Fuseless Capacitor Bank Protection

Transcription

1 Fuseless Bank Protection Minnesota Power Systems Conference St. Paul, MN. November 2, 1999 by: Tom Ernst, Minnesota Power Other Papers of Interest Presented at Western Protective Relay Conference, Oct. 26, 1999 Protection of Fuseless Shunt Banks Using Digital Relays, by M. Dhillon and D. Tziouvaras. New Techniques for Bank Protection and Control, by J. McCall, T. Day, A. Chaudhary and T. Newton. 1

2 Types of s Internally Fused Externally Fused Fuseless Internally Fused Internal Fuse 2

3 Internally Fused s shorts blow internal element fuses Can continues to operate with blown element fuse(s) Failure Mode of Internally Fused Blown Internal Fuse Shorted Voltage Increases on Remaining s in the Group 3

4 Externally Fused External Fuse Externally Fused s First element short raises voltage stress on remaining element groups Additional elements cascade fail External fuse blows for 2 or 3 element groups shorted 4

5 Can Current Increases Through Fuse Failure Mode of Externally Fused (Initial Failure) Shorted Voltage Increases on Remaining Groups External Fuse Blows After 2 or 3 Failures Failure Mode of Externally Fused (Cascaded Failure) Original Shorted Cascaded Failures 5

6 Fuseless Fuseless s shorts raise voltage stress on remaining element groups Can continues to operate with shorted element(s) Cascaded element failures are not necessarily in same can 6

7 Failure Mode of Fuseless Shorted Voltage Increases on Remaining Groups Typical Bank Installations Externally Fused Fuseless 7

8 Externally Fused Bank External Fuses Cans Externally Fused Banks First blown fuse raises voltage stress on remaining cans Cans can cascade fail after exceeding 110% of can nameplate 8

9 Externally Fused Bank Failures Phase 1 Blown Can Fuse Failed Can Voltage Increases Across Other Cans in the Group Phase 2 Phase 3 Fuseless Bank Phase 1 Phase 2 Phase 3 Cans Protection Module (single capacitor element) 9

10 Fuseless Bank Phase 1 Cans Protection Module (single capacitor element) Phase 2 Phase 3 Fuseless Bank with Neutral Protection Module Phase 1 Phase 2 Phase 3 Cans Protection Module (single capacitor element) 10

11 Fuseless Banks First failed element raises voltage stress on remaining elements in series group s can cascade fail after exceeding 110% of element nameplate failures do not necessarily occur in same can Fuseless Bank Failures Phase 1 Voltage Increases Across Other s in the Series Group Failed Phase 2 Phase 3 11

12 Protection Objectives Short circuit protection for phase and ground faults Overvoltage protection resulting from excessively high power system voltages Overvoltage protection resulting from element failures Short Circuit Protection Phase overcurrent relaying (50/51) on breaker phase CTs Overlapping bus differential relays (87B) Residual overcurrent relaying (50/51G) Trip and lock-out bank 12

13 System Overvoltage Protection Phase overvoltage relaying (59B) connected to bus PTs. Trip bank for 110% of nameplate voltage (no lock-out) -Failure Caused Overvoltage Protection Voltage differential (87V) Neutral overvoltage (59N) Neutral overcurrent (51N) 13

14 Voltage Differential (87V) Phase 1 Phase 2 Phase 3 Monitors the voltage difference between the bus and the protection module Tap VT Bus VT 87V Alternate Voltage Differential (87V) Phase 1 Phase 2 Phase 3 Monitors the voltage difference between the protection modules on each series group 87V 14

15 Voltage Differential Objectives Alarm for 2 or 3 failed elements (4-5% element overvoltage) Trip and lock-out bank for 10% element overvoltage Neutral Overvoltage (59N) Phase 1 Phase 2 Phase 3 Operates on the voltage across the neutral caused by phase unbalances 59N 15

16 Neutral Overvoltage Objectives Alarm for 2 or 3 failed elements (4-5% element overvoltage) Trip and lock-out bank for 10% element overvoltage Calculations assume all failed elements are in the same phase Neutral Overcurrent (51N) Phase 1 Phase 2 Phase 3 Monitors the neutral unbalance current to detect failed elements 51N 16

17 Neutral Overcurrent Objectives Alarm for 2 or 3 failed elements (4-5% element overvoltage) Trip and lock-out bank for 10% element overvoltage Calculations assume all failed elements are in the same phase Questions?? 17