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EE1 PEEE Refresher Class Power Part 1 notes by T. Ernst

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Presentation on theme: "EE1 PEEE Refresher Class Power Part 1 notes by T. Ernst"— Presentation transcript:

1 EE1 PEEE Refresher Class Power Part 1 notes by T. Ernst
EE1 – Power Part 1 Notes Fall 2011, Page 1

2 Vectors, phasors & phasing 1-phase & 3-phase Per Unit System
Power System Review Vectors, phasors & phasing 1-phase & 3-phase Per Unit System Bases (VA, V, amp & ohm) Convert between different bases EE1 – Power Part 1 Notes Fall 2011, Page 2

3 Static (don’t change over time) Map Coordinates
Vectors Static (don’t change over time) Map Coordinates EE1 – Power Part 1 Notes Fall 2011, Page 3

4 Static (don’t change over time) X-Y Plots
Vectors Static (don’t change over time) X-Y Plots EE1 – Power Part 1 Notes Fall 2011, Page 4

5 Static (don’t change over time) Impedance
Vectors Static (don’t change over time) Impedance EE1 – Power Part 1 Notes Fall 2011, Page 5

6 Polar versus Rectangular Coordinate System
EE1 – Power Part 1 Notes Fall 2011, Page 6

7 Polar versus Rectangular Coordinate System
EE1 – Power Part 1 Notes Fall 2011, Page 7

8 Polar versus Rectangular Coordinate System
EE1 – Power Part 1 Notes Fall 2011, Page 8

9 Vectors that rotate: ω = 2πf (radians/sec)
Phasors Vectors that rotate: ω = 2πf (radians/sec) Representation: Sine and Cosine functions over time EE1 – Power Part 1 Notes Fall 2011, Page 9

10 Phasors EE1 – Power Part 1 Notes Fall 2011, Page 10

11 Express leading or lagging as: Current wrt voltage
Phasing Convension: Express leading or lagging as: Current wrt voltage Angle less than 180 degrees EE1 – Power Part 1 Notes Fall 2011, Page 11

12 ELI the ICE man EE1 – Power Part 1 Notes Fall 2011, Page 12

13 Single Phase Power Ohms Law (V, I & Z) Note: V & I are phasors
Z is a vector EE1 – Power Part 1 Notes Fall 2011, Page 13

14 VA = V * I* where I* = complex conjugate
Single Phase Power VA = W + jVAR (S = P + jQ ) VA = V * I* where I* = complex conjugate EE1 – Power Part 1 Notes Fall 2011, Page 14

15 VA = V * I* where I* = complex conjugate
Single Phase Power VA = W + jVAR (S = P + jQ ) VA = V * I* where I* = complex conjugate EE1 – Power Part 1 Notes Fall 2011, Page 15

16 Cos Θ = power factor (PF = W/VA)
Θ = power factor angle Cos Θ = power factor (PF = W/VA) EE1 – Power Part 1 Notes Fall 2011, Page 16

17 Balanced Systems (V, I and Z)
3-Phase Power Balanced Systems (V, I and Z) EE1 – Power Part 1 Notes Fall 2011, Page 17

18 Balanced Systems (V, I and Z)
3-Phase Power Balanced Systems (V, I and Z) EE1 – Power Part 1 Notes Fall 2011, Page 18

19 Open vector representation
EE1 – Power Part 1 Notes Fall 2011, Page 19

20 Closed Vector Representation
EE1 – Power Part 1 Notes Fall 2011, Page 20

21 Phase-phase versus Phase Quantities
EE1 – Power Part 1 Notes Fall 2011, Page 21

22 Use phase quantities for ohms law Vpn, Ip, Zpn
EE1 – Power Part 1 Notes Fall 2011, Page 22

23 Ipp is usually Iwdg or Iload
EE1 – Power Part 1 Notes Fall 2011, Page 23

24 3-Phase equations EE1 – Power Part 1 Notes Fall 2011, Page 24

25 3-Phase equations EE1 – Power Part 1 Notes Fall 2011, Page 25

26 Power Transformer 375 MVA, 115 – 230 kV, 3-phase
Find FLI on 115 kV side EE1 – Power Part 1 Notes Fall 2011, Page 26

27 Power Transformer 375 MVA, 115 – 230 kV, 3-phase
Find FLI on 230 kV side EE1 – Power Part 1 Notes Fall 2011, Page 27

28 VABase (3-phase value for 3-phase systems)
Per-Unit System Normalize V, I Z & VA Base Values VABase (3-phase value for 3-phase systems) VBase (P-P value for 3-phase systems) IBase (“line” current for 3-phase systems) ZBase (P-N value) EE1 – Power Part 1 Notes Fall 2011, Page 28

29 Choose VABase for convenience (Same across the entire circuit)
Per-Unit System Approach Choose VABase for convenience (Same across the entire circuit) Assign VBase = nominal system voltage (different at different points of the circuit) Calculate IBase and ZBase EE1 – Power Part 1 Notes Fall 2011, Page 29

30 Calculate per-unit values of actual V, I & Z
EE1 – Power Part 1 Notes Fall 2011, Page 30

31 Converting Zpu from one base to another
EE1 – Power Part 1 Notes Fall 2011, Page 31

32 An Example: EE1 – Power Part 1 Notes Fall 2011, Page 32

33 Choose Bases: EE1 – Power Part 1 Notes Fall 2011, Page 33

34 Get everything on same base
EE1 – Power Part 1 Notes Fall 2011, Page 34

35 EE1 – Power Part 1 Notes Fall 2011, Page 35

36 EE1 – Power Part 1 Notes Fall 2011, Page 36

37 EE1 – Power Part 1 Notes Fall 2011, Page 37

38 Draw the per-unit one-line
EE1 – Power Part 1 Notes Fall 2011, Page 38

39 Reduce the network EE1 – Power Part 1 Notes Fall 2011, Page 39

40 Use voltage division to calculate Vload
EE1 – Power Part 1 Notes Fall 2011, Page 40

41 Use Vload to calculate PU load currents
EE1 – Power Part 1 Notes Fall 2011, Page 41

42 Use Ibase to calculate load currents
EE1 – Power Part 1 Notes Fall 2011, Page 42

43 EE1 – Power Part 1 Notes Fall 2011, Page 43

44 EE1 – Power Part 1 Notes Fall 2011, Page 44

45 EE1 – Power Part 1 Notes Fall 2011, Page 45

46 EE1 – Power Part 1 Notes Fall 2011, Page 46

47 EE1 – Power Part 1 Notes Fall 2011, Page 47

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