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Module T7 Power Flow

Module T7 Power Flow. Read Module T7. Work problems 1, 2, 3, 7 at end of Module T7. Turn in on Tuesday, April 9. Learning the power flow problem. 1. High-Level View. Program Output & Use (project). 9. Problem solution. 8. Problem formulation. FOUNDATION. 2. Gen React Cap Curves.

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Module T7 Power Flow

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  1. Module T7 Power Flow Read Module T7. Work problems 1, 2, 3, 7 at end of Module T7. Turn in on Tuesday, April 9.

  2. Learning the power flow problem. 1. High-Level View Program Output & Use (project) 9. Problem solution 8. Problem formulation FOUNDATION 2. Gen React Cap Curves 6. PF equations for injections 5. Admittance matrix 7. # of equations, # of variables 3. Injections 4. Bus types

  3. 2. Gen reactive capability curve Field current limit due to field heating, enforced by overexcitation limiter on If. Q Qmax Armature current limit due to armature heating, enforced by operator control of P and If. Typical approximation used in power flow programs. P Qmin Limit due to steady-state instability (small internal voltage E gives small |E||V|Bsin), and due to stator end-region heating from induced eddy currents, enforced by underexcitation limiter (UEL).

  4. 3. Injections

  5. 4. Bus types • First classification: • Gen • Load • Both • Bus type PV (usually gen) • Knowns: • Pinj • V • Unknowns: • Qinj • θ • 2nd classification (in terms of info known at the buses). • What is possible info? • V • θ • Pinj • Qinj • Bus type PQ (usually load) • Knowns: • Pinj • Qinj • Unknowns: • V • θ

  6. 4. Bus types • One more type…. • This type is motivated by a power specification issue inherent to solving the power flow problem: • We need to specify all MW gen and load. • To do this, we need to know losses. • Losses are a function of line flows. • We cannot know line flows until we specify all MW gen & load. • So what do we do?

  7. 4. Bus types Pull out one gen: • Bus type “Swing” • Knowns: • V • θ • Unknowns: • Pinj • Qinj And same for reactive power. This one gen is called the swing bus, slack or reference bus.

  8. 4. Admittance matrix KCL Add bus 4 connection Gather terms Do same for other four buses and then put in matrix form Off-diagonals: negative of admittance connecting corresponding two buses. Diagonals: sum of admittances for all lines & shunts connected to corresponding bus.

  9. 4. Admittance matrix Admittance matrix (or “Y-bus”):

  10. 4. Admittance matrix Admittance matrix (or “Y-bus”):

  11. Learning the power flow problem. 1. High-Level View Program Output & Use (project) 9. Problem solution 8. Problem formulation FOUNDATION 2. Gen React Cap Curves 6. PF equations for injections 5. Admittance matrix 7. # of equations, # of variables 3. Injections 4. Bus types

  12. 6. PF Equations Previously, we wrote the power flow equations for the power flowing over a certain line. Now, we want to write the PF equations for the power injection. The procedure is the same in both cases. Please do understand the difference. What we computed before. What we are computing now. =Sk=SGk-SLk

  13. 6. PF Equations

  14. 6. PF Equations

  15. 6. PF Equations

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