KR101592059B1 - Apparatus and method for controlling synchronism-check relay - Google Patents

Abstract

The present invention relates to an apparatus and method for controlling a synchronous detection relay, in which an operator sets whether a synchronous condition, whether to use a CB (Circuit Breaker) state input condition, whether to use a DI input state condition, A synchronous ON signal is generated when the input condition of the condition, the CB state, and the DI input condition are satisfied, thereby making it possible to prevent the interruption due to the power failure and to achieve the interruption due to an accident other than the power failure.

Description

[0001] Apparatus and method for controlling synchronism detection [0002]

The present invention relates to an apparatus and method for controlling a synchronous detection relay.

Generally, a synchronous detection relay is used to link the system and the system, the generator and the system, or the two separate power systems when the generator and the generator are operated in parallel without harming the stability.

Unlike conventional overcurrent relays, under voltage relays and thermal relays, the synchronous detection relays do not directly control the CB (Circuit Breaker), but if the set synchronous conditions are satisfied, for example, , And generates a synchronization ON signal at a specific DO (Digital Output) when the voltage difference, the phase difference, and the frequency difference between the two systems are within a predetermined allowable value.

However, the above-mentioned synchronization detection relay only generates the synchronization ON signal when the synchronization condition to be set is satisfied, and its operation function is limited.

Therefore, the problem to be solved by the present invention is that the operator does not detect whether or not the synchronous detection relay satisfies the synchronous condition, and the operator can set whether or not to use the CB input state and the DI input state The present invention also provides an apparatus and method for controlling a synchronous detection relay, which enables a sequence to prevent an interruption caused by a power failure and to achieve an interruption caused by an accident other than an outage.

The present invention is not limited to the above-mentioned technical problems and other technical objects which are not mentioned can be clearly understood by those skilled in the art from the following description will be.

A control apparatus for a synchronous detection relay according to the present invention includes: a command input section for inputting an operation command in accordance with an operation of an operator; a first voltage transformer and a second transformer outputting voltages of the first system and the second system, A signal input unit for inputting a detection signal of a first low voltage relay and a second low voltage relay that detect whether each of the first system and the second system is a low voltage and a status signal of a CB (Circuit Breaker) A controller for determining whether or not an operation command is satisfied according to an operator's operation with a signal input through the signal input unit and controlling generation of a synchronization ON signal when an operation command is satisfied in accordance with an operation of an operator; And a signal output unit for generating the synchronization ON signal according to control.

Wherein the controller sets the synchronous condition only when the operation command inputted by the operator is operated and when the use of the CB state input condition and the use of the DI input state condition are both not set, And controlling the generation of the synchronization-on signal.

The controller is further configured so that when an operation command inputted in accordance with an operation of the operator is set to use a synchronous condition and a CB state input condition and the use of a DI input state condition is not set, Whether the condition is satisfied or not, and generates the synchronization ON signal.

The controller is further configured to set the synchronous condition and the DI input state when the operation command inputted according to the operator's operation is set to use the synchronous condition and the DI input state condition and the use of the CB state input condition is not set, Whether the condition is satisfied or not, and generates the synchronization ON signal.

The controller may also be configured such that, when an operation command input according to the operation of the operator is set to use a synchronous condition, a CB state input condition, and a DI input state condition, the synchronous condition, the CB state input condition, DI input state condition is satisfied, and generates the synchronization ON signal.

A control method of a synchronous detection relay according to the present invention includes the steps of setting a synchronous condition, a use state of DI (Digital Input) state input condition and a use state of CB (Circuit Breaker) input state condition through an instruction input unit, Determining whether the synchronous condition is satisfied by the controller when the CB input state condition is not used without using the DI state input condition; and if the controller satisfies the synchronous condition, And controlling the generation of the light beam.

Determining whether the controller satisfies the synchronization condition and the DI state input condition when the DI state input condition is used and the CB input state condition is not used; And controlling the generation of the synchronization ON signal by the controller when the DI state input condition is satisfied.

Determining whether the controller satisfies the synchronization condition and the CB input state condition when the CB input state condition is set to be used without using the DI state input condition; And controlling the generation of the synchronization ON signal by the controller when the CB input state condition is satisfied.

Determining whether the controller satisfies all of the synchronization condition, the DI status input condition, and the CB input status condition when the DI status input condition and the CB input condition condition are all set to be used; And controlling the generation of the synchronization ON signal by the controller when the synchronization condition, the DI status input condition, and the CB input condition condition are all satisfied.

The synchronization condition is characterized by an allowable voltage difference, an allowable phase difference, and an allowable frequency deviation between two systems.

According to the apparatus and method for controlling the synchronization detection relay of the present invention, the operator sets whether or not to use synchronous conditions, CB (Circuit Breaker) state input conditions, and DI (Digital Input) input state conditions in advance.

The synchronization detection relay generates a synchronization ON signal when the synchronization condition, the use condition of the CB state input condition, and the DI input state condition satisfy the condition.

Therefore, it is possible to use a synchronous detection relay to prevent the interruption due to the power failure, and to enable the interruption due to an accident other than the power failure.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, in which like reference numerals refer to like elements throughout.
BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic view of a general power supply system,
FIG. 2 is a drawing showing an example of an input screen of setting conditions set by the user in the synchronous detection relay of FIG. 1;
3 is a diagram showing a configuration of a preferred embodiment of a power supply system according to a control apparatus of the present invention,
4 is a diagram showing a configuration of a preferred embodiment of a synchronous detection relay in a power supply system according to the present invention,
5 is a diagram illustrating an example of an input screen of setting conditions set by the user in the synchronization detection relay in the power supply system according to the present invention,
6A to 6C are signal flow diagrams showing the operation of a preferred embodiment of the synchronization detection relay of the present invention.

The following detailed description is merely an example, and is merely an example of the present invention. Further, the principles and concepts of the present invention are provided for the purpose of being most useful and readily explaining.

Accordingly, it is not intended to provide a more detailed structure than is necessary for a basic understanding of the present invention, but it should be understood by those skilled in the art that the present invention can be embodied in various forms.

1 is a schematic view showing a configuration of a general power supply system. Here, reference numerals 100 and 102 are a first system and a second system for supplying commercial power.

The first system 100 and the second system 102 may be a system in which two generators (not shown in the figure) generate electricity to supply electric power. Further, one of the first system 100 and the second system 102 supplies electric power that the generator (not shown in the figure) generates, and the other system supplies electric power to the power supply company Lt; / RTI > In addition, the first system 100 and the second system 102 may be systems that supply power to two different power supply companies.

Numerals 110 and 112 are the first load and the second load. The first load 110 and the second load 112 may operate using power supplied through the first system 100 and the second system 102, respectively.

120 is a first voltage transformer, and 122 is a second voltage transformer. Each of the first voltage transformer 120 and the second voltage transformer 122 reduces the voltage level of power supplied through the first system 100 and the second system 102.

Reference numeral 130 denotes a synchronization detection relay. The synchronization detection relay 130 stores synchronization conditions previously set by the user. Further, the synchronization detection relay 130 generates a synchronization ON signal when the stored synchronization condition is satisfied.

Reference numeral 140 denotes a circuit breaker (CB). The CB 140 operates according to a synchronization ON signal generated by the synchronization detection relay 130.

Here, the CB 140 may operate directly by a synchronization ON signal generated by the synchronization detection relay 130. [ In addition, the CB 140 can indirectly operate by a switching signal generated by a switching generating means (not shown in the figure) by a synchronization ON signal generated by the synchronization detecting relay 130. [

In the power supply system having such a configuration, a user first inputs a synchronization condition to the synchronization detection relay 130 and stores the same. Here, the synchronization condition may be, for example, at least one of permissible voltage difference, permissible phase difference and permissible frequency error between powers supplied through the first system 100 and the second system 102, as shown in FIG. 2 And may include any one or more of them.

When the synchronous condition is stored, the power generated by the generator or the power provided by the power supply company is supplied to the first load 110 and the second load 112 through the first system 100 and the second system 102, So that the first load 110 and the second load 112 are operated.

Here, the first load 110 and the second load 112 are various electric devices using electric power including a motor, a washing machine, a refrigerator, and the like.

In this state, the first voltage transformer 120 and the second voltage transformer 122 respectively lower the voltage level of the power supplied through the first system 100 and the second system 102, The voltage is output to the synchronization detection relay 130.

The synchronization detection relay 130 first determines whether the CB 140 is in an open state. When the CB 140 is in an open state, the synchronization detection relay 130 satisfies preset synchronization conditions using the voltage input from the first voltage transformer 120 and the second voltage transformer 122 Or not.

For example, the synchronization detection relay 130 may be configured such that the voltage difference between the power supplied through the first system 100 and the second system 102 is within 50 V, the tolerable phase difference is within 45 degrees, Is less than or equal to 0.5 Hz.

If the synchronization condition is satisfied, the synchronization detection relay 130 generates a synchronization ON signal. If the synchronization condition is not satisfied, the synchronization detection relay 130 generates a synchronization OFF signal.

When the synchronization detection relay 130 generates the synchronization ON signal, the CB 140 is directly connected in accordance with the generated synchronization ON signal, or indirectly connected by the switching signal generated by the switching generating means by the synchronization ON signal .

When the CB 140 is connected, the electric power supplied through the first system 100 can be supplied to the second load 112 through the CB 140 and operated, and the second system 100 102 may be supplied to the first load 110 through the CB 140 and operated.

The synchronous detection relay 130 of the power supply system generates a synchronization ON signal and outputs a synchronization ON signal to the first load 110 when power is not supplied through the first system 100. [ Power can be supplied to operate the first system 100, and when the power is not supplied through the second system 102, the power of the first system 100 can be supplied to the second load 112 and operated .

The above-described synchronization detection relay 130 determines whether or not a synchronization condition preset by the user is satisfied, and generates a synchronization ON signal when the synchronization condition is satisfied.

However, the above-mentioned synchronous detection relay judges whether or not a synchronous condition to be set is satisfied, and generates a synchronous ON signal only when the synchronous condition is satisfied.

3 is a diagram showing a configuration of a preferred embodiment of a power supply system according to the control apparatus of the present invention. Here, reference numerals 300 and 302 denote a first system and a second system for supplying commercial power.

The first system 300 and the second system 302 may be a system in which two generators (not shown in the figure) generate electricity to supply electric power. Further, one of the first system 300 and the second system 302 supplies electric power to be generated by a generator (not shown in the figure), and the other system supplies electric power to a power supply company Lt; / RTI > In addition, the first system 300 and the second system 302 may be systems that supply power to two different power supply companies.

Reference numeral 310 and reference numeral 312 are a first load and a second load. The first load 310 and the second load 312 may operate using power supplied through the first system 300 and the second system 302, respectively.

Reference numeral 320 denotes a first voltage transformer, and reference numeral 322 denotes a second voltage transformer. Each of the first voltage transformer 320 and the second voltage transformer 322 reduces the voltage level of the power supplied through the first system 300 and the second system 302.

Reference numeral 330 denotes a first low-voltage relay, and reference numeral 332 denotes a second low-voltage relay. The first low voltage relay 320 and the second low voltage relay 334 are connected to the first system 300 using the output voltages of the first voltage transformer 320 and the second voltage transformer 322, And the second system (302), respectively, and generates a determination signal.

Reference numeral 340 denotes a first circuit breaker. The first circuit breaker 340 may be provided between the first system 300 and the first load 310 and may be connected to the first system 300 when the first undervoltage relay 320 detects a low voltage. ) And the first load (310).

Reference numeral 342 denotes a second circuit breaker. The second circuit breaker 350 is provided between the second system 302 and the second load 312 and the second circuit 302 is provided between the second system 302 and the second load 312 when the second under- ) And the second load (312).

Reference numeral 350 denotes a synchronization detection relay. The synchronization detection relay 350 sets a synchronization condition in advance, and generates a synchronization-on signal when the synchronization condition is satisfied. In addition, when the use of the CB (Circuit Breaker) state input condition is set, the synchronization detection relay 350 generates a synchronization ON signal that satisfies both the synchronous condition and the CB state input condition. Further, the synchronization detection relay 350 generates a synchronization ON signal that satisfies both the synchronization condition and the DI input condition when the use of the DI input condition is set. In addition, when the use of the CB state input condition and the use of the DI input state condition are set, the synchronization detection relay 350 generates a synchronization ON signal that satisfies both the input condition of the synchronous condition, the CB state, and the DI input state condition .

Reference numeral 360 denotes a circuit breaker (CB). The CB 360 connects or disconnects the first system 300 and the second system 302 to each other when the synchronization detection relay 350 generates a synchronization ON signal.

Here, it is shown that the CB 360 operates directly by the synchronization ON signal generated in the synchronization detection relay 350. [

However, the CB 360 can be operated indirectly by a switching signal generated by a separate switching generating means (not shown in the figure) by the synchronization ON signal generated by the synchronization detecting relay 350.

4 is a diagram showing a configuration of a preferred embodiment of a synchronous detection relay in a power supply system according to the present invention. Here, reference numeral 400 denotes an instruction input unit. The command input unit 400 inputs an operation command corresponding to the operation of the synchronization detection relay 350 according to an operation of an operator. In addition, the command input unit 400 inputs a synchronization condition according to an operation of an operator. The command input unit 400 inputs a CB 360 status input condition and a CB 360 status input condition The state condition of the CB 360 is input. In addition, the command input unit 400 may include an input terminal of a DI to which an external signal is input and an input terminal of a DI to which an external signal is input, Enter the conditions of use.

Reference numeral 410 denotes a memory. The memory 410 stores an operation program and various operation commands input through the instruction input unit 400. [

Reference numeral 420 denotes a display section. The display unit 420 displays the operation state of the synchronization detection relay 350.

Reference numeral 430 denotes a signal input unit. The signal input unit 430 receives signals of the first voltage transformer 320 and the second voltage transformer 322 from the outside and a signal of each of the first low voltage relay 320 and the second low voltage relay 334 Signal.

Reference numeral 440 denotes a controller. The controller 440 receives various commands of the operator through the command input unit 400 and controls the memory 410 to store the commands. In addition, the controller 440 determines whether or not various commands inputted by the signal input unit 430 are satisfied by the various commands of the operator stored in the memory 410, and outputs a synchronization ON signal when satisfied . Further, the controller 440 controls the display unit 420 to display the current operation state of the synchronization detection relay 350.

Reference numeral 450 denotes a signal output section. The signal output unit 450 outputs a synchronization ON signal under the control of the controller 440.

In the present invention having such a configuration, the operator first operates the command input unit 400 provided in the synchronization detection relay 350 to input a predetermined operation command required for the operation of the synchronization detection relay 350.

For example, as shown in FIG. 5, the synchronization condition including the allowable voltage difference, the allowable phase difference, and the allowable frequency deviation, the use state of the state input condition of the CB 360, the use state of the DI input state condition . Also, when the use condition of CB (360) status input condition is set, the condition of CB (360) status condition is closed or open condition is inputted, and when DI input condition condition is set, DI And whether or not the use condition of the sink is returned or operated.

When the predetermined operation command required for the operation of the synchronization detection relay 350 is inputted in this manner, the controller 440 stores the predetermined operation command in the memory 410.

The controller 440 inputs various signals for determining the operation command through the signal input unit 430. For example, the controller 440 receives the signals of the first voltage transformer 320 and the second voltage transformer 322 and the signals of the first and second low voltage relays 320 and 322 through the signal input unit 430, 2 low-voltage relays 334, a state signal of the CB 360, and the like.

In this state, the controller 440 determines predetermined operation commands set by the user. As a result of the determination, if neither the use of the CB 360 state input condition nor the use of the DI input state condition is set, the controller 440 determines whether or not the synchronization condition is satisfied. For example, the controller 440 determines whether the permissible voltage difference, permissible phase difference, and permissible frequency deviation are satisfied.

If it is determined that both the use of the CB 360 state input condition and the use of the DI input state condition are not set, the controller 440 outputs a synchronization on signal .

If the use of the CB 360 state input condition is set and the use of the DI input state condition is not set as a result of the determination, the controller 440 sets the synchronous condition and the CB 360 state input condition And generates a synchronization ON signal when the synchronization condition and the CB 360 state input condition are satisfied.

If it is determined that the use of the CB 360 state input condition is not set and the use of the DI input state condition is set as a result of the determination, the controller 440 determines whether the synchronous condition and the DI input state condition are satisfied And generates a synchronization ON signal when the synchronization condition and the DI input condition are satisfied.

If it is determined that both the use of the CB 360 state input condition and the use of the DI input state condition are all set, the controller 440 sets the synchronous condition, the CB 360 state input condition, And generates a synchronization ON signal when both the synchronous condition, the CB 360 state input condition, and the DI input state condition are satisfied.

6A to 6D are signal flow diagrams illustrating the operation of a preferred embodiment of the sync detection relay of the present invention. 6A, the controller 440 of the synchronization detection relay 350 inputs an operation setting condition through the command input unit 400 (S600), and stores the input operation setting condition in the memory 410. FIG.

In step S602, the controller 440 determines whether the inputted operation setting condition uses the DI state input condition. In step S604, the controller 440 determines whether the state input condition of the CB 360 is used.

If the DI state input condition and the CB input state of the CB 360 are not all used, the controller 440 determines whether the set synchronization condition is satisfied (S606). That is, the controller 440 determines whether the allowable voltage difference, the allowable phase difference, and the allowable frequency deviation are satisfied.

If it is determined that the allowable voltage difference, the allowable phase difference, and the allowable frequency deviation, which are synchronous conditions, are all satisfied, the controller 440 outputs a sync on signal through the signal output unit 450 (S608).

If it is determined that the allowable voltage difference, the allowable phase difference, and the allowable frequency deviation are not satisfied as a result of the determination, the controller 440 outputs a synchronization off signal through the signal output unit 450 (S610) .

When the DI state input condition is not set in the step S602 and the use of the CB 360 state input condition is set in the step S604, the controller 440 sets the state of the CB 360 as shown in FIG. 6B The controller 440 determines whether the state input condition of the CB 360 is open or closed (S612).

If it is determined that the state input condition of the CB 360 is open, the controller 440 determines whether the current CB 360 is open (S614).

If the CB 360 is in the open state, the controller 440 determines whether the synchronization condition is satisfied (S616). If the synchronization condition is satisfied, the controller 440 generates a synchronization on signal (S620).

If it is determined in step S614 that the CB 360 is in the closed state or does not satisfy the synchronization condition set in step S616, the controller 440 generates a synchronization off signal in step S620.

If it is determined in step S612 that the state input condition of the CB 360 is a closed state, the controller 440 determines whether the current CB 360 is in a closed state (S622).

When the CB 360 is in the closed state, the controller 440 determines whether the synchronization condition is satisfied (S624). If the synchronization condition is satisfied, the controller 440 generates a synchronization ON signal (S626).

If it is determined in step S622 that the CB 360 is not in the closed state or does not satisfy the synchronization condition set in step S624, the controller 440 generates a synchronization off signal (step S628) ).

If it is determined in step S602 that the DI input condition is set, the controller 440 determines whether the DI input condition is set to return or operate as shown in FIG. 6C S630).

If it is determined in step S630 that the DI input state is set to return, the controller 440 determines whether the DI input state is the return state (S632).

If the DI input state is not the return state, the controller 440 returns to the step 612 shown in FIG. 6B, determines the input condition of the CB 360, A synchronization ON signal or a synchronization OFF signal is generated depending on whether the CB 360 is in the closed or open state according to the input condition and whether or not the synchronization condition is satisfied.

If it is determined in operation S630 that the DI input state is set to the operation state, the controller 440 determines whether the DI input state is the return state (S634).

If the DI input state is not the operating state, the controller 440 returns to the step 612 shown in FIG. 6B to determine the input condition of the CB 360, Generates a synchronization-on signal or a synchronization-off signal according to whether the CB 360 is in the closed or open state according to the input condition and whether or not the synchronization condition is satisfied.

If it is determined in step S630 that the DI input state is set to return and the DI input state is not reset or the DI input state is set to the operation state, The controller 440 generates a synchronization off signal and terminates.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, I will understand.

Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be determined by equivalents to the appended claims, as well as the appended claims.

100, 300: first system 102, 302: second system
110, 310: first load 112, 312: second system
120, 320: first voltage transformer 122, 322: second voltage transformer
130, 350: synchronization detection relay 140, 360: CB (Circuit Breaker)
330: First Low Voltage Relay 332: Second Low Voltage Relay
340: first breaker 342: second breaker

Claims (11)

A command input unit for inputting an operation command according to an operation of an operator;
An output voltage of each of the first voltage transformer and the second transformer for respectively reducing the voltage of the first system and the second system from the outside and a first low voltage relay for detecting whether the first system and the second system are low voltage, And a signal input unit for inputting a detection signal of a second low voltage relay and a state signal of a CB (Circuit Breaker);
A controller for determining whether an operation command is satisfied according to an operator's operation with the signal inputted through the signal input unit and controlling generation of a synchronization ON signal when the operation command is satisfied according to an operation of an operator; And
And a signal output unit for generating the synchronization ON signal under the control of the controller,
The controller comprising:
A synchronous detection relay for determining whether or not at least one of a synchronous condition, a CB state input condition, and a DI input condition satisfies at least one of an operation command input according to an operation of the operator and a generation of the synchronous ON signal, Lt; / RTI >
2. The apparatus of claim 1, wherein the controller comprises:
When the operation instruction inputted by the operator's operation sets only the synchronous condition and does not set both the use of the CB state input condition and the use of the DI input state condition,
And controls generation of the synchronization-on signal by determining whether or not the synchronization condition is satisfied.
2. The apparatus of claim 1, wherein the controller comprises:
When the use of the synchronous condition and the CB state input condition is set and the use of the DI input state condition is not set,
And generates the synchronous ON signal by determining whether the synchronous condition and the CB state input condition are satisfied.
2. The apparatus of claim 1, wherein the controller comprises:
When the operation instruction inputted by the operator's operation is set to use the synchronous condition and the DI input state condition and the use of the CB state input condition is not set,
And generates the synchronization ON signal by determining whether the synchronization condition and the DI input condition are satisfied.
2. The apparatus of claim 1, wherein the controller comprises:
When the operation instruction inputted by the operator's operation is set to use the synchronous condition, the use of the CB state input condition and the use of the DI input condition,
And generates the synchronous ON signal by determining whether the synchronous condition, the CB state input condition, and the DI input state condition are both satisfied.
Setting whether or not to use a synchronous condition, a DI input condition condition, and a CB break condition input condition through a command input unit;
Determining, by the controller, whether the motion command input according to an operator's operation satisfies at least one of the synchronization condition, the CB state input condition, and the DI input state condition; And
And controlling the controller to generate a synchronization-on signal based on the determination result,
When the DI input state condition is not used and the CB state input condition is set not to be used, the controller determines whether or not the operation command satisfies the synchronization condition, And a control method of the synchronous detection relay.
7. The method of claim 6, further comprising: when using the DI input state condition and not using the CB state input condition;
Wherein the controller determines whether the operation command satisfies the synchronization condition and the DI input condition,
And the controller generates the synchronization ON signal when the synchronization condition and the DI input condition are satisfied.
7. The method of claim 6, further comprising: when the CB state input condition is set to be used without using the DI input state condition;
Wherein the controller determines whether the operation command satisfies the synchronization condition and the CB state input condition,
And the controller generates the synchronization ON signal when the synchronization condition and the CB state input condition are satisfied.
7. The method of claim 6, further comprising: if the DI input state condition and the CB state input condition are all set to be used;
Wherein the controller determines whether the operation command satisfies both the synchronization condition, the DI input condition condition, and the CB condition input condition,
Wherein the controller generates the synchronization ON signal when both the synchronization condition, the DI input condition condition and the CB condition input condition are satisfied.
10. The method according to any one of claims 6 to 9, wherein the synchronization condition comprises:
A tolerable voltage difference between the two systems, an allowable phase difference and an allowable frequency deviation between the two systems. 6. The method according to any one of claims 1 to 5, wherein the synchronization condition comprises:
And a permissible voltage difference, an allowable phase difference, and an allowable frequency deviation between the two systems.

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