MVA方法短路电流计算MVA Method Short Circuit Calculation.doc

MVA Method Short Circuit CalculationA Short Circuit Study is an important tool in determining the ratings of electrical equipment to be installed in a project. It is also used as a basis in setting protection devices. Computer software simplifies this process however, in cases where it is not available, alternative methods should be used. The per-unit and ohmic method are very tedious manual calculation. These hand calculations are very prone to errors due to so many conversion required. In per unit, base conversion is a normal part of the calculation method while in ohmic method, complex entities conversion.The easy way to do hand calculation is the MVA method.In this example, we shall be presenting a short circuit study of a power system. Motors are are already lumped with ratings 37kW and below assigned an impedance value of 25% while larger motors are 17%. A 4MVA generator is also included into the system to augment the utility.Figure 1Utility: 33KV, 250 MVAsc （the 250MVA in this example is just assumed. Ask your utility for the actual fault level at your point of connection）Transformer 1: 10 MVA, 33/11KV, 9% Z11KV BusGenerator: 4MVA, X"d = 0.113Transformer 2: 5 MVA, 11/6.6KV, 7% ZMotor 1: 5MVA (Lumped), 17% Z6.6KV BusTransformer 3: 2 MVA, 6.6KV/400V, 6% ZMotor 3: 6.8 MVA (Lumped), 17% Z400V BusMotor 4: 300 KVA (Lumped), 17% ZMotor 5: 596 KVA (Lumped), 25% ZIn the event of a short circuit, the sources of short circuit current are1. Utility2. Generators3. MotorsStatic loads such as heaters and lighting do not contribute to short circuit.The "Equivalent MVA" are:Transformers and MotorsGeneratorsCables and ReactorsIn Figure 1, I have calculated the Equivalent MVAs of each equipment, writing it below the ratings.Figure 2Utility: MVAsc = 250MVATransformer 1: MVAsc = 10 / 0.09 = 111.11 MVA11KV BusGenerator: MVAsc = 4 / 0.113 = 35.4 MVATransnformer 2: MVAsc = 5 / 0.07 = 71.43 MVAMotor 1: MVAsc = 5 / 0.17 = 29.41 MVA6.6KV BusTransformer 3: MVAsc = 2 / 0.06 = 33.33 MVAMotor 3: MVAsc = 6.8 / 0.17 = 40 MVA400V BusMotor 4: MVAsc = 0.3 / 0.17 = 1.76 MVAMotor 5: MVAsc = 0.596 / 0.25 = 2.38 MVAFigure 3Upstream ContributionStarting from the utility, combine MVAs writing each one above the arrows.At Transformer 1:MVAsc @ 33KV = 250 MVAMVAsc @ 11KV = 1/ (1 / 250 + 1 /111.11) = 76.87 MVAAt Transformer 2:MVAsc @ 11KV = 76.87 + 35.4 + 29.41 = 141.68 MVAMVAsc @ 6.6KV = 1/ (1 / 141.68 + 1 / 71.43) = 47.49 MVAAt Transformer 3:MVAsc @ 6.6KV = 47.49 + 40 = 87.49 MVAMVAsc @ 400V = 1/ (1 / 87.49 + 1 / 33.33) = 24.14 MVAAt 400V MotorsMotor 3: MVAsc = 24.14 x 1.76 / ( 1.76 + 2.38 ) = 10.26 MVAMotor 4: MVAsc = 24.14 x 2.38 / ( 1.76 + 2.38 ) = 13.88 MVADownstream ContributionStarting from the bottom (400V Bus), I combined MVAs writing each one below the arrows. In this bus, the motor contribution to short circuit is the sum of the MVAs of the lumped motors Motor 3 and Motor 4.At Transformer 3:MVAsc @ 400V = 1.76 + 2.38 = 4.14 MVAMVAsc @ 6.6KV = 1/ (1 / 4.14 + 1 / 33.33) = 3.68 MVAAt Transformer 2:MVAsc @ 6.6KV = 3.68 + 40 = 43.68 MVAMVAsc @ 11KV = 1/ (1 / 43.68 + 1 / 71.43) = 27.11 MVAAt Transformer 1:MVAsc @ 11KV = 27.11 + 29.41 + 35.4 = 91.92 MVANote: Two downstream plus the generator contribution.MVAsc @ 33KV = 1/ (1 / 91.92 + 1 /111.11) = 50.3 MVATo determine the Faults Current at any bus on the power system, add the MVA values above and below the arrows. The sum should be the same on any branch.Example:11 KV Bus:From Transformer 1: MVAsc = 76.87 + 91.92 = 168.79 MVAFrom Generator : MVAsc = 35.4 + 133.39 = 168.79 MVAFrom Transformer 2: MVAsc = 141.68 + 27.11 = 168.79MVAFrom Motor 1: MVAsc = 139.38 + 29.41 = 168.79 MVAThis is a check that we have done the correct calculation.Ifault @ 11KV = 168.79 / (1.732 x 11) = 8.86 kAAll we have done above are three phase faults, you may ask, how about single phase faults?For single phase faults, positive sequence, negative sequence and zero sequence impedances need to be calculated.If = 3 (I1 + I2 + I0)Examining the circuit in Figure 1, at the 400V Bus, on Transformer 3 contributes to the zero sequence current.For transformers, the negative sequence and zero sequence impedance are equal to the positive sequence impedance.Z1 = Z2 = Z0 orMVA1 = MVA2 = MVA0At the 400V Bus1 / MVAsc =1/3 (1 / MVAsc1 + 1 / MVAsc2 + 1 / MVAsc0)1 / MVAsc = 1/3 (1 / 28.28 + 1 / 28.28 + 1 / 33.33 )MVAsc =3 x  9.93 = 29.79  MVAIf = 29.79 / (1.732 x 0.4) = 43 kAAt 6.6KV Bus1 / MVAsc = 1/3 (1 / MVAsc1 + 1 / MVAsc2 + 1 / MVAsc0)1 / MVAsc = 1/3 (1 / 91.17 + 1 / 91.17 + 1 / 71.43)MVAsc = 3 x 27.83  = 83.49 MVAIf = 83.49 / (1.732 x 6.6) = 7.26 kAConclusion:This example illustrates that using the MVA Method of Short Circuit Calculation, it will be very easy to calculate the fault current at any node within a power s。