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Transcript
2 Steady-State Analysis of Single Phase A.C. Circuit 2.1 ALTERNATING QUANTITY An alternating quantity is that which acts in alternate directions and whose magnitude undergoes a definite cycle of changes in definite intervals of time. When a simple loop revolves in a magnetic field, an alternating emf is induced in the loop. If the loop revolves with an uniform angular velocity the induced alternating emf is sinusoidal in nature. The alternating quantity may have various other wave forms like triangular, semicircular, stepped, distorted, etc. as shown in Fig. 2.1(a), (b), (c) and (d), respectively. The graph repeats after regular intervals. One complete set of positive and negative values of an alternating quantity is called a cycle. The important alternating quantities, f (t) that will be discussed in the chapter are current and voltage. 2.2 ALTERNATING VOLTAGE Alternating voltage may be generated by (A) By rotating a coil in a stationary magnetic field. (B) By rotating a magnetic field within a stationary coil. The value of the voltage generated in each case depends on: (i) The number of turns in the coils. (ii) The strength of the field. (iii) The speed at which the coil or magnetic field rotates. (a) Maximum flux links with the coil when its plane is in vertical position (perpendicular) to the direction of flux between the poles. (b) When the plane of a coil is horizontal no flux links with the coil. 2.4 2.4 ADVANTAGES OF SINE WAVE 1. Any periodic non-sinusoidal wave can be expressed as the sum of a number of sine wave of different frequencies. 2. Sine wave can be expressed in a simple mathematical form. 3. The resultant of two or more quantities varying sinusoidally at the same frequency is another sinusoidal quantity of same frequency. 4. Rate of change of any sinusoidal quantity is also sinusoidal. 2.5 CYCLE A cycle may be defined as one complete set of positive and negative values of an alternating quantity repeating at equal intervals. Each complete cycle is spread over 360° electrical as shown in Fig. 2.5. 2 0 180 3 360° 540° 1- Cycle rad 4 720 degree Fig. 2.5 2.6 PERIODIC TIME The time taken by an alternating quantity in seconds to trace one complete cycle is called periodic time or time-period. It is usually denoted by symbol T. 2.7 FREQUENCY The number of cycles per second is called frequency and is denoted by symbol f. Thus, or, f= 1 T T= 1 f If the angular velocity w is expressed in radians per second, then 2 T = 2 f = 2.5 2.8 PHASE DIFFERENCE Let OP and OQ be the two vectors (more preferred to be called phasors) representing two alternating quantities of the same frequency at any instant. The angle between them is called the phase angle. The direction of rotation in counter clockwise direction is usually taken as positive. If OQ and OP represent voltage and current vectors, then Q t P O Fig. 2.6 e = OQ sin t and, i = OP sin (t – ) where, is called the phase difference. In above phasor OQ is said to lead the phasor OP. The ‘phase’ of an AC wave may be defined as its position with respect to a reference axis or reference wave. Phase angle as the angle of lead or lag with respect to reference axis or with respect to another wave. e A B i O t /2 Phase shift = degrees A is ahead of B because A attains its maxima or minima before B A leads B B lags A Fig. 2.7 • A is degree ahead of B. • A attains its maxima degrees before B or α = t t sec before B. ω t t 2 T sec T second or 2 2.6 2.9 PHASOR NOTATION Sinusoidal quantities can be represented by a function. f(t) = Vme jt = Vm e j = Vm Y C B O Vm X A Fig. 2.8 This function has constant magnitude Vm and as t moves through 0 ot 2 radians. OA = Vm cos , OB = Vm sin OC = (OA) + j(OB), = tan–1 OB OA by Euler theorem e j = cos + j sin V Vm Vm (cos j sin ) In rectangular form OC = OA + j OB |OC| = x + j y where = tan–1 y/x |OC| = x2 y 2 V1 = Vm1 1 , V2 = Vm2 2 Then V1V2 = Vm1Vm2 1 2 = Vm[cos (1 + 2) + j sin (1 + 2)] V1/V2 = Vm1 Vm2 1 2 = Vm [cos (1 – 2) + j sin (1 – 2)] V1 + V2 = Vm1 1 + Vm2 2 = Vm1 (cos 1 + j sin 1) + Vm2 (cos 2 + j sin 2) V1 V2 Vm1 cos 1 Vm2 cos 2 j Vm1 sin 1 Vm2 sin 2 2.7 Phasor diagram: Let V1 = Vm1 sin = Vm1 O = t V2 = Vm2 sin (t + ) = Vm2 (means V2 leads, V1 by angle °) V2 V1 Fig. 2.9 2.10 MEASUREMENTS OF AC MAGNITUDE So far we know that AC voltage alternates in polarity and AC current alternates in direction. We also know that AC can alternate in a variety of different ways, and by tracing the alternation over time we can plot it as a “waveform”. We can measure the rate of alternation by measuring the time it takes for a wave to evolve before it repeats itself (the “period”), and express this as cycles per unit time, of “frequency”. In music, frequency is the same as pitch, which is the essential property distinguishing one note from another. However, we encounter a measurement problem if we try to express how large or small an AC quantity is. With DC, where quantities of voltage and current are generally stable, we have little trouble expressing how much voltage or current we have in any part of a circuit. But how do you grant a single measurement of magnitude to something that is constantly changing? One way to express the intensity, or magnitude (also called the amplitude), of an AC quantity is to measure its peak height on a waveform graph. This is known as the peak or crest value of an AC waveform: Fig. 2.10 Another way is to measure the total height between opposite peaks. This is known as the peak-to-peak (P-P) value of an AC waveform. 2.8 Unfortunately, either one of these expressions of waveform amplitude can be misleading when comparing two different types of waves. For example, a square wave peaking at 10 volts is obviously a greater amount of voltage for a greater amount of time than a triangle wave peaking at 10 volts. The effects of these two AC voltages powering a load would be quite different. Fig. 2.11 Fig. 2.12 One way of expressing the amplitude of different wave-shapes in a more equivalent fashion is to mathematically average the values of all the points on the graph of a waveform + + + + to a single, aggregate + + + + number. This amplitude + + measure is known as the + + + + average value of the waveform. If we average – – – – all the points on the – – – – waveform algebraically – – – – – – (that is, to consider their True average value of all points sign, either positive or (considering their signs) is zero. negative), the average Fig. 2.13 2.9 value for most waveforms is technically zero, because all the positive points cancel all the negative points over a full cycle. This, of course, will be true for any waveform having equal-area portions above and below the “zero” line of a plot. However, as a practical measure of a waveform’s aggregate value, “average” is usually defined as the mathematical mean of all the points’ absolute values over a cycle. In other words, we calculate the practical average value of the waveform by considering all points on the wave as positive quantities as if the waveform looked like this: Fig. 2.14 Polarity-insensitive mechanical meter movements (meters designed to respond equally to the positive and negative half-cycles of an alternating voltage or current) register in proportion to the waveform’s (practical) average value, because the inertia of the pointer against the tension of the spring naturally averages the force produced by the varying voltage/current values over time. Conversely polarity-sensitive meter movements vibrate uselessly if exposed to AC voltage or current, their needles oscillating rapidly about the zero mark, indicating the true (algebraic) average value of zero for a symmetrical waveform. When the “average” value of a waveform is referenced in this text, it will be assumed that the “practical” definition of average is intended unless otherwise specified. Another method of deriving an aggregate value for waveform amplitude is based on the waveform’s ability to do useful work when applied to a load resistance. Unfortunately, an AC measurement based on work performed by a waveform is not the same as that waveform’s average value, because the power dissipated by a given load (work performed per unit time) is not directly proportional to the magnitude of either the voltage or current impressed upon it. Rather, power is proportional to the square of the voltage or current applied to a resistance (P = E2/R, and P = I2R). Although the mathematics of such an amplitude measurement might not be straightforward, the utility of it, is. Current would produce the same amount of heat energy dissipation through an equal resistance: 2.10 Fig. 2.15 In the two circuits above, we have the same amount of load resistance (2 ) dissipating the same amount of power in the form of heat (50 watts), one powered by AC and the other by DC. Because the AC voltage source pictured above is equivalent (in terms of power delivered to a load) to a 10 volt DC battery, we would call this a “10 volt” AC source. More specifically, we would denote its voltage value as being 10 volts RMS. The qualifier “RMS” stands for Root Mean Square, the algorithm used to obtain the DC equivalent value from point on a graph (essentially, the procedure consists of squaring all the positive and negative points on a waveform graph, averaging those squared values, then taking the square root of the average to obtain the final answer). Sometimes the alternative terms equivalent or DC equivalent are used instead of “RMS”, but the quantity and principle are both the same. RMS amplitude measurement is the best way to relate AC quantities to DC quantities, or other AC quantities of differing waveform shapes, when dealing with measurements of electric power. For other considerations, peak or peakto-peak measurements may be the best to employ. For instance, when determining the proper size of wire (ampacity) to conduct electric power from a source to a load, RMS current measurement is the best to use, because the principal concern with current is overheating of the wire, which is a function of power dissipation caused by current through the resistance of the wire. However, when rating insulators for service in high-voltage AC applications, peak voltage measurements are the most appropriate, because the principal concern here is insulator “flashover” caused by brief spikes of voltage, irrespective of time. Peak and peak-to-peak measurements are best performed with an oscilloscope, which can capture the crests of the waveform with a high degree of accuracy due to the fast action of the cathode-ray-tube in response to 2.11 changes in voltage. For RMS measurements, analog meter movements (D’ Arsonval, Weston, iron vane, electrodynamometer) will work so long as they have been calibrated in RMS figures. Because the mechanical inertia and dampening effects of an electromechanical meter movement makes the deflection of the needle naturally proportional to the average value of the AC, not the true RMS value, analog meters must be specifically calibrated (or miscalibrated depending on how you look at it) to indicate voltage or current in RMS units. The accuracy of this calibration depends on an assumed waveshape, usually a sine wave. Electronic meters specifically designed for RMS measurement are best for the task. Some instrument manufacturers have designed ingenious methods for determining the RMS value of any waveform. One such manufacturer produces “True-RMS” meters with a tiny resistive heating element powered by a voltage proportional to that being measured. The heating effect of that resistance element is measured thermally to give a true RMS value with no mathematical calculations whatsoever, just the laws of physics in action in fulfilment of the definition of RMS. The accuracy of this type of RMS measurement is independent of waveshape. For “pure” waveforms, simple conversion coefficients exist for equating peak, peak-to-peak, average (practical, not algebraic), and RMS measurements to one another: RMS = 0.707 (Peak) AVG = 0.637 (Peak) Sinusoidal wave P-P = 2 (Peak) RMS = Peak AVG = Peak P-P = 2 (Peak) Square wave RMS = 0.577 (Peak) AVG = 0.5 (Peak) Triangular wave P-P = 2 (Peak) Fig. 2.16 2.14 1/2 1 T 2 Irms = i dt T 0 • For a sinusoidal wave i = Im sin t 1/2 1 T 2 (i) dt Irms = T 0 1/2 1 T 2 2 = I m sin t . d t T 0 1/2 1 T 2 (1 cos 2t ) = Im dt 2 T 0 1/2 I2 = m T T t sin 2t 2 4 0 I2 = m T T 0 2 = 1/2 2 t sin 2t sin 2.2 ft sin 2. T when t = T {sin 2t = sin 4 = 0 Im 2 • Ratio of maximum value to the RMS value is known as crest or peak factor or amplitude factor. Peak factor = Maximum Value RMS value • Ratio of effective value to average value is known as form factor form factor = RMS value Average value 2.15 Fig. 2.17 2.11.2 Graphic Method In Fig. 2.18(a) a positive half cycle of an unsymmetrical alternating current is T seconds. Let the n instantaneous middle values of current in the intervals be i1, i2, i3, ..., in. If R be the resistance of the circuit through which varying current is passed, then: Heat produced in: shown. Divide the period T into n equal intervals of time 1st interval = i12 R T watts n i5 i4 l i3 i2 i1 O T t T n (a) M D 2 i5 2 i4 l2 N 2 i3 2 i1 2 i2 O T n T t T Fig. 2.18 (b) 2.18 Consider small interval d as shown in Fig. 2.19. If i is the average value of current in the interval, then area of elementary strip = id. Total area of half cycle = i d Hence, the average value of current is given by two ways. t i O d t Fig. 2.19 (i) Iav = area of half cycle interval id = 0 I = m sin d 0 = Im cos 0 2I m = 0.637 Im = Similarly, for alternating sine voltage Eav = 2I m . 2.19 (ii) 1 Iav = T T /2 idt 0 1 = T /2 I = m T /2 T /2 Im sin(wt).d t 0 T /2 sin wtdt 0 T /2 I cos wt = m T /2 w 0 = I m .2 wT cos 0 cos 2 Tw w = 2f = = 2 T 2I m [cos – cos 0] 2 I av 2I m 0.637 I m 2.12.2 Graphical Method For an unsymmetrical wave as shown in Fig. 2.19(a), area of curve = (i1 + i2 + i3 + ... + in). T n (i1 i2 i3 ... in ). T n Iav = = T (i1 i2 i3 ... in ) n 2.13 FORM FACTOR The form factor is defined as the ratio of the effective value to the average value of an alternating quantity. 2.21 From factor = = 1 2 Vm 4 Vrms = 1 Vm 2 Vrms 0.5Vm = = 1.572 Vav 0.318Vm Example 2: Find the average and effective values of the saw tooth wave form shown in Fig. 2.21 below. Solution: From Fig. 2.21 below, the period is T. v Vm 0 T 2T Fig. 2.21 T Vav = 1 Vm t dt T0 T 1 Vm = T T = T t dt 0 Vm T 2 Vm 2 T2 2 T Effective values Vrms = = = 1 2 v dt T0 1 T Vm 3 T 0 2 Vm t dt T 3T t 2.22 Example 3: Find the average and rms value of the full wave rectified sine wave shown in Fig. 2.22 v 5V 0 3 2 t Fig. 2.22 1 Solution: Average value Vav = 5 sin t d (t) 0 = 3.185 1 (5 sin t ) 2 d (t ) 0 Effective value or rms value = 25 = 3.54 2 = Example 4: The full wave rectified sine wave shown in Fig. 2.23 has a delay angle of 60°. Calculate Vav and Vrms. v 10 V 0 60° 3 2 t Fig. 2.23 1 Solution: Average value Vav = = 10 sin (t) d (t) 0 1 10 sin t d (t) 60 2.23 Vav = 10 (– cos t ) 60 = 4.78 1 (10 sin t ) 2 d (t ) 60 Effective value Vrms = 100 1 cos 2t d (t ) 2 60 = = 6.33 2.15 OPERATOR j • An alternating voltage or current is a phasor quantity, but since the instantaneous values are changing continuously, it must be represented by a rotating vector phasor. • A phasor is a vector rotating at a constant angular velocity. • j is defined as an operator which turns a phasor by 90° counter-clockwise (CCW) without changing the magnitude of phasor j = 1 90°, jr = r 90° 2.16 CIRCUIT WITH PURE RESISTANCE ONLY A pure resistance is that in which there is ohmic voltage drop only. Consider a circuit having a pure resistance R as shown is Fig. 2.24 below. Let the instantaneous value of the alternating voltage applied be, e = Em sin t The instantaneous value of current, i= e Em sin t R R R() e.i i e e i (a) (b) I E = IR (c) Fig. 2.24 2.25 2.17 CIRCUIT WITH PURE INDUCTANCE ONLY A pure inductive circuit possesses only inductance and no resistance or capacitance as shown in Fig. 2.25. When an alternating voltage is applied to it, a back emf of self inductance is induced in it. As there is no ohmic resistance drop, the applied voltage has to oppose the self induced emf only. So the applied voltage is equal and opposite to the back emf at all instants. Let the applied voltage e = Em sin t (1) 90° I= E wL instantaneous value of self induced emf is e e = – L di = di = –e dt E L i 1 e dt L e = Em sin wt Fig. 2.25 integrating both side, we get 1 di = L E m sin t.dt i= Em (– cos t) L i= Em sin t 2 L i = Im sin t 2 integration constant will cancel out from both side E (2) I m m L observing (1) and (2) we find that the current lags the applied voltage by 90° or radian. 2 impedance Em 0 E 2 Z= = Em I 2 2 Z= Em = L 2 2 Im 2.26 The quantity L is called inductive reactance and is usually devoted by symbol XL and units is ohm. XL = L ohms where, L is in henry and is in rad/sec. Wave diagram and Phasor diagram for Pure inductance e E Em sin wt i = Im sin (wt –/2) i o /2 2 /2 /2 I Fig. 2.26 Average Power 1 P= 2 2 1 2 2 1 = 2 2 = = ei d (wt ) 0 sin wt . I m sin wt d ( wt ) 2 E m 0 E m I m sin wt .cos wt . d ( wt ) 0 Vm I m 2 2 0 sin 2 wt . d ( wt ) 2 =0 This shows power consumed in purely inductive circuit is zero. Hence, the average power consumption in an inductive circuit is zero and is periodic with twice the supply frequency as expressed by equation (1). The stored energy in the inductive circuit in one quarter of a cycle is released in the next quarter. 2.28 Em = C Em sin t = .sin t 2 1 C 2 Comparing equations, we see that the current leads the voltage vector by 90° as shown in Fig. 2.28. Maximum value of current is given by, Im = Em 1 C The quantity 1/C is called inductive capacitance and is usually denoted by Xc. Its unit is ohm. 1 ohms C C = Capacity in farads Xc = where, = angular velocity in rad/sec Impedance Since Z= E Em 0 I I m 90 Z= Em – 90° Im 2 2 Em 1 = XC = C Im Z = XC – 90° = – j XC Average Power instantaneous power P = vi P = Vm sin t.Im sin t 2 = Vm Im sin t.cos t = Pav = Vm I m sin 2t 2 1 2 2 P d (t ) 0 (1) 2.29 1 = 2 2 0 Vm I m sin 2t . d (t ) 2 =0 This shows that the power consumed in purely capacitive circuit is zero. A capacitor receives energy during the first quarter cycle of voltage and returns the same during the next quarter cycle. 2.19 CIRCUIT WITH RESISTANCE AND INDUCTANCE IN SERIES Consider circuit of Fig. 2.29. Let R = Resistance in ohms in the circuit. L = Inductance in henries XL = Inductive reactance = L E = Effective value of applied emf I = Effective value of current in circuit. Voltage drop across resistance, ER = R.I in phase with current vector as shown in vector diagram of Fig. 2.30. Voltage across reactance, EL = I.L = IXL, 90° ahead of vector I E 90° I = E/R R I ER ER I= L E L EL e = Em sin wt Fig. 2.29 Fig. 2.30 Z = R + j XL = here R 2 X L2 tan 1 = tan–1 XL R XL R 2.30 and | Z| = R 2 X L2 Z = | Z | I= E E Z | Z | I E Z instantaneous value of current is, i = Im sin (t –), where Im = E Z XL R hence in R-L circuit current lags the applied voltage by angle = tan–1 The applied voltage is therefore given by, E= Er2 EL2 E E = ( IR) 2 ( IX L ) 2 E = I R 2 X L2 = IZ = tan–1 or, I= The quantity R =I R EL = j XL I XL L = tan–1 R R E R 2 X L2 R 2 X L2 is called impedance. Since, the power is consumed by the resistance only, so the power in the circuit is given by, P = I 2 R = I.IR E . IR = 2 R X L2 or, P = E.I R R X L2 If is the angle between E and I, then cos = 2 R ER IR = 2 2 Z E I R XL 2.31 P = E.I cos Cos is called the power factor of the circuit. Obviously the power factor is lagging in an inductive circuit. So instantaneous current across R-L is i = Im sin (t – ). 2.20 CIRCUIT WITH RESISTANCE AND CAPACITANCE IN SERIES Consider circuit of Fig. 2.31. Voltage drop across resistance, ER = IR in phase with I as shown in vector diagram of a Fig. 2.32. 1 = I XC, 90° lagging C with respect to the current vector. EC = I. I= I = E/R I E C ER= IR 90° E R C ER EL 90° E I EC = I XC Fig. 2.32 Fig. 2.31 The applied voltage is, therefore, given by, E= ER2 EC2 = I R 2 X C2 = IZ Thus, ohm’s law is applicable to AC circuit also after replacing the term resistance by impedance. Power = EI cos Cos = R 2 R X C2 Z = R – j XC R Z ...(2.53) 2.32 Z= XC R 2 X C2 tan 1 R XC Z = |Z| – here tan 1 R I= E E = Z |Z | E = Im Z instantaneuous value of current throw R-C is I= i = Im sin (t + ) where Im = E Z XC hence current leads the voltages by aug = tan–1 . R 2.21 SERIES R-L-C CIRCUIT EL I I I EC R L C ER EL EC i Fig. 2.33 Problems on alternating current circuits can be attempted easily by using j-notation. Voltage across inductance = + jI XL = EL Voltage across capacitance = – jI XC = EC Net voltage across them = + jI (XL – XC) = j (EL – EC) Resistance drop = IR = ER. Applied voltage in j-notation is represented by, E = IR + jI(XL – XC) 2.33 E = I R 2 ( X L X C )2 or, Impedance in j-notation may be written as, Z = R + j(XL – XC) or, Z= I= E Z E= R2 ( X L X C )2 Em 2 0 Z = R + j (XL – XC) Z= R 2 ( X L X C )2 | Z | = tan–1 where X L XC R if XL > XC then is +ve if XL < XC then is –ve I= Em 0 | Z | 2 hence if XL > XC then current lags the applied volt. I = I EL EL – EC E 90° 90° EC ER I = IR = IL = IC Phasor diagram of series R–L–C Circuit 2.34 R-L-C Ckt taking E as a refrence phasor when XL > XC EL EL – EC E I ER EC Phasor diagram of a series R-L-C Ckt taking current I as a refrence phasor. 2.22 POWER IN AC CIRCUITS • When the current is out of phase with the voltage the power indicated by the product of the applied voltage and the total current gives only what is known as apparent power and measured in volt-ampere. • Power that is returned to the source by the reactive components in the circuit is called reactive power and is measured in VAR. • Power that actually used in the circuit (dissipated in resistance) is true or active power and is measured in watts or kW. 2.22.1 Active and Reactive Power and Apparent Power Form Fig. given below Impedance Z = R ± jX = |Z| = |Z| cos + j |Z| sin I X R L I Sin C I 90° E (a) I Cos (b) V 2.35 Magnitude or amplitude of impedance, |Z| = R2 X 2 R | Z | cos X | Z | sin Power factor of the circuit, cos = R . Z E . Z This current has two components I cos and I sin . The component I cos is called in phase or wattfull component and I sin is perpendicular to E and is called wattless component, as shown in Fig. 2.30(b). Then Current in the circuit I= Active (Real) Power = Voltage Current cos watts Since, the angle between the voltage and the wattless component of current is 90°, hence the power absorbed by this component is zero. The power is only absorbed by the wattful component. The total power EI in volt amperes supplied to a circuit consists of two components: (a) Active power = EI cos watts (b) Reactive power = EI sin volt amperes reactive or simply VAR. The above components can be shown in vector from in Fig. 2.34. B Z KVA VAR X R O Watts (a) KVAR VA B A O (b) kW A (c) Fig. 2.34 From Fig. 2.31(b) OA = Active power = EI cos presented by watts AB = Reactive power = EI sin expressed by VAR OB = Total power = EI expressed by VA Obviously VA = Watts 2 + VAR 2 ...(2.4) 2.37 a2 cos 2 = a22 b22 , sin 2 = b2 a22 b22 Active power: = OA.OB cos AOB = = a12 b12 a22 b22 . cos (2 – 1) a12 b12 a22 b22 [cos 2.cos 1 + sin 2.sin 1] a1 a2 = a12 + b12 a22 b22 2 2 2 2 a b a b 2 2 1 1 b2 a22 b22 b1 2 2 a1 b1 = a1a2 + b1b2 Reactive power: = OA.OB sin AOB = a12 b12 a22 b22 .sin (2 – 1) = a12 b12 a22 b22 [sin 2.cos 1 – cos 2.sin 1] = b2 a1 a12 b12 a22 b22 2 2 2 2 a b a b 2 2 1 1 a2 a22 b22 b1 2 2 a1 b1 = a1b2 – a1b2 Note: V.I. = (a1 + jb1) (a2 + jb2) = (a1a2 – b1b1) + j(a2b1 + a1b2) If we write V Conjugate of I = (a1 + jb1) (a2 – jb2) = (a1a2 + b1b2) + j (a1b2 – b1a2) = a1a2 + b1b2 + j (a1b2 – b1a2) (Active power) (Reactive power) Note 1: Hence, the active and reactive powers would be given by the real and j ports of the vector product of voltage with the conjugate of the current vector. Note 2: Active power can also be expressed by the sum of the algebraic product of the real parts of the current and the voltage and the algebraic product of the j parts of the current and voltage. Alternate approach Let E and I are the phasors given by E = E 1 2.38 and I = I ± 2 + sign for leading current sign for lagging current there complex power is given by S if I I 2 * I I 2 S= E I* = E 1 . I 2 = EI 1 2 S = EI cos (1 2) + j EI sin (1 2) S P jQ if V is the refrence phasor 1 = 0 S = EI cos 2 + j EI sin ( 2) S = EI cos 2 j EI sin 2 S P jQ ve for leading P.f load S P jQ +ve for lagging P.f load S P jQ P = active power Q = reactive power 2.24 POWER FACTOR The power factor of an alternating-current device or circuit or electric power system is defined as the ratio of real or true power to the apparent power (VA) and is between 0 to 1. Real power is the capacity of the circuit for performing work in a particular time, and apparent power is the product of current and voltage of a system. Reactive power is the power that magnetic equipment (transformer, motor and relays) needs to produce the magnetizing flux. • In a single-phase circuit the power factor is also a measure of the phase angle between the phase voltage (Vph) and phase current (Iph) Power factor = V ph I ph cos P real power S apparent power V ph I ph Power factor cos 2.39 • Power factor is said to be lagging if the current lags behind voltage and leading if the current leads the voltage. • The significance of power factor lies in the fact that utility companies supply customers with volt-amperes, but bill them for watts. 2.24.1 Problems of Low Power Factor (1) Power factor below 1.0 requires a utility to generate more than the minimum volt-amperes necessary to supply the real power (watts). This increases generation and transmission cost. (2) If the load power factor were as low as 0.7, the apparent power would be real power 1.4 times the real power used by the load. Line current in 0.7 the circuit would also be 1.4 times the current required at unity power factor, so the losses in the circuit would be doubled (proportional to square of current) result in all components of the system such as generator, conductors, transformers and switchgear would be increased in size (cost) to carry the extra current. (3) Higher current produces larger voltage drop in cables and other apparatus. This results in poor voltage regulation. In practice, power factor is rarely corrected to unity because the cost of equipment required to improve the power is usually greater than the saving on tariff. 2.24.2 Causes of Low Power Factor Many alternating-current machines (transformer, induction motors) absorb reactive power to produce their magnetic fields, this decreases the power factor. Reactive power (kVAr) required by inductive loads increases the amount of apparent power (kVAr) in our, distribution system (Fig. 2.36). This increase in reactive and apparent power results in a larger angle (measured between kW and kVA). Recall that, as increases, cosine (or power factor) decreases. KVAR KVA KVA KVAR KW KW Fig. 2.36 So inductive loads (with large kVAr) results in low power factor. 2.41 (3) The more increased voltage level in the electrical system and cooler, the more efficient motors will be. As mentioned above, uncorrected power factor causes power system losses in the distribution system. As power losses increase, we may experience voltage drops. Excessive voltage drops can cause overheating and premature failure of motors and other inductive equipment. So, by raising the power factor, these voltage drops can be minimized along feeder cables and avoid related problems. The motor will run cooler and more efficiently, with a slight increase in capacity and starting torque. 2.24.4 Power Factor Correction Power factor correction is the process of adjusting the characteristics of elective loads in order to improve power factor closer to unity. A high power factor is generally desirable in a transmission system to reduce transmission losses and improve voltage regulation at the load. • The presence of reactive power causes the real power to be less than the apparent power, and so the electrical load has a power factor less than unity. • The reactive power increases the current flowing between the power source and the load, which increase the power losses though transmission and distribution lines. (1) Power factor correction can be done by supplying reactive power of opposite sign adding capacitors or inductors which act to cancel the inductive or capacitive effects of the load, respectively. For example, the inductive effect of motor loads may be offset by locally connected capacitors, sometimes when the power factor is leading due to capacitive loading, inductors are used to correct the power factor. (2) Minimizing operation of idling or lightly loaded motors because low power factor is caused by running induction motor lightly loaded. (3) Avoiding operation of equipment above its rated voltage. (4) Replacing standard motors as they burn out with energy-efficient motors. (5) By using synchronous motor or synchronous condenser. Power Factor Correction by Static Capacitor: Consider an inducting load consisting of resistor R and an inductor L connected to an ac supply. Current I1 lags the voltage V by angle 1 so PF is cos 1. 2.42 V I1 1 R V L I1 Let us now for improving the power factor connect a capacitor parallel to a load. This capacitor takes a leading current from the supply. The capacitor produces a reactive power in the opposite direction hence net reactive power decreases. D I2 O I1 R IC V V IC V kW A 1 (kV A) I2 B 2 (kVA)1 IC 2 (kVAr)2 (kVAr)1 L I1 C from the phasor diagram OA = I1 cos 1 = I2 cos 2 I2 = I1 cos 1 cos 2 2 > 1 so cos 2 > cos 1 cos 2 > cos 1, I2 < I1 Since Hence, current drawn from the supply is less than the load current I1. Hence if power factor reduces then apparent power (VI) from the supply will also reduce. I2 cos 2 = I1 cos 1 VI2 cos 2 = VI1 cos 1 = Real power The above relation shows that active or true power taken from supply has not altered, Example 4: A fluorescent lamp takes a current of 0.75 A when connected across a 240 V, 50 Hz ac supply. The power consumed by the lamp is 80 W. Calculate the values of the capacitance to be connected in parallel with the lamp to improve the power factor to (a) unity (b) 0.95 lagging. Solution: I1 = 0.75 A, I1 cos 1 = V = 240 V, P = 80 W; P 80 1 ; V 240 3 cos 1 = VI1 cos 1 = P 1 1 = 0.444 3I1 3 0.75 2.43 1 = 63.61°, tan 1 = 2.0155 (a) cos 2 = 1, 2 = 0, tan 2 = 0 IC = I1 cos 1 (tan 1 – tan 2) = C= 1 (2.0155 – 0) = 0.6718 A 3 IC 0.6718 = 8.91 10–6 F = 8.91 F V 240 2 50 (b) cos 2 = 0.95, 2 = 18.19°, tan 2 = 0.3287 1 IC = I1 cos 1 (tan 1 – tan 2) = (2.0155 – 0.3287) = 0.5623 A 3 I 0.5623 C= C = 7.457 10 –6 F = 7.457 F V 240 2 50 Example 5: A single-phase 50 Hz motor takes 20A at 0.75 power factor from a 230 V sinusoidal supply. Calculate the kVAr and capacitance to be connected in parallel to raise the power factor to 0.9 lagging. What is the new supply current? f = 50Hz Solution: I1 = 20A, cos 1 = 0.75, 1 = 41.4°, tan 1 = 0.8819 cos 2 = 0.90, 2 = 25.84°, tan 2 = 0.4843 IC = I1 cos 1 (tan 1 – tan 2) = 20 0.75 (0.8819 – 0.4843) = 5.9637 A C= IC 5.9637 = 82. 53 10 –6 F = 82.53 F V 2 50 230 QC = VIC = 230 5.9637 = 1371.65 VAr = 1.3716 kVAr Let I2 be the new supply current. Since the active component of supply current remains changed. I2 cos 2 = I1 cos 1 I2 = I1 cos 1 0.75 20 = 16.67 A cos 2 0.9 Example 6: A factory draws an apparent power of 300 kVA at a power factor of 65% (lagging). Calculate the kVAr capacity of the capacitor bank that must be installed at the service entrance to bring the overall power factor to (a) unity (b) 85 percent lagging. Solution: (a) Apparent power absorbed by the plant is S = 30 kVA Active power absorbed by the plant is P = S cos = 300 0.65 = 195 kW 2.45 or, Y = Y1 + Y2 + Y2 + ... ...(2.63) The impedance Z has two components resistance R and reactance X. Admittance has also two components, the conductance ‘g’ and suceptance ‘b’. The impedance and admittance triangles are similar as shown in Fig. 2.37. Z X y b R g Impedance triangle (a) Admittance triangle (b) Fig. 2.37 From Fig. 2.37(b), conductance is given by, g = Y cos Since, and, Y= cos = g= = 1 Z R from Fig. 2.33(a) Z 1 R R Z Z Z2 R R X2 2 ...(2.64) Similarly, susceptance is given by, b = Y sin = 1 X X . 2 Z Z Z = X R X2 2 ...(2.65) If y1, y2, y3, ... are equal to g1 + jb1, g2 + jb2, g3 + jb3 ... then, g = g1 + g2 + g3 + ... mho ...(2.66) 2.46 b = b1 + b2 + b3 + ... mho ...(2.67) y = g + jb ...(2.68) = g 2 + b2 ...(2.69) Total current I= E = E.Y Z ...(2.70) Power factor angle, = tan–1 b g ...(2.71) Power factor will be lagging if b is + ve Power factor will be leading if b is – ve Note: Inductive suceptance b is assigned + ve sign and capacitive susceptance –ve sign. 2.25.2 Vector-method Consider a parallel circuit shown in Fig. 2.38(a) I2 I1 R1 jXL I2 R2 I – jXC 2 I 1 E E (a) (b) I1 Fig. 2.38 Branch I. Impedance Z1 = I1 = R12 X L 2 E Z1 1 = tan–1 ...(2.72) ...(2.73) XL lagging R1 ...(2.74) 2.47 Take E as reference vector. Draw I1 lagging at an angle 1 with E as shown in vector diagram of Fig. 2.34(b). Branch II. Impedance Z2 = I2 = R2 2 ( X c )2 = R2 2 X c 2 E Z2 Xc 2 = tan–1 R leading 2 ...(2.75) ...(2.72) ...(2.77) Draw I2 leading E by 2. The resultant of I1 and I2 will give total current I and the angle between E and I will give the p.f. angle. Thus, a parallel circuit can be solved easily in this way. 2.25.3 j-Method Consider a parallel CKT of Fig. 2.34, we can express the various impedances in j form as under. Z1 = R1 + j XL Z2 = R2 – j XC 1 1 1 1 1 = = Z1 Z 2 R1 jxL R2 jxc Z Z= Z= ( R1 jxL ) ( R2 jxc ) ( R1 R2 ) j ( X L X c ) j ( X L R2 X c R1 ) ( R1 R2 ) ( X L X c ) ( R1 R2 X L X c ) 2 2 ( R1 R2 ) ( X L X c ) ( R1 R2 ) 2 ( X L X c ) 2 Z = R + jX Total current drawn = E Z R Z Power factor be lagging if X is +ve leading if X is –ve Power factor cos = 2.49 voltage across capacitance VC = V I = = j c Z ( jc) V 1 ( jc ) R j L c V | VC | = 1 2 1 2 c R 2 L c Frequency fc at which VC is maximum can be obtained dVC =0 d 1 1 1 R2 2 fc 2 LC 2 L2 LV VL = I ( jL) = 1 2 2 2 1 R L c fL 1 2 2 1 2 frequency at which VL is max RC 2 LC 2 it has been found that at resonance the values of VL and VC may be higher even then the supply voltage at resonance VLO = VCO . Phasor diagram at resonance VLO V = VRO VCO Fig. 2.40 IO 2.50 2.28 BAND WIDTH Band width of a series CKT is defined as the range of frequency for which the power delivered to the resistance is greater than or equal to half the power delivered at resonance. Curve I I0 = Current at resonance I0 Less R I0 2 XC >> XL High R Capacitive region inductive region f1 f f frequency f2 (Resonance curve) Fig. 2.41 Curve between current and frequency is known as resonance curve. Band width = f2 – f1 = 2 – 1 1 and 2 are the angular frequencies at which the power delivered is half the power delivered at resonance. These are also known as half power frequencies. At resonance Z= At half power point Z= V =R Io V V 2 =R 2 = Io Io 2 Z= R2 X 2 R 2 = R2 X 2 Lower half power frequency 1 XC – XL = R 1 – 1 L = R 1 c so at this point X = R XC > XL 2.51 21 + R 1 – =0 L 1 LC 1 R 2 1 2 R 1 = ± LC 2L 2 L 1 1 1 [(2 20 )] 2 R , o 2L 1 LC –ve frequency is meaningless so we take only +ve frequency. At upper half frequency 1 XL – XC = R 2 L – 22 – 1 =R 2c R 1 2 – =0 L LC 1 2 1 2 R R 2 = 2 L 2 L LC 1 2 (2 02 ) 2 Band width = 2 – 1 = 2 = and, take +ve value R L 12 = 20 2.29 QUALITY FACTOR AND SELECTIVITY Ratio of resonant frequency to band width is an indication of the degree of selectivity of the CKT and this is known as Quality factor, Q. 0 L 1 0 =Q= selectivity 2 1 R or, 1 2 1 0 Q= = LC = 0 ( 2 1 ) 0 cR R 0 L 2.52 L Higher values of Q o Resonance curve is very narrow and sharp () R Sharpness of the curve depends on the parameters R and L. By changing C, the resonance can be made to occur at different values of frequencies. 1 (2 f0 ) LI 02 o L 2 Q= = 1 2 R I R 2 0 V VL R X L V ω L o R VL QV Hence at series resonance voltage across inductance and capacitance becomes Q times of applied voltage. So it is also called voltage resonance. 1 ( LI 02 ) total stored energy 2 Q= 2 = 2 2 energy dissipated/cycle ( I 0 R) 2 f0 Q= o L 2 L 1 L = = R C R 2 LC R Selectivity = o L = o R A CKT with a flat frequency response curve (high R) will be more responsive and therefore less selective at frequencies in the neighbourhood of the resonant frequency. 2.30 PARALLEL RESONANCE OR CURRENT RESONANCE A parallel combination of R, L and C or (R, L) and C branches connected to a source will produce a parallel resonance (anti-resonance) when the resultant current through the combination is in phase with applied voltage at resonance power factor is unity for this. 1 Hz LC fo = 1 . Thus, R the is minimum at resonance. A CKT consisting of parallel R, L, and C is called a second order parallel resonant circuit Parallel LC combination is known as tank circuit. admittance at resonance is yo = 1 2 1 rad/sec LC Wo = 1 R2 2L LC L 1 R2 2L LC L 1 fo = 2H Wo = R X j WC 2 L 2 2 R XL R XL 2 1 2 R2 1 LC L2 R2 1 LC L2 Wo L =0 R 2 Wo2L2 fo = 1 2 1 LC if R is small— fo = Wo = WoC – Y = G + jB at resonance B = 0, W = Wo Y= 2.54 2.55 2.32 IMPEDANCE AT RESONANCE At resonance w = wo = Y= R R w2 L2 Z= R 2 w2 L2 R 2 1 R2 2 LC L At resonance Zd = Resistive part Zd = Rd is dynamic resistance Zd = R + L2 1 R2 R LC L2 Zd = R + Zd L L – R Zd = RC RC L RC Zd is called dynamic impedance, this is pure resistive. It is seen lower the R higher the Zd. Hence the value of impedance at resonance is maximum and the resultant current is minimum. A parallel resonant circuit is also called a rejector circuit since the current at resonance is minimum or tank circuit almost rejects the current at resonance. Io = Current at resonance = VCR V = , it R = 0 ckt will draw no current Zd L at resonance. The supply current is zero and large current circulates in parallel ckt at resonance. 2.33 CURRENT MAGNIFICATION Current drawn from supply at resonance is I = or, I= VCR L V Rd 2.56 I IL Ic R V –jc L Fig. 2.42 So circulating current is Vwo C. Q= Lwo Circulating current Vwo C = = R R Current drawn from supply VC . L Parallel tuned circuit exhibits a current amplification of Q, whereas series ckt exhibits voltage amplification of Q. 2.34 SELECTIVITY AND BAND WIDTH At half power frequency w1 and w2. ckt impedance is Rd 2 {At reasonance V = I. Rd {At half power V = I . Rd 2 Band width = w2 – w1 = Rd so Z 2 wo Q Q= 1 wo L 1 L = = R woCR R C Comparison between Parallel and Series Resonance Parallel Resonance (i) Net susceptance is zero (ii) Admittance is equal to conductance (iii) Impedance is L CR Series Resonance Net reactance is zero Impedance is equal to resistance Impedance is R 2.58 If R is small enough, whose squares may be neglected, then g= R X L2 ...(2.86) SOLVED EXAMPLES Example 7: A two element series circuit is connected across an AC source V = 300 cos (314t + 20°) volts. The current is drawn 15 cos (314t – 10°) Amp. Determine circuit impedance magnitude and phase angle. What is the average power drawn? (U.P. Tech 2003-04) Solution: Given, In polar form V = V = 300 cos (314t + 20°) V = 300 sin (314t + 110°) [cos = sin ( + 90°) 300 110° 2 i = 15 cos (314t – 10°) = 15 sin (314t + 80°) I= 15 + 80° 2 300 110 2 Z (circuit impedance) = 1 15 80 2 Z = 20 30 Hence, the angle between voltage and current is 30° and current lags V I Z the voltage by 30°. Phase angle = 30° Pav = = Vm I m cos (in R-L ckt) 2 1 15 300 cos 30° 2 = 1949.85 watt. 2.59 Example 8: A 120 V, 100 W lamp is to be connected to a 220 V, 50 Hz AC supply. What value of pure inductance should be connected in series in order to run the lamp on rated voltage? (2003-04) Solution: Z = R + jXL V 2 VL2 Vsupply = V + jVL = 220 = 1202 VL2 VL = 184.39 120 Volt 100 W L henry VL V Vsupply = 220, 50 Hz Fig. 2.43 Current through the lamp and inductance is same. Current through lamp I= P 100 = V 120 100 V = L 120 XL 120 VL 120 = 184.39 = 221.269 ohm. 100 100 XL = XL = 2fL L= 221.269 X2 = 2 f 2 3.14 50 L 0.7046 henry 2.60 Example 9: For the circuit shown in figure, find the current and power drawn from the source. (2004-05) 3 j4 6 j8 230 V1 50 HZ Fig. 2.44 Solution: Let Z1 = 3 + j4 = 5 53.13 Z2 = 6 + j8 = 10 53.13 Z1 + Z2 = 9 + j12 = 15 53.13 Both Z1 and Z2 are parallel hence net impedance of the circuit is Z Z= Z1Z 2 5 10 106.26 = Z1 Z 2 15 53.13 Z 3.33 53.13 Current drawn from the ckt is I = I= V Z V 0 230 = Z 3.33 53.13 I 69 53.13 Amp Hence, net current lags the net voltage by 53.13° and circuit is inductive in nature. Power drawn from source = VI cos = 230 69 cos (53.13) = 9.522 kw Ans. 2.61 Example 10: A coil connected to 100 V DC supply draws 10 Amp and the same coil connected 100V, AC voltage of frequency 50 Hz draws 5 Amp. Calculate the parameters of the coil and power factor. [2004-05] Solution: Coil means a resistance and inductance both. Let impedance of a coil Z = R + jXL When DC supply is connected to coil inductance behave like a short circuit (XL = 2fL = 2 0 L = 0 ) Vdc 100 = = 10 ohm. 10 I When AC is applied across the same coil. Given V = 100 volt of 50 Hz frequency. So resistance of coil R = I = 5 amp. V = IZ Z= V 100 = = 20 I 5 Z2 = R2 + X L2 X L2 = Z2 – R2 = 202 – 102 XL = L= Power factor of coil = 300 = 17.32 17.32 XL = = 0.05 henry 2 3.14 50 2 f R 10 = = 0.5 lagging Ans. Z 20 Example 11: Discuss the effects of varying the frequency upon the current drawn and the power factor in a RLC series circuit, a series RLC circuit with R = 10 , L = 0.02 Hz, and C = 2f is connected to 100 V variable frequency source. Find the frequency for which the current is maximum. (2004-05) Solution: R L I V,f Fig. 2.45 C 2.62 Impedance Z = R + jXL – jXC Z = R + j(XL – XC) Z= I= |Z| = R 2 ( X L X C )2 tan 1 X L XC = |Z | R V | Z | R 2 ( X L X C ) 2 and P.F. cos = cos tan–1 ( X L X C) R (1) when XL = XC source frequency f = resonant freq (fr) | Z | = R so current is maximum and power factor is unity. (2) now if we increase the frequency from resonance frequency f > fr . Then XC = 1 will decrease and XL increases. Impedance increases hence 2 fC current will decrease and power factor decreases and becomes lagging. (3) If frequency decreases below resonance frequency (f < fr), then XL decrease and XC increases but net impedance will increase, so current will decrease and power factor will also decrease. R but it becomes capacitive. Z Current is maximum at resonance so at resonance frequency cos = fr = 1 2 LC I Z=R Io Capacitive Inductive fr Fig. 2.46 2.63 fr = Example 12: 1 2 2 10 6 2 10 2 = 795.5 Hz A load having impedance of (1 + j1) is connected to an AC voltage represented as V = 20 2 cos (t + 10°) volt. Find the current in load expressed in the form of i = Im sin (t + ) A. Find the real and apparent power. (2004-05) Solution: 2 45 Load impedance Z = 1 + j1 = Voltage across the load V = 20 2 cos (t + 10°) = 20 2 sin (t + 100°) Current through load V= 20 2 100 = 20 100° 2 I= V 20 100 = Z 2 45 I 14.144 55 is rms value of current 14.144 2 i = Im sin (t + ), Im = 5 i= 2 . I sin (wt + 55°) i = 20 sin (t + 55) (ii) Real power = Vrms .Irms cos = 1 Vm Im cos 2 = 1 20 2 .20.cos 45 2 P 200 watt 2.64 (iii) Apparent power = = 1 V I 2 m m 1 20 2 20 2 = 282.84 VAR Example 13: An emf given by 100 sin 314 t volts in applied to a 4 circuit and the current is 20 sin (314t – 1.5808) ampere. Find (i) frequency (ii) circuit elements. [2005-06] Solution: (i) Let instantaneous emf be e e = 100 sin 314 t 4 (ii) t = 314t 2f = 314 E= 100 2 f = 50 Hz 4 i = 20 sin (314t – 1.5808) 1.5808 180 = 20 sin 314t 3.14 i = 20 sin 314 t I= 20 2 2 reference axis 2 4 Circuit impedance Z = I 2 /4 /2 V V I Fig. 2.47 2.66 Z = 100 – 60° = R + jXL (ckt is inductive) 100 cos 60 + j 100 sin 60 = R + jXL R = 100 cos 60 = 100 XL = 100 sin 60 = 100 1 = 50 2 3 = 86.6 2 Frequency of supply = 50 Hz L= 86.6 XL = = 2.758 10–1 H 314 2 f (ii) Now the choke coil is connected to 100 V, 25 Hz supply. R and L will be same as above. Now, XL = 2fL = 2 3.14 25 2.758 10–1 = 43.3 Now, R 2 X L2 = Z= 502 43.32 = 66.1 tan 1 43.3 50 = 66.1 40.89 and current from the coil = V Z I= 100 = 1.5 40.89 Amp 66.1 40.89 Power consumed = VI cos = 100 1.5 0.75 = 112.5 W or, I 2 R = (1.5)2 50 = 112.5 W Example 15: Two coils of 5 and 10 and inductances 0.04 H and 0.05 H respectively are connecting in parallel across a 200 V, 50 Hz supply. Calculate: (i) Conductance, susceptance and admittance of each coil. (ii) Total current drawn by the circuit and its power factor. (iii) Power absorbed by the circuit. 2.67 (iv) The value of resistance and inductance of single coil which will take the same current and power as taken by the original circuit. [2005-06] Solution: Given I1 5 0.04 H 10 0.05 H I2 I 200 V1 50 HZ Fig. 2.49 (i) Z1 = R1 + j X L1 Z1 = 5 + j12.56 = 13.52 68.29 Z2 = R2 + j X L2 = 10 + j 15.7 = 18.62 57.51 Admittance of coil (1) is y1 = G1 + jB1 = XL1 = 2fL1 = 2 3.14 50 0.04 = 12.56 XL2 = 2fL2 = 2 3.14 50 0.05 = 15.7 1 Z1 1 1 = = 0.074 – 68.29 Z1 13.52 68.29 Y1 = 0.074 68.29 Y1 = 0.0274 – j0.069 G1 = 0.0274 and susceptance B1 = 0.069 Admittance of coil (2) is Y2 = G2 + jB2 Y2 = 1 1 = = 0.0537 – 57.51 Z2 18.62 57.51 Y2 = 0.029 – j0.0453 2.68 So conductance G2 = 0.029, susceptance B2 = 0.0453 (ii) Total admittance of ckt is Y = Y1 + Y2 Y = 0.0274 – j0.069 + 0.029 – j0.0453 = 0.0564 – j0.1143 Y = 0.1275 – 63.74 Current drawn by the circuit is I = VY I = 200 0.1275 – 63.74 I 25.5 63.74 Amp Hence, current lags the supply voltage by 63.74°. So power factor = cos (63.74) = 0.443 (iii) Power absorbed by the circuit P = VI cos P = 200 25.5 cos (63.74) = 2.256 kW Ans. (iv) Current taken by original circuit is I = 25.5 – 63.74 Amp V = 200 V Impedance of coil Z = R + jXL = V 200 = I 25.5 63.74 Z = 7.843 63.74 = 3.47 + j7.034 So R = 3.47 and X2 = 7.034 , Power = I 2 R = (25.5)2 3.47 = 2.256 kW Example 16: An AC voltage e(t) = 141.4 sin 120t is applied to a series RC circuit. The current through the circuit is obtained as i(t) = 14.14 sin 120t + 7.07 cos (120t + 30°). (2004-05) 2.71 (ii) Power factor = R 12 = = 0.6 Z 20 (iii) Voltage across the coil is VL, then VL = I (2 + jXL) VL = 10(2 + j 16) = 161.245 82.87 volt Example 18: For the given figure shown Z1 1.6 100 V 50 Hz 4 j3 6 –j8 j 7.2 Z3 Z2 Fig. 2.51 (i) (ii) (iii) (iv) Admittance of each parallel branch Total circuit impedance Supply current and power factor Total power supplied by the source. (2005-06) Solution: Z3 = 1.6 + j7.2 = 7.375 77.47 Z1 = 4 + j3 = 5 36.86 Z2 = 6 – j8 = 10 –53.13 (i) Admittance of each parallel branch is Y1 and Y2, then Y1 = 1 1 = = 0.1356 77.47 Z1 7.375 77.47 Y1 0.029 j 7.18 Y2 = 1 1 = = 0.2 36.86 Z2 5 36.86 2.72 Y2 = 0.2 [cos (–36.86)2 + j sin (–36.86)] = 0.16 – j 0.119 (ii) Total circuit impedance is Z = (Z1 || Z2) + Z3 Z = Z3 + Z 2 Z1 Z 2 Z1 = 1.6 + j7.2 + 5 36.86 10 53.13 (4 j 3) (6 j 8) = 1.6 + j7.2 + 50 16.27 10 j 5 = 1.6 + j7.2 + 50 16.27 11.18 26.56 = 1.6 + j7.2 + 4.47 10.29 = 1.6 + j 7.2 + 4.398 + j0.798 Z 5.998 j 11.598 13.06 62.65 (iii) Supply current I = V 100 = Z 13.06 62.65 I 7.65 62.65 Amp Power factor = cos 62.65 = 0.459 (iv) Power supplied by source = VI cos P = 100 7.65 cos (62.65) = 351.13 watt or, P = I 2 R = (7.65)2 5.998 = 351.02 watt Example 19: For the circuit shown below, determine: (i) Resonant frequency (ii) Total impedance at resonance Ans. 2.74 Example 20: Draw the phasor diagram showing the following voltage and find the RMS value of resultant voltage. V1 = 100 sin 500t, V2 = 200 sin 500 t 3 V3 = –50 cos (500t), V4 = 150 sin 500 t 4 Solution: Vm and 2 If V = Vm sin (wt + ) can be represented in a polar for V = shown in X-Y plane Vm 2 Similarly V1 = 100 sin 500t V1 = 100 2 0 Ref axis 200 V2 = 200 sin 500 t V2 = 3 3 2 V3 = –50 cos (500t) 50 = –50 sin 500 t V3 = 2 2 2 V4 = 150 sin 500 t 150 V4 = 4 4 2 Phasor diagram V2 /3 ref-axis V1 /4 /2 V4 V3 Fig. 2.54 Fig. 2.53 2.75 Resultant voltage V = V1 + V2 + V3 + V4 V= = 100 200 50 150 0 3 2 2 4 2 2 2 1 100 200 cos 3 j 200 sin 3 j 50 150 cos 4 2 j 150 sin 4 = = V= 1 2 1 2 [100 + 100 + j173.20 – j50 + 106.06 – j106.06] [306.06 + j17.14] 306.54 2 32.05 RMS value of resultant voltage = 306.54 2 = 216.756 volt and resultant voltage leads from reference axis by 32.05°. Instantaneous voltage V = Vm sin (wt + ) V 306.54 sin (500 t 32.05) Example 21: A series R-L-C circuit has R = 10 , L = 0.1 H and C = 8 F. Determine, (i) Resonant frequency (ii) Q-factor of circuit at resonance (iii) The half power frequencies Solution: Given: R = 10 , L = 0.1 H, C = 8 10–6 F (i) For a series R-L-C circuit resonant frequency fr is given by fr = 1 2 LC 2.76 fr = 1 2 3.14 0.1 8 10 6 (ii) Q–factor at resonant = = = 177.94 Hz. wr L R 2 f r L 2 3.14 177.94 0.1 10 R = 11.17 B.W = f2 – f1 (iii) f1 = fr – = fr – f2 = fr + {f1 and f2 are half power frequencies. B.W 2 10 R = 177.94 – = 169.99 Hz 4 3.14 0.1 4 L B.W = 177.94 + 7.95 = 185.89 Hz. 2 Example 22: An alternating current of frequency 50 Hz, has a maximum of 1 second after the instant the current is zero 600 and its value decreasing thereafter (b) How many seconds after the instant the current is zero (increasing therefore words)? Will the current attain the value of 86.6 A? (Elect. Tech. Allah. Univ. 1991). 100 A. Calculate (a) its value Solution: The equation of the alternating current (assumed sinusoidal) with respect to the origin of Fig. 2.51. i = 100 sin 2 50t = 100 sin 100t. (a) It should be noted that, in this case, time is being measured from point A and not from O. If the above equation is to be utilized, then, this time must be referred to point O. For this purpose, half period i.e., 1 sec. has to be added to 100 2.77 86.6A i O 100 A B A 60° t – 50A 210° 1 Sec 50 Fig. 2.55 1 1 1 sec. The given time as referred to point O becomes = + 600 100 600 = 7 sec. 600 i = 100 sin 100 180 7 = 100 sin 210°. 600 1 = 100 = –50 A 2 ...Point B. (b) In this case the reference point is O or 86.6 = 100 sin 100 180t or sin 18,000t = 0.866 18,000t = sin–1 (0.866) = 60° t= 60 1 = second. 18000 300 Example 23: An alternating voltage e = 200 sin 314t is applied to a device which offers an ohmic resistance of 20 to the flow current in one direction, while preventing the flow of current in opposite direction. Calculate RMS value, average value and form factor for the current over one cycle. (Elect. Engg. Nagpur Univ. 1992). Solution: Comparing the given voltage equation with the standard form of alternating voltage equation, we find that Vm = 200 V, R = 20 , Im = 200 = 10 A. 20 2.79 = 350 sin (2 180 50 0.018) = –205.72 Volt Ans. Example 25: A sinusoidal alternating current of frequency 25 Hz has a maximum value of 100 A. How long will it take for the current to attain values of 20, and 100 A? Solution: For AC current i = Im sin (wt) Im = 100 A, f = 25 Hz Given i = 100 sin 50t (a) When current attain value of 20 amp, means instantaneous value i = 20 amp. 20 = 100 sin 50t sin 50t = 0.2 50t = sin–1 0.2 = 11.5° t= 11.5 11.5 = 0.00128 sec 50 50 180 (b) When instantaneous current i = 100 amp i = 100 sin 50t 100 = 100 sin 50t 50t = sin–1 = 90° t= 90 = 0.01 sec. 50 180 Example 26: The voltage across and current through a circuit are given by v = 250 sin (314t – 10°) volt and i = 10 sin (314t + 50°) A. Calculate, the impedance, resistance, reactance and power factor of the circuit. Solution: given v = 250 sin (314t – 10°) volt i = 10 sin (314t + 50°) amp 2.80 above voltage are in time domain we can write in polar form V= I= 250 10 2 10 2 50 V I Impedance of ckt = Z = 250 10 2 Z= 10 50 2 Z 25 60 From this it is clear that current leads the voltage by 60°. So power factor = cos 60° = 0.5 Z = R – jXC = 25[cos 60 + j sin (–60)] R – jXC = 12.5 – j 21.65 Comparing real and imaginary part R = 12.5 , XC = 21.65 Ans. Example 27: – j5 1 1 2 I 2 I2 B j3 I3 V = 10 0 C 4 3 Fig. 2.56 Find (a) Total impedance (b) Current drawn from supply V2 j2 V3 2.82 (d) 2 = 6.65 36.8 VBC = = 1.30 41.9 Z2 1 j5 current I2 leads the VBC by (41.9° + 36.8°) Im = 6.65 36.8 VBC = = 1.49 63.4 Z3 4 j2 (e) Power factor cos = cos (15.7) = 0.963 lagging or, cos = R 5.65 = = 0.963 Z 5.87 (f) Apparent power s = VI = 10 1.70 = 17.0 VA True power = I 2 R = 1.7 1.7 5.65 = 16.32 W. = VI cos = 10 1.7 0.963 = 16.34 W. Reactive power = I 2 X = 1.7 1.7 1.59 = 4.59 vars = VI sin = 10 1.7 sin (15.7°) = 4.6 vars. (g) Phasor diagram Let V = 10 0 is a reference. I2 V1 41.9° V 63.4° I 36.° 15.7° VBC I3 V3 Fig. 2.57 2.83 Example 28: An alternating current of frequency 60 Hz, has a maximum value of 120 A. Write down the equation for its instantaneous value. Reknocking time from the instant the current is zero and is becoming positive Find (a) The instantaneous value after 1/360 second and (b) The time taken to reach 96 A for the first time. Solution: The instantaneous current equation is i = 120 sin 2f t = 120 sin 120 t. Now, when t = 1/360 second, then (a) i = 120 sin (120 1/360) ... angle in radians = 120 sin (120 180 1/360) ... angle in degree = 120 sin 60° = 103.9 A. (b) 96 = 120 sin 2 180 60 t angle in degree or, sin (360 60 t) = 96/120 = 0.8 360 60 t = sin–1 0.8 = 53° (approx.) t = 0/2 f = 53/360 60 = 0.00245 second. Example 29: An alternating current varying sinusoidally with a frequency of 50 Hz, has an RMS value of 20A. Write down the equation for the instantaneous value and find this value. (a) 0.0025 second (b) 0.0125 second after passing through a positive maximum value. At what time, measured from a positive maximum value, will the instantaneous current be 14.14 A? [Elect. Sc. I Allah. Univ. 1992] Solution: Im = 20 2 = 28.2 A, W = 2 50 = 100 red/sec. i +20A 28.2 A 14.14 A O A C B D 45° 60° 225° Fig. 2.58 –20 A Q 2.85 This gives us the equation for the function for one cycle. Yav = 1 T 1 = T 1 Mean square value= T = 1 T T 0 T 0 T 0 ydt = 1 T T 0 10 10 t dt T 10 1 5t 2 10 10 . . = t dt t dt T T T T 2 y dt = 0 = 15 0 2 10 10 t dt T 100 2 200 t dt 100 2 t T T T 0 1 100t 3 100t 2 100t = T 3T 2 T or, T T = 0 700 3 RMS value = 10 7/3 = 15.2 Example 31: Determine average value, effective value and form factor of a sinusoidally varying alternating current whose half wave is rectified in each cycle. Solution: Average value of current is given by, Iav = area of rectified wave interval i O Fig. 2.60 2 2.86 = 0 2 = id 0 I m sin d 2 = Im [ cos ]0 2 Im Effective value of current, = ...(2.24) 0 I= i 2d = 2 0 I m2 sin 2 d 2 (1 cos 2) d 2 = Im 2 = Im 2 1 sin 2 2 2 0 = Im = 2 Form factor = 0 I = m 2 2 I m /2 = = 1.57 Ans. 2 Im / Example 32: Three coils of resistances 20, 30 and 40 and inductance 0.5, 0.3 and 0.2H, respectively are connected in series across a 230 V, 50 c/s supply. Calculate the total current, power factor and the power consumed in the circuit. Solution: Total resistance R = 20 + 30 + 40 = 90 Total resistance L = 0.5 + 0.3 + 0.2 = 1.0 XL = 2 fL = 2 50 1.0 = 314 Impedance Z = = R 2 X L2 902 3142 = 327 2.87 Current I = Power factor cos = E 230 = = 0.704 A. Z 327 R 90 = . Z 327 = 0.275 lagging. Power consumed = EI cos . = 230 0.704 0.275. = 44.5 watts. Example 33: A resistance of 100 and a capacitance of 40 F are connected in series across a 400 V supply of 50 c/s. Find the current, power factor and the power consumed in the circuit. Draw the vector diagram. Solution: R = 100 XC = 1 1 = = 79.5 2 50 40 10 6 2 f .c. Impedance Z = 1002 79.52 = 127.8 Current = 400 = 3.13 A. 127.8 IR = 313 V = 38.5° 90° F = 400V Fig. 2.61 I = 3.13 A I X c = 248.5 2.90 = 240 1.725 0.72 = 298 watts. Ans. (f) Resonance will occur, when XL = XC or, 2 fL = fo = = 1 2 f .c. 1 2 LC 1 2 .2 20 10 6 = 39.8 c/s. Ans. Example 35: A circuit consisting of resistance of 10 in series with an XL = 15 is connected in parallel with another circuit consisting of resistance of 12 and capacitive reactance of 20 combination is connected across a 230 V, 50 Hz supply. Find (a) Total current taken from supply (b) Power factor of circuit. Solution: (a) The given circuit is shown in Fig. 2.63. 10 15 I 12 II –20 230V Fig. 2.64 Branch I: Conductance g1 = = R1 Z12 10 = 0.0307 10 152 2 2.91 Susceptance b1 = 15 = – 0.0461 2 10 15 Conductance g2 = 12 R2 = 2 = 0.022 2 2 12 20 Z2 2 Branch II: Since, branch II has capacitive susceptance, so it will be assigned –ve sign. Susceptance b2 = 20 = + 0.0368 2 12 20 2 Combined circuit: Total conductance g = 0.0307 + 0.022 = 0.0527 Total susceptance b = b2 – b1 = 0.0368 – 0.0461 = – 0.0093 g 2 b2 Total admittance Y = 0.0527 2 0.00932 = = 0.0535 Current taken from supply, I = E.Y = 230 0.0535 = 12.3 A Ans. (b) Power factor cos = = g Y 0.0527 = 0.985 lagging Ans. 0.0535 Example 36: In a parallel circuit, branch I consists of a resistance of 20 in series with an inductive reactance of 15 and branch II has a perfect condenser of 50 reactance. The combination is connected across 200 V, 60 c/s supply. Calculate: (a) Current taken by each branch. (b) Total current taken. (c) P.F. of the combination. Draw vector diagram. 2.92 Solution: 20 j5 I2 = 4A I1 2 = 90° – j5 E = 200V I2 1 = 36.9° I 200V I1 = 8A Fig. 2.65 Fig. 2.66 (a) Branch I: Z1 = I1 = 202 152 = 25 200 =8A 25 1 = tan–1 15 = 36.9° lagging. 20 Branch II: Za = I2 = 0 ( 50) 2 = 50 . 200 = 4 A. 50 50 = tan–1 0 = 90° leading. 2 = tan–1 (b) Combined circuit: Total current I is the vector sum of the two branch currents I1 and I2. Resolving the currents along E (i.e., in their active components). I cos = I1 cos 1 + I2 cos 2 = 8 cos 36.9° + 4 cos 90° = 8 0.8 = 6.4 A. equivalent impedance of the parallel circuit, 1 1 1 = Z 23 Z 2 Z3 = 1 1 (3 j 4) (4 j 3) = 4 j3 3 j 4 (4 j 3) (3 j 4) = = 7 j1 24 j 7 = 24 j 7 7 j1 = (24 j 7) 7 j1 7 j1 7 j1 175 j 25 175 j 25 50 7 2 12 = 3.5 – j 0.5. Symbolic expression of the total impedance, Z13 = Z1 + Z23 = (2.5 + j 1.5) + (3.5 – j 0.5) = 6 + j 1. Ans. Taking the voltage as reference vector, = E = 200 + j 0. E 200 j 0 Total current I = – Z13 6 j1 = 200 (6 – j 1) = 32.4 – 5.4 = 62 + 1 32.42 5.42 = 328 A Ans. I= and, 5.4 = tan–1 = tan–1 (–0.1665) = –9.5° 32.4 2.95 2.96 Voltage across the series branch, E = I .Z1 = (32.4 – j 5.4) (2.5 + j 1.5) = 89.1 + j 35.1 35.1 12 = tan–1 = tan–1 0.394 = 21.5° 89.1 E23 = E13 – E12 = 200 + j 0 – (89.1 + j 35.1) = 110.9 – j 35.1 35.1 23 = tan–1 = tan–1(–0.317) = – 17.6° 110.9 E23 = 110.92 35.12 = 116 V. Current in upper parallel branch, E 110.9 j 35.1 I1 = 23 = Z2 4 j3 = (110.9 j 35.1) (4 j 3) 338.3 j 473.1 25 42 32 = 13.55 – j 18.9 I1 = 13.52 18.92 = 23.2 A Ans. and, 18.9 = tan–1(–1.395) = – 54.4°. 1 = tan–1 13.55 Current in lower parallel branch, I2 = = E23 110.9 j 35.1 3 j 4 = Z3 3 j4 3 j4 473.1 j 338.3 = 18.9 + j 13.55. 25 = 2.99 100 5 cos 45° = 176.78 W 2 2 Example 40: A 100 V, 60 W lamp is to be operated on a 250 V 50 Hz supply. Calculate the value of (a) non-inductive resistor, (b) pure inductance, lamp in order that it may be used at its rated voltage. What would be required to place in series with the lamp in order that it may be used as its rated voltage. Solution: Current taken by the lamp I= P 60 = = 0.6 A V1 100 If R1 is the resistance of the lamp, P = I2R1 R1 = P 60 = 166.66 2 = I (0.6) 2 (a) Non-inductive resistor R When a non-inductive resistance R is placed in series with the lamp, the total resistance of the circuit becomes RT (say), where RT = R1 + R = 166.66 + R Since, the circuit is purely resistive V = RTI 250 = (166.66 + R) 0.6 R= 250 – 166.66 = 250 0.6 (b) Pure inductance L When a pure inductance L placed in series with the lamp the total impedance of the circuit is given by Z2 = R1 + jXL = 166.66 + j 2 50L By Ohm’s law V = Z2I 250 = (166.66 + j 2 50L) 0.6 250 = 0.6 (166.66) 2 (2 50 L ) 2 2.100 2 250 2 2 0.6 – (166.66) = (2 50L) (173611 27775) = 2 50L L = 1.2155 H Example 41: Three sinusoidally alternating currents of RMS values 5, 7, 5 and 10 A are having same frequency of 50 Hz. with phase angles of 30°, – 60° and 45°. (i) Find their average values. (ii) Write equation for their instantaneous values. (iii) Draw wave forms and phasor diagrams taking first current as the reference. (iv) Find the instantaneous values at 100 m sec from the original reference. [Nagpur Univ. Nov. 1996] Solution: (i) Average value of alternating quantity in case of sinusoidal nature of variation = (RMS values)/1.11 Average value of 1st current = 5/1.11 = 4.50 A Average value of 2nd current = 7.5/1.11 = 6.76 A Average value of 3rd current = 10/1.11 = 9.00 A (ii) Instantaneous values i1(t) = 5 2 sin (314t + 30°) i2(t) = 7.5 2 sin (314t – 60°) i3(t) = 10 2 sin (314t + 45°) (iii) First current is to be taken as a reference, none form the expression second current lags, behind the first current by 90°. Third current leads the first current by 15° wave form with this description are drawn in Fig. 2.71 (a) and the phasor diagrams in Fig. 2.71 (b). (iv) A 50 Hz AC quantity completes a cycle in 20 m sec. In 100 m sec, it completes five cycles original reference is the starting point required for this purpose. Hence, at 100 m sec from the reference. 2.101 i3 i i2 i1 O 270° 130° 90° 360° wt Fig. 2.70(a) I3 = 10A 5° I1 = 5A I2 =7.5A Fig. 2.70(b) (v) Instantaneous value of i1(t) = 5 2 sin 30° = 3.53 A Instantaneous value of i2(t) = 7.5 2 sin (–60°) = –9.816 A Instantaneous value of i3(t) = 10 2 sin (45°) = 10 A Example 42: A resultant current wave is made up of two components. 5 A DC component and a 50 Hz AC component. Which is of sinusoidal wave form and which has a maximum value of 5 A. (i) Draw a sketch of the resultant wave. (ii) Write an analytical expression for the current wave, reckoning t = 0 at a point where the AC component is at zero value and when di/dt is +ve. (iii) What is the average value of the resultant current over a cycle? (iv) What is the effective or RMS value after resultant current? 2.103 RMS value I = 37.5 = 6.12 A. Alternate Let the effective value of resultant current is I. Instantaneous current i = 5 + 5 sin t 2 5 I R=5 R+ R 2 2 2 I= 52 25 37.5 2 I = 6.12 amp Example 43: If the current in a 20 resistor is given by i = 4 + 5 sin t – 3 cos 3 t. Determine the power consumed by the resistor. Solution: P = P0 + P1 + P2 2 5 3 = 4 20 + 20 + 20 2 2 2 2 = (16 + 12.5 + 4.5) 20 = 660 watt. effective value of current = 660 33 = 5.7 Amp 20 Example 44: A large coil of inductance 1.405 H and resistance of 40 is connected in series with a capacitor of capacitance 20 µF. Calculate the frequency at which the circuit resonates. If a voltage of 100 V is applied to the circuit at resonant condition, calculate the current drawn from the supply and the voltage across the coil and the capacitor, quality factor, band width. Solution: R = 40 , L = 1.405 H, C = 20 10–6 F resonant frequency f0 = At resonance current I0 = 1 2 LC = 1 2 1.405 20 10 6 V 100 = 2.5 A R 40 At resonance impedance Z0 = R + j X L0 = 30 Hz. 2.104 R 2 X L20 = Z0 = 402 264.82 = 267.8 Voltage across the coil at resonance is X L0 VL0 = I0 Z0 = 2.5 267.8 = 669.5 volt Capacitive reactance at resonance is X C0 X C0 = 1 1 = 265.2 2 f0C 2 30 20 10 6 Voltage across the capacitor VC0 = X C0 I0 = 265.2 2.5 = 663 V Quality factor Q0 = Band width = 2 f0 L 2 30 1.405 W0 L = = 6.6175 Ans. 40 R R R 40 = 28.469 L 1.405 Example 45: A current of 120 – j 50 flows through a circuit when the applied voltage is 8 + j 2, determine (i) impedance (ii) power factor (iii) power consumed and reactive power. Solution: V = (8 + j 2)V = 8.25 14° V I = (120 – j 50)A = 130 –22.62° A V 8.25 14 = 0.0635 36.62° I 130 22.62 (i) Z= Z = 0.0635 (ii) (iii) = 36.62° lag. p.f. = cos = cos 36.62° = 0.803 lag Complex VA, S = Phasor voltage conjugate of phasor current or p + jQ = 8.25 14° 130 22.62° = 1072.5 36.62° VA = 1072.5 (cos 36.62° + j sin 36.62°) = (860.8 + j 639.75)VA Power consumed, P = 860.8 W Reactive power, Q = 639.75 VAr. 2.105 Example 46: In an R – L series circuit R = 10 and XL = 8.66 if current in the circuit is (5 – j 10) A, find (i) the applied voltage (ii) power factor and (iii) active power and reactive power. Solution: Z = R + jXL = (10 + j 8.66) = 13.23 40.9° I = (5 – j 10)A = 11.18 –63.43° A (i) V = IZ = 11.18 –63.43° 13.23 40.9° = 148 –22.53° V V = 148 Volts. (ii) = 63.43° – 22.53° = 40.9° p.f. = cos = cos 40.9° = 0.756 lag. (iii) or S = phasor voltage conjugate of phasor current. P + jQ = 148 –22.53° 11.18 63.43° = 1654.64 40.9° VA. = (1250.66 + j 1083.36)VA Active power, P = 1250.66 W Reactive power Q = 1083.36 VAr. Example 47: Two circuits having the same numerical ohmic impedance are joined in parallel. The power factor of one circuit is 0.8 and the other 0.6. What is the power factor of the combination? Solution: Let Z be the impedance of each circuit Z1 = Z cos–1 0.8 = Z 36.87° = Z (0.8 + j 0.6) Z2 = Z cos–1 0.6 = Z 53.13° = Z (0.6 + j 0.8) Since, the two impedances are connected in parallel, the equivalent impedance of the combination is given by Zp = Z1 || Z2 = Z1Z 2 Z1 Z 2 = ( Z 36.87) ( Z 53.13) Z 2 90 Z (0.8 j 0.6 0.6 j 0.8) Z (1.4 j 1.4) = Z 45 Z 2 90 = 1.98 Z (1.98 45) The power factor of the combination is cos = cos 45° = 0.707 Y1 = = 2.107 1 1 6 j5 Z1 6 j 5 (6 j 5) (6 j 5) 6 j5 = 0.09836 – j 0.08196 S 62 52 Z2 = 8 – j 6 = 10 – 36.87° Y2 = 1 1 8 j6 8 j6 Z 2 8 j 6 (8 j 6) (8 j 6) 82 62 = 0.08 + j 0.06 S Z3 = 8 + j10 = 12.8 51.34° Y3 = 1 1 8 j 10 8 j 10 2 = 8 j 10 (8 j 10) (8 j 10) 8 102 Z3 = 0.04878 – j 0.06097 S Total admittance of the circuit Y = Y1 + Y2 + Y3 = 0.09836 – j 0.08196 + 0.08 – j 0.06 + 0.04878 – j 0.06097 = 0.22714 – j 0.08293 = 0.2418 20.06 S Total circuit voltage V = IZ = I1 = I 20 0 = = 82.71 20.06° V Y 0.2418 20.06 V 82.71 20.06 = Z1 7.81 39.8 = 10.59 – 19.74° A = 9.967 – j 3.576 A I2 = V 82.71 20.06 = Z2 10 36.87 = 8.271 56.93° A = 4.513 + j 6.930 A I3 = V 82.71 20.06 = Z3 12.8 51.34 2.108 = 6.46 – 31.28° A = 5.52 – j 3.35 A I1 + I2 + I3 = 20 + j 0 = I Example 50: A single phase circuit consists of three parallel branches, the admittance of the branches are Y1 = 0.4 + j 0.6 Y2 = 0.1 + j 0.4 Y3 = 0.06 + j 0.23 Determine the total admittance and impedance of the circuit. Solution: Since, the admittances are in parallel Y = Y1 + Y2 + Y3 = (0.4 + j 0.6) + (0.1 + j 0.42) + (0.06 + j 0.23) = (0.4 + 0.1 + 0.06) + j (0.6 + 0.42 + 0.23) = 0.56 + j 1.25 = 1.369 65.86 Impedance = Z = 1 1 = = 0.73 65.86 Y 1.369 65.86 Z = 0.298 – j 0.666 Example 51: In the network shown in Fig. 2.74, determine (a) the total impedance, (b) the total current (c) the current in each branch, (d) the overall power factor, (e) volt-amperes, (f) active power, and (g) reactive volt-amperes. 7 A I 5 0.01 H I1 0.015 H 1 C 3 230 V, 50 Hz I2 12 2 180 F Fig. 2.72 Solution: (a) Branch 1: R1 = 7 L1 = 0.015 H X L1 = 2fL1 = 2 50 0.015 = 4.71 Z1 = R1 + j X L1 = 7 + j 4.71 = 8.437 33.93 2.109 Branch 2: R2 = 12 C2 = 180 F = 180 10–6 F X C2 = 1 1 = = 17.68 2 f C2 2 50 180 10 6 Z2 = R2 – j X C2 = 12 – j 17.68 = 21.37 – 55.83° Since, Z1 and Z2 are connected in parallel, their equivalent impedance Zp is given by Zp = Z1 || Z2 = Z1Z 2 Z1 Z 2 = (8.437 33.93) (21.37 55.83) (7 j 4.71) (12 j 17.68) = 180.3 21.9 180.3 21.9 19 j 12.97 23 34.3 = 7.839 + 12.4° = 7.656 + j 1.68 Branch 3: R3 = 5 , L3 = 0.01 H X L3 = 2fL3 = 2 50 0.01 = 3.14 Z3 = R3 + j X L3 = 5 + j 3.14 = 5.9 32.13° is Since, Z3 and Zp are connected in series, the total impedance of the circuit Z = Z3 + Zp = 5 + j 3.14 + 7.656 + j 1.68 = 12.656 + j 4.82 = 13.54 20.85 (b) Let the supply voltage V be taken as reference phasor. V = 230 0° V = 230 + j 0 V. By Ohm’s law total circuit current is I= V 230 0 = = 16.99 –20.85° A Z 13.54 20.85 = 15.87 – j 6.046 A 2.111 I I120 60°A IL40 –30°A 230 30°V Fig. 2.73 (i) Z = V 230 30 = 5.14 33.46° I 44.7 3.46 (ii) P = V.I cos = 230 44.7 cos 33.46° = 8577 W. Example 53: A parallel circuit consists of a 2.5 F capacitor and a coil whose resistance and inductance are 15 and 260 mH, respectively. Determine (i) the resonant frequency (ii) Q-factor of the circuit at resonance (iii) dynamic impedance of the circuit. Solution: (i) Resonant frequency, fr = (ii) Q-factor (iii) 1 2 1 R2 2 LC L = 1 106 (15) 2 = 197 Hz 2 0.260 2.5 (0.260) 2 = 2 f r L 2 197 0.260 = 21.45 15 R Zr = 0.260 L = 6933 CR 2.5 10 6 15 EXERCISE 1. What is meant by an alternating quantity? Explain how a sine wave is produced. 2. Define: cycle, periodic time and frequency. 2.112 3. What is understood by “phase difference” between two alternating quantities? Explain the term lagging current and leading current with the aid of suitable curves. 4. Define RMS value of an alternating current. Derive RMS value in case of a: (a) Sinusoidal wave (b) Rectangular wave (c) Triangular wave (d) Semicircular wave (e) Trapezoidal wave (g) Stepped wave. 5. Define average value of an alternating current. Derive average value in case of a: (a) Sinusoidal wave (b) Rectangular wave (c) Triangular wave (d) Semicircular wave (e) Trapezoidal wave (g) Stepped wave. Also define form factor and find its value in case of all the above waves. 6. Define peak or crest factor and state its practical utility. 7. Determine average value, effective value and form factor of a triangular wave whose half wave is suppressed in each cycle. 8. Two waves represented by e1 = 3 sin t. and e2 = 4 sin t are 3 acting in a circuit. Find an expression of their resultant and check the result by a graphical construction. Also find the peak and RMS values of the resultant. [ 37 sin (t. – 0.605); 37 , 4.3] 9. An alternating current is given in amperes by the expression, i = 50 sin 44 t. Find (a) frequency. (b) w in radians per second (c) maximum value of the current (d) effective value of the current [(a) 70 c/s, (b) 440, (c) 50 A and (d) 35.35 A] 2.115 Calculate also the total current supplied in each case if the applied voltage is 240 V. [6.74 F, 16 A & 0.0648 A] 26. Define effective, equivalent or dynamic impedance of a rejecter circuit. Find the current in a parallel circuit at resonance after making practical assumptions. 27. Define Q-factor and determine its value in: (a) Series resonant circuit (b) Parallel resonant circuit