KR101152364B1 - Control device for reactive power compansator of hvdc system and hvdc system having the same - Google Patents

Abstract

PURPOSE: A device for controlling a reactive power compensator of an HVDC(High-Voltage Direct Current) system and an HVDC system therewith are provided to reduce capacity used for supplying reactive power. CONSTITUTION: A device(100) for controlling a reactive power compensator of an HVDC system comprises a discontinuous reactive power compensation unit and a variable reactive power compensation unit(50) connected to an AC power source of an HVDC system. A filter controller turns on/off a switch element of the discontinuous reactive power compensation unit by comparing the active power of the HVDC system with a set reference value. A reactive power compensation coordinating controller(110) generates a switch control signal for turning on/off the switch element by comparing the reactive power value inputted from the discontinuous reactive power compensation unit with the reactive power value inputted from the variable reactive power compensation unit.

Description

TECHNICAL FIELD [0001] The present invention relates to a reactive power compensation facility control apparatus for a HVDC system, and a HVDC system including the same. BACKGROUND OF THE INVENTION [0002]

The present invention relates to a reactive power compensation facility control apparatus for an HVDC system and an HVDC system including the same.

The HVDC system is a power transmission system that converts AC power generated from an AC power source to DC power using a converter, transfers it to a long-distance line or cable, and then converts the DC power to AC power using an inverter.

The HVDC system includes a filter, a parallel capacitor, a synchronous ancillary unit, an SVC (70), and the like for supplying reactive power required for the converter and maintaining the HVDC system number front end voltage. The filter and the parallel capacitor supply the reactive power needed for the converter, while the synchronous shunt and the SVC maintain the voltage of the HVDC system before the water supply.

At this time, the input and the opening of the filter and the parallel capacitor increase the reactive power supply or reduce the reactive power supply. The characteristic curves according to the increase and decrease of the reactive power are performed discontinuously. That is, the increase or decrease of the reactive power supply by the filter or the parallel capacitor is performed stepwise according to the effective power.

In the reactive power, the compensating region and the under compensating region, an additional reactive power must be increased or decreased in a synchronous phase compensator such as a synchronous phase compensator or SVC which can continuously control the reactive power. In this case, Quot; Qunder " (reactive power reduction amount), and the maximum reactive power to be further reduced is " Qover (reactive power increase amount). At this time, the amount of the reactive power which is further increased or decreased in the continuous variable compensator causes the capacity of the reactive power for maintaining the voltage of the continuous variable compensator as the original purpose thereof to be reduced, and accordingly, it corresponds to the fluctuation of the voltage according to the disturbance of the system The performance of the HVDC is deteriorated.

In addition, since the continuous variable compensator uses a power electronic switch, the response speed is fast, and the discontinuous compensator uses a mechanical switch, so that the response speed is slow. Therefore, when a large disturbance such as a system failure or HVDC stop occurs, first, the continuous variable compensator is operated to supply or consume reactive power until the control power is lost, and the reactive power compensation . Therefore, at the time of compensating the reactive power by the discontinuous compensator, the reactive power is compensated as much as compensated by the continuous variable compensator, resulting in overvoltage or undervoltage, which causes the increase of the insulation cost of the HVDC. Also, after the discontinuous compensator is turned on, there is a problem that the voltage fluctuation phenomenon occurs due to the reduction of the reactive power due to the control operation of the continuous variable compensator.

The present invention reduces the reactive power to be supplied to the synchronous phase shifter, the SVC, and the like in order to balance the supply and demand of the reactive power required by the converter due to the discontinuity of the reactive power supplied by the filter or the parallel condenser, And an HVDC system including the reactive power compensating facility control apparatus of the HVDC system, which can mitigate the excess or deficiency of the generated reactive power.

According to an aspect of the present invention, there is provided a control device for controlling a reactive power compensator comprising a discontinuous reactive power compensator and a variable reactive power compensator connected in parallel to an AC power source of an HVDC system, A filter controller for turning on or off a switch element included in the discontinuous reactive power compensator; And a reactive power compensation coordinator controller for generating a switch control signal for turning on or off the switch element by comparing the reactive power input from the discontinuous reactive power compensator with the reactive power input from the variable reactive power compensator The reactive power compensation facility control device of the present invention can be provided.

The filter controller may supply a switch control signal to turn on the plurality of switch elements in a number proportional to the set reference values.

Wherein the variable reactive power compensating unit is any one of a synchronous ancillary unit, an SVC, and a STATCOM, and the reactive power compensating cooperative controller is operable to set a reactive power of any one of the synchronous phase shifter, the SVD, If the reactive power amount of either the synchronous phase shifter, the SVD or the STATCOM is smaller than the reactive power amount of the compared filter, the switch element connected to the compared filter filter can be turned off.

Wherein the reactive power compensation cooperative controller compares the sum of the reactive power amount of any one of the synchronous phase converter, the SVD, and the STATCOM and the reactive power amount sum of two or more filters among the plurality of filters, And turns off at least two of the compared filters when any one of the reactive power amounts is small.

According to another aspect of the present invention, there is provided an AC power source for generating AC power; A converter for converting the AC power into DC power and transmitting the AC power; A reactive power compensator for supplying reactive power to the converter and including a discontinuous reactive power compensating unit and a variable reactive power compensating unit; And a reactive power compensator control unit connected in parallel with the AC power source and controlling the reactive power compensator, wherein the reactive power compensator controller compares the active power of the converter with the reference values, A filter controller for selectively turning on or off switch elements included in the discontinuous reactive power compensating unit; and a controller for comparing the reactive power input from the discontinuous reactive power compensator and the reactive power input from the variable reactive power compensating unit, And a reactive power compensation cooperative controller for generating a switch control signal for turning on or off the power supply.

The discontinuous reactive power compensator may further include first through n-th filters connected to the first through the n-th switch elements, respectively, where n is a natural number equal to or greater than 2,

The filter controller may supply a switch control signal to turn on the plurality of switch elements in a number proportional to the set reference values.

The variable reactive power compensating unit may include any one of a synchronous phase shifter, an SVC, and a STATCOM.

Wherein the reactive power compensation cooperative controller compares the reactive power amount of any one of the synchronous phase converter, the SVD, and the STATCOM with the reactive power amount of any one of the first to the n-th filters, The first switch and the second switch may be turned off when the reactive power of the first filter is less than the reactive power of the filter.

Wherein the reactive power compensation cooperative controller compares the sum of the reactive power amount of any one of the synchronous phase converter, the SVD, and the STATCOM and the reactive power amount sum of two or more filters among the first to n-th filters, If any one of the STATCOM's reactive power is small, two or more of the first to n-th filters may be turned off.

According to the embodiment of the present invention, by reducing the capacity used for reactive power supply irrespective of the voltage maintenance in the synchronous phase shifter, SVC, etc., it is possible to increase the ability to cope with a large change in voltage such as system failure, HVDC shutdown, .

In addition, the cooperative control of a low-cost filter or a parallel capacitor can lead to a reduction in facility capacity for an expensive synchronous phase converter and SVC, thereby reducing the HVDC installation cost.

In addition, the HVDC insulation cost can be reduced by lowering the overvoltage level by reducing the over-compensation of the reactive power caused by the difference in the operation speed between the discontinuous reactive power compensator and the variable reactive power compensator.

According to the embodiment of the present invention, it is possible to reduce the number of switching times of the filter to increase the lifetime and to improve the system instability by harmonic interference.

1 is a block diagram illustrating an HVDC system in accordance with an embodiment of the present invention.
2 is a graph of a reactive power control characteristic by a switch control signal output from an HVDC filter controller.

While the present invention has been described in connection with certain exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and similarities. It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In addition, numerals (e.g., first, second, etc.) used in the description of the present invention are merely an identifier for distinguishing one component from another.

Also, in this specification, when an element is referred to as being "connected" or "connected" with another element, the element may be directly connected or directly connected to the other element, It should be understood that, unless an opposite description is present, it may be connected or connected via another element in the middle.

Hereinafter, a reactive power compensating apparatus for an HVDC system and an HVDC system including the same according to embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram illustrating an HVDC system in accordance with an embodiment of the present invention.

1, an HVDC system according to an embodiment of the present invention includes an AC power source 10, a transformer 20, a converter 30, a reactive power compensation unit and a reactive power compensator control unit 100 .

Specifically, the AC power supply 10 may include a power supply for generating an AC power such as a generator. The AC power source 10 can produce three phases of AC power.

The transformer 20 can increase the AC power generated by the AC power supply 10 according to the transforming ratio and output the AC power. The transformer may use any one of Y-Y, Y-Δ, and Δ-Δ connections or a combination of them in order to transform the three-phase AC power according to the transforming ratio.

The converter 30 converts the AC power inputted from the transformer 20 into high voltage or ultra high voltage DC power and transmits it to the customer side. The converter can be implemented with a thyristor valve combination. The converter 30 includes a rectifier and is capable of outputting typical voltage and current waveforms through a bridge operation.

The reactive power compensating unit is connected between the AC power source 10 and the transformer 20 to supply the reactive power necessary for the converter 30. [ The reactive power compensating unit may include a discontinuous reactive power compensating unit and a variable reactive power compensating unit.

The discontinuous reactive power compensating unit may include a filter unit 40 or a parallel capacitor. The description of the parallel capacitor will be omitted in the present embodiment.

The filter unit 40 will be described with reference to a first-order filter in which a capacitor and an inductor are connected in series. However, the present invention is not limited to this, and a secondary or tertiary filter may be used. The filter unit 40 is used as a filter that always removes harmonics.

The filter unit 40 and the AC power supply 10 can determine the reactive power supply amount by the switch elements S1 to S3. The switch elements S1 to S3 are disposed between the filter unit 40 and the AC power source 10 and are turned on when reactive power is to be supplied and can be turned off when reactive power is not supplied.

A plurality of filters 41 to 43 may be connected in parallel in the filter section 40. [ Three LC resonant filters can be used as shown in Fig.

Each of the filters 41 to 43 can supply reactive power to the system by turning on / off the switch elements S1 to S3.

In Fig. 1, three filters 41 to 43 are used. The first to third filters 41 to 43 are arranged in parallel with the AC power source 10.

The first to third switches 41 to 43 and the AC power source 10 are provided with first to third switch elements S1 to S3 to turn on and off the reactive power.

The variable reactive power compensating section 50 can perform functions such as reactive power compensation, voltage adjustment, and voltage flicker suppression. The variable reactive power compensating unit 50 may include a synchronous phase shifter 60, a static reactive power compensator (SVC), and a static compensator (STATCOM).

In the embodiment of the present invention, the variable reactive power compensating section 50 shows that the synchronous phase shifter 60, the SVC 70 and the STATCOM 80 are connected in parallel to the AC power source 10, The SVC 70 and the STATCOM 80 included in the variable reactive power compensating unit 50 may be provided.

The synchronous anchorage (60) is a mechanical compensator using the excitation current and terminal voltage characteristics of the synchronous motor to control the reactive power.

The SVC 70 is a stationary reactive power compensator, which is capable of performing functions such as improvement of voltage stability, improvement of power factor, flicker prevention, and phase unbalance correction because of less malfunction, easy maintenance, and excellent dynamic performance. In particular, the SVC 70 can actively supply or absorb reactive power.

The SVC 70 may include a thyristor control reactor for obtaining a variable reactor function and a thyristor switch capacitor for obtaining a variable capacitor function.

The TCR consists of a bidirectional thyristor switch and a reactor connected in series to control the angle of deflection and continuously regulate the reactive current flowing through the reactor.

The TSC consists of a bidirectional thyristor switch and a capacitor connected in series. TSC synchronizes with the grid to turn on or off the switch at the moment when the bus voltage is at its maximum, thereby constantly supplying or interrupting the reactive power.

The STATCOM (80) allows operation at maximum output current even at low voltages with a bus voltage of 0.2 pu. The STATCOM 80 maintains the maximum phase current and the maximum ground current independently of the bus voltage and the reactive power supplied or absorbed can vary linearly with the bus voltage.

In addition, the STATCOM 80 can maintain the maximum phase current at low voltages, thereby improving the transient stability of the power system.

The reactive power compensator controller 100 may include an HVDC filter controller 120 and a reactive power compensation coordinator controller 110.

The HVDC filter controller 120 receives the active power (P _HVDC ) of the HVDC system and provides the received active power value to the reactive power compensation coordination controller 110. The HVDC filter controller 120 may send a filter switch control signal to the filter unit 40 to control the filter switches S1 to S3.

The HVDC filter controller 120 transmits a filter switch control signal to turn on the first switch S1 when the active power P _HVDC of the HVDC system is 0.3 pu or less as shown in Fig. And transmits a filter switch control signal for turning on the first switch S1 and the second switch S2 when it is 0.6 pu or less. When the first switch S1 to the third switch S3) to be turned on.

The reactive power compensation coordinator controller 110 receives the reactive power _signals Q _SC , Q _SVC and Q _STATCOM inputted from the synchronous averager 60, the SVC 70 and the STATCOM 80 and outputs the reactive power Q _filter1 , Q _filter2 , Q _filter3 ) to generate a filter switch control signal.

The reactive power compensation coordinator controller 110 can generate the filter switch control signal by comparing the reactive power quantity Q _SC of the synchronous ancillator with the reactive power quantity of each filter.

For example, the reactive power compensation coordinator controller 110 may output a filter switch control signal for turning off the first switch S1 when the reactive power amount Q _SC of the synchronous contractor is smaller than the reactive power amount of the first filter . The reactive power compensation coordinator controller 110 also controls the first switch S1 and the second switch S2 when the reactive power amount Q _SC of the synchronous phase shifter is smaller than the sum of the reactive power amounts of the first filter and the second filter It is possible to generate a filter switch control signal which turns off all of the filter switch control signals.

On the other hand, the reactive power compensation coordinator controller 110 can output a filter switch control signal that turns on the first switch S1 when the reactive power amount Q _SC of the synchronous phase shifter is larger than the reactive power amount of the first filter . When the reactive power amount Q _SC of the synchronous phase shifter is larger than the sum of the reactive power amount of the first filter and the reactive power of the second filter, the reactive power compensation coordinator controller 110 sets the first switch S1 and the second switch S2 It is possible to generate a filter switch control signal that turns on all of them.

Table 1 shows filter switch control signal states according to the reactive power amount condition of the synchronous phase shifter.

Condition filter Filter switch control signal Q _SC <Q _filter1 The first filter OFF Q _SC < _{Qfilter1 + Qfilter2} The first filter and the second filter OFF Q _SC <-Q _filter1 The first filter ON Q _SC <-Q _filter1- Q _filter2 The first filter and the second filter ON

In the above description, the first switch S1 and the second switch S2 are turned on / off by way of example, but the third switch S3 may be turned on / off. That is, when the reactive power amount Q _SC of the SVC is smaller than the sum of the reactive power amounts of the first filter, the second filter and the third filter, the reactive power compensation coordinator controller 110 sets the first to third switches S1 to S3 And when the reactive power amount Q _SC of the synchronous phase shifter is larger than the sum of the reactive power amounts of the first filter, the second filter and the third filter, the first to third switches S1 to S3 are turned off, S3) are all turned on.

The reactive power compensation coordinator controller 110 can output the filter switch control signal by comparing the reactive power amount Q _SVC of the SVC with the reactive power amount of each filter.

For example, the reactive power compensation coordinator controller 110 may output a filter switch control signal to turn off the first switch S1 when the reactive power amount Q _SVC of the _SVC is smaller than the reactive power amount of the first filter. When the reactive power amount Q _SVC of the _SVC is smaller than the sum of the reactive power amount of the first filter and the reactive power of the second filter, the reactive power compensation coordinator controller 110 _outputs both the first switch S1 and the second switch S2 Off of the filter switch control signal.

On the other hand, the reactive power compensation coordinator controller 110 may output a filter switch control signal that turns on the first switch S1 when the reactive power amount Q _SVC of the _SVC is larger than the reactive power amount of the first filter. When the reactive power amount Q _SVC of the _SVC is larger than the sum of the reactive power amount of the first filter and the reactive power of the second filter, the reactive power compensation coordinator controller 110 _outputs both the first switch S1 and the second switch S2 The filter switch control signal can be generated.

Table 2 shows the state of the filter switch control signal according to the reactive power amount condition of the SVC.

Condition filter Filter switch control signal Q _SVC <Q _filter1 The first filter OFF Q _SVC < _{Qfilter1 + Qfilter2} The first filter and the second filter OFF Q _SVC <-Q _filter1 The first filter ON Q _SVC <-Q _filter1- Q _filter2 The first filter and the second filter ON

In the above description, the reactive power compensation cooperative controller 110 has turned on / off the first switch S1 and the second switch S2. However, the third switch S3 can be turned on / off. That is, when the reactive power amount Q _SVC of the _SVC is smaller than the sum of the reactive power amounts of the first filter, the second filter and the third filter, the reactive power compensation coordinator controller 110 sets the first to third switches S1 to S3 And when the reactive power amount Q _SVC of the _SVC is larger than the sum of the reactive power amounts of the first filter, the second filter and the third filter, the first to third switches S1 to S3 ) Can be turned on.

The reactive power compensation coordinator controller 110 may output the filter switch control signal by comparing the reactive power amount Q _STATCOM of the STATCOM with the reactive power amount of each filter.

For example, the reactive power compensation coordinator controller 110 may output a filter switch control signal that turns off the first switch S1 when the reactive power amount Q _STATCOM of the _STATCOM is smaller than the reactive power amount of the first filter. In addition, the reactive power compensation cooperative controller 110 may control both the first switch S1 and the second switch S2 when the reactive power amount Q _STATCOM of the _STATCOM is smaller than the sum of the reactive power amount of the first filter and the second filter Off of the filter switch control signal.

On the other hand, the reactive power compensation coordinator controller 110 may output a filter switch control signal to turn on the first switch S1 when the reactive power amount Q _STATCOM of the _STATCOM is larger than the reactive power amount of the first filter. When the reactive power Q _STATCOM of the _STATCOM is greater than the sum of the reactive power amount of the first filter and the reactive power of the second filter, the reactive power compensation coordinator controller 110 _outputs both the first switch S1 and the second switch S2 The filter switch control signal can be transmitted.

Table 3 shows filter switch control signal states according to the reactive power amount condition.

Condition filter Filter switch control signal Q _STATCOM <Q _filter1 The first filter OFF Q _STATCOM < _{Qfilter1 + Qfilter2} The first filter and the second filter OFF Q _STATCOM <-Q _filter1 The first filter ON Q _STATCOM <-Q _filter1- Q _filter2 The first filter and the second filter ON

In the above description, the first switch S1 and the second switch S2 are turned on / off by way of example, but the third switch S3 may be turned on / off. That is, when the reactive power amount Q _STATCOM of the _STATCOM is smaller than the sum of the reactive power amounts of the first filter, the second filter and the third filter, the reactive power compensation coordinator controller 110 sets the first to third switches S1 to S3 ). If the reactive power amount Q _STATCOM of the _STATCOM is larger than the sum of the reactive power amounts of the first filter, the second filter and the third filter, the first to third switches S1 to S3 ) Can be turned on.

As described above, the reactive power compensation unit control apparatus according to the embodiment of the present invention can reduce the number of switches of the filter switch, thereby increasing the lifetime of the filter unit. In addition, the stability of the HVDC system can be improved by solving the instability of the HVDC system due to the harmonic interference.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the following claims And changes may be made without departing from the spirit and scope of the invention.

10: AC power source
20: Transformer
30: Converter
40:
41: first filter
42: second filter
43: third filter
50: reactive power compensating unit
60: Synchronous ancestors
70: SVC
80: STATCOM
100: reactive power compensator control device
110: reactive power compensation cooperative controller
120: HVDC filter controller

Claims (10)

A control apparatus for controlling a reactive power compensating unit including a discontinuous reactive power compensating unit and a variable reactive power compensating unit connected in parallel to an AC power source of an HVDC system,
A filter controller which compares the active power of the HVDC system with the reference values and receives a switch element included in the discontinuous reactive power compensator; And
And a reactive power compensation cooperative controller for generating a switch control signal for turning on or off the switch element by comparing the reactive power input from the discontinuous reactive power compensator with the reactive power input from the variable reactive power compensator,
Wherein the discontinuous reactive power compensator further comprises first through nth filters connected to the first through the nth switch elements, respectively, wherein n is a natural number of 2 or more,
Wherein the variable reactive power compensator is any one of a synchronous phase shifter, an SVC, and a STATCOM,
The reactive power compensation cooperative controller
The SVC and the STATCOM are compared with the reactive power amount of any one of the filters of the first to the n-th filters so that the reactive energy amount of any one of the synchronous phase shifter, the SVC, and the STATCOM And turns off the switch element connected to the compared filter if the reactive power of the comparator is less than the reactive power of the compared filter.
The method according to claim 1,
The filter controller
And a switch control signal for turning on the switch element in a number proportional to the magnitude of the set reference values is supplied to the HVDC system.
delete The method according to claim 1,
The reactive power compensation cooperative controller
The sum of the reactive power amount of any one of the synchronous converter, the SVC, and the STATCOM and the sum of the reactive power amounts of at least two filters among the first to the n-th filters, And turns off at least two of the compared filters when the power is small.
AC power generating AC power;
A converter for converting the AC power into DC power and transmitting the AC power;
A reactive power compensator for supplying reactive power to the converter and including a discontinuous reactive power compensating unit and a variable reactive power compensating unit; And
And a reactive power compensation unit controller connected in parallel to the AC power source and controlling the reactive power compensator,
The reactive power compensator control device
A filter controller for selectively turning on or off the switch elements included in the discontinuous reactive power compensator by comparing the active power of the converter with preset reference values,
And a reactive power compensation cooperative controller for generating a switch control signal for turning on or off the switch element by comparing the amount of reactive power inputted from the discontinuous reactive power compensating section and the amount of reactive power inputted from the variable reactive power compensating section,
Wherein the discontinuous reactive power compensator comprises first through n-th filters connected to the first through the n-th switch elements, respectively, wherein n is a natural number of 2 or more,
Wherein the variable reactive power compensator includes any one of a synchronous phase shifter, an SVC, and a STATCOM,
The reactive power compensation cooperative controller
The SVC and the STATCOM are compared with the reactive power amount of any one of the filters of the first to the n-th filters so that the reactive energy amount of any one of the synchronous phase shifter, the SVC, and the STATCOM And turns off the switch element connected to any one of the first to the n-th filters if it is smaller than the reactive power of the compared filter.
delete 6. The method of claim 5,
The filter controller
And a switch control signal for turning on the first to the n-th switch elements in a number proportional to the magnitude of the set reference values.
delete delete 6. The method of claim 5,
The reactive power compensation cooperative controller
The sum of the reactive power amount of any one of the synchronous converter, the SVC, and the STATCOM and the sum of the reactive power amounts of at least two filters among the first to the n-th filters, And turns off at least two of the first through n-th filters when the power is small.

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