1. Medium voltage systems can use different neutral grounding methods including solid grounding, impedance grounding, and high resistance grounding.
2. Impedance grounding limits line-to-ground fault current using a neutral grounding resistor or transformer, while high resistance grounding is used to control arc flash hazards in mines.
3. The neutral grounding method affects protection schemes, equipment ratings, and overvoltage stresses on the system. Core balancing CTs and open delta PTs are commonly used for earth fault detection on impedance grounded systems.
2. MV system transmission & distribution practices
MV system when transmitted through bare conductor through O/head lines ,in
such cases the Neutral should be solidly grounded .
The neutral is solidly grounded for safety of life/properties and in such case the L-g
fault is supposed to get cleared within 200ms.
The associated circuit equipments eg cables, termination kits/splicing CT & PTs, LA
and insulators are also specified differently for effectively grounded system.
The L-g fault current is not controlled so protection systems are relatively easier.
The normal 50/51 A,B,C,N can be used with normal residually connected systems
for earth fault protections .
3. MV system impedance grounded
Impedance grounding achieved by limiting the L-g fault .
For High impedance grounding with limited MVA level and arc flash
control requirements and also for limiting the L-g fault current of the
winding for large generators this is achieved by a Neutral grounding
Transformer maximum rating up to 15amps short time 1minute.
During any L-g fault conditions the ground fault current is passed through
NGR ,and is called let off current and this must be >=capacitive charging
current and this will control dangerous( on the other two healthy
phases)o/voltage due to arcing ground and this will not be > 3PU.
For low impedance grounding the NGR rating should be 100Amp
minimum,for practically offering a better equipment protection beyond
90% of the winding the NGR rating -with the minimum basic necessity of
10Amp /MVA for short time ie 10sec rating
Higher NGR rating upto 1000 Amp provides better protection ie 99%
protection of the winding which is found in many refineries and in O/seas
plants.
8. High resistance grounding
In colliery and mines where there are presence of hazardous trapped
gases and the arc flash hazard control is achieved by the HRG - NGT system
where the L-g current is controlled within 10-15 amp.
The mines and collieries are having relatively smaller distribution and the
system capacitive charging current can be limited within 10-15 amp and
the main objective is to limit the Arc flash /fire hazard.
The selection of CT/PTs , LA-surge supressors, Busducts /SWGRs, Cable
termination n Splicing kits voltage selection should be graded for UE
system.
11. Low impedance grounding
The low impedance grounding is applicable for large instalations where the arc
flash is not a very important factor stability of system is paramount.
The system equipments selection of CT/Pts, LA-surge supressors, Busducts/SWGRs,
Cable termination n Splicing kits voltage selection should be made compatible for
UE system.
This system offers greater stability as with one L-g fault the fault current is limited
to the NGR rated current and generates alarm to clear the fault subsequently.
During any L-g fault condition the CBCT senses the current and isolates the faulty
system and thus prevents any further unstability to the system.
12. Low impedance grounding
• Neutral grounding resistors limit the fault current when any one phase of the systems gets
grounded or arcs. In this condition the NGR typically limits the fault current to 200-
400amp(NGR rating).
13. MV neutral resistance grounded system effects on protections and
overvoltage
In this system any L-g fault will create an earth fault current with limited
value which will not be detectable by normal residually connected CT and
even though detectable this does not offer proper equipment protection.
In this system for Earth fault detection on the Bus bar there should be a
Open Delta PT ie Up/√3/110/3 ratio with a stabilizing resistor across the
secondary winding with neutral side grounded(to limit ferro resonance
and provide a stabilizing ground path ) .
For Earth fault detection on O/g service feeders ie motor/transformer
there should be Core balancing/Z Cts of ratio 50/1.
This core balancing CT will protect system against L-G fault and effectively
isolate the faulty system .
The Cable Sheath needed to be returned back through CBCT and then
grounded to nullify the circulating current.
14. MV system core balacing CT
The CBCT acts in case of a single L-g fault and the actuation value is set at 10amp
primary current.
The CBCT current setting must be > than the capacitive charging current of the
largest feeder connected with the system or else there will be spurious
(sympathetic) tripping..
The CBCT current value should be set <10amp and minimum 0.132*CTR ie 6.6Amp
to limit the overvoltage on the other healthy phases.
On a gross calculation for the APPDCL BFP motor of 18.5MW the capacitive
charging current was found approx 8.5Amp.
The max allowable CBCT operating current level should be not greater than
10amp (primary) and this value must be >than the capacitive charging current of
the connected system the O/voltage on the other two healthy phases cannot be
limited to 3PU.
16. MV –neutral grounding effect on LA selection
For non effective grounding system
In GSU-GCB-UAT-ExcitationTrafo-Generator section the grounding is at the NGT at 10amp at
the most .
The O/v factor is 1.4Un for 5secs for GSU/IPBD/UAT t and all associated section n equipment
.
The Un=21KV,taking AVR regulation +/-5% the Um=1.05Un=22KV
The LA should be 27.5 KV grade by taking care of O/voltage related TOV and GT-AVR
regulation of +/-5%.
17. MV neutral grounding-CT /PT selection
The rated voltage factor with a non effective grounded system
should be
1.2Un continuous.
1.9Un for 30secs
19. MV neutral grounding-Reference
IEC-60099
IEC-60044,61869
IEC-60071
IEEE-C.62.92.1,2,3,4,5
EBG paper on CBCT
GE –NGR paper
ABB-LA paper
IEEE-141,143
GE publications-GEI-72116