Journal of Power and Energy Engineering, 2014, 2, 416-422 Published Online April 2014 in SciRes. http://www.sc irp.org/journal/jpee http://dx.doi.org/10.4236/jpee.2014.24056 How to cite this paper: Hu, H.M., et al. (2014) Dynamic Equivalent Method of Motor Loads for Power Systems Based on the Weighted. Journal of Power and Energy Engineering, 2, 416-422. http://dx.doi.org/10.4236/jpee.20 14.24056 Dynamic Equivalent Method of Motor Loads for Power Systems Based on the Weighted Hanmei Hu1, Bo Hong1, Ting Chen2, Qinfeng Li1 1College of Electrical Engineering and New Energy, China Three Gorges University, Yichang, China 2College of Electrical Engineering, Wuhan University, Wuhan, China Email: hongbo8966@163.com Received Dec emb er 2013 Abstract Dynamic equivalence can not only largely reduce the system size and the computation time but also stress the dominant features of the system [1]-[3]. This paper firstly recommends the basic concept of dynamic equivalent and the status of both domestic and abroad development in this area. The most existing equivalent methods usually only deal with st atic load models and neglect the dynamic characteristics of loads such as induction motors. In addition, the existing polymeri- zation method which is based on the frequency domain algorithm of induction electric machines parameters takes a long time to equivalent for the large system, then the new method based on the weighted is proposed. Then, the basic steps for dynamic equivalence with the weighted method are introduced as follows. At first, th e clustering criterion of motor loads based on time domain simulation is given. The motors with similar dynamic characteristics are classified into one group. Then, the simplication of the buses of motors in same group and network is carried out. Finally, parameters of the equivalent motor are calculated and the equivalent system is thus obtained based on the weighted. This aggregation method is applied to the simple distribution system of 4 generators. Simulation results show that the method can quickly obtain polymerization parame- ters of generator groups and the aggregation model retains the dynamic performance of the orig- inal model with good accuracy, the active and reactive power fitting error is smaller as well. Keywords Power System; Dynamic Equivalent; Induction Moto rs; Parameter A gg reg atio n; The Weighted Method 1. Introduction With the increasing growth of power grid interconnection, the scale of power system becomes larger and larger. Power systems consist of many synchronous generators and each generator includes many elements. In the study of power system dynamics, employing all of the detailed elements of generators in modeling creates a sophisti- cated and large system which put a heavy computational burden in simulation. Generally we only interested in one local system which is called research system (also called internal system). For external subsystem far side, we just need to keep its dynamic effects on research system unchanged in the study. There is no need to investi-
H. M. Hu et al. gate its internal structure in detail, at the same time we can simplify the system by making appropriate equiva- lent. This area we want to simplify is the so-called external equivalent system. These are the fundamentals of dynamic equivalents. Dynamic equivalents are used to reduce the computing effort and manifest the principal characteristics of Power systems. In general it consists of coherency method, mode method and identification method so far. The coherency method is widely used for its advantages in physical transparence, adaptation to non-linear systems and big disturbances, and it can be used directly in transient stability analysis. It is also fit for equivalent of large scale system with a great velocity and a controllability of precision. Many research works have been carried out in the dynamic equivalence area [4]-[17]. Researchers in China also have made important contributions. The most existing equivalent methods usually only deal with static load models and neglect the dynamic characteristics of loads such as induction motors. In addition, most equivalence methods existing in the domestic adopt the frequency domain aggregation algorithm. This approach assumes that the transfer function of the generator and its control system are divided into several links which are aggre- gated respectively. Since the polymerization of coherent generators is complex, it takes a long time to equivalent for the large system. In order to solve this situation, in this paper, a dynamic equivalent method based on the weighed which considers motor dynamics is presented. The basic principle and procedure for aggregation are described. Clustering criterion of motors and parameter aggregation for the equivalent motor are also discussed in detail. Simulation results with a simple distribution system have validated the proposed method. During the disturbance, the power generation unit has the same speed, voltage, total mechanical power and total active power as the original group. 2. Clustering of the Motors Most generator clustering is based on the coherency principle. It depends on whether the rotor angle of each ge- nerator can swing coherently. In fact it demands the synchronous rotors speed to be the same in a group. Similarly, the clustering of motors may be determined according to whether each motor rotor speed is the same. The spectral coefficient clustering analysis method is applied to motor clustering. It can be done as follows. 1) Forming the parametric index set , where , 2) Normalizing the original indexes. is used to represent the parametric index set after normaliza- tion. 3) Preliminary clustering. At the beginning each motor is clustered into a group. It can be written as { } (0) i 0,,,1,2,,, Mi M l mNGXiN ′ ==== where is used to count the loops, is the number of motor groups and is the number of motor bus- es. 4) Calculating the parametric distance between each group. The parametric distance is calculated by A symmetric parametric distance matrix is available after this step. 5) Finding out the closest groups in the distance space. The parametric distance and electrical distance are comprehensively considered. 6) Checking the number of motor groups . Generally speaking, the simulation results will have satisfying accuracy when the motors are classified into two groups. So, if is greater than 2, then return to step 4) to repeat the clustering of motors; otherwise stop. 3. The Simplication of Buses and Network 3.1. The Simplication of Motor Buses The motor buses will be combined and simplified first after identification of the coherent motor group. Assume the bus set of the motor group which is used for combine as , and the system bus set associated with as , and the system bus set not related to as . In the simplify, use an equivalent bus set to
H. M. Hu et al. replace bus set and retain bus set , but the associated branch of need to be converted into the associated branch of equivalent bus set , keep the bus set and all of its power system the same before and after simplification. The node equation of original system is obtained as follows (the subscripts A, B, C re- spectively represent bus , , ): 0 . 0 AAA ABA BBA BBBCB CCBCCC I YYU IYYY U IYY U = (1) the node equation for the new system after the simplification of the coherent motor bus is as follows: 0 . 0 AAA ABA BBA BB BtB ttB ttt I YYU I YYYU I YYU ∗ = (2) Remain , , the same in the equivalent and calculate , , . And the diagonal element of in the original system node equation need to correct as accordingly. The equivalent need to sa- tisfy the constraint conditions for and in the steady state. The exchanged power between different bus in and is unchanged in the steady state, so it is also called identical power transformation. 3.2. Network Simplication The key of network simplification is the elimination of nonlinear load. The network steady trend deviation can be reduced to zero and the dynamic error can be as small as possible by displacing the nonlinear load to the re- mained bus equally in the process of elimination .The common methods just like REI (Radial Equivalent Inde- pendent) . 4. Aggregation of Motor Parameters Based on the Weighted The traditional frequency domain polymerization is rigorous in theory, but it also has some weaknesses as below: aggregation algorithm is complex, and it takes a long time to equivalent for the large system. The following weighted method simplifies the parameter aggregation process under the condition of guaranteeing accuracy, which can save the calculation time and advantageous to project realization. We can get one motor group by the correlation recognition. Since the capacity of the synthe- sis equivalent motor is the sum of the capacity of each motor, namely (3) the subscript represents equivalent motor, then we can export the parameters for the model of equivalent motor and its control system in detail. 4.1. Basic Principle The so-called equivalent means that the external characteristic of equivalent motor is the same or similar as the overall external characteristic of the motors in parallel. Each motor adopts the T-end equivalent circuit, as shown in Figure 1, now simplify the parallel circuits to an equivalent circuit. 4.2. The Equivalent of Inertia Time Constant Assume that the kinetic energy of equivalent motor in synchronous speed is the sum of that of each motor. Ac- cording to the definition of inertia time constant, is the value that kinetic energy in synchronous speed mul- tiply two then divide by capacity, so 1 11 22 m JMNMJi Ni i T STS = = ∑ (4) where is inertial time constant of ith asynchronous motor; is the inertial time constant of the equiva-
H. M. Hu et al. (a) (b ) Figure 1. Equivalent T–end Circuit of Motor. (a) Equivalent Circuit before simplified (b) Equivalent Cir- cuit after simplified. lent motor; is the rated capacity of ith asynchronous motor; is the capacity of the equivalent motor. Since (5) suppose (6) with the both sides of Equation (10) divided by the half of , we get (7) 4.3. The Equivalent of Electrical Parameters Equivalent excitation reactance is the value of excitation reactance in parallel of the m motors. It should be noted that the impedance in figure are all per unit values under the total capacity, and the impedance are per unit values under the capacity of each motor. The connection between and is as follows: (8) from what has been discussed above, we get (9) in the same way, we get 1 1mi rm ri i IM li Mi RR jX jX SS ρ = = ++ ∑ (10) where , is the slip of ith motor and the equivalent motor respectively; , is the rotor resistance of them; , is the sum of the stator leakage reactance and the rotor leakage reactance of them . When , the same is true for Equation (14), thereby , (11) where , (12)
H. M. Hu et al. 4.4. The Equivalent of Slip Assume that the motor runs at a constant slip , set , (13) we get (14) 4.5. The Weighted Sum Method Equivalent inertia time constant and equivalent admittance is the weighted sum of inertia constant and admit- tance of each motor, weights is the proportion that each motor capacity accounts in total capacity. In order to simplify the analysis and calculation, the method that add them together after multiply weights is sometimes extended to the calculation of the equivalent slip, equivalent mechanical torque and the equivalent parameters. When the motor takes the T–end equivalent circuit as shown in figure, the Weighted Sum Method may be adopted approximatively to calculate the equivalent electrical parameters. Then we can assume that inner node in each motor equivalent circuit is in parallel, so (15) where is the electrical branch impedance of the ith electric motor; is electrical branch impedance of the equivalent motor. For the branch of stator, ; for excitation branch, and for the branch the rotor, . 5. Simulation Example A simple power distribution network is shown in Figure 2, all the impedance of the transformer and line shown in the figure is per unit values. Table 1 lists the four electric motor parameters. The active and reactive power models both use the power function model, and the power function adopt the IEEE recommended parameters. Equivalent motor parameters is shown in Table 2. Make the mistress line voltage drop 50%, monitor the total output active and reactive power of mistress line 1 respectively before and after polymerization. The curve is shown in Figures 3 and 4. Use the fitting degree of active and reactive power absorbed in motor before and after polymerization as the basis for aggregation effect judgment. From the curve, we can conclude that the aggregation model retains the dynamic performance of the original model with good accuracy, the active and reactive power fitting error is smaller as well. Figure 2 . A sample distribution network. ( ) ∑ = + = ′ m ili iri iri i X sR sR a 12 ρ ( ) ∑ =+ = ′m iliiri lii XsR X b 12 ρ M4 M3 M2 M1 0037+j0132 0.024+j0.053 0.042+j0017 0.001+j0.002 0.0023+j0.08 1
H. M. Hu et al. Figure 3. Active curves before and after polymerization. Figure 4. Reactive curves before and after polymerization. Table 1. Motor parameters. Motor Rs Xs Xm Rr Xr Tj/s Sb/KVA Ub/KV 1 0.0163 0.0816 2.25 0.0287 0.0836 1 597 4.16 2 0.0022 0.0759 2.62 0.0288 0.1037 0.66 3420 4.16 3 0.0235 0.1353 2.58 0.044 0.143 0.2 4269 1.1 4 0.0235 0.1353 2.58 0.044 0.143 0.2 2712 1.06 Table 2. Equivalent moto r parameters. Equivalent motor Rs Xs Xm Rr Xr Tj/s Sb/KVA Ub/KV Para m eters 0.0165 0.114 2.57 0.0384 0.1 276 0.39 10998 13.8 6. Conclusion This paper proposes the weighted method which follows the principle that the total output active and reactive power of distribution network respectively remains unchanged before and after polymerization to calculate the equivalent parameter of the distribution network. By adding the coherency identification to motors and intro- ducing the calculation method of the weighted summation on the basis of traditional equivalence calculation, aggregation model of active and reactive power of the steady-state error is very small and it can accurately maintain oscillation mode of the original system, in addition, the deviation of oscillation amplitude is also small. Acknowledgements I would like to express my gratitude to all those who helped me during the writing of this thesis. I gratefully ac- knowledge the help from my supervisor, Ms. Hu Hanmei, who has offered me valuable suggestions in the aca- before polymerization after polymerization active power in per unit (pu) time (s) before polymerization after polymerization reactive power in per unit (pu) time (s)
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