THE DYNAMIC BEHAVIOUR OF SYNCHRONOUS AND ASYNCHRONOUS MACHINES WITH TWO-SIDE ASYMMETRY CONSIDERING SATURATION

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THE DYNAMIC BEHAVIOUR OF SYNCHRONOUS AND ASYNCHRONOUS MACHINES WITH TWO-SIDE ASYMMETRY CONSIDERING SATURATION By P. VAS Department of Electric IIIachines. Technical University. Bndapest Received February 3. 1973 Pres~nted by Prof. Dr. Gy. RETTER Introduction In recent years a new effort "was made to calculate the transient operation of electrical machines with the help of the state yariable Park-yector component method. Problems were solved in connection "\vith control theory of thyristor connections in electrical machines [1, 2, 3]. In the present paper it will be shown how the method can be used for calculating the transient operational characteristics of synchronous and asynchronous machines with t.. woside asymmetry when saturation is also present. The steady state analysis of an induction motor "\vith asymmetrical cage has been discussed by VAS [4], from the paper the quadrature and direct axis rotor operator impedances can be derived, and be of use if the transients of asymmetrical squirrel cage motors are calculated by the method of this paper. Steady state and transient behaviour of the induction motors -..vith asymmetrical rotor has been discussed in [5], [6], [7], but "\"ith no asymmetry in the stator side. Saturation of the main flux paths was also neglected, to be considered here. Dynamical equations of asymmetrical machines neglecting saturation Using the well-known assumptions [9], the Park-vector equations of a three-phase symmetrical ac. machine - lacking zero sequence components - in a reference-frame rotating at an arbitrarily varying speed Wa (1) (2)

32 P. VAS where Us, Un is, i,,1ps and ifr are the stator and rotor voltage, current and flux vectors. The fluxes are here Ls and LT are the stator and rotor inductances, Lm is the mutual inductance between stator and rotor. The torque is (3) (4) 3 (_ -;;) m = -p 'IflsXLs 2 (5) where p is the number of pole pairs. Assuming asymmetrical stator and rotor, these equations can be resolved into d, q components. However, as the voltage equations consist of the derivatives of both stator and rotor currents, for sake of simplicity the differential equations are solved for the fluxes. Thus the state vector equation in a reference-frame rotating at an arbitrary speed Wa is: x = Ax + Bu (6) where x is the state vector of fluxes, A is the transition matrix, B is a unity matrix order four, and u is the column vector of the stator and rotor voltage components }~= f l k r Wa! T;d T;d 1 k Wa 0 r T;q T;q J:~ 1 0 Wo - Wr T;d T;d 0 ~ 1 - Wo + Wr L T;q T;q x= [lpsd,lpsq' 'Iflrd' 'Iflrq]t ; U= [USd' usq' Urd' urq]t (7) 0 where Wr is the speed of the rotor, and k and T are constants given in Appendix 1. For an induction motor the rotor voltages are UTd = u rq = 0 as the rotor circuits are short-circuited, and for a synchronous generator Urd = Ue

DYNAMIC BEHAVIOUR OF MACHINES WITH CONSIDERING SATURATION 33 where U e is the voltage of the exciting coil, and u rg = 0. The stator volt ages for an asymmetrically fed induction motor are: Usd = 0,666(ua - 0,5Ub - 0,5ue) where usq = 0,666(0,866ub - 0,866ue) U a = Usa sin (WIt) Ub = Usb sin (wit - 271:/3) Ue = Use sin (WIt - 471:/3) (8) (Usa, Usb, Use are the peak values of the a, b, c stator phase voltages, and for the synchronous generator it can be shown that USd] = Us [Sin 0] [ cos b U Sq (Q) where Us is the peak value of the stator voltage, and 0 is the load angle.) In Eq. (7) for synchronous machines it must be considered that in case of a generator o = S (w r - w I ) dt + 0 0 (10) o where W I is the angular frequency of the stator. The equation of motion, using (5) for an induction motor is: dt (11) where J is the moment of inertia, T L is the load torque, and Ir is the coefficient of viscous damping. For the synchronous generator, using (10) and the equation of motion, a similar equation can be derived: d 2 (o'p) 1 [ 3 kr d(o'p)] dt 2 = J T mech - P 2 L~ (lpsq"prd - lprq1j!sd) - K -d-t- (12) where T mech is the mechanical torque of the turbine generator, and K is the coefficient of damping. From (5) it is seen if the rotor resistances of an induc- 3 Periodica P"lytechnica El. 22/1

34 P. VAS tion motor differ from each other (Rra # R rb # R rc), the d, q resistances of the rotor can be expressed as In case of a squirrel cage machine 'with asymmetrical rotor, equations for the d, q rotor impedances can be derived from paper [4]. If the stator resistances of the synchronous or asynchronous machine differ, the d and q stator resistances can be obtained analogue to Eq. (13). The general equations considering saturation. In the follo"\\ing only the saturation of the main flux paths "\~ill be considered, such a case may also occur with a symmetrical motor. From Eq. (6) - assuming that the magnetizing curve I Urn I (Iimi) is known, where im is the magnetizing current Park-vector (i = is + ir) and the stator and rotor reactances are Xs = Xm + XSO"' Xr = X + XrO"' - we get: (14) where the current state vector is Ys (subscript S refers to saturation), As is the transition matrix and B a voltage coefficient matrix: where the submatrices are: Wa(C1X s - -C1RSq w a (C 2 X r - C 1 X m )1 I C 2 Rrq C 2 X m)] Wa(C 3 Xm - C 4 X S) - W rc 3 Xm] C 4 RSq Wa(C 3Xr - C 4 X m) - wrc 3 Xr] -C 3 Rrq

DYNAAnC BEHAVIOUR OF MACHINES WITH CONSIDERING SATURATION 35 Coefficients k and C are found in Appendix 2. y = [isd' i sq, i rd, irq]t ; U = [Usd' u sq, Urd, urq]t; r 0 -C2 Bs = C 0 Cl 0 C 4 0 -C z -~, 1 0 C 4 0 -C 2 Eq. (14) with the equation of motion can be solved step-'wise by Runge Kutta or other well-known methods solving differential equations. In every step the d, q components of the stator and rotor currents can be calculated to yield the absolute value of the magnetizing current: \ _ 1((' I') 2 I (. I ) Z \ Lm - Y Lsd T Lrd T Lsq T Lrq (15) Using (15), the C coefficients, functions of the first derivative of the magnetized curve, can be calculated. The developed model suits to calculate the dynamical behaviour of symmetrical or asymmetrical synchronous or asynchronous machines, >vithout or 'with saturation. The derived equations are of a form to be directly solved by a digital computer. Detailed results of computerized calculation will be shown in a following paper, for asymmetrical cases and for the case of a symmetrical three-phase step induction motor where the saturation cannot be neglected, as the stator voltage is not constant but greatly variable. Also time harmonic analysis will be presented. APPENDIX 1 The constants k are: (1) The stator and rotor transient time constants: T~d = L~!Rsd ; T~q = L~!Rsq T;d = L;JRrd ; T;q = LflRrq where L~ and L; are the stator and rotor transient inductances. (2) (3) APPENDIX 2 The stator and rotor leakage coefficients are: (4) 3*

36 P. VAS where Xscr and X rcr are the stator and rotor leakage reactances, X = X(i m ) is known from the magnetizing curve, X being its first derivative The coefficients care: C = [(1 + kscr) (1 + krcr) - kscrkrcrl-1 (5) Cl = (1 + krcr)/lscr C 2 = kscrllscr Ca = (1 + ksrr)/lsrr Summary Differential equations in state-variable form have been given to calculate the behaviour of asynchronous and synchronous machines during transient operation assuming two-side asymmetry. Also saturation of the main flux: paths was present. The equations are ready to solve on a digital computer. A following paper will discuss the results of several asymmetrical and symmetrical cases obtained by a digital computer. It will be also shown how the method can be applied for the calculation of electric machines with thyristor circuits if saturation is also considered. References 1. R..\.cz, I.: Matrix calculation of thyristor machine schemes, 1st Conference on Electronics, Budapest, 1970 2. R'\'cz, I.: Control theory of thyristor connections, 2nd Conference on Power Electronics, Budapest, 1973 3. A. ABD EL-SATTAR: Speed control of induction motors by three-phase thyristors in the rotor circuit, Control in Power Electronics and Electrical Drives, IFAC Symposium, Dusseldorf, 1974 4. VAS, P.: Investigation of sqnirrel cage induction motors with concentrated rotor asymmetries,* Elektrotechnika, Vol. 68, 1975, pp. 461-463, Budapest 5. VAS, P.: Performance of Three-phase Squirrel Cage Induction l\i:jtors with Rotor Asymmetries, Periodica Polytechnica, Electrical Eug., Vol. 19, No. 4,1975, pp. 309-315 6. VAS, P.-VAS, J.: Transient and Steady State Operation of Induction l\htors with Rotor Asymmetries, Archiv fur Elektrotechnik, Vol. 59, 1977, pp. 121-127 7. VAS, P.-VAS, J.: Operational Characteristics of Induction l\!jtors with Asymmetrical Rotor, J. Inst. Eng. (India), Vol. 57, pt. E16, 1977, pp. 265-267 8. Kov..\.cs, K. P.: Pulsierendes Moment im asymmetrischen Betrieb von Wechseltstrommaschinen. Archiv fur Elektrotechnik, Vol. 42, 1955 9. KOVACS, K. P.-R'\'cz, 1.: Transients of A. C. Machines*, AkademiaiKiad6, Budapest,1954 10. RETTER, Gy: The Unified Electrical Machine Theory, * :l\!uszaki Konyvkiad6 Budapest 1976 Dr. Peter VAS, H-1521 Budapest.. In Hungarian

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