JP2000245052A - Protective relay - Google Patents

Abstract

PROBLEM TO BE SOLVED: To recognize imperfect input settling and a defective forced control tap and inform them to the outside. SOLUTION: This protective relay is provided with a settling and displaying part 3 having operation input parts 60, 61, 63 which set relay elements turning to objects of settling change, input new corresponding settling into the set relay elements, and write the values in settling storing part 13, a plurality of LED's 65, 26, 27 for lighting and displaying the information concerning a protective relay 1 to the outside, and a completion switch 64 making settling changing operation complete in accordance with the operation of an operator, and an arithmetic processing part 11 which executes a judging process judging whether one out of the operation input parts and the completion switch 64 is operated before an elapsed time after the relay elements are selected and set by the operation of the settling and displaying part 3 exceeds a specified time, and a display mode changing process changing display modes of at least a part of the LED 65 out of the plurality of LED's 65, 26, 27 when the judgment is performed, in accordance with a program stored in a program data storage part 12.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a protective relay for protecting an electric power system and equipment, and more particularly to a function of setting each relay element of the protective relay and displaying information on the protective relay such as settled set values. The present invention relates to a protective relay having:

[0002]

2. Description of the Related Art Conventionally, a setting / display unit of a protection relay includes a setting unit for setting operation values of a plurality of relay elements.
A display unit is provided for externally displaying an operation value (set value) set by the setting unit, an operation state of each relay element, a failure state of the protection relay, and the like.

The protection relay has a forced control function for forcibly controlling the operation and return of each relay element in order to maintain and test the protection sequence processing function.

FIG. 9 is a diagram schematically showing a part of a setting display panel in a setting / display section of a protection relay.

According to FIG. 9, the settling display panel 41 of the settling / display section 40 includes a plurality of relay elements (in FIG. 9, distance relay elements 44S (first stage 44SX1, second stage 44SX2) and overcurrents. A setting switch 60 provided corresponding to each relay element for selecting and setting a relay element to be set from the relay elements 51 #, and a numerical value for inputting a set value for the selected and set relay element, for example. Set value input unit 61 having keys, input switches, etc.
A set value display unit 62 for displaying the current set value or the set value input by the set value input unit 61 for each relay element; and a protection calculation unit for setting the set value input by the set value input unit 61. A write switch 63 for writing to the set value storage unit of the above, a set completion switch 64 for completing the set value setting process for the relay element, and a set switch 60 provided for each relay element. An LED 65 for display during setting is provided for displaying the set relay element during execution of the settling operation (during setting) to the outside.

The settling display panel 41 constructed as described above.
When the set value is changed via the set / display unit 40 having the setting, the operator (operator) selects and sets the relay element to be set value change by the setting switch 60 while watching the set value of each relay element. And the set value input unit 61
To input a new set value. At this time, the input new set value is displayed on the set value display unit 62 corresponding to the set relay element, and the LED 65 for setting display corresponding to the above-mentioned relay element is operated by a protection operation unit (not shown). Lights up.

Then, the operator sets the set value display section 62
When the user confirms that the set value is to be actually changed by looking at the new set value displayed by, the write switch 63 is pressed. By the processing of the protection calculation unit in accordance with the pressing signal of the write switch 63, the set value (current set value) of the change target relay element is changed (rewritten) to the new set value input by the operator. Is written to the set value storage unit.

By repeatedly performing the operation of the setting switch 60 → the input operation of the set value input section 61 → the operation of the write switch 63 in accordance with all the relay elements whose setting values are to be changed, all setting operations are performed. When the value change operation is completed, the operator presses the setting completion switch 64. By the processing of the protection operation unit according to the pressing signal of the setting completion switch 64, the protection relay operation related to the relay element to be changed of the protection relay is performed based on the rewritten new setting value.

FIG. 10 shows a protection sequence S in which a plurality of relay elements (for example, a distance relay element 44S and an overcurrent relay element 51) of a protection relay are combined.
FIG. 3 is a diagram for explaining a forced control function in a protection sequence S (implemented as operation software of a protection operation unit). In FIG. 10, the protection sequence S is shown in hardware for easy understanding.

According to the protection sequence S of the protection relay shown in FIG. 10, when both the distance relay element 44S and the overcurrent relay element 51 operate, a trip command is sent from the AND operation unit 70 to the auxiliary relay unit 71. Then, the contact output of the auxiliary relay unit 71 is sent to the circuit breaker. As a result, an alarm display LED (not shown) is turned on, and the circuit breaker performs a breaking operation (opening operation). When at least one of the distance relay element 44S and the overcurrent relay element 51 becomes inactive in the operation state of the protection relay (the interruption state of the circuit breaker), a return command is sent from the AND operation unit 70 to the auxiliary relay unit 71. Sent. As a result, the circuit breaker that has been opened through the contact output of the auxiliary relay unit 71 is restored (closed), and the alarm display LED is turned off.

When the protection sequence S is maintained and tested, each of the relay elements 44S,
Forced control terminals (tap) 72P1 and 72P2 for forcibly simulating the operation output of 51 are provided for each relay element, and regardless of the actual operation state of each relay element 44S and 51, the forced control tap is provided. By inputting, for example, an operation control signal for normal operation via 72P1 and 72P2, respectively, the operation signal is forcibly sent to the AND operation unit 70 via the OR operation units 73 and 74, and a trip command is output. You. As a result, the circuit breaker performs the breaking operation via the auxiliary relay unit 71, and the alarm display LED is turned on. In addition, when the protection relay is in the operating state, by inputting an operation control signal for recovery via at least one of the forced control taps 72P1 and 72P2, the corresponding O is controlled.
The return signal is forcibly output from the AND operation unit 70 through the R operation unit.
And a return command is output. As a result, the circuit breaker performs a return operation via the auxiliary relay unit 71, and the alarm display LED is turned off.

[0012]

According to the protection relay having the setting / display section described above, even if the set value of the target relay element is changed, the setting complete switch is forgotten to be pressed, and the setting / writing switch such as a setting write switch is set. When the protection operation unit cannot recognize the input new set value and write it to the set value storage unit due to a failure of the display unit (hereinafter, referred to as a setting error).
, The protection operation of the target relay element may be performed based on a set value different from the new set value displayed on the set value display unit (the current set value before change stored in the set value storage unit). .

As is well known, a protective relay (each relay element thereof) is to be used based on an optimum set value in order to properly protect an object to be protected such as a power system, and is not intended (unintended). In addition, when performing a protective relay operation based on the set value, when an event such as a system fault that should perform a normal operation occurs, the protective relay malfunctions and cannot detect the above event, or a normal operation such as an accident occurs. Since there is a possibility that the circuit breaker may be erroneously operated to perform the breaking operation despite the state in which the event to be generated does not occur, it is necessary to make the operator recognize the setting failure from the viewpoint of accurate protection of the protection target. Had occurred.

However, in the conventional protective relay, there is no suitable means for recognizing a setting error to the outside (operator or the like). Thus, only the new set value that has been changed and input can be distinguished from the current set value before change stored in the set value storage unit, and the setting failure cannot be directly notified to the outside.

Further, as described above, the forced control tap is selectively used only during maintenance and testing of the protection relay (protection sequence). In a normal operation state, the forced control tap is selectively used. It will not be done.

However, in a normal operation state,
Trouble such as hardware failure in the forced control tap
If a forcible control signal is output erroneously due to the tap failure, the alarm display L
It was not possible to immediately judge whether the alarm display by the lighting of the ED was based on the normal operation of the relay or the failure of the forcible control tap, and could not be used normally as a protective relay.

Further, a defect (failure) of the output circuit (protection command output circuit of the protection relay including the auxiliary relay unit) in the conventional protection relay is distinguished from a normal operation corresponding to a state change such as a system accident. If the operation of the auxiliary relay unit (contact output) has continued for a certain period of time or more, the output of the protection arithmetic unit is monitored by the constant monitoring function.
, And the monitoring failure display LED is constantly lit to notify the outside.

However, when the operation state of the relay element alone at the preceding stage reaching the auxiliary relay unit in the plurality of relay elements constituting the protection sequence is forcibly controlled through the corresponding forcible control tap, the forcible control tap is defective. Therefore, even if an erroneous operation output is sent to the auxiliary relay unit, the auxiliary relay unit does not operate with the operation output of only the single relay element, so that the failure of the forcible control tap could not be detected.

The present invention has been made in view of the above-mentioned circumstances, and recognizes a setting failure or a failure of a forced control tap and notifies the outside of the failure, thereby eliminating an erroneous condition caused by the setting failure or the failure of the forced control tap. It is an object of the present invention to prevent the operation and testing of the protection relay based on the above and improve the reliability of the protection relay.

[0020]

According to the first aspect of the present invention, a plurality of relay elements related to a protection sequence for a protection target and the plurality of relay elements stored in a set value storage unit. In the protection relay that executes the protection calculation processing based on the set value according to the operation of, the relay element to be set value change target is selected from among the plurality of relay elements and set according to the operation of the operator, and set. An operation input unit for inputting a new set value corresponding to the relay element and writing the set value to the set value storage unit, including a plurality of light emitting elements, and outputting information on the protection relay to the outside via the plurality of light emitting elements. An input display unit having a light emitting device for displaying light and a completion switch for completing a set value changing operation in accordance with an operation of the operator; and an operation of the operation input unit. The elapsed time from the predetermined timing is counted starting from a predetermined timing after selectively setting the relay element, and the operation input unit and the completion switch are output until the counted elapsed time exceeds the predetermined time. Determining means for determining whether any one of the plurality of light-emitting elements has been operated; and determining that one of the operation input unit and the completion switch has not been operated by the determining means, Display mode changing means for changing the display mode of at least some of the elements.

[0021] In the first invention, the plurality of light emitting elements include a first light emitting element provided corresponding to each of the relay elements for lighting and displaying the relay element being settled to the outside. The unit has a setting switch for selecting and setting each relay element provided for each relay element, a setting value input unit capable of inputting the new setting value, and a writing switch for writing the new setting value. A setting unit for setting a relay element corresponding to the setting switch selected by the operator as the set value change target relay element; and a first light emitting element corresponding to the set relay element. Lighting means for turning on the light, and a new set value input by the operator via the set value input unit, in accordance with the operation of the write switch by the operator, the set value storage unit And a writing means for writing.

In the first invention, the lighting means is means for lighting a first light emitting element corresponding to the set relay element in a predetermined display color, and the display mode changing means is a light emitting element. Means for changing the display color of the first light-emitting element illuminated by.

In a preferred aspect of the first invention, when the completion switch is operated in a state where a set value outside the allowable set range is input by the set value input unit, the set relay element corresponds to the set relay element. Means for flickering the first light emitting element at a first cycle, wherein the display mode changing means causes the first light emitting element illuminated by the lighting means to:
This is means for flicker lighting in a second cycle different from the first cycle.

[0024] In the first invention, more preferably, an automatic inspection means for automatically inspecting the operation of the protective relay, and a second inspection means for the plurality of light emitting elements in accordance with an automatic inspection result of the automatic inspection means. Lighting control means for controlling lighting of the light emitting element, wherein the display mode changing means changes the display mode of the second light emitting element illuminated by the lighting control module.

According to the second aspect of the present invention for solving the above-mentioned problem, a plurality of relay elements related to a protection sequence for a protection target and a set value related to the operation of the plurality of relay elements stored in the set value storage unit. In the protection relay that executes the protection arithmetic processing based on the light emitting device for displaying information on the protection relay to the outside, and provided for each relay element, forcibly simulate the operation of each relay element A forced control terminal for transmitting a signal to perform a test of the protection sequence, and a lighting unit for lighting the light emitting device by detecting that the forced simulation signal has been transmitted through the forced control terminal. ing.

In the second invention, the light emitting device has a plurality of light emitting elements corresponding to the respective forced control terminals, and the lighting means corresponds to the forced control terminal to which the forced control signal has been transmitted. The light emitting element to be turned on is lit in a predetermined display color.

In the second invention, preferably, the lighting means determines whether or not the forcible simulation signal has been continuously transmitted for more than a predetermined time, and the forcible simulation signal is determined by the determination means. When it is determined that the signal has been continuously transmitted beyond the predetermined time, the display color of the light emitting element corresponding to the forcible control terminal to which the forcible simulation signal is continuously transmitted is the predetermined display color. Means for lighting in different display colors are provided.

[0028]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing an embodiment of a protection relay according to the present invention. In the present embodiment, a case where the protection target of the protection relay is a power system will be described.

(First Embodiment) FIG. 1 is a block diagram schematically showing a hardware configuration of a protection relay 1 according to a first embodiment of the present invention.

According to FIG. 1, a protection relay 1 is a protection operation unit 2 for performing a protection operation process for protecting a power system based on a state quantity related to the power system input from a power system or the like.
And a plurality of (n)
), And a setting / display unit 3 for inputting the set values of the relay elements and displaying the operation state of the protection relay 1 to the outside, and each component (processing block) and setting of the protection calculation unit 2 to be described later. A bus 4 for connecting each component (processing block) of the display unit 3 described below so that data can be transmitted and received among them;

As shown in FIG. 1, the protection arithmetic unit 2 receives an input of a state quantity (electric quantity) of each equipment constituting the electric power system and performs an A / D conversion process and the like. An RO that stores in advance a sequence program for protection arithmetic processing based on a plurality of relay elements (programs) and a program for new set value setting processing in cooperation with the set / display unit 3
M and a program / data storage unit 11 having a RAM for storing data and the like at the time of the protection operation processing, and a duplicated first data for storing the set value of each relay element in an electrically rewritable manner. And a set value storage unit 12 having a ^second E ² PROM, and a C for executing a protection operation process based on a sequence program and a set value for the protection operation process and executing a new set value setting process program.
Interface for inputting contact information of an arithmetic processing unit 13 having a PU and an external device such as a circuit breaker, and for outputting contact information to an external device (circuit breaker) based on the result of the protection arithmetic processing of the arithmetic processing unit 13 And an external interface 14 for performing processing.

The program / data storage unit 12 stores a time (for example, Tset (minute order)) slightly longer than the time normally required for the set value setting processing performed via the set / display unit 3 as the settling allowable time. ing.

The external interface 14 is provided with forcible control taps 15P1 to 15Pn for each relay element. The arithmetic processing unit 11 receives an operation control signal from the outside via at least one forcible control tap. Then, an operation signal of the relay element corresponding to the operation control tap is sequence-processed as an operation signal corresponding to the input operation control signal, regardless of the actual operation state.

The arithmetic processing unit 11 further includes a program
It has a function (automatic / constant monitoring function) for automatically checking each constituent element of the protection operation unit 2 and the settling / display unit 3 according to a sequence program in the data storage unit 12, for example, in processing block units. .

The settling / display unit 3 is an interface unit for an operator (human machine interface unit).
As specifically shown on the setting display panel 40 (see FIG. 9), the setting switch 60 for setting the relay element selection and the setting value input unit 6 for setting the setting value are set.
1, a set value display section 62 for set value display, a write switch 63 for setting value write, a set value complete switch 64 for finalizing the set value (set setting process completed), and a relay element display in the set state LED during setting (hereinafter, also referred to as LED during setting) 65.

The setting switch 60, the writing switch 63, and the setting completion switch 64 are each embodied by, for example, a push button switch.

The setting / display unit 3 is provided with an alarm display LED 26 which emits an alarm to the outside by lighting up in response to the tripping operation, each processing block of the protection arithmetic unit 2 and the setting / display unit 3, That is, the LED 27 is provided for each of the constantly monitored objects of the arithmetic processing unit 11 and is turned on when the corresponding always monitored object result is “defective” to emit an alarm to the outside. Have.

The arithmetic processing section 11 also has a settling / display processing function of the settling / display section 3, and performs a relay element selection / setting processing in accordance with an operation of a setting switch by the operator.
Set value input processing based on the operation of the operator's set value input unit, write processing according to the operator's write switch operation, display processing of the input set value via the set value display unit 62, and the operator's operation of the set completion switch The setting and completion process for turning on and off the LEDs 65 and 26 to 27 are performed.

Hereinafter, the overall operation of the protection relay 1 will be described focusing on the processing operation of the arithmetic processing unit 11.

When power is applied to the protection relay 1, the arithmetic processing unit 11 of the protection relay 1 performs a predetermined initialization operation according to the initialization program stored in the program / data storage unit 12. Thereafter, according to the sequence program (main sequence program) stored in the program / data storage unit 12, a protection operation processing sequence based on a plurality of relay elements, a constant monitoring processing sequence, and an alarm display based on the protection operation processing result / continuous monitoring processing result. The alarm / display processing sequence via the monitoring LED 26 and the constantly monitoring failure display LED 27 is repeatedly executed.

During the execution of the main sequence program by the arithmetic processing section 11, the set value of each relay element is displayed on the set value display section 62.

At this time, for example, it is assumed that the operator has selected and set the setting switch 60 of the corresponding relay element in order to change the set value of a predetermined relay element and set the new set value.

The arithmetic processing section 11 is stored in the program / data storage section 12 by, for example, interrupt processing, time division processing, or parallel processing with the main sequence in response to an operation signal based on the selection setting of the setting switch 60. The processing shown in FIG. 2 is executed according to the new set value setting processing program.

That is, the arithmetic processing unit 11 controls the turning-on of the LED 65 during the stabilization corresponding to the operated setting switch 60, and sets the LED 65 during the stabilization to a predetermined color (in this embodiment, yellow) ) (Step S1). When the operator confirms that the LED 65 during setting of the relay element whose setting value is to be changed is lit in yellow, the operator operates the setting value input unit 61 to input a new setting value of the relay element to be changed. As a result, the new set value is displayed on the set value display unit 62 corresponding to the relay element to be changed.

When a new set value is input and displayed via the set value input unit 61, the arithmetic processing unit 11 reads the new set value and uses the timing function of the CPU to execute a predetermined operation after the setting switch is operated. With the timing (for example, the new set value reading timing as a starting point (initial value (0 minute 0 second, hereinafter simply referred to as 0)), the counting of the time T for detecting a setting error is started (step S2).

Next, the arithmetic processing unit 11 determines whether or not the current set value corresponding to the relay element to be changed does not match the read new set value (step S3).

As a result of the determination in step S3, if the new set value matches the current set value (step S3 → NO
(N)), the arithmetic processing unit 11 sets the count time T to the initial value 0
And turning off the LED 65 during settling (step S4).
The process returns to the main sequence.

On the other hand, if the result of determination in step S3 is that the new set value and the current set value do not match (step S3 → YES)
(Y)), the arithmetic processing unit 11 determines that the current count time T is the settling allowable time stored in the program / data storage unit 12.
It is determined whether it is less than Tset (step S5).

If the result of the determination in step S5 is that T <Tset (step S5 → YES), the arithmetic processing section 11 determines whether or not a state change has occurred in the settling / display section 3, that is, for example, the operator's It is determined whether or not an operation signal (write signal) by operating the write switch 63 has been transmitted (step S6).

As a result of the determination in step S6, for example,
If the write signal is not transmitted even if the operator operates the write switch 63 of the settling / display unit 3 due to the failure of the write switch 63 of the settling / display unit 3, the determination of step S6 of the arithmetic processing unit 11 is NO. And the arithmetic processing unit 1
1 is the current count time T, step S5-step
Assuming that “T = T + t1” to which the processing time t1 up to S6 has been added (step S7), the process returns to the determination processing of step S5.

When the count time T increases by repeating the processing of steps S5 to S7, as a result, the count time T exceeds Tset without transmitting a write signal from the write switch 63 (T ≧ Tset ) To (Step S5
(→ NO), the arithmetic processing unit 11 determines that some kind of failure such as a hardware failure has occurred in the settling / display unit 3, and performs lighting control of the setting LED 65 that has been lit yellow,
During the settling, the lighting color of the LED 65 is changed from yellow to a predetermined color (red in the present embodiment) indicating an abnormal state (settling failure state) (step S8), and the process returns to step S6.

At this time, since the operator can visually recognize that the setting LED 65 corresponding to the relay element to be changed has changed from yellow to lit red, the operator has forgotten to press the write switch 63 or failed the write switch 63. Recognition and appropriate action can be taken.

On the other hand, if the result of determination in step S6 is that an operator has operated the write switch 63 of the settling / display unit 3 and a write signal has been transmitted, the arithmetic processing unit 11
The determination in step S6 is YES, and the arithmetic processing unit 11
The input new set value is stored in one E ² PRO of the set value storage unit 13.
It is written to the corresponding addresses of M (the first E ² PROM) (step S9).

Subsequently, the arithmetic processing section 11 determines whether or not the set completion switch 64 has been pressed (depressed), that is, whether or not the set value setting processing has been completed (step S1).
S10) If the result of this determination is that the set complete switch 64 has not been pressed, the set value setting process has not been completed, and it is determined that a new set value is to be set for another relay element, and the current count time is set. T is set in the above steps S1 to S10
Assuming that “T = T + t2” in consideration of the processing time t2 up to (T1) (step S11), similarly to step S5, it is determined whether or not T = T + t2 is less than the allowable settling time Tset (step S1).
2).

As a result of the determination in step S12, T <Tset
If (Step S12 → YES), the arithmetic processing unit 11
The process shifts to the process of step S1, and the processes of steps S1 to S12 are repeatedly performed. As a result, new setting values are input to all relay elements set via the setting switch 60.
Write processing is performed.

On the other hand, the count time T increases by repeating the processing of steps S1 to S12. As a result, for example, if the operator forgets to press the setting completion switch 64, or the failure (defective) of the setting completion switch itself, etc. The count time T is set to Tset without pressing the set complete switch 64.
Is exceeded (T ≧ Tset) (step S12 → NO),
The arithmetic processing unit 11 determines that there is a setting input failure such as forgetting to press the setting completion switch 64, and shifts to the process of step S8 to execute the above-described lighting color change control of the setting LED 65 (from yellow to red). Then, the process returns to step S10.

At this time, the operator can visually recognize that the LED 65 during setting corresponding to the relay element to be changed has changed from yellow to lit red, so that a setting input failure such as forgetting to press the setting completion switch 64 or the like. Recognition and appropriate action can be taken.

On the other hand, the processing of steps S1 to S12 is repeatedly performed, for example, and the result of the determination in step S12 is YES and the result of the determination in step S10 is YES, that is, the operation corresponding to the pressing operation of the setting completion switch 64 by the operator When the signal is transmitted to the arithmetic processing unit 11 within the settling time Tset, the arithmetic processing unit 11 determines whether the new set value stored in the first E ² PROM is within the settable range ( Steps
S13) If the result of this determination is that all the new set values are within the settable range (step S13 → YES), the set LED 65 that has been lit is turned off and stored in the first E ² PROM. The new set value is written to the corresponding address (the address where the current set value is written) of the second E ² PROM (step S14), and the process proceeds to the main sequence. As a result, the arithmetic processing unit 11 executes a protection sequence process based on the changed new set value and the relay element.

On the other hand, if the result of determination in step S13 is that at least one new set value exceeds the settable range (step S13 → NO), the arithmetic processing unit 11 sets a new set value outside the range. For example, by transmitting a pulse signal of a predetermined cycle to the corresponding LED 65 during settling of the set relay element, the LED 65 is flickered (flashing) at the predetermined cycle (step S1).
5), the process returns to step S13.

At this time, since the operator can visually recognize that the LED 65 during setting corresponding to a certain relay element flickers, the operator recognizes that the setting of the new setting value of the relay element is erroneous and takes appropriate action. Can be dealt with.

As described above, according to the present embodiment,
When setting a new setting by changing the setting of a given relay element, if a setting failure has occurred due to forgetting to press the setting completion switch or a failure of the setting / display unit 3 such as a setting writing switch. However, LE recognizes the setting error and
By changing the display color of D65, an alarm indicating the setting failure can be issued to the outside (operator). Therefore, the operator recognizes the change in the display color of the LED 65 during setting, and operates the setting completion switch 64. Appropriate measures can be taken, such as a push operation and a restoring operation of the setting / display unit 3.

Therefore, it is possible to avoid the risk that the protection operation of the target relay element is performed based on the current set value different from the new set value, and it is possible to improve the reliability of the protection relay.

According to the present embodiment, the display color indicating the normal settling state is yellow, and the display color indicating the poor settling state is red. However, the present invention is not limited to this. If the display color indicating the settling state is different from the display color indicating the setting error state, the lighting control can be performed for any of the display colors.

Further, in the present embodiment, the lighting display color of the LED 65 during settling is changed in order to notify the setting error state to the outside. However, the present invention is not limited to this. Lighting control may be performed to a display mode different from the display mode.

FIG. 3 is a flowchart showing a new set value setting process of the arithmetic processing section 11 according to a first modification of the first embodiment.

According to FIG. 3, instead of step S8 in FIG. 2, the arithmetic processing section 11 controls the lighting of the LED 65 during settling, and turns on the color (not limited to a predetermined color or yellow) of the LED 65 during settling. Are flickered at a predetermined cycle (see step S8A). At this time,
For example, the flicker cycle of the LED 65 during the setting is different from the cycle of turning on the alarm flicker when the new set value exceeds the setting range. Is set to be longer (see FIG. 3; step S8A and step S15A).

As a result, the operator recognizes that he or she has forgotten to press the setting completion switch 64 or a malfunction of the setting / display unit 3 and flickers the LED 65 during setting, thereby issuing an alarm indicating the setting error to the operator. Therefore, similarly to the first embodiment, the risk that the protection operation of the target relay element is performed based on the current set value different from the new set value can be avoided, and the reliability of the protection relay can be improved. .

FIG. 4 is a flowchart showing a new set value setting process of the arithmetic processing unit 11 according to the second modification of the first embodiment.

According to FIG. 4, instead of step S8 in FIG. 2, the arithmetic processing section 11 turns on the constantly monitoring failure display LED (referred to as a constantly monitoring failure LED) 27 instead of the setting LED 65. (Step
S8B).

As a result, the operator recognizes that the operator has forgotten to press the setting completion switch 64 or a failure of the setting / display unit 3 and constantly turns on the monitoring failure LED 27 to issue an alarm indicating the setting failure to the operator. Therefore, similar to the first embodiment and the first modification, the danger that the protection operation of the target relay element is performed based on the current set value different from the new set value is avoided, and the reliability of the protection relay is reduced. Can be improved.

(Second Embodiment) FIG. 5 shows a second embodiment of the present invention.
It is a figure showing the hardware constitutions of protection relay 1a concerning an embodiment.

As shown in FIG. 5, the setting / display unit 3 of the protection relay 1a is provided corresponding to each of the forced control taps 15P1 to 15Pn.
It has tap control display LEDs 30a1 to 30an for displaying the operation control state via 15Pn.

The ROM of the program data storage section 12a of the protection relay 1a stores the tap control display LEDs 30a1 to 30an in addition to the sequence program for the protection calculation processing and the program for the new set value setting processing.
Is stored.

Hereinafter, the overall operation of the protection relay 1a will be described focusing on the processing operation of the arithmetic processing section 11a of the present embodiment.

According to the present embodiment, similarly to the first embodiment, the arithmetic processing section 11a of the protection relay 1a performs the protection arithmetic processing sequence according to the sequence program stored in the program / data storage section 12, The monitoring processing sequence and the alarm / display processing sequence are repeatedly executed. At the start of the above-described sequence processing, all the tap control display LEDs 30a1 to 30a3 are displayed.
0an is off.

Then, the arithmetic processing unit 1 in the present embodiment
1a executes the processing shown in FIG. 6 according to the lighting control program stored in the program / data storage unit 12 by, for example, time division processing.

That is, the arithmetic processing unit 11 determines whether or not a forcible control signal has been transmitted from the forcible control taps 15P1 to 15Pn (FIG. 6, step S20).
If the operation control signal is not transmitted as a result of the determination in step S20, the process temporarily returns to the main sequence and repeats the determination process in step S20 periodically.

On the other hand, in the operation state (protection sequence state) of the protection relay 1a described above, the forced control tap 15
A tap failure such as a hardware failure occurs in at least one of the taps P1 to 15Pn (for example, 15Pk (1 ≦ k ≦ n)), and an erroneous operation control signal is output from the tap 15Pk via the external interface 14. It is assumed that the data is sent to the arithmetic processing unit 11a.

At this time, the arithmetic processing section 11a performs a reception process on the sent operation control signal (the result of the determination in step S20 is YES), and performs lighting control of the tap control display LED 30ak corresponding to the operation control signal. Then, the tap control display LED 30ak is turned on in a predetermined color (step S21), and the process once returns to the main sequence, and the determination process in step S20 is periodically repeated.

As a result, the operator sets the defective tap 15
By visually recognizing that the tap control display LED 30ak corresponding to Pk has been turned on, it is possible to recognize that a failure has occurred in the tap 15Pk and take appropriate action.

That is, according to the present embodiment, in the normal operating state of the protective relay 1a, even if a tap failure occurs in the forcibly controlled tap and the forcible control signal is output erroneously due to the tap failure, the failure is not detected. By turning on the tap control display LED corresponding to the generated tap, an alarm indicating the tap failure can be issued to the outside (operator). Therefore, the operator immediately recognizes the failure of the forced control tap. Therefore, the reliability of the protection relay 1a can be improved.

As a modification of this embodiment, the failure of the above-mentioned forced control tap can be clearly identified even during maintenance / testing of the protection sequence irrespective of the operation of the forced control tap in the maintenance / test. The protection relay will be described.

The program / data storage unit 12b in the protection relay 1b according to the present modification includes not only the above-mentioned sequence program for the protection calculation process, the program for the new set value setting process, and the program for the lighting control, but also the actual maintenance /
A time (for example, Tset1 (minute order)) slightly longer than the forced control tap operation time (forced control signal transmission time) at the time of inspection is stored as the forced control allowable time.
Note that the other configuration of this modified example is substantially the same as the configuration of the second embodiment.

That is, the protection relay 1 according to this modification is
According to b, for example, the simulation target compulsory control tap 15P related to the protection sequence of the maintenance / test target is received from the operator.
By transmitting an operation control signal via i, 15Pj (1 ≦ i, j ≦ n) to forcibly simulate the operation of the relay element to be simulated, correct operation through the protection sequence of the maintenance / test object (For example, a trip operation) is checked.

In the maintenance / test state, a tap failure such as a hardware failure occurs in the forcible control tap 15Pk corresponding to the relay element other than the simulation target relay element, and an erroneous operation control signal is output from the tap 15Pk. It is assumed that the data is sent to the arithmetic processing unit 11b via the interface 14.

At this time, similarly to the second embodiment, the arithmetic processing section 11b executes the lighting control processing by the protection sequence execution processing and the time division processing, and executes the maintenance / inspection taps 15Pi, 15Pj and the failure. The operation control signals transmitted from the taps 15k are respectively received (FIG. 7; the result of the determination in step S30 is YES), and the transmission duration of each of the compulsory control signals, that is, using the timekeeping function of the CPU, ie,
The counting of the operation control time T1 of each of the forced control taps 15Pi, 15Pj, 15k is started with the reception timing of the forced control signal as a starting point (initial value (0 minutes 0 seconds, hereinafter simply referred to as 0)) (step S31). ).

Then, the arithmetic processing section 11 determines whether or not the count time T1 of each of the taps 15Pik is less than the forcible control allowable time Tset1 stored in the program / data storage section 12b (step S32). .

At this time, the count time T1 of each of the taps 15Pi and 15Pj is always less than Tset1 because the forcible control allowable time Tset1 is set to be slightly longer than the forcible control signal transmission time during actual maintenance and inspection. Becomes That is, the result of the determination in step S32 is YES
Thus, the operation control signals from the taps 15Pi and 15Pj are determined to be signals based on actual maintenance and testing.

Next, the arithmetic processing section 11b outputs the tap control display LEDs 30ai, 3 corresponding to the operation control signal.
0aj is turned on and its tap control display LE
D30ai and 30aj are each turned on in a predetermined color (step S33).

On the other hand, tap 1 where a tap failure has occurred
Since the operation control signal from 5Pk is continuously transmitted irrespective of the operation of the operator, the count time T1
Increases beyond Tset1. Therefore, the arithmetic processing unit 1
The result of the determination in step S32 of 1b is NO, and it is determined that the operation control signal from the tap 15Pk is a signal based on a tap failure.

Subsequently, the arithmetic processing section 11b flickers the tap control display LED 30ak corresponding to the operation control signal at a predetermined cycle (step S34).

The above-described determination processing in step S32 and the processing in steps S33 and S34 are executed simultaneously and in parallel for each operation control signal.
When the LED lighting / flicker lighting process is completed, the arithmetic processing unit 11b once returns to the main sequence and periodically repeats the determination process of step S30.

As a result, the operator presses the tap 15P.
Tap control display LED 30a corresponding to i, 15Pj
By visually recognizing that i, 30aj is turned on, it can be confirmed that the forced control operation is being performed via the taps 15Pi, 15Pj.

In this embodiment, the tap 15Pk
By visually recognizing that the tap control display LED 30ak corresponding to the flicker is turned on, the tap 15P
It is possible to recognize that a defect has occurred in k and take appropriate action.

As described above, according to the present embodiment,
During maintenance and testing of a predetermined protection sequence in the protection relay 1b, a tap failure occurs in the forcibly controlled tap,
Even if a forced control signal is output erroneously due to the tap failure, the tap control display LED corresponding to the tap where the failure has occurred is replaced with the tap control display LED corresponding to the tap used in the above maintenance / test. Is turned on in different display modes (for example, LED corresponding to maintenance / test tap → continuous lighting, LED corresponding to defective tap → flicker lighting), so that an alarm indicating the tap failure can be issued to the operator. Therefore, the operator can immediately recognize the failure of the forcible control tap even during the maintenance / test of the protection sequence, and the reliability of the protection relay 1b can be further improved.

As described above, in the present embodiment, the corresponding tap control display LED is flickered in order to notify the tap failure state to the outside, but the present invention is not limited to this, and the present invention is not limited to this.・ LE corresponding to defective tap in display mode different from LED corresponding to test tap
D may be turned on.

FIG. 8 is a diagram showing another example related to the lighting control of the LED corresponding to the defective tap in the first modified example of the second embodiment.

In FIG. 8, in step S33a, the arithmetic processing section 11b sets the tap control display LED 30
ai and 30aj are respectively lit in a predetermined color (for example, yellow), and in step S34a, the tap control display LED 30ak is lit in a display color (for example, red) different from the predetermined color (yellow) (step S3).
4a).

Even with such a configuration, the operator visually recognizes the LED which is lit in a display color (red) different from the normal yellow, so that even if the protection sequence is maintained or tested, the failure of the forced control tap can be prevented. Can be immediately recognized, and the reliability of the protection relay can be further improved.

In the above-described second embodiment and its modifications, tap control display LEDs corresponding to the respective forced control taps are provided. However, the present invention is not limited to this. An existing LED for displaying information on the operation state of the protection relay 1b provided in the setting / display unit 3 may be turned on to display an alarm indicating a failure of the forced control tap to the operator.

For example, when the failure of a certain forced control tap is detected by the process of step S32, the LED for setting display can be turned on in a display mode different from the display mode in the normal setting state. .

Further, in each of the above-described embodiments, information relating to the operation state of the protection relay (selection relay element information in the above-mentioned settling operation, information relating to tripping, information relating to the failure of constant monitoring, etc.) is used as an optical signal. Although all devices to be displayed outside are LEDs, the present invention is not limited to this, and other light-emitting devices (light-emitting elements) other than LEDs can be applied.

[0103]

As described above, according to the protection relay according to the present invention, even if a set value input failure or a forced control terminal failure occurs, the failure state is detected and, for example, the display color of the display device is changed. The alarm can be notified to the outside (operator) by flickering or flickering, etc., and the operator recognizes a setting value input fault or a forced control terminal fault in response to the alarm,
We can take appropriate measures.

Therefore, it is possible to avoid operating the protection relay based on erroneous conditions caused by the above-mentioned set value input failure and the failure of the forcible control terminal failure, and to perform the protection sequence test, thereby improving the reliability of the protection relay. Can be improved.

[Brief description of the drawings]

FIG. 1 is a block diagram schematically showing a hardware configuration of a protection relay according to a first embodiment of the present invention.

FIG. 2 is a schematic flowchart showing an example of processing according to a new set value setting processing program of an arithmetic processing unit shown in FIG. 1;

FIG. 3 is a flowchart schematically showing a new set value setting process of an arithmetic processing unit according to a first modification of the first embodiment of the present invention.

FIG. 4 is a flowchart schematically showing a new set value setting process of an arithmetic processing unit according to a second modification of the first embodiment of the present invention.

FIG. 5 is a block diagram schematically showing a hardware configuration of a protection relay according to a second embodiment of the present invention.

FIG. 6 is a schematic flowchart showing an example of processing according to a lighting control program of an arithmetic processing unit shown in FIG. 5;

FIG. 7 is a flowchart schematically showing a lighting control process of an arithmetic processing unit according to a first modification of the second embodiment of the present invention.

FIG. 8 is a flowchart illustrating another example of the lighting control of the LED corresponding to the defective tap according to the first modification of the second embodiment;

FIG. 9 is a diagram schematically showing a part of a setting display panel in a setting / display unit of the protection relay.

FIG. 10 is a diagram for explaining a protection sequence of a protection relay and a forced control function in the protection sequence.

[Explanation of symbols]

 1, 1a, 1b protection relay 2 protection operation unit 3 setting / display unit 4 bus 10 input processing unit 11 operation processing unit 12 program / data storage unit 13 setting value storage unit 14 external interface 15P1 to 15Pn forcible control tap 26 alarm display LED 27 LED for constantly monitoring failure display 30a1 to 30an LED for tap control display 60 Setting switch 61 Setting value input section 62 Setting value display section 63 Write switch 64 Setting completion switch 65 Setting LED during setting

Claims (9)

[Claims] 1. A protection relay for executing a protection calculation process based on a plurality of relay elements related to a protection sequence for a protection target and a set value related to an operation of the plurality of relay elements stored in a set value storage unit. The user selects and sets a relay element whose set value is to be changed from the plurality of relay elements in response to a user operation, inputs a new set value corresponding to the set relay element, and writes the new set value in the set value storage unit. And a light emitting device for displaying information on the protection relay to the outside via the plurality of light emitting elements and a setting value changing operation in accordance with the operation of the operator Input display means having a completion switch for completing
The elapsed time from the predetermined timing is counted starting from a predetermined timing after the relay element is selectively set by the operation of the operation input unit, and the operation input unit and the counted time exceed the predetermined time. Determining means for determining whether or not one of the completion switches has been operated; and when the determining means determines that one of the operation input unit and the completion switch has not been operated. And a display mode changing means for changing a display mode of at least a part of the plurality of light emitting elements. 2. The method according to claim 1, wherein the plurality of light-emitting elements include a first light-emitting element provided in correspondence with each of the relay elements to light up and display the relay element being set outside. A setting switch provided for each relay element for setting the selection of each relay element, a set value input unit capable of inputting the new set value, and a write switch for writing the new set value; Display means for setting a relay element corresponding to a setting switch selected by the operator as the set value change target relay element; and lighting for lighting a first light emitting element corresponding to the set relay element. Means for writing a new set value input by the operator via the set value input unit into the set value storage unit in response to operation of the write switch by the operator; Protection relay according to claim 1, characterized by comprising and. 3. The lighting means is means for lighting a first light emitting element corresponding to the set relay element in a predetermined display color, and the display mode changing means is lighted by the lighting means. 3. The protection relay according to claim 2, wherein the protection relay changes a display color of the first light emitting element. 4. When the completion switch is operated in a state where a set value out of a set allowable range is input by the set value input unit, a first light emitting element corresponding to the set relay element is set to a first light emitting element. Means for flicker lighting at the cycle of
The protection relay according to claim 2, wherein the display mode changing means is means for flicker-lighting the first light-emitting element lit by the lighting means at a second cycle different from the first cycle. 5. An automatic inspection means for automatically inspecting the operation of the protection relay, and a lighting control for controlling the lighting of the second light emitting element in the plurality of light emitting elements according to an automatic inspection result of the automatic inspection means. 3. The protection relay according to claim 2, further comprising: means for changing a display mode of the second light emitting element lit by the lighting control means. 6. A protection relay for executing a protection calculation process based on a plurality of relay elements related to a protection sequence for a protection target and a set value related to an operation of the plurality of relay elements stored in a set value storage unit. A light emitting device for displaying information about the protective relay to the outside, and a light emitting device provided for each of the relay elements, for transmitting a signal for forcibly simulating the operation of each of the relay elements, and performing a test of the protection sequence. A forced control terminal,
A protection relay comprising: lighting means for detecting that the forcible simulation signal is transmitted via the forcible control terminal and for lighting the light emitting device. 7. The light-emitting device has a plurality of light-emitting elements corresponding to the respective forced control terminals, and the lighting means includes a light-emitting element corresponding to the forced control terminal to which the forcible control signal is transmitted. 7. The protection relay according to claim 6, wherein the protection relay is lit in a predetermined display color. 8. The lighting means includes: determining means for determining whether or not the forced simulation signal has been continuously transmitted for more than a predetermined time; and the determining means determines whether the forced simulation signal has been transmitted for more than the predetermined time. 8. The protection relay according to claim 7, further comprising means for flickering a light emitting element corresponding to the forcible control terminal to which the forcible simulation signal is continuously transmitted when it is determined that the forcible simulation signal is continuously transmitted. 9. A lighting device comprising: a judging device for judging whether or not the forcible simulation signal has been continuously transmitted for more than a predetermined time; When it is determined that transmission has been continuously performed, means for lighting the display color of the light emitting element corresponding to the compulsory control terminal to which the compulsory simulation signal is continuously transmitted with a display color different from the predetermined display color is provided. The protective relay according to claim 7, further comprising: