      60MVA, 132/33KV

      33KV BUS

      IT = IR + IY + IB 1.5

      Copper losses in each phase = R (Red Phase), R (Yellow Phase), R, (Blue Phase).

      Where R is the winding resistance of the transformer per phase. Therefore

      Total copper loss =

      R + R + R = + + ) 1.6

      If the load on the transformer is balanced,

      BDPA FEEDER

      IKPOBA DAM FEEDER

      33KV BUS

      GUINNESS 15MVA, 33/11KV INJECTION SUBSTATION

      11KV BUS

      ASABA ROAD

      then IR

      = IY

      = IB = I

      FEEDER

      Therefore equation 1.6 becomes:

      Total copper loss = R( I2 + I2 + I2)=3 I2R 1.7

      Equation 1.7 gives the total copper losses in a transformer under balanced load condition, while equation 1.6 gives the total copper losses for unbalanced load.

      Subtracting equation 1.7 from 1.6 yields:

      R( + + ) – 3 I2R = Ploss unbalanced load

      R(( + + ) – 3 I2) 1.8

      Equation 1.8 shows that the total losses in a transformer would be higher as a result of unequal current flowing through the different phases of the transformer under unbalanced load condition.

      In the section that follows we will evaluate the total losses due to unbalanced transformer loading in the Guinness 15MVA, 33/11KV, Injection Substation

      Figure 1.0: One line Diagram Showing Power Source for the Injection Substation.

      As shown in figure 1.1, from the Guinness injection substation radiates two (2) feeders. Asaba Road feeder and BDPA feeder. The Asaba Road feeder has a total of fifty seven (57) 11/0.415KV distribution transformers of various ratings connected to it at various points along its length, while the BDPA feeder has a total thirty-seven (37) 11/0.415KV distribution transformers connected to it at various points along its length.

    2. Collection of Data

The injection substation under review was visited and the following data was collected:

  1. Single lines diagram of the Guinness 15MVA, 33/11/0.415KV injection substation and its associated feeders.

  2. Document containing list of all 11/0.415kv transformers connected to the substation and their ratings.

Since the load reading for each of the 11/0.415 transformer in the network was not available, we embarked on taking load readings at each transformer (excluding privately owned transformers because these are not severely affected by unbalanced loads) at different times of the day, this we did between October 2011 September 2012) with the help of Mastech Digital Power Clamp; Model MS2203 capable of

measuring power (real and reactive), voltage, power factor and phase current. The average load reading for the period under review and other data collected for the two feeders is presented in tables 1.0 and 1.1 .

Table 1.0: Substation Parameters; (Asaba Road feeder)

Average Load Current (Amps)

S/N

NAME OF SUBSTATION

Transformer Rating (KVA)

Red Phase

Yellow Phase

Blue Phase

TOTAL

Load Current

1

ADUWAKA

300

124

121

40

285

2

OWIE

500

222

260

157

639

3

ODIONVBA

500

171

125

279

575

4

OGBESON PALACE

500

262

188

212

662

5

IYOBOSA

500

250

228

143

621

6

ADAZE

300

88

58

101

247

7

EBIKADE

500

150

317

197

664

8

OHOVBE PALACE

500

132

67

35

234

9

IGABOR

500

68

30

12

110

10

UNITY

200

25

21

32

78

11

UGOKPOLOR

500

220

280

207

707

12

LIBERTY

500

192

3

124

319

13

IGBINIDU

500

36

11

106

153

14

AZAGBA

300

129

65

196

390

15

SONOWE

300

62

56

70

188

16

PHILOVE JUNCTION

300

105

22

37

164

17

DAO

100

30

70

24

124

18

PIPELINE

500

294

155

133

582

19

UWAIMA II

500

181

116

8

305

20

UWAIMA II

500

80

110

100

290

21

UYIGUE

00

346

359

352

1057

22

AMUFI

500

179

159

8

346

23

UGBOZIGUE

500

220

230

243

693

24

JEHOVAH

300

228

76

261

565

25

AGBOWO 1

500

230

191

83

504

26

AGBOWO 11

500

191

118

92

401

27

IGUOMON 1

500

126

170

176

472

28

IGUOMON 11

500

130

160

180

470

29

IKHUENIRO 1

500

218

186

101

505

30

IKHUENIRO 11

500

216

197

87

500

31

NEPASCO 1

500

145

342

315

802

32

NEPASCO 11

300

112

123

116

351

33

ST MICHEAL

300

87

69

78

234

34

AFENGE

500

219

221

219

659

35

EHIKHIANMWEN

500

346

359

355

1060

36

BULLSEYE

500

115

135

177

427

37

GODIAC

500

219

253

165

637

Table 1.1: Substation Parameters (BDPA feeder)

Average Load Current(Amps)

S/N

NAME OF SUBSTATION

Transformer Rating (KVA)

Red Phase

Yellow Phase

Blue Phase

TOTAL

Load Current

1

ARUNDE

300

270

283

335

888

2

EVBADOLOYI

300

337

193

200

730

3

IHASE

500

85

126

178

389

4

ASOWATA

315

262

167

54

483

5

OSASUMWEN

200

126

133

109

368

6

ALAGHODARO

300

122

136

95

353

7

IFASUYI

300

209

258

108

575

8

OTABOR

500

146

185

58

389

9

OWANAZE

300

207

250

120

577

10

SUNNY FOAM

500

300

330

142

772

11

POGAH

500

300

268

330

898

12

POGAH RELIEF

300

268

200

190

658

13

UGBOKODU

300

206

240

119

565

14

ARMY SIGNAL

500

300

340

280

920

15

OBASUYI

500

306

269

340

915

16

OBASUYI 2

500

90

130

180

400

17

BDPA 1

500

340

260

350

950

18

BDPA 2

500

237

203

135

575

19

BDPA 3

500

240

124

122

486

20

OBANOSA

300

136

160

104

400

2.4.1 Data Analysis

From tables 1.0 and 1.1, the copper losses for each transformer in the network was calculated using equation 1.6; i.e.

Total copper loss (unbalanced load condition) = R + R + R = R + +).

In doing this the winding resistance per phase is assumed to be unity since this value is the same and

constant for all phases of the transformer irrespective of loading.

Next balanced load condition was considered, which implies that the total load current will be shared equally among the phases of the transformer.

Under this condition equation 1.7 holds. i.e.

Total copper loss (balance load condition) = R ( I2 + I2 + I2) = 3 I2R. Thus the total copper losses under balanced load condition were also calculated.

The results for the two feeders are presented in table 1.3 and 1.4 respectively.

Table 1.3: Copper Losses for BDPA feeder

Unbalanced Load Condition

Balanced Load Condition

S/N

NAME OF SUBSTATION

Transfor mer Rating (KVA)

Total CU

Loss (Red Phase)

Total CU Loss (blue Phase)

Total CU Loss (yellow Phase)

Total loss in the Three Phases

Total CU Loss (Per Phase)

Total loss in the three Phases

1

ARUNDE

300

72900

80089

112225

265214

87616

262848

2

EVBADOLOYI

300

113569

37249

40000

190818

59211.11

177633.3

3

IHASE

500

7225

15876

31684

54785

16813.44

50440.33

4

ASOWATA

315

68644

27889

2916

99449

25921

77763

5

OSASUMWEN

200

15876

17689

11881

45446

15047.11

45141.33

6

ALAGHODARO

300

14884

18496

9025

42405

13845.44

41536.33

7

IFASUYI

300

43681

66564

11664

121909

36736.11

110208.3

8

OTABOR

500

21316

34225

3364

58905

16813.44

50440.33

9

OWANAZE

300

42849

62500

14400

119749

36992.11

110976.3

10

SUNNY FOAM

500

90000

108900

20164

219064

66220.44

198661.3

11

POGAH

500

90000

71824

108900

270724

89600.44

268801.3

12

POGAH RELIEF

300

71824

40000

36100

147924

48107.11

144321.3

13

UGBOKODU

300

42436

57600

14161

114197

35469.44

106408.3

14

ARMY SIGNAL

500

90000

115600

78400

284000

94044.44

282133.3

15

OBASUYI

500

93636

72361

115600

281597

93025

279075

16

OBASUYI 2

500

8100

16900

32400

57400

17777.78

53333.33

17

BDPA 1

500

115600

67600

122500

305700

100277.8

300833.3

18

BDPA 2

500

56169

41209

18225

115603

36736.11

110208.3

19

BDPA 3

500

57600

15376

14884

87860

26244

78732

20

OBANOSA

300

18496

25600

10816

54912

17777.78

53333.33

Table 1.4: Copper Losses for Asaba Road feeder

Unbalanced Load Condition

Balanced Load Condition

S/N

NAME OF SUBSTATION

Transformer Rating (KVA)

Total CU

Loss (Red Phase)

Total CU

Loss (blue Phase)

Total CU Loss (yellow Phase)

Total loss in the Three Phases

Total CU Loss (Per Phase)

Total loss in the three Phases

1

ADUWAKA

300

15376

14641

1600

31617

9025

27075

2

OWIE

500

49284

67600

24649

141533

45369

136107

3

ODIONVBA

500

29241

15625

77841

122707

36736.11

110208.3

4

OGBESON PALACE

500

68644

35344

44944

148932

48693.78

146081.3

5

IYOBOSA

500

62500

51984

20449

134933

42849

128547

6

ADAZE

300

7744

3364

10201

21309

6778.778

20336.33

7

EBIKADE

500

22500

100489

38809

161798

48988.44

146965.3

8

OHOVBE PALACE

500

17424

4489

1225

23138

6084

18252

9

IGABOR

500

4624

900

144

5668

1344.444

4033.333

10

UNITY

200

625

441

1024

2090

676

2028

11

UGOKPOLOR

500

48400

78400

42849

169649

55538.78

166616.3

12

LIBERTY

500

36864

9

15376

52249

11306.78

33920.33

13

IGBINIDU

500

1296

121

11236

12653

2601

7803

14

AZAGBA

300

16641

4225

38416

59282

16900

50700

15

SONOWE

300

3844

3136

4900

11880

3927.111

11781.33

16

PHILOVE JUNCTION

300

11025

484

1369

12878

2988.444

8965.333

17

DAO

100

900

4900

576

6376

1708.444

5125.333

18

PIPELINE

500

86436

24025

17689

128150

37636

112908

19

UWAIMA II

500

32761

13456

64

46281

10336.11

31008.33

20

UWAIMA II

500

6400

12100

10000

28500

9344.444

28033.33

21

UYIGUE

500

119716

128881

123904

372501

124138.8

372416.3

22

AMUFI

500

32041

25281

64

57386

13301.78

39905.33

23

UGBOZIGUE

500

48400

52900

59049

160349

53361

160083

24

JEHOVAH

300

51984

5776

68121

125881

35469.44

106408.3

25

AGBOWO 1

500

52900

36481

6889

96270

28224

84672

26

AGBOWO 11

500

36481

13924

8464

58869

17866.78

53600.33

27

IGUOMON 1

500

15876

28900

30976

75752

24753.78

74261.33

28

IGUOMON 11

500

16900

25600

32400

74900

24544.44

73633.33

29

IKHUENIRO 1

500

47524

34596

10201

92321

28336.11

85008.33

30

IKHUENIRO 11

500

46656

38809

7569

93034

27777.78

83333.33

31

NEPASCO 1

500

21025

116964

99225

237214

71467.11

214401.3

32

NEPASCO 11

300

12544

15129

13456

41129

13689

41067

33

ST MICHEAL

300

7569

4761

6084

18414

6084

18252

34

AFENGE

500

47961

48841

47961

144763

48253.44

144760.3

35

EHIKHIANMWEN

500

119716

128881

126025

374622

124844.4

374533.3

36

BULLSEYE

500

13225

18225

31329

62779

20258.78

60776.33

37

GODIAC

500

47961

64009

27225

139195

45085.44

135256.3

    1. Discussion

      The results from the copper losses calculations for both balanced and unbalanced load conditions and the resultant tables (table 1.3 & 1.4 above) show that:

      1. The copper losses of transformer varies considerably with the degree of load unbalance. (b)The total transformer copper loss in the Asaba road feeder is 3547002 units and 3318863 units for balance and unbalanced load conditions respectively.

        1. The total transformer copper losses in the BDPA feeder is 2937661units and 2802828units for balance and unbalanced load conditions respectively

        2. The total transformer copper losses on both feeders can be reduced by about 6% if steps are taken to balance the loads on the phases of the transformer.

        3. Unbalanced loading will reduce the capacity of the transformers since the protective devices of the overloaded phase will operate even before other phases senses overload.

    2. Conclusion and Recommendations.

In this paper loss evaluation in distribution systems considering both unbalanced load and balanced load Scenarios in the transformers is presented.

The study shows that high levels of load unbalance produced greater losses in the transformers. This means that network reconfiguration considering load balancing is highly recommend in order to diminish overall system losses. It is recommended that balanced repartition of single-phase loads between the phases of the three-phase network should be vigorously pursued by the authorities concerned. The authorities concerned should also ensure that all the phases are always available to discourage consumers from shifting their loads when a phase fails. To this end, it is recommended that automatic phase monitors that would promptly report an open phase be installed in all the transformers in the network. This will not only help to reduce losses but it will also enhance the systems availability and reliability.

References.

[1]. Ikbal A, Mini S. T, Pawan K; Optimal capacitor placement in smart distribution systems to improve its maximum loadability and energy efficiency International Journal of Engineering, Science and Technology Vol. 3, No. 8, 2011.

[2]. Oodo O S; Liu Y; Sun H; Application of Switched Capacitor banks for Power Factor Improvement and Harmonics Reduction on the Nigerian Distribution Electric Network International Journal of Electrical & Computer Sciences IJECS-IJENS Vol: 11 No: 06

  1. Meliopoulos A. P; Kennedy J, C; Nucci, C.A; Borghetti A;and Contaxies, G Power distribution practices in USA and Europe: Impact on power quality, 8th International Conference on Harmonics and Quality of Power Proceeding, pp 24-29, October 1998

  2. Balda J.C; Oliva A.R; McNabb D.W; and Richardson R.D; Measurements of neutral currents and voltages on a distribution feeder, IEEE Trans. Power Delivery, 12(4), pp 1799-1804,

    October 1997

  3. Chen T.H; and Yang W.C;, Analysis of Multigrounded Four-Wire Distribution Systems Considering the neutral grounding, IEEE Trans. Power Delivery, 16(4), pp 710-717, October 2001 [6]. Nasser D. Tleis; 2008 Power Systems Modelling and Fault Analysis Published by Elsevier Ltd

  1. Kubo, T; Sachs, H.; Nadel, S. (2001). Opportunities for New Appliance and Equipment Efficiency Standards. American Council for an Energy-Efficient Economy.

    http://www.aceee.org/research-report/a016. Visited November 16th, 2012

  2. Allan, D.J. (Jan. 1991). "Power Transformers The Second Century". Power Engineering Journal 5 (1): 5

    14. http://ieeexplore.ieee.org/xpl/freeabs_

  3. Kulkarni, S. V.; Khaparde, S. A. (May 24, 2004). Transformer Engineering: Design and Practice. CRC. [10]Riemersma, H.; Eckels, P.; Barton, M.;

Murphy, J.; Litz, D.; Roach, J. (1981). "Application of Superconducting Technology to Power Transformers". IEEE Transactions on Power Apparatus and Systems PAS-100 (7): 3398.

  1. Steinmetz's Formula for Magnetic Hysteresis". http://www.ee-reviewonline.com Retrieved 7 February 2013.

  2. Say M.G 2005,The Performance and Design of Alternating Current Machines CBS publishers and distributors.

  3. Grainger, J.; Stevenson, W. (1994). Power System Analysis. New York: McGrawHill. ISBN 0-07-061293-5

Leave a Reply