KR102503475B1 - An inactive power compensator - Google Patents

Abstract

The reactive power compensator includes a valve monitoring unit that generates a valve monitoring signal based on the valve status of each of a plurality of valves, a power monitoring unit that generates a power monitoring signal based on the power status flowing into the reactive power compensator, and and a firing signal control unit for generating a firing signal for driving a valve based on a valve control signal, a valve monitoring signal, and a power monitoring signal input from a control unit.

Description

Reactive power compensator {An inactive power compensator}

The embodiment relates to a reactive power compensator.

As the industry develops and the population increases, electricity demand soars, but electricity production is limited.

Accordingly, a power system for supplying power generated in a production area to a demand area stably without loss is becoming increasingly important.

The need for FACTS (Flexible AC Transmission System) facilities to improve power flow, system voltage, and stability is emerging. FACTS facilities include reactive power compensators such as SVC (Static Var Compensator) or STATCOM (STATic synchronous COMpensator). This reactive power compensator is connected in parallel to the power system to compensate for the reactive power required by the power system.

SVC includes VBE (Vale Based Electronics) equipment that controls the entire valve system and a firing signal controller that generates or controls firing pulses under the control of VBE. A plurality of valves are connected to VBE, and each valve is equipped with a firing signal controller.

The conventional SVC checks and controls the state of the valve based on the starting point of the firing signal, and is designed for the purpose of self-determination. As a result, various side effects may occur because the delay time of the signal itself received from each valve cannot be considered according to various conditions that may occur during operation.

In addition, when an error occurred in an unstable environment, a lot of time and manpower had to be invested in coping with and handling it. In particular, there was a limit to quickly taking the control cycle in a situation where all of the firing signals had to be checked with individual signal lines. In addition, considering various conditions in order to establish the conditions for generating the firing signal, a lot of delay time occurred, and the timing of the actual firing signal was different, so it was difficult to control the valve. In the end, there was no choice but to attach a separate sync circuit to the valve itself to ensure simultaneous operation.

The most fatal problem in the SVC is that there is no condition to protect it in the initial operation when power is applied, and damage may be applied to the valve.

Embodiments are aimed at solving the foregoing and other problems.

Another object of the embodiment is to provide a novel reactive power compensator.

Another object of the embodiment is to provide a reactive power compensator in which the structure of the valve is simplified because the valve is not provided with a firing signal generator.

Another object of the embodiment is to provide a reactive power compensator capable of quickly protecting a valve.

Another object of the embodiment is to provide a reactive power compensator capable of preemptively blocking an error that may damage a valve.

According to one aspect of the embodiment to achieve the above or other object, the reactive power compensator includes a valve monitoring unit for generating a valve monitoring signal based on a valve state of each of a plurality of valves; A power monitoring unit for generating a power monitoring signal based on the power state flowing into the reactive power compensator; and a firing signal control unit generating a firing signal for driving the valve based on a valve control signal, the valve monitoring signal, and the power monitoring signal input from the upper control unit.

The effect of the reactive power compensator according to the embodiment is described as follows.

According to at least one of the embodiments, since the control unit directly generates a firing signal to drive the valve, there is an advantage in simplifying the structure of the valve because the valve is not equipped with a firing signal generator.

According to at least one of the embodiments, by preventing any signal from being output as a firing signal for a certain period of time after the firing signal is output, an unintended firing signal is output due to a system error or the like for a certain time after the firing signal is output. There is an advantage that the malfunctioning of the valve can be blocked.

According to at least one of the embodiments, when the state of the power flowing into the reactive power compensator is abnormal, there is an advantage in preventing damage to the valve by temporarily blocking the output of the firing signal.

A further scope of applicability of the embodiments will become apparent from the detailed description that follows. However, since various changes and modifications within the spirit and scope of the embodiments can be clearly understood by those skilled in the art, it should be understood that the detailed description and specific embodiments, such as preferred embodiments, are given by way of example only.

1 is a block diagram showing a reactive power compensator according to an embodiment.
2 is a block diagram illustrating a control unit according to an embodiment.
3 is a circuit diagram illustrating a firing signal control unit according to an embodiment.
4 shows signal waveforms when the power state is normal.
5 shows signal waveforms when the power state is abnormal.

Hereinafter, the embodiments disclosed in this specification will be described in detail with reference to the accompanying drawings, but the same or similar components are given the same reference numerals regardless of reference numerals, and redundant description thereof will be omitted. The suffixes "module" and "unit" for components used in the following description are given or used together in consideration of ease of writing the specification, and do not have meanings or roles that are distinct from each other by themselves. In addition, in describing the embodiments disclosed in this specification, if it is determined that a detailed description of a related known technology may obscure the gist of the embodiment disclosed in this specification, the detailed description thereof will be omitted. In addition, the accompanying drawings are only for easy understanding of the embodiments disclosed in this specification, and the technical idea disclosed in this specification is not limited by the accompanying drawings, and all changes included in the spirit and technical scope of the embodiments, It should be understood to include equivalents or alternatives.

1 is a block diagram showing a reactive power compensator according to an embodiment. The reactive power compensator according to the embodiment may include, for example, an SVC.

Referring to FIG. 1 , a reactive power compensator according to an embodiment may include a controller 100 and a plurality of valves 200 . The reactive power compensator according to the embodiment may further include an upper control unit 300 . The upper control unit 300 may or may not be included in the reactive power compensator. The upper control unit 300 may be referred to as a first control unit, and the control unit 100 may be referred to as a second control unit or vice versa.

The upper control unit 300 may control and manage the power system as a whole. The upper control unit 300 may control the control unit 100 so that the plurality of valves 200 are driven. That is, the control unit 100 may generate a firing signal for driving each valve 200 based on the valve control signal received from the upper control unit 300 . Each firing signal is transmitted to the corresponding valve 200, and the corresponding valve 200 can be driven.

Valve 200 may be switched to generate reactive power. For example, the valve 200 may include a thyristor. The valve 200 may receive a firing signal from the controller 100, and the thyristor may be switched according to the received firing signal. The valve 200 may be provided with various sensors for measuring the valve state as well as the thyristor. For example, the valve 200 may include a voltage sensor or a current sensor capable of sensing voltage or current. For example, the valve 200 may include a temperature sensor capable of sensing temperature. Accordingly, the valve 200 may provide valve-related information, for example, valve state information detected by various sensors to the control unit 100 .

An optical communication interface may be provided between the controller 100 and the valve 200 . For example, the optical communication interface connects the optical transmission/reception module provided in the control unit 100, the optical transmission/reception module provided in each valve 200, and the optical transmission/reception module provided in the control unit 100 and the optical transmission/reception module provided in each valve 200. It may include an optical cable for Accordingly, data or signals between the controller 100 and the valve 200 may be transmitted and received through an optical cable.

2 is a block diagram illustrating a control unit according to an embodiment.

Referring to FIGS. 1 and 2 , the controller 100 according to the embodiment may include a communication controller 110 . The communication control unit 110 may be in charge of communication with the upper control unit 300 . The communication control unit 110 may be in charge of controlling data exchanged through communication with the upper control unit 300 . For example, the communication control unit 110 may provide a valve-related command received from the upper control unit 300 to the signal processing unit 120 . For example, the valve-related command may include a valve control signal, but is not limited thereto. For example, the communication control unit 110 may provide valve-related state information received from the valve 200 to the upper control unit 300 .

Data exchanged between the communication control unit 110 and the upper control unit 300 may have a packet form. For example, the upper control unit 300 may provide a packet (first packet) including an identification code (ID) and a valve control signal to the communication control unit 110 of the control unit 100 in units of 16.64 ms. The first packet may also include a command for an operation mode. The operation mode may include a standby operation mode and a normal operation mode. The standby operation mode may be a mode in which each valve 200 is not operated and maintains a standby state. The normal operation mode may be a mode in which each valve 200 is normally operated. The controller 100 may determine whether to maintain each valve 200 in a standby state or operate normally with reference to the operation mode.

The communication control unit 110 may extract an identification code (ID) and a valve control signal from the received first packet, and then provide them to the signal processing unit 120 . For example, the communication control unit 110 may generate a packet (second packet) including an identification code (ID) and valve state information, and then provide the packet to the upper control unit 300 . After extracting the identification code (ID) and valve state information from the second packet, the upper control unit 300 may provide a command including an action corresponding to the valve state information to the control unit 100 .

The control unit 100 according to the embodiment may include a signal processing unit 120. The signal processing unit 120 may signal-process the valve control signal received from the communication control unit 110 and then provide the signal to the firing signal control unit 130 .

The control unit 100 according to the embodiment may include a valve monitoring unit 140. The valve monitoring unit 140 may be individually connected to the plurality of valves 200 and receive valve-related information provided from each valve 200 , for example, valve state information. The valve monitoring unit 140 may monitor valve state information to check whether a firing signal is normally transmitted to each valve 200 and whether the state of each valve 200 is normal. Such valve state information may be received in real time through an optical communication interface. The valve monitoring unit 140 may provide a valve monitoring signal as a result of the monitoring to the firing signal control unit. As will be described later, the firing signal control unit 130 may generate a firing signal depending on whether each valve 200 has an abnormality based on the valve monitoring signal.

The control unit 100 according to the embodiment may include a power monitoring unit 150. Typically, when operating in the standby operation mode and operating in the normal operation mode, a large surge voltage may flow into the reactive power compensator. If such a surge voltage is supplied to the valve, the valve may be damaged.

The power monitoring unit 150 may monitor power flowing into the reactive power compensator and provide a power monitoring signal as a result of the monitoring to the firing signal control unit 130 . As will be described later, the firing signal control unit 130 blocks the generation of a firing signal or the output of the generated firing signal when an abnormality occurs in the power supply based on the power monitoring signal, so that each valve 200 is not operated or switched. By doing so, damage to the valve 200 can be prevented.

The control unit 100 according to the embodiment may include a firing signal control unit 130. The firing signal control unit 130 may generate a firing signal for each of the plurality of valves 200 based on the valve control signal received from the signal processing unit 120 . The firing signal generated in this way is transmitted to each valve 200 so that the corresponding valve 200 can be switched.

The firing signal control unit 130 generates and outputs a firing signal based on the valve monitoring signal received from the valve monitoring unit 140 and/or the power monitoring signal received from the power monitoring unit 150, blocks generation of the firing signal, Alternatively, the output of the generated firing signal may be cut off.

3 is a circuit diagram showing a firing signal control unit according to an embodiment, FIG. 4 shows signal waveforms when the power state is normal, and FIG. 5 shows signal waveforms when the power state is abnormal.

The starting point shown in FIGS. 4 and 5 is the starting point of one cycle, and a firing signal may be generated and provided to the valve 200 at every cycle. One period may be, for example, 16.64 ms, but is not limited thereto.

1 to 3 , the firing signal control unit 130 according to the embodiment may include an output unit 133. The output unit 133 may receive the valve control signal (②, PHS_U) from the signal processing unit 120 . The output unit 133 may generate a firing signal PHS_U_OUT based on the valve control signal PHS_U and output the generated firing signal PHS_U_OUT to the corresponding valve 200 .

The firing signal PHS_U_OUT may or may not be generated depending on the driving mode. To implement this, the firing signal control unit 130 according to the embodiment may include a OR processing unit 131. The OR processing unit 131 may be referred to as a first OR processing unit. The first OR processing unit 131 may receive the valve control signal PHS_U and the block/deblock signals ③ and D/DB. The block/deblock signal B/DB may have a low level, for example, “0” or a high level, that is, “1”. When the block/deblock signal (B/DB) has a low level, the reactive power compensator is operated in the standby operation mode, and thus the valve 200 may not be switched. When the block/deblock signal B/DB has a high level, the invalidation compensator is operated in a normal operation mode, so that the valve 200 can be normally switched. The first OR processing unit 131 may perform OR processing on the valve control signal PHS_U and the block/deblock signal B/DB and provide the output signals ④ and PHS&B/DB to the output unit 133. . The block/deblock signal B/DB may be referred to as an operation mode control signal. The output signal PHS&B/DB may be referred to as a first output signal. The output unit 133 may generate a firing signal PHS_U_OUT based on the first output signal PHS&B/DB. For example, when the first output signal PHS&B/DB has a low level, the output unit 133 determines that the reactive power compensator is operated in the standby operation mode and does not generate the firing signal PHS_U_OUT. For example, when the first output signal PHS&B/DB has a high level, the output unit 133 may determine that the reactive power compensation device is operated in a normal operation mode and generate a firing signal PHS_U_OUT.

The output unit 133 may include a latch 1331 , an OR processing unit 1333 , a blocking unit 1335 and a holding unit 1337 . The OR processing unit 1333 may be referred to as a second OR processing unit. Some components of the latch 1331, the second OR processing unit 1333, the blocking unit 1335, and the holding unit 1337 may be omitted.

The latch 1331 may generate output signals ⑤ and FF_out based on the first output signal PHS&B/DB from the first OR processing unit 131 . The output signal FF_out may be referred to as a second output signal. The second output signal FF_out may be provided to the second OR processor 1333 . The latch 1331 may provide the first output signal PHS&B/DB from the first OR processing unit 131 to the second OR processing unit 1333 as it is. For example, when the first output signal PHS&B/DB has a high level, the latch 1331 converts the high level first output signal PHS&B/DB to the high level second output signal FF_out and uses the second logical sum. It can be provided to the processing unit 1333.

In addition to the second output signal FF_out from the latch 1331, the second OR processing unit 1333 outputs the valve monitoring signals ① and FVD_U from the valve monitoring unit 140 and the power monitoring signal from the power monitoring unit 150. (⑧, HFV_U) can be input. The second OR processing unit 1333 may perform OR processing on the second output signal FF_out, the valve monitoring signal FVD_U, and the power monitoring signal HFV_U. A signal resulting from OR processing in the second OR processing unit 1333 may be provided to the holding unit 1337 .

The holding unit 1337 is connected to the output terminal of the second OR processing unit 1333 to hold the resulting signal for a predetermined time. For example, the resulting signal may be held for 20 μs, but is not limited thereto. The holding unit 1337 may output a signal held for a predetermined time as a firing signal (PHS_U_OUT).

The blocking unit 1335 is connected between the input terminal and the output terminal of the second OR processing unit 1333, and after the firing signal PHS_U_OUT is output for a predetermined period of time (first period), the second OR for a predetermined period of time (second period) The output of the processing unit 1333 may be blocked. To this end, the blocking unit 1335 may provide a low-level input signal to the second OR processing unit 1333 for a second predetermined period of time. The second predetermined time may be, for example, 50 μs, but is not limited thereto. The second OR processing unit 1333 receives the second output signal FF_out of the latch 1331, the valve monitoring signal FVD_U from the valve monitoring unit 140, and the power monitoring signal HFV_U from the power monitoring unit 150. Even if all of them have a high level, since the input signal from the blocking unit 1335 is a low level, the second OR processing unit 1333 outputs a low level result signal, and consequently, the firing signal PHS_U_OUT is not generated. In this way, no signal is output as the firing signal PHS_U_OUT for a certain period of time (50 μs) after the firing signal PHS_U_OUT is output by the blocking unit 1335, so that a certain time after the firing signal PHS_U_OUT is output. During (50 μs), another high-level result signal is output as a firing signal (PHS_U_OUT) due to a system error or the like, so that malfunction of the valve 200 can be prevented.

The firing signal control unit 130 according to the embodiment may include a holding and resetting unit 134. The holding and resetting unit 134 may hold the output signal FF_out of the latch 1331 for a certain period of time (a third period) and then reset it. For example, the holding and resetting unit 134 outputs a high-level output signal (PHS&B/DB) for, for example, 3 ms from the falling time of the output signal (PHS&B/DB) from the first OR processing unit 131. and resetting the high-level output signal (PHS&B/DB) to the low-level output signal (PHS&B/DB) at the time of 3 ms from the polling time of the output signal (PHS&B/DB) from the first OR processing unit 131 can

The holding and reset unit 134 generates a low level output signal (PHS&B/DB) during a period in which the output signal (PHS&B/DB) from the first OR processing unit 131 maintains a high level and a period in which 3 ms elapses from the polling time. may be provided as the R terminal of the latch 1331. The latch 1331 outputs the high-level output signal (PHS&B/DB) input to the S terminal from the first OR processing unit 131 according to the low-level output signal (PHS&B/DB) input to the R terminal as it is as an output signal ( FF_out) may be provided to the second OR processing unit 1333.

The holding and reset unit 134 may provide a high level output signal (PHS&B/DB) to the R terminal of the latch 1331 when 3 ms has elapsed from the polling time of the first OR processing unit 131. The latch 1331 outputs the high level output signal (PHS&B/DB) input to the S terminal from the first OR processing unit 131 to the low level according to the high level output signal (PHS&B/DB) input to the R terminal. Transition to the signal (PHS&B/DB) may be provided to the second OR processing unit 1333. That is, the output signal FF_out of the latch 1331 is held by the high level output signal FF Reset from the holding and reset unit 134, and the low level output signal from the holding and reset unit 134 It can be reset by (FF Reset).

The firing signal control unit 130 according to the embodiment may provide a counter 135. The counter 135 may count the holding period of the output signal FF Reset from the holding and reset unit 134. That is, the counter 135 may receive the valve monitoring signals FVD_U and FVD_X from the valve monitoring unit 140 and the block/deblock signal B/DB from the upper control unit 300 . The counter 135 may count the holding period (3 ms) of the holding and reset unit 134 based on the valve monitoring signals FVD_U and FVD_X and the block/deblock signal B/DB. When the holding period (3 ms) of the holding and resetting unit 134 ends, the counter 135 may provide a corresponding counting signal to the holding and resetting unit 134 . The holding and reset unit 134 recognizes the end time of the holding period based on the counting signal provided from the counter 135, and provides a high level output signal (FF Reset) to the latch 1331 at the end time. The latch 1331 may be reset with the low-level output signal FF_out.

The firing signal control unit 130 according to the embodiment may provide an inverting unit 137. The inverting unit 137 may invert the power monitoring signal HFV_U provided from the power monitoring unit 150 and provide the inverted signal to the second OR processing unit 1333 .

As shown in FIG. 4 , when the power state flowing into the reactive power compensator is normal, the power monitoring signal provided from the power monitoring unit 150 may have a low level. The inverting unit 137 may invert the low-level power monitoring signal HFV_U into a high-level power monitoring signal HFV_U and provide the inverted power supply monitoring signal HFV_U to the second OR processing unit 1333 . In this case, the high-level output signal FF_out provided from the latch 1331 may be output as an output signal of the second OR processor 1333 as it is.

As shown in FIG. 5, when the power state flowing into the reactive power compensator is abnormal, that is, the power monitoring signal HFV_U provided from the power monitoring unit 150 generates a high-level pulse for a certain period (fourth period). can have The inverting unit 137 may invert a pulse having a high level to a low level and provide the inverted pulse to the second OR processing unit 1333 . In this case, the high level output signal FF_out provided from the latch 1331 is not output as an output signal of the second OR processing unit 1333. Accordingly, since the firing signal (PHS_U_OUT) is not output from the output unit 133, no firing signal is provided to the valve 200 from the firing signal control unit 130, so the valve 200 is not driven. It is possible to prevent the valve 200 from being damaged by the firing signal transmitted to the valve 200 when the state is abnormal.

The above detailed description should not be construed as limiting in all respects and should be considered illustrative. The scope of the embodiments should be determined by reasonable interpretation of the appended claims, and all changes within the equivalent range of the embodiments are included in the scope of the embodiments.

100: control unit 110: communication control unit
120: signal processing unit 130: firing signal control unit
131, 1333: logical sum processing unit 133: output unit
134: holding and reset unit 135: counter
137: inverting unit 140: valve monitoring unit
150: power monitoring unit 200: valve
300: upper control unit 1331: latch
1335: blocking part 1337: holding part
PHS_U: valve control signal HFV_U: power monitoring signal
FVD_U, FVD_X: valve monitoring signal
B/DB: block/deblock signal
PHS&B/DB: output signal
PHS_U_OUT: firing signal

Claims (15)

A valve monitoring unit for generating a valve monitoring signal based on the valve state of each of the plurality of valves;
A power monitoring unit for generating a power monitoring signal based on the power state flowing into the reactive power compensator; and
A firing signal control unit for generating a firing signal for driving the valve based on a valve control signal input from an upper control unit, the valve monitoring signal, and the power monitoring signal,
The firing signal control unit,
a first OR processing unit generating a first output signal by performing OR processing on the valve control signal and the operation mode control signal; and
An output unit for generating the firing signal based on the first output signal, the valve monitoring signal, and the power monitoring signal;
the output unit,
a latch generating a second output signal based on the first output signal;
a second OR processing unit generating the firing signal by OR processing the second output signal, the valve monitoring signal, and the power supply monitoring signal;
a holding unit connected to an output terminal of the second OR processing unit and outputting a signal resulting from OR processing by the second OR processing unit during a first period; and
A reactive power compensator comprising a blocking unit connected between an input terminal and an output terminal of the second OR processing unit and not generating the firing signal by blocking an output of the second OR processing unit for a second period after the firing signal is output. . delete delete delete According to claim 1,
The first section is 20 μs,
The second section is 50 μs of reactive power compensator. According to claim 1,
The firing signal control unit,
The reactive power compensator further comprises a holding and reset unit configured to reset the second output signal of the latch after being held for a third period. According to claim 6,
The third section,
Reactive power compensator for 3 ms from the polling time of the first output signal from the first OR processing unit. According to claim 6,
the latch,
a first input terminal connected to the first OR processing unit; and
Reactive power compensator comprising a second input terminal connected to the holding and reset unit. According to claim 8,
The latch is held by a high-level output signal from the holding and reset unit,
The reactive power compensation device wherein the latch is reset by a low level output signal from the holding and reset unit. According to claim 6,
The firing signal control unit,
Reactive power compensator further comprising a counter counting the third period of the holding and reset unit. According to claim 10,
The counter is
A reactive power compensator for generating a counting signal for counting the third section of the holding and reset unit based on the valve monitoring signal and the operation mode control signal. According to claim 1,
The firing signal control unit,
Inactive power compensation device further comprising an inverting unit for inverting the power monitoring signal and providing it to the output unit. According to claim 12,
When the power state flowing into the reactive power compensator is normal, the power monitoring signal has a low level,
The inverting unit inverts the low-level power monitoring signal into a high-level power monitoring signal. According to claim 13,
When the power state flowing into the reactive power compensator is abnormal, the power monitoring signal has a high-level pulse during a fourth period,
The inverting unit inverts the power monitoring signal of the high level pulse into a power monitoring signal of a low level. According to claim 13,
The output unit does not output a firing signal in response to the low-level power monitoring signal.

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