Detection of capacitor bank fuse/switch failure

Abstract

A method for detecting the operating condition of each phase of a three-phase capacitor bank in a power distribution system, including the steps of, if the RMS neutral current is above the bank status closed setting, comparing the phase angle of neutral current (IN) with respect to voltage on one of the phases (VA, VB or VC) and sending an alarm signal when the comparison of the phase angle of neutral current with respect to the phase voltage differs appreciably from the expected phase angles.

Claims

1. A method for detection of the operating condition of each phase of a three-phase capacitor bank in a power distribution system, comprising the steps of: measuring one of the phase voltages (VA, VB or VC) and the neutral current in the capacitor bank; comparing a RMS neutral current with all open (bank status open) and all closed (bank status closed) settings to determine if all the three phases of the capacitor bank are open or closed; if the RMS neutral current is above the bank status closed setting, comparing the phase angle of neutral current (IN) with respect to voltage on phase A (VA), or phase B (VB) or phase C (VC); sending an alarm signal when the comparison of the phase angle of neutral current (IN) with respect to the phase voltage (if VA is used add 0 , if VB is used add 120 or for VC add) 240 differs appreciably from the phase angles indicated in the following chart: TABLE-US-00002 Phase angle of I.sub.N with respect to VA (If VB is used add OPEN/CLOSE state of each Phase 120 or for VC add 240 to A B C the angles shown below) OPEN OPEN OPEN N/A CLOSE OPEN OPEN 90 OPEN CLOSE OPEN 30 OPEN OPEN CLOSE 210 CLOSE CLOSE OPEN 30 OPEN CLOSE CLOSE 270 CLOSE OPEN CLOSE 150 CLOSE CLOSE CLOSE N/A.

2. The method as set forth in claim 1, wherein the appreciable difference compared between the phase angle of neutral (IN) with respect to the phase voltage comprises approximately the phase angle indicated in the chart 10.

3. A method as set forth in claim 1, wherein measuring one of the three phase voltages in phases (VA), (VB), (VC) and calculating neutral current comprises as follows:
neutral current (I.sub.NE) =magnitude of (I.sub.A.sub._.sub.cap*a +I.sub.B.sub._.sub.cap*b+I.sub.C.sub._.sub.cap*c) Where a=1 if phase A is closed else a=0 b=1 if phase B is closed else b=0 c=1 if phase C is closed else c=0
I.sub.A.sub._.sub.cap=(1000*Q.sub.CAP)/(3*V.sub.A)
I.sub.B.sub._.sub.Cap=(1000*Q.sub.CAP)/(3*V.sub.B)
I.sub.C.sub._.sub.cap=(1000*Q.sub.CAP)/(3*V.sub.C) Q.sub.CAP=3 Phase Capacitor Bank Size in KVArs V.sub.A, V.sub.B and V.sub.C are phase to ground voltage phasors and I.sub.A cap, I.sub.B cap and I.sub.C cap are calculated Capacitor Bank current phasors.

4. The method as in claim 3, further including the step of detecting a high resistance contact of a switch wherein the neutral current is less than an undercurrent pickup setting.

5. The method as in claim 3, further including the step of detecting capacitor bank short circuit wherein the neutral current is greater than a neutral overcurrent setting.

6. An apparatus for detection of the operating condition of each phase of a three-phase capacitor bank in a power distribution system, comprising in combination: a voltage meter for measuring one of the phase voltages (VA, VB or VC) and a current meter for measuring the neutral current in the capacitor bank; a controller for comparing a RMS neutral current with all open (bank status open) and all closed (bank status closed) settings to determine if all the three phases of the capacitor bank are open or closed and if the RMS neutral current is above the bank status closed setting, then opening or closing each phases when required while comparing the phase angle of neutral current (IN) with respect to voltage on phase A (VA), or phase B (VB) or phase C (VC) and when the comparison of the phase angle of neutral current (IN) with respect to the phase voltage (if VA is used add 0, if VB is used add 120 or if VC is used add 240) differs appreciably from the phase angles indicated in the following chart: TABLE-US-00003 Phase angle of I.sub.N with respect to VA (If VB is used add OPEN/CLOSE state of each Phase 120 or for VC add 240 to A B C the angles shown below) OPEN OPEN OPEN N/A CLOSE OPEN OPEN 90 OPEN CLOSE OPEN 30 OPEN OPEN CLOSE 210 CLOSE CLOSE OPEN 30 OPEN CLOSE CLOSE 270 CLOSE OPEN CLOSE 150 CLOSE CLOSE CLOSE N/A.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) For a fuller understanding of the nature and objects of the invention, reference should be had to the following detailed description taken in connection with the accompanying drawings in which:

(2) FIG. 1 is a schematic of a 3-phase capacitor bank installation

(3) FIG. 2 setting screen showing bank open close status and neutral over/under current setting screens

(4) FIG. 3 is a setting screen showing capacitor bank size

(5) FIG. 4 is an alarm status indication screen showing neutral magnitude unbalance (neutral over current/undercurrent) and phase unbalance (indication of fuse/switch failed phase)

(6) FIG. 5 is a Setting screen for phase overcurrent function; and

(7) FIG. 6 of Table 1 shows the phase angle relationship between VA (or VB or VC) and IN.

(8) Similar reference characters refer to similar parts throughout the several views of the drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

(9) A new inventive technique is described in this disclosure which will properly detect a fuse or a switch failure and also indicates which phase (A phase, B phase or C phase) the fuse or switch failure occurred. A microprocessor based capacitor bank controller 3 is used in this invention to control the capacitor bank by sending switch OPEN and switch CLOSE commands 8 to the capacitor bank. The controller measures 3-phase voltages (VA, VB and VC) using voltage sensors (or transformers) for controllers that switch based on voltage. For controllers that switch based on reactive power (var) the controller measures 3-phase voltages and load currents 9 (VA, IA), 10 (VB, IB), 11 (VC, IC) using voltage and current sensors (or transformers) 4. The controller also measures neutral current using neutral current sensor (or transformer) 6. Capacitor banks are switched by a variety of control techniques and two prominent techniques are switching based on voltage measurement and the other one is based on reactive power measurement. No matter how the capacitor bank switching is accomplished the inventive technique disclosed here is applicable as long as phase voltage(s) and neutral current measurements are available.

(10) Detection of all Three Phases Open Condition

(11) When the switches of all three phases 2 are OPEN then there will not be any current going through the neutral and the neutral current is expected to be around zero. The Bank Status Open neutral RMS current setting 14 should be set to at least twice the noise current level measured when all three phases of the capacitor bank are open. If the measured neutral current magnitude is less than the Bank Status Open neutral RMS setting 14 then the controller considers all three phases of the capacitor bank are OPENED.

(12) Detection of all Three Phases Closed Condition

(13) When all switches of the three phases 2 are CLOSED then a small unbalance current is flown through the neutral due to normal voltage unbalance on the three phases or small differences in capacitance values of the three phases. The Bank Status Closed neutral RMS current setting 13 should be set at least to twice the maximum RMS neutral current level measured when all three phases of the capacitor bank are CLOSED. If the measured neutral current magnitude is greater than the Bank Status Open neutral RMS current setting 14 and less than the Bank Status Closed neutral RMS current setting 13 then the capacitor bank is considered as CLOSED.

(14) Detection of One or Two Phases of the Capacitor Bank in Closed Condition

(15) When the measured neutral current is greater than the Bank Status Closed setting 13 the inventive technique compares the phase angle relationship between IN with respect to VA (as shown in Table 1, note that VB or VC can also be used as a reference) to determine the status of each phase of the capacitor bank. As an example a tolerance of 10 is used in Table 1 and it can be adjusted if needed. If the status of the bank obtained based on the real time measurement of phase angle relationship between IN with respect to VA from Table 1 does not match the status of the commands sent by the capacitor bank controller then phase(s) (A, B or C) of the failed fuse(s) 9 (or switch(s)) can be determined and a Neutral Phase Unbalance Alarm 19 can be sent.

(16) As an example if the commands are sent to CLOSE A phase, OPEN B phase and CLOSE C phase switches then the phase angle of IN with respect to VA is expected to be around 150 (see Table 1). However, due to fuse (or switch) failure the measured phase angle of IN with respect to VA is around 90 indicating phase A: CLOSED, phase B: OPENED, phase C: OPENED instead of 150 phase A: CLOSED, phase B: OPENED, phase C: CLOSED condition. From this one can determine that the fuse is blown (or faulty switch) on phase C. This information (failure of phase C fuse (or switch)) can be sent using wireless communications 12 to the maintenance personnel to get immediate attention.

(17) Detection of Internal Faults in a Capacitor Bank and High Resistance Switch Contact

(18) In this invention a technique is developed to detect the health of the capacitor bank, internal short circuits and high resistance switch contacts by incorporating neutral overcurrent and undercurrent elements. The neutral current when one or two out of the three phases of the capacitor bank are closed can be determined from the measured voltage on each phase of the capacitor bank and the capacitor bank size (Q.sub.CAP) as follows:

(19) Expected neutral current (I.sub.NE)=magnitude of (I.sub.A.sub._.sub.cap*a+I.sub.B.sub._.sub.cap*b+I.sub.C.sub._.sub.cap*c)

(20) Where a=1 if phase A is closed else a=0

(21) b=1 if phase B is closed else b=0

(22) c=1 if phase C is closed else c=0
I.sub.A.sub._.sub.cap=(1000*Q.sub.CAP)/(3*V.sub.A)
I.sub.B.sub._.sub.Cap=(1000*Q.sub.CAP)/(3*V.sub.B)
I.sub.C.sub._.sub.cap=(1000*Q.sub.CAP)/(3*V.sub.C)

(23) Q.sub.CAP=3 Phase Capacitor Bank Size in KVArs 17 (see FIG. 3)

(24) V.sub.A, V.sub.B and V.sub.C are measured phase to ground voltage phasors and I.sub.A.sub._.sub.cap, I.sub.B.sub._.sub.cap and I.sub.C.sub._.sub.cap are the Capacitor Bank current phasors.

(25) A Neutral Magnitude Unbalance alarm 18 (see FIG. 4) is generated if the measured neutral current is greater than the Neutral Overcurrent Pickup setting 15 or less than the neutral Undercurrent Pickup setting 16 (see FIG. 2).

(26) A neutral overcurrent or an undercurrent is an indication of the deterioration of the capacitor bank, faults inside the capacitor bank or high resistance switch contacts.

(27) Phase Overcurrent Detection

(28) When the capacitor controller is connected with 3-phase load currents (IA, IB and IC) the control measures three phase load currents providing phase overcurrent detection. Phase overcurrent detection can be used to detect the faulty segment of the distribution feeder. In order to detect a phase overcurrent condition the controller compares the measured load current in each phase with an overcurrent pickup. When the controller detects a phase overcurrent condition it triggers an input to the Sequence of Events recorder and Oscillograph recorder for an Overcurrent Phase A, B, or C event and keeps track of which individual phase caused the event along with the magnitude of current. The current and voltage magnitude along with the phase angle information can be sent to the distribution management system (DMS) using wireless communications. The DMS can calculate the approximate fault location from the Capacitor bank location so that maintenance personnel can be dispatched to the location of the fault. Alternatively, the capacitor controller can be equipped with fault location algorithms by calculating the impedance from the capacitor bank location to the fault and send the location information directly to the maintenance personnel.

(29) The overcurrent detection requires measurement of current over a large dynamic range and the signal will saturate during fault conditions if special provisions are not made to measure these large fault currents. The design includes two different paths for the current signals. One path measures the normal load current accurately and has a dynamic range required for measuring normal load current. These current measurements are used for metering and also used to measure reactive power when the capacitor bank switching based on reactive power is selected. The other path is designed to measure fault currents which has a large dynamic range suitable for overcurrent detection. The control measures current signals in both paths and uses the signals appropriately. The overcurrent detection feature measures the fault currents, voltages and reports these values along with the calculated fault impedance to the distribution management system. This will allow easy identification of faulty segment of the distribution line.

(30) The settings screen for the phase overcurrent function is shown in FIG. 5.