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Three Phase Circuits

Three Phase Circuits. Introduction: The generator , motor , transformer or rectifier have only one winding is called a single phase system If the current or voltage follows a phase difference 90 0 in a two windings , called two phase systems

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Three Phase Circuits

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  1. ThreePhase Circuits www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  2. Introduction: • The generator , motor , transformer or rectifier have only one winding is called a single phase system • If the current or voltage follows a phase difference 900 in a two windings , called two phase systems • If the phase difference is 1200 between voltages or currents in a three winding , called as Three phase systems • In poly-phase systems , there are more than three windings Advantages of three phase system: • More efficient than single phase system • Cost is less • Size is small . Compared to single phase system www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  3. Adavantages of Three Phase Circuits • The amount of conductor material is required less for transmitting same power, over the same distance , under same power loss • Three phase motors produce uniform torque , where as torque produced by single motor is pulsating • Three phase generators not produce the harmonics when they are connected in parallel • Three phase motors are self starting whereas single phase motors are not self starting www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  4. Generation of Three Phase Voltages www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  5. Vectorially r.m.s values of voltages induced in three windings are represented in the diagram • ER = E ∟0o v, • EY = E ∟-120o v • EB= E ∟+120o v www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  6. Balanced three phase supply: • A three phase supply is said to be balanced, when all the three voltages have the same magnitude but differ in phase by 120° with respect to one another. • The three phase supply is said to be unbalanced, even if one of the above conditions is not satisfied. Balanced Load: • A three phase load is said to be balanced, when the impedances of all the three phases are exactly the same. Even if one of them is different from the other, then the three phase load is said to be unbalanced www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

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  8. In a three phase balanced load, whether star connected or delta connected, the magnitudes of the phase currents are the same but differ in phase by 120o with respected to one another • But in an unbalanced load, when a three phase balanced supply is given, the magnitudes and phases of all the three phase currents will be different. Three phase connections: • There are two types of three phase connections • Star connection (Y) • Delta connection (Δ) Star connection (Y): • In this method of inter-connection, the similar ends, say, “start” ends of three coils (it could be “finishing” ends also) are joined together at point ‘N’ www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  9. The point ‘N’ is known as star point or neutral point • If this three-phase voltage is applied across a balanced symmetrical load, the neutral wire will be carrying three currents which are exactly equal in magnitude but are 120o out of phase with each other. Hence, their vector sum is zero IR + IY + IB = 0 Voltages and Currents in Y-Connection: • The voltage induced in each winding is called the ‘phase’ voltage and current in each winding is known as ‘phase’ current. www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  10. The vector diagram for phase voltages and currents in a star connection shows that ER = EY = EB= Eph (phase e.m.f) • Line voltage VRY between line 1 and line 2 is the vector difference of ER and EY. • Line voltage VYB between line 2 and line 3 is the vector difference of EY and EB. • Line voltage VBR between line 3 and line 1 is the vector difference of EB and ER. www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  11. The p.d. between lines 1 and 2 is VRY = ER - EY (Vector difference) • VRY is found by compounding ER and EY reversed and its value is given by the diagonal of the paral1elogram in figure. • The angle between ER and EY reversed is 60°. If ER = EY = EB = Eph the Phase e.m.f then, C O www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  12. Hence, in star connection It will be noted from figure that • (a) Line voltages are 120° apart. • (b) Line voltages are 30° ahead of their respective phase voltages. • (c) The angle between the line currents and the corresponding line voltages is (30 + ɸ) with current lagging. www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  13. Line Currents and Phase Currents: • Current in line 1 = IR • Current in line 2 = IY • Current in line 3 = IB Since IR = IY = IB = say, Iph - the phase current Line current IL = Iph Power: • The total power in the circuit is the sum of the three phase powers. Hence • Total Power =3 x phase power= www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  14. Delta (Δ) or Mesh Connection: • Phase sequence is R, Y, B • R leads Y by 120° and Y leads B by 120°. • The voltage between lines 1 and 2 as VRY • The voltage between lines 2 and 3 as VYB VRY leads VYB by 120 VYB leads VBR by 120°. • VRY =VYB = VBR = line voltage VL • Then, it VL = Eph www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

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  16. Line Currents and Phase Currents: • Current in line 1 is I1 = IR – IB • Current in line 2 is I2 = IY – IR • Current in line 3 is I3 = IB - IY • Current in line 1 is found by compounding IR with IB reversed and its value is given by the diagonal of the parallelogram • The angle between IR and IB reversed (-IB) is 60°. • If IB = IR = IY = Iph phase current, then current in line 1 is www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  17. Contd.. Since all line currents are equal in magnitude i.e., I1= I2 = I3 = IL From Vector diagram, it should be noted that • (a) Line currents are 120o apart. • (b) Line currents are 30o behind the respective phase currents. • (c) The angle between the line current and the corresponding line voltage is (30 + ɸ) with the current lagging. www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  18. Power: www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  19. Measure of power in Three Phase Circuits: • Wattmeter is the instrument which is used to measure power in an electrical circuit. • It consists of (i) a current coil ML’ through which the line current flows • (ii) a potential coil PV, which is connected across the circuit. • The full voltage is applied across the potential coil and it carries a very small current proportional to the applied voltage. • Three single phase watt-meters may be connected in each phase • The algebraic sum of their readings gives the total power consumed by the three phase circuit. • It can be proved that only two watt-meters are sufficient to measure power in a three phase circuit. www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  20. Two Wattmeter Method: 1. Balanced or Unbalanced Load: • The current coils of the two watt meters are inserted in any two lines • The potential coils joined to the third line. • Sum of the instantaneous powers indicated by W1 and W2 gives the instantaneous power absorbed by the three loads L1, L2 and L3. • Instantaneous current through W1 = IR • Instantaneous P.D. Across W1 = VRB = ER - EB • Power read by W1 = IR (ER – EB) www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  21. Contd.. • Instantaneous current through W2 = IY • Instantaneous P.D. across W2 = VYB = EY - EB • Power read by W2 = IY (EY – EB) Therefore, W1 + W2= IR (ER – EB) + IY (EY – EB) = IR ER +IY EY – EB (IR + IY) IR + IY + IB = 0 IR + IY = -IB = IR ER +IY EY – EB (-IB) = IR ER +IY EY + EB IB = P1 + P2 + P3 • Where P1 is the power absorbed by load L1, P2 that absorbed by L2 and P3 that absorbed by L3. W1 + W2 = total power absorbed www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  22. Balanced Load: • The load is said to be balanced, when the impedances of the three phases are equal • The supply is said to be balanced, if the three voltages are equal and are displaced by 120o with respect to one another. • When a balance supply is given to a balanced load, the currents flowing through the three phases will be equal in magnitude and are displaced by 120o with respect to each other. • Two wattmeter connections to measure power in a three phase balanced circuit as shown above figure www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  23. Let ER, EY and EB be the r.m.s. values of the three-phase voltages and IR, IY and IB be the r.m.s. values of the currents • The currents lagging behind their phase voltages by ‘ɸ’. • Current through wattmeter W1 = IR • P.D. across voltage coil of W1 = VRB = ER – EB • Now reading W1 = VRB IR cos (30° - ɸ) • Current through wattmeter W2 = IY • P.D. across voltage coil of W2 = VYB = EY – EB • W2 = VYB IY cos (30° + ɸ) • Since the load is balanced, VRB = VYB = line voltage, VL IR = IY = line current, IL W1 = VL IL cos (30° - ɸ) --------(1) W2 = VL IL cos (30° + ɸ)-------(2) -EB www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  24. Contd.. W1 + W2 = VL IL cos (30° - ɸ) + VL IL cos (30° + ɸ) = VL IL [cos 30° cos ɸ + sin 30° sin ɸ + cos 30° cos ɸ - sin 30° sin ɸ] = VL IL (2 cos 30° cos ɸ) • Expression for Power Factor (p.f): W1 - W2 = VL IL cos (30° - ɸ) - VL IL cos (30° + ɸ) = VL IL [cos 30° cos ɸ + sin 30° sin ɸ - cos 30° cos ɸ + sin 30° sin ɸ] = VL IL (2 sin 30° sin ɸ) = VL IL sin ɸ www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  25. Contd.. www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  26. Effect of p.f. on W1 and W2: W1 = VL IL cos (30° - ɸ) = VL IL cos 30° (ɸ = 0) = (√3/2) VL IL W2 = VL IL cos (30° + ɸ) = VL IL cos 30° (ɸ = 0) = (√3/2) VL IL The two wattmeter readings are positive and equal. W1 = VL IL cos (30° - 60o) = VL IL cos (-30°) (ɸ = 60o) = (√3/2) VL IL W2 = VL IL cos (30° + 60o) = VL IL cos 90° (ɸ = 60o) = 0 One of the watt meters reads zero. W1 = VL IL cos (30° - 90o) = VL IL cos (-60°) (ɸ = 90o) = (1/2) VL IL W2 = VL IL cos (30° + 90o) = VL IL cos (120°) (ɸ = 90o) = - (1/2) VL IL One of the watt-meters, reads negative (-ve). www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

  27. Observations: • One of the watt-meters reads -ve. The pointer of this watt-meter kicks back and hence the reading can not be taken. • Then, either the current coil connections or potential coil connections are interchanged, pointer moves in the forward direction and the reading can be taken. • But this reading has to be considered as -ve. Conclusion: • For p.f. lying between 0 to 0.5, one of the watt-meters, reads negative (-ve). • When p.f. = 0.5, one wattmeter reads zero (0). • When p.f. lies between 0.5 to 1.0, both watt-meter readings are positive (+). • When p.f. = 1, the readings of both watt-meters are equal. www.bookspar.com | Website for Students | VTU NOTES | QUESTION PAPERS

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