ABB HCB-1 Instruction Leaflet page 8

41-971.3M
4.5. PILOT-WIRE REQUIREMENTS
The relays should not be applied with pilot-wire
series resistance or shunt capacitance exceeding the
following values:
Table 4
Insulating Transformer Rate
4/1
No. of
Relays R
L
2 2000
3 500/LEG
R = series loop resistance in ohms.
L
C = total shunt capacitance in microfarads.
S
(Total wire to wire capacitance)
Where the shunt capacitance exceeds the above
amount, it may be feasible in some cases to provide
shunt reactors to compensate for the excessive
capacitance. The amount of capacitance which can
be compensated is limited and varies depending
upon the magnitude of the pilot-wire distributed
effect.
A shielded, twisted pilot-wire pair, preferably of #19
AWG or larger, is recommended; however, open
wires may be used if they are frequently transposed
in areas of exposure to power circuit induction. The
voltage impressed across either insulating trans-
former (H1-H4 Terminals) as a result of induction or a
8
N
S
N S
Moving Contact
BALANCED AIR GAPS
Figure 5: Polar Unit Permanent Magnet Flux Paths
6/1
C R
S L
1.5 4500 0.33
1.8 1000/LEG 0.75
Type HCB-1 Pilot Wire Relay System
Permanent
N
Magnet
Armature
N
UNBALANCED AIR GAPS
rise in station ground potential, should be less than
7.5 volts to prevent undesired relay operation.
C
S
Figure 6: Typical Curves Showing the Effect of the Pilot-
wire on Minimum Trip Current, Two-Terminal Line
(Maximum Resistant Tap). Insulating Transformer 4/1 ratio
For three-terminal applications, the loop resistance of
all legs of the pilot-wire must be balanced within 5
percent, with variable resistors. The pilot-wire resis-
tance to be balanced is divided by 16 and 36 for the 4
to 1 and 6 to 1 ratio insulating transformers respec-
tively, since the balancing resistors are located on
the relay side of the insulating transformers.
Induced voltages and rises in station-ground poten-
tial may be handled by the following means:
Shunt
S
Additional
Flux Path
S
N
Sub 5
183A062
Sub 1
619594