P rospective S hort C ircuit (PSC) and P rospective F ault C urrent (PFC) are both designed to calculate the maximum current that will flow within a fault loop path during the event of an electrical fault as required by regulations.
The Prospective Short Circuit Current is the maximum current that could flow between Line and Neutral conductors on a single phase supply or between Line conductors on a three phase supply. A PSC test calculates the current that will flow in the event of a short circuit fault between the live conductors. That is, Line and Neutral on a single phase installation or Line to Line/ Line to Neutral on a three phase installation. A PFC test calculates the maximum current that will flow in the event of an earth fault; i.e., Line to Earth.
The test result can be determined by calculation, ascertained by enquiry to the relevant electricity board, or measured using a Loop Tester. If you are using a Loop Tester, you would measure both PSC and PFC values and record the highest value. Due to the nature of different supply types, you would expect to find a PSC value higher than a PFC value on both TT and TN-S systems, however on a TNC-S system both the PFC and PSC value should be identical.
It is important that we conduct the tests to make sure that the protective devices installed within a circuit are rated at the correct breaking capacity. Within a domestic installation, it is common to find 6000A (6kA) rated MCB’s installed within a circuit. If a domestic premises is situated particularly close to a supply sub-station and the measured external impedance (Ze) of the property was 0.03 Ohms, Ohm’s law calculates that 7,666A may flow in the event of a fault on a 230V supply. This may cause concern if the switch gear is only rated at 6000A.
Protective devices such as circuit breakers and fuses must be selected with an interrupting rating that exceeds the prospective short-circuit current, if they are to safely protect the circuit from a fault. When a large electric current is interrupted an arc forms, and if the breaking capacity of a fuse or circuit breaker is exceeded, it will not extinguish the arc. Current will continue, resulting in damage to equipment, fire or explosion.
PFC is conducted at the origin of the installation, such as at the main switch or at other switchgear connected directly to the tail from the electricity distributor’s metering equipment. Where a measurement is made at a point in the installation other than the origin, such as an item of switchgear fed by a distribution circuit, it would not be the maximum value for the installation.
Particular care should be exercised during the testing process, as fault conditions are most severe at the origin of an installation, where this test is performed. The earthing conductor, main protective bonding conductors and circuit protective conductors should all be connected as for normal operation during these tests, because the presence of these and any other parallel paths to earth may reduce the impedance of the earth fault loop and so increase the level of prospective fault current.
PSC will be higher than the PFC. Prospective fault current and short circuit current of a circuit is automatically calculated when making a loop impedance test. The calculation uses a nominal circuit voltage, not the actual circuit voltage.
The nominal supply voltage used in the calculation is automatically selected depending on the actual circuit voltage. The instrument uses the following voltage values:
| Actual measured voltage | Nominal voltage |
| < 75 V | 55 V |
| ≥= 75 V and <150 V | 110 V |
| ≥= 150 V and <300 V | 230 V |
| ≥=300 V | 400 V |
Prospective Fault Current tester or the PFC function of a multifunctional tester such as the Megger 1553 is selected, and we make sure that the supply is ON, but the Main Switch is in OFF position.
Step 2: The test leads are connected on the incoming side of the Main Switch, one test lead on Line and another on the Neutral terminals of the Main Switch.
Step 3: TEST switch is pressed and a note of the value (kA) is made.
For three phase installations each phase is tested separately and the measured reading (test between Line 1 and Neutral, then Line 2 and Neutral and last Line 3 and Neutral) is doubled.
Some test meters require that the third (usually green) lead to be connected on the Neutr.
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We discuss your facility requirements, compliance goals, and project timeline.
Our engineers gather system data, single-line diagrams, and equipment specifications on-site.
We perform the study using industry-standard software and IEEE/IEC methodologies.
You receive actionable documentation with findings, risk ratings, and remediation recommendations.
We help implement recommendations including labeling, PPE selection, and system modifications.
Final review ensures full alignment with DEWA regulations and international standards.
FAQ
What & Why of PFC and PSC Test | Carelabz.com is a critical component of electrical safety and compliance. Our team follows IEEE 1584, NFPA 70E, and DEWA standards to deliver thorough, actionable results for your facility.
Regular what & why of pfc and psc test | carelabz.com helps identify potential hazards, ensures regulatory compliance with DEWA requirements, and protects personnel and equipment from electrical incidents.
Industry best practice recommends conducting what & why of pfc and psc test | carelabz.com every three to five years, or after any major system modification. DEWA may require more frequent assessments for certain facility types.
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