Author :
Hiskens, Ian A. ; Pai, M.A. ; Sauer, P.W.
Author_Institution :
Dept. of Electr. & Comput. Eng., Illinois Univ., Urbana, IL, USA
Abstract :
Available transfer capability (ATC) quantifies the viable increase in real power transfer from one point to another in a power system. ATC calculation has predominantly focused on steady-state viability. Point-to-point transfer can be increased until equilibrium point quantities, given by a power flow, reach security limits. Generally the equilibria are evaluated for a number of contingencies. Security limits typically include voltage thresholds, and limits associated with feeder thermal capacity and generator reactive power output. In many power systems, however, point-to-point transfer is not restricted by steady-state limits, but by undesirable dynamic behaviour following large disturbances. The post-disturbance operating point certainly must be viable; but it is also important to ensure that the system can safely make the transition from the pre- to the post-disturbance operating point. Here, the authors describe dynamic ATC, which is concerned with calculating the maximum increase in point-to-point transfer such that the transient response remains stable and viable
Keywords :
control system analysis; load flow control; power system control; power system dynamic stability; power system faults; power system security; dynamic available transfer capability; equilibrium point quantities; feeder thermal capacity; generator reactive power output; point-to-point transfer; post-disturbance operating point; power flow; power systems; security limits; steady-state viability; transient response; voltage thresholds; Load flow; Power generation; Power system dynamics; Power system security; Power system transients; Reactive power; Stability; Steady-state; Threshold voltage; Transient response;
Conference_Titel :
Power Engineering Society Winter Meeting, 2000. IEEE
Print_ISBN :
0-7803-5935-6
DOI :
10.1109/PESW.2000.847587
