is actual of earth loop impendance for maximum value.
for comprisoner the current through the cicruit
by calculating the loop current
You can't have a three phase earth fault, you can have a phase to phase or a phase to earth fault. If you want the potential phase to earth fault current it will be your voltage times your impedance. If you want the phase to phase potential fault current then you should just double the above result.
The earth-fault loop includes the consumer's line conductor, the consumer's protective conductor, and the earth parth external to the consumer's installation (including the low-voltage winding of the transformer, the distribution line conductors to the installation, and the earth return path.The purpose of this test is to measure the actual value of the earth-fault loop impedance and to confirm that its value complies with the tabulated maximum values listed in BS 7671:2008 Regulations for Electrical Installations, Tables 41.2 - 41.5. The value must be low enough to enable sufficient fault current to flow to cause any overcurrent protection device to operate within the periods specified -i.e. 0.4 s for circuits supplying socket outlets and fixed equipment in bathrooms, and 5.0 s for circuits supplying fixed equipment.The theory behind the test is as follows. With no current flowing around the loop, there are no voltage drops and, so, the transformer's full open-circuit voltage (U1) will appear between the line and protective conductors at the point where the test is conducted.A simulated earth fault is then applied, by inserting a current-limiting resistor between the line and protective conductors. The resulting fault current (IF) is then measured, together with the voltage drop (U2) across the limiting resistor. The duration of this fault should not be allowed to exceed two cycles (40 ms at 50 Hz) to avoid damaging the circuit.The earth-fault loop impedance is then calculated by dividing the difference between the two voltages (U2 - U1) by the resulting fault current (IF), which will give the impedance of the complete loop (including the limiting resistor), from which we must then subtract the value of the limiting resistor.As the simulated earth fault must not exceed 2 cycles, this (theoretical) test obviously cannot be conducted with a voltmeter and an ammeter, and so it is conducted with a commercial instrument, called an earth-fault loop tester, which performs all the measurements (U1, U2, IF), makes all necessary calculations, and provides an digital readout directly in ohms -while, at the same time limiting the duration of the test to less than 40 ms.Before conducting the test, the continuity of the protective conductors must have been confirmed. If the test was to be performed with a break in the protective conductor, then the protective conductor up to the point of that break would represent a safety hazard to anyone in contact with equipment at the time.
OK, well Earth Loop Tester have a permanent magnet in it. When we rotate it, the flux cut the the conductor and consequently an emf is produced. As we connect the two point of the tester to the earth it complete the circuit and current start flowing through it. The ratio of voltage and current give us the Impedance of Earth.
The input impedance of a current shunt feedback amplifier is the open loop impedance of the amplifier divided by 1+(A*beta)
by calculating the loop current
You can't have a three phase earth fault, you can have a phase to phase or a phase to earth fault. If you want the potential phase to earth fault current it will be your voltage times your impedance. If you want the phase to phase potential fault current then you should just double the above result.
I am assuming that its a 240 Volt AC circuit supplying an inductive load with a fault loop impedance of 1.9 ohms at the time of the short circuit. The power factor is assumed to be 0.8 The instantaneous earth fault current value would be; Current = (Voltage x Power Factor) / Impedance (240 x 0.8) / 1.9 192 / 1.9 = 101 Amps. However this may be a trick question as it doesn't ask for an instantaneous value, the fuse will limit the fault current to 15 amps and should disconnect the circuit within 0.4 seconds.
As per my openion standby earth fault relay work on zero impedance measurement, when earth fault occures than zero
The earth-fault loop includes the consumer's line conductor, the consumer's protective conductor, and the earth parth external to the consumer's installation (including the low-voltage winding of the transformer, the distribution line conductors to the installation, and the earth return path.The purpose of this test is to measure the actual value of the earth-fault loop impedance and to confirm that its value complies with the tabulated maximum values listed in BS 7671:2008 Regulations for Electrical Installations, Tables 41.2 - 41.5. The value must be low enough to enable sufficient fault current to flow to cause any overcurrent protection device to operate within the periods specified -i.e. 0.4 s for circuits supplying socket outlets and fixed equipment in bathrooms, and 5.0 s for circuits supplying fixed equipment.The theory behind the test is as follows. With no current flowing around the loop, there are no voltage drops and, so, the transformer's full open-circuit voltage (U1) will appear between the line and protective conductors at the point where the test is conducted.A simulated earth fault is then applied, by inserting a current-limiting resistor between the line and protective conductors. The resulting fault current (IF) is then measured, together with the voltage drop (U2) across the limiting resistor. The duration of this fault should not be allowed to exceed two cycles (40 ms at 50 Hz) to avoid damaging the circuit.The earth-fault loop impedance is then calculated by dividing the difference between the two voltages (U2 - U1) by the resulting fault current (IF), which will give the impedance of the complete loop (including the limiting resistor), from which we must then subtract the value of the limiting resistor.As the simulated earth fault must not exceed 2 cycles, this (theoretical) test obviously cannot be conducted with a voltmeter and an ammeter, and so it is conducted with a commercial instrument, called an earth-fault loop tester, which performs all the measurements (U1, U2, IF), makes all necessary calculations, and provides an digital readout directly in ohms -while, at the same time limiting the duration of the test to less than 40 ms.Before conducting the test, the continuity of the protective conductors must have been confirmed. If the test was to be performed with a break in the protective conductor, then the protective conductor up to the point of that break would represent a safety hazard to anyone in contact with equipment at the time.
Check the MEN link is in place Check if the PEC terminations are tight at the switchboard and socket outlets Use a PEC with larger cross section area
OK, well Earth Loop Tester have a permanent magnet in it. When we rotate it, the flux cut the the conductor and consequently an emf is produced. As we connect the two point of the tester to the earth it complete the circuit and current start flowing through it. The ratio of voltage and current give us the Impedance of Earth.
A fault can be resistive in nature, and the amount of resistance in the fault is unpredictable. It is unusual for a fault to be inductive or capacitive, so a typical method is to determine the impedance to the fault, and compare only the inductive part of this to the inductive part of the line impedance.
The input impedance of a current shunt feedback amplifier is the open loop impedance of the amplifier divided by 1+(A*beta)
A varley loop test is a test used to find the earth fault location in an underground cable. It uses the Wheatstone bridge to help determine the distance from the test point to a fault in a telephone or telegraph line or cable.
This wire provides a low impedance return path to the distribution panel in case of a circuit fault. This direct fault current path will trip the circuit's breaker and open the circuit.
They both reduce earth fault levels by inserting impedance in the return path. A reactor is used when the earth fault level wanted is greater than about 25% of the phase fault current. This limit is due to over voltages experienced in arcing faults, the higher the reactor impedance the higher the potential overvoltage. With resistors lower fault levels are possible, but as the resistor has to dissipate all energy it will generally be more expensive and larger than a reactor.