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Transcript
Session 1b. Electric Power Systems and How They Work 1 What really makes power flow ? • The amount of power flowing over the bulk power system is proportional to the difference between the power angles of the machines • Actually, proportional to the sine of the angle 2 3 Power Swing Equation P12 = E1 E2 sine δ12 _____________ X12 Note: Above equation can be derived from Kirchhoff’s Laws Note: Said derivation intended only for professional drivers on a closed course – do not attempt this at home! 4 5 Stability The property of a system by virtue of which it will attain a new steady state condition following any one of a list of specified contingencies. Not unlike an Alexander Calder mobile. 6 Stability (cont.) • Simulation of the dynamic response of the system, particularly the generators, to a sudden contingency. • Normally judged by examining plots of the power angles of the various generators vs. time. • In a stable case, the generator power angles will oscillate, but settle at a new equilibrium. In an unstable case, they will diverge, usually quite dramatically. 7 8 9 10 Electric Systems of Pangaea 11 12 VARs (Volt Amperes Reactive) • VARs are based on “Imaginary Numbers” • What’s an “Imaginary Number” ? – The square root of 9 is 3 – The square root of 4 is 2 – The square root of 1 is 1 – What’s the square root of minus 1 ? A number whose square is a minus 13 Blame it on the Italians • 16th Century – Italian mathematicians – Cubic & quadratic equations – Solutions to some didn’t make sense – Square root of minus 1 • Raffael Bombelli – Developed first consistent theory of imaginary and complex numbers c1550 – Published Algebra in 1572 14 Bombelli’s Great Insight “Imaginary” numbers include the square root of minus 1 – “real” numbers do not Cannot combine “real” and “imaginary” numbers • Ergo, must express them as “complex numbers” with 2 distinct parts • Form: a + bi (or, a + jb) – where a is the “real” part and b is the “imaginary” part – and i (or j) is the square root of minus 1 15 Bombelli’s Algebra • What Newton’s Principia is to Physics … • What the Thomas Aquinas’ Summa is to Theology … • Bombelli’s Algebra is to Mathematics 16 VARs (cont.) WATTs / VARs Real / Imaginary Active / Reactive VARs = VOLTAGE CONTROL • Too few VARs, voltage goes down • Too many VARs, voltage goes up • Can’t live without ’em, can’t shoot ’em ! (apologies to Stephen Wright) 17 18 VARs (cont.) • • • • Need VARs all along the way Can’t move WATTs without VARs VARs don’t travel well Generally, they need to be produced locally • That’s because X >> R • “You want VARs with that?” 19 20 Transmission Losses Examples New York “Central East” • 1 – 765 kV line operated at 345 kV • 1 – 345 kV line • 2 – 230 kV lines, a number of 115 kV lines At interface loading of about 3000 MW, losses are: • 87.7 MW • 861 MVAR (717 net after line charging) Typical ECAR (Ohio Valley) to NPCC • Incr. MW losses about 10% of incr. transfer 21 Where do VARs Come From? (And Where do they Go to Die?) VARs are produced by : • generators & synchronous condensers • capacitors (or capacitor banks) • transmission lines (capacitive effect – “line charging”) VARs are consumed by : • the customers’ electrical load • series reactors • transmission lines (inductance – creates magnetic field) • generators & synchronous condensers French blackout – 12/7/78 – insufficient VARs 22 VAR Analogies VARs are like your brother-in-law; they do no work. But, unlike your brother-in-law, they’re absolutely essential. • • • • • • Steam locomotive Dyeing fabric Carrier wave Telephone poles Head on the beer (?) Pushing car across inclined plane 23 VAR Analogies (cont.) • You can think of power flow as consisting of two separate and distinct kinds of STUFF -- which can’t be mixed together, so you always have to identify them separately. • If you were ordering 6 hamburgers and 4 orders of fries, you wouldn’t try to combine them and say, “I want 10 (somethings)” !! • NO! You’d say, “I want 6 hamburgers and 4 fries.” 24 Loehr’s First Law • VARs roll down the voltage hill – They flow in accordance with differences in voltage magnitude • WATTs roll down the angle hill – They flow in accordance with differences in voltage angle 25 Useful Approximation Difference in voltage magnitude equals MVAR flow times inductive reactance (in per unit) E2 - E1 = Q x X12 26 Prof. Vladimir Karapetoff (Cornell Univ.) upon death of Steinmetz: “He was allowed to try to generate electricity out of the square root of minus one.” 27
