GE N60 Instruction Manual page 380

FLEXLOGIC
Traditionally, protective relay logic has been relatively limited. Any unusual applications involving interlocks, blocking, or
supervisory functions had to be hard-wired using contact inputs and outputs. FlexLogic minimizes the requirement for
auxiliary components and wiring while making more complex schemes possible.
The logic that determines the interaction of inputs, elements, schemes, and outputs is field-programmable through the use
of logic equations that are sequentially processed. The use of virtual inputs and outputs in addition to hardware is
available internally and on the communication ports for other relays to use (distributed FlexLogic).
FlexLogic allows users to customize the relay through a series of equations that consist of operators and operands. The
operands are the states of inputs, elements, schemes, and outputs. The operators are logic gates, timers, and latches (with
set and reset inputs). A system of sequential operations allows any combination of operands to be assigned as inputs to
specified operators to create an output. The final output of an equation is a numbered register called a virtual output.
Virtual outputs can be used as an input operand in any equation, including the equation that generates the output, as a
seal-in or other type of feedback.
A FlexLogic equation consists of parameters that are either operands or operators. Operands have a logic state of 1 or 0.
Operators provide a defined function, such as an AND gate or a Timer. Each equation defines the combinations of
parameters to be used to set a Virtual Output flag. Evaluation of an equation results in either a 1 (=ON, or flag set) or 0
(=OFF, or flag not set). Each equation is evaluated at least four times every power system cycle.
Some types of operands are present in the relay in multiple instances, for example contact and remote inputs. These types
of operands are grouped together (for presentation purposes only) on the front panel display. The table lists characteristics
of the different types of operands.
Table 5-24: N60 FlexLogic operand types
Operand type
Contact Input
5
Contact Output
(type Form-A contact
only)
Direct Input
Element
(Analog)
Element
(Digital)
Element
(Digital Counter)
Fixed
5-186
State Example of format
On Cont Ip On
Off Cont Ip Off
Contact Closed Cont Op 1 Closed
Current On Cont Op 1 Ion
Voltage On Cont Op 1 VOn
Voltage Off Cont Op 1 VOff
On DIRECT INPUT 1 On
Pickup PHASE TOC1 PKP
Dropout PHASE TOC1 DPO
Operate PHASE TOC1 OP
Block PHASE TOC1 BLK
Pickup Dig Element 1 PKP
Dropout Dig Element 1 DPO
Operate Dig Element 1 OP
Higher than Counter 1 HI
Equal to Counter 1 EQL
Lower than Counter 1 LO
On On
Off Off
N60 NETWORK STABILITY AND SYNCHROPHASOR MEASUREMENT SYSTEM – INSTRUCTION MANUAL
Characteristics
[Input Is '1' (= ON) if...]
Voltage is applied presently to the input (external contact
closed)
Voltage is not applied presently to the input (external
contact open)
Contact output is closed
Current is flowing through the contact
Voltage exists across the contact
Voltage does not exist across the contact
The direct input is presently in the ON state
The tested parameter is presently above the pickup setting
of an element that responds to rising values or below the
pickup setting of an element that responds to falling values
This operand is the logical inverse of the above PKP
operand
The tested parameter has been above/below the pickup
setting of the element for the programmed delay time, or
has been at logic 1 and is now at logic 0 but the reset timer
has not finished timing
The output of the comparator is set to the block function
The input operand is at logic 1
This operand is the logical inverse of the above PKP
operand
The input operand has been at logic 1 for the programmed
pickup delay time, or has been at logic 1 for this period and
is now at logic 0 but the reset timer has not finished timing
The number of pulses counted is above the set number
The number of pulses counted is equal to the set number
The number of pulses counted is below the set number
Logic 1
Logic 0
CHAPTER 5: SETTINGS