Fault Loop Impedance Measurement in Circuits Fed by UPS and Principle of Safety Protection
Abstract
:1. Introduction
2. Short-Circuit in a Line Fed by Online UPS
2.1. Short-Circuit in a Line Fed by Online UPS Working in Double Conversion Mode (AC-DC-AC)
- Zlim—impedance limit value of the short-circuit loop, above which the inverter output voltage is stabilized to nominal value with an accuracy of 1% (typical for most UPSs);
- UnUPS—UPS nominal output voltage (typically UL-N = 230 V, for most countries);
- Iinvmax—max. inverter output current at which the voltage is still stabilized with an accuracy of 1% (typically Iinvmax = 150% InUPS, InUPS—UPS nominal output current).
- Zs—total impedance measured from the source to the fault point;
- ZQ—system impedance;
- ZTr—transformer impedance;
- Zk1—substitute impedance of the cable line including the resistance of connections between the transformer and UPS;
- ZEB—EB path impedance;
- Zk2—substitute impedance of the cable line including the resistance of connections between UPS output and the fault point.
2.2. Short-Circuit in a Line Fed by Online UPS Working in Battery Mode (DC-AC)
- UUPS—UPS output voltage between phase and neutral;
- Iinvlim—inverter limited current (typically from 150 to 300% of InUPS);
- Zs—fault loop impedance; comparing to Formula (2) Zs = Zk2, because EB thyristor is switched off (ZEB→∞).
3. UPS FLI Measurement in Lines Fed by UPS
3.1. FLI Measurement during UPS Double Conversion Operation (AC-DC-AC)
- Zk2—FLI calculated from UPS output terminals to the measured point;
- UnUPS—nominal UPS output voltage (from inverter, typically 230 V);
- Iinv—inverter current, which does not exceed the UPS inverter overload capacity (typically Iinv < 150% · InUPS).
- Zs—determined FLI at any point of UPS-powered circuit;
- ZMB closed MEASURED—measured FLI value when MB is closed;
- Zthyristor CALCULATED—thyristor impedance value read from the characteristic Zthyristor = Ut/It for the largest current value, visible on the characteristic.
3.2. FLI Measurement during UPS Battery Operation (on Battery DC-AC)
4. FLI Measurement and Assessment of the Effectiveness of Electrical Safety by Automatic Disconnection of Supply Algorithm in Lines Fed by UPS
5. Conclusions
- During UPS commissioning when there is no load;
- With the asymmetric load (for example L1—60%, L2—50%, L3—0%);
- When the UPS is heavily oversized because of the load character;
Author Contributions
Funding
Conflicts of Interest
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FLI Meter No. (ITEST [A]) | Z1 [mΩ] AC-DC-AC | Z2 [mΩ] EB Active | Z3 [mΩ] MB Closed | Z4 = Z2 − Z3 [mΩ] | Z5 [mΩ] According to Formula (5) |
---|---|---|---|---|---|
1 (3 A) | 160 | 590 | 180 | 410 | 190 |
2 (6 A) | 170 | 380 | 180 | 200 | 190 |
3 (6 A) | 40 | 300 | 170 | 130 | 180 |
4 (6 A) | 30 | 300 | 170 | 130 | 180 |
5 (20 A) | 390 | 200 | 150 | 50 | 160 |
6 (140 A) | 478 | 164 | 150 | 14 | 160 |
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Katarzyński, J.; Olesz, M. Fault Loop Impedance Measurement in Circuits Fed by UPS and Principle of Safety Protection. Sustainability 2020, 12, 10126. https://doi.org/10.3390/su122310126
Katarzyński J, Olesz M. Fault Loop Impedance Measurement in Circuits Fed by UPS and Principle of Safety Protection. Sustainability. 2020; 12(23):10126. https://doi.org/10.3390/su122310126
Chicago/Turabian StyleKatarzyński, Jacek, and Marek Olesz. 2020. "Fault Loop Impedance Measurement in Circuits Fed by UPS and Principle of Safety Protection" Sustainability 12, no. 23: 10126. https://doi.org/10.3390/su122310126
APA StyleKatarzyński, J., & Olesz, M. (2020). Fault Loop Impedance Measurement in Circuits Fed by UPS and Principle of Safety Protection. Sustainability, 12(23), 10126. https://doi.org/10.3390/su122310126