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5 SETTINGS
DIRECT INPUT 9 DEVICE ID
DIRECT INPUT 9 BIT NUMBER
DIRECT INPUT 9 DEFAULT STATE
Now the three blocking signals are available in UR IED 1 as
. Upon losing communications or a device, the scheme is inclined to block (if any default state is set to "On"), or to trip
ON
the bus on any overcurrent condition (all default states set to "Off").
EXAMPLE 2: PILOT-AIDED SCHEMES
Consider a three-terminal line protection application shown in the figure below.
Assume the Hybrid Permissive Overreaching Transfer Trip (Hybrid POTT) scheme is applied using the architecture shown
below. The scheme output operand
Figure 5–154: SINGLE-CHANNEL OPEN-LOOP CONFIGURATION
In the above architecture, Devices 1 and 3 do not communicate directly. Therefore, Device 2 must act as a 'bridge'. The fol-
lowing settings should be applied:
UR IED 1:
DIRECT OUT 2 OPERAND:
DIRECT INPUT 5 DEVICE ID:
DIRECT INPUT 5 BIT NUMBER:
DIRECT INPUT 6 DEVICE ID:
DIRECT INPUT 6 BIT NUMBER:
UR IED 3:
DIRECT OUT 2 OPERAND:
DIRECT INPUT 5 DEVICE ID:
DIRECT INPUT 5 BIT NUMBER:
DIRECT INPUT 6 DEVICE ID:
DIRECT INPUT 6 BIT NUMBER:
UR IED 2:
DIRECT INPUT 5 DEVICE ID:
DIRECT INPUT 5 BIT NUMBER:
DIRECT INPUT 6 DEVICE ID:
DIRECT INPUT 6 BIT NUMBER:
GE Multilin
: "4"
: "3"
: select "On" for security, select "Off" for dependability
UR IED 1
Figure 5–153: THREE-TERMINAL LINE APPLICATION
is used to key the permission.
HYB POTT TX1
TX1
UR IED 1
RX1
UR IED 3
"
"
HYB POTT TX1
"2"
"2" (this is a message from IED 2)
"2"
"4" (effectively, this is a message from IED 3)
"
"
HYB POTT TX1
"2"
"2" (this is a message from IED 2)
"2"
"3" (effectively, this is a message from IED 1)
"1"
"2"
"3"
"2"
T60 Transformer Protection System
,
DIRECT INPUT 7 ON
DIRECT INPUT 8 ON
UR IED 2
UR IED 3
842713A1.CDR
RX1
RX2
UR IED 2
TX1
TX2
RX1
TX1
842714A1.CDR
5.8 INPUTS AND OUTPUTS
, and
DIRECT INPUT 9
5-277
5
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