JP5318156B2 - Voltage reactive power control system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a voltage and reactive power control system which performs voltage adjustment with transmission losses of power taken into consideration in a loop system, and thereby enables voltage adjustment to be exerted while aiming at reducing transmission losses of power within a voltage operations range. <P>SOLUTION: A voltage and reactive power control system maintains the bus voltage of a loop system, configured with power transmission lines in loop form via a plurality of substations to supply electric power, in an appropriate range. When the bus voltage exceeds a target set voltage range, the amount of reactive power which would occur when phase modifying facilities at each substation of the loop system are separately switched on or off is calculated, and a simulation is made to see if it is possible to reduce transmission losses of power on the basis of the calculated amount of reactive power. At the same time, a simulation is made to see if the bus voltage would fall within the target set voltage range. When it is found that transmission losses of power can be reduced and that the bus voltage would fall within the target set voltage range, the phase modifying facilities are controlled so that they will be in the state of settings that the simulation was conducted. <P>COPYRIGHT: (C)2013,JPO&amp;INPIT

Description

  The present invention is for adjusting voltage / reactive power by turning on / off control of phase-adjusting equipment installed in each substation and tap control of transformer in order to maintain the bus voltage of loop system in an appropriate state. The present invention relates to a voltage reactive power adjustment system.

As equipment for adjusting the voltage of the power grid, the substations usually have a transformer with a load tap changer that can adjust the secondary side voltage, a reactive power supply / absorption capacitor or reactor, etc. A power conditioner (phase adjusting equipment) is installed.
However, due to the remote power supply, the capacitance between the power supply and the ground has increased, the adjustment range of reactive power by the generator has decreased, and consumers (loads) connected to the power system have a large capacity. As a result, the required amount of reactive power has increased in proportion to this, and customers (loads) are concentrated and distributed in the power system, which has hindered voltage maintenance. In addition, transmission loss due to reactive power is increasing.

  As a technique for solving this problem, voltage instability is prevented from occurring in the power system by cooperatively controlling automatic voltage regulators and automatic voltage reactive power regulators that have been installed in power plants and substations. A voltage reactive power control device has been proposed.

JP-A-4-275026

  However, in the control device described above, the control conditions are set in the automatic voltage regulator installed in the substation so that the optimum voltage regulation control can be performed with the voltage operation width (voltage maintenance target) determined in the power system. However, control is not performed from the viewpoint of reducing power transmission loss only by adjusting the voltage within the voltage operating range. For this reason, even if the voltage is optimally controlled within a predetermined operating width, there may be a disadvantage that the power transmission loss due to reactive power increases.

  The present invention has been made in view of such circumstances, and in particular, in a loop system, voltage adjustment that incorporates the viewpoint of power transmission loss in the power system is performed, and voltage adjustment is performed while reducing power transmission loss within the voltage operation range. The main problem is to provide a voltage reactive power control system that can perform the above.

  In order to achieve the above object, a voltage reactive power control system according to the present invention is configured to generate a bus line voltage of a loop system configured to supply power by configuring a transmission line in a loop shape via a plurality of substations. A voltage reactive power control system for maintaining in an appropriate range, the bus voltage measuring means for measuring the bus voltage for each of the substations, and the reactive power measurement for measuring the reactive power and the direction of each of the substations Means, phase-adjusting equipment state detecting means for detecting the state of the phase-adjusting equipment provided for each power generation substation, and when the bus voltage exceeds a target set voltage range, the control of each power generation substation in the loop system Reactive power calculation means for calculating the reactive power amount when the phase equipment is separately turned on or opened, and a transmission for simulating whether or not transmission loss is reduced based on the reactive power calculated by the reactive power calculation means. Loss simulation means, voltage simulation means for simulating whether or not the bus voltage falls within a target set voltage range when the phase adjusting equipment of each power generation substation is turned on or opened, and the bus voltage by the voltage simulation means If there is a simulation that is determined to be within the target set voltage range and it is determined that the transmission loss can be reduced by the transmission loss simulation means, the phase adjusting equipment is set to the setting state in which the simulation is performed. And a control means for controlling.

  Therefore, when the bus voltage exceeds the target set voltage range, the reactive energy calculation means calculates the reactive energy when the phase-adjusting equipment at each power generation substation of the loop system is turned on or off separately. The loss simulation means simulates whether or not transmission loss can be reduced based on the calculated reactive power amount, and the voltage simulation means separately turns on or opens the phase-adjusting equipment of each power substation. If the bus voltage falls within the target set voltage range, the control means determines that the transmission loss can be reduced, and the bus voltage is determined to fall within the target set voltage range. Therefore, the phase adjusting equipment is controlled so that the simulation is performed and the phase adjustment equipment is controlled. It is possible to adjust the voltage.

  Further, the voltage reactive power control system includes a tap state detection unit that detects a tap state of a transformer provided for each power generation substation, and the reactive power amount calculation unit includes the bus voltage exceeding a target set voltage range. Means for calculating the reactive power when the transformer taps of each power generation substation of the loop system are changed separately, the power transmission loss simulation means is the transformer calculated by the reactive power calculation means Including a means for simulating the presence or absence of a reduction in power transmission loss based on the reactive power amount when the transformer tap is changed, wherein the voltage simulation means is configured such that the bus voltage is within a target set voltage when the transformer tap is changed. Including a means for determining whether or not it fits, and the control means can reduce the power transmission loss after the tap change by the power transmission loss simulation means. When there is a simulation that is determined and determined that the bus voltage is within the target set voltage range after the tap is changed by the voltage simulation means, the transformer tap is switched so that the simulation is performed. Control may be included.

  In such a configuration, when the bus voltage exceeds the target set voltage range, the reactive energy is calculated when the transformer taps of each generating substation in the loop system are changed separately by the reactive energy calculation means. The transmission loss simulation means simulates whether the transmission loss can be reduced based on the reactive power amount when the transformer tap calculated by the reactive power calculation means is changed, and the voltage simulation means When the transformer tap is changed, it is simulated whether or not the bus voltage falls within the target set voltage, and it is determined by the control means that the transmission loss can be reduced after the tap change, and the bus voltage is changed after the tap change. When it is determined that the voltage falls within the target set voltage range, the transformer touch is set so that the simulation is performed. By switching the transformer tap, reactive power is circulated through the loop system, thereby reducing the reactive power before changing the transformer tap and reducing the power transmission loss while reducing the bus voltage to the voltage operating range. Can be adjusted to

  Here, when there are a plurality of simulations capable of reducing the power transmission loss by the power transmission loss simulation means, it is preferable to perform control by the control means so that the simulation setting state having the highest power transmission loss reduction effect is obtained.

  Further, in the above-described control, it is determined that the transmission loss can be reduced as a result of the simulation by the power transmission loss simulation means, and the bus voltage is determined to be within the target set voltage range as a result of the simulation by the voltage simulation means. In the case where there is no simulation, the second simulation is performed to determine whether the bus voltage falls within the target set voltage range when the primary side taps of the transformers of the power generation substations in the loop system are simultaneously controlled to be lowered or raised. When the bus voltage is determined to be within the target set voltage range by the simulation of the voltage simulation means and the second voltage simulation means, each of the loop systems is set so that the simulation is performed. 2nd to switch the primary tap of the transformer in the substation It may further comprise a control means.

  According to such a configuration, there is no simulation in which it is determined that the power transmission loss can be reduced by the power transmission loss simulation unit, or there is no simulation in which the bus voltage is determined to be within the target set voltage range by the voltage simulation unit. In this case, the second voltage simulation means simulates the bus voltage when the primary side taps of the transformers of the power generation substations of the loop system are simultaneously lowered or raised, and the bus voltage is set to the target set voltage. When it falls within the range, the second control means controls the primary taps of the transformers of each power generation substation in the loop system so as to be in the setting state obtained by the simulation, thereby reducing the transmission loss. However, when it is difficult to keep the bus voltage within the target setting voltage range, priority is given to control to stabilize the voltage. Theft is possible.

Moreover, when it is determined that the bus voltage does not fall within the target set voltage range as a result of the simulation by the second voltage simulation means, it is difficult to stabilize the voltage by controlling the phase adjusting equipment and the transformer tap. In this case, it is preferable to provide a notification means for notifying the operator and leave it to the control by the operator.
According to such a configuration, since the operator is notified when the bus voltage does not fall within the target set voltage range as a result of the simulation by the second voltage simulation means, the power plant connected to the system by the operator It becomes possible to keep the voltage within the target set voltage by adjusting the excitation of the generator and controlling the phase adjusting equipment of another power generation substation.

  As described above, according to the voltage reactive power control system according to the present invention, when the bus voltage exceeds the target set voltage range, the invalidation when the phase-adjusting equipment of each power generation substation is separately turned on or opened. It is simulated whether the amount of electric power is calculated and power transmission loss can be reduced, and whether or not the bus voltage is within the target set voltage range when the phase-adjusting equipment at each power substation is turned on or opened. When the simulation is performed and it is determined that the transmission loss can be reduced, and the bus voltage is determined to be within the target set voltage range, the phase adjusting equipment is controlled so that the simulation is performed. Thus, it is possible to adjust the bus voltage to the voltage operating range while reducing power transmission loss.

  Further, in the above-described voltage reactive power control system, when the bus voltage exceeds the target voltage range, the reactive power amount when the transformer tap of each generating substation of the loop system is changed separately is calculated, Based on this, we simulated whether or not the transmission loss was reduced, and also simulated whether or not the bus voltage would fall within the target set voltage when the transformer tap was changed. When it is determined that reduction can be achieved and it is determined that the bus voltage is within the target set voltage range, the transformer tap may be controlled so as to be in a set state in which simulation is performed. According to the control, the loop system that occurred before the tap change due to the reactive power circulating by changing the transformer tap Reduce the reactive power, it is possible to adjust the bus voltage to the voltage operation range.

  Here, when there are multiple simulations that can reduce power transmission loss, control by the control means to achieve the setting state of the simulation with the highest power transmission loss reduction effect can effectively reduce power transmission loss. However, it is possible to stabilize the voltage.

  In the above simulation, when the transmission loss cannot be reduced, or when the bus voltage does not fall within the target set voltage range, the primary taps of the transformers at each power station in the loop system are simultaneously lowered or raised. Simulation of whether the bus voltage is within the target set voltage range, and if it is determined that the bus voltage is within the target set voltage range, By controlling the primary side tap of the transformer of the substation so as to be in the setting state in which the simulation is performed, it is possible to stabilize the voltage in preference to the reduction of power transmission loss.

  In addition, if it is determined that the bus voltage does not fall within the target set voltage range as a result of simulation when the primary taps of the transformers at each power generation substation in the loop system are controlled to be lowered or raised simultaneously, By notifying the operator, voltage adjustment by the operator can be prioritized.

FIG. 1 is a diagram showing a configuration example of a loop system to which a voltage reactive power control system according to the present invention is applied, where (a) is a loop system diagram, and (b) is equipment of each substation constituting the loop system. It is a table | surface explaining a specification. FIG. 2 is a block diagram illustrating the configuration of the voltage reactive power control system according to the present invention. FIG. 3 is a flowchart showing an example of control processing in the calculation / control apparatus of the voltage reactive power control system. FIG. 4 is a diagram for explaining changes in reactive power around the 220 kV transmission line and reactive power around the 110 kV transmission line when one ShR of the B substation is inserted. FIG. 5 is a diagram for explaining a change in reactive power around the interconnection transformer of the A substation and reactive power around the 110 kV transmission line when one ShR of the A substation is inserted. FIG. 6 is a diagram showing distributions in the case where transmission loss can be reduced by turning on ShR at the A substation and transmission loss can be reduced by turning on ShR at the B substation, centering on the straight line of Q2 = Q1 + 4. is there. FIG. 7 is a diagram for explaining a change in reactive power when the primary tap of the interconnection transformer is switched. FIG. 8 is a diagram for explaining the change in reactive power before and after the introduction of one ShR at the B substation.

  Hereinafter, the voltage reactive power control system of the present invention will be described with reference to the accompanying drawings. In this embodiment, a description will be given of a different voltage loop system (annular system) in which systems having different voltages are looped via transformers (banks) of a plurality of substations. However, the present invention is not limited to this. Absent.

  FIG. 1 shows a configuration example of a loop system applied to the voltage reactive power control system according to the present invention. A substation 1 and a B substation 2 are connected by a B connection line 3 of 220 kV. In addition, they are connected by an AB line 4 of 110 kV. Furthermore, the A substation 1 and the C substation 5 are connected by a 110 kV AC line 6, and the C substation 5 and the B substation 2 are connected by a 110 kV C line 7. In this example, the impedance of the 110 kV transmission line is set to be very large compared to the impedance of the 220 kV transmission line.

  For this reason, although the A substation 1 and the B substation 2 have different voltages, they are connected by a loop system, and the adjustment of the system voltage is performed in the phase-adjusting facilities (the A substation 1 and the B substation 2) ShR, SC) is controlled by switching on and off the primary side tap of the interconnection transformer, and the 110 kV bus voltage of the A substation and the B substation is set to 112 ± 1.0 kV at the peak. And is adjusted so as to be 109 ± 1.0 kV at the off-peak time.

Here, the A substation has two 220/110 kV and 200 MVA transformers as interconnection transformers, and one 20 MVA ShR (shunt reactor) as phase adjusting equipment. The substation has two 220 / 110kV, 300MVA interconnected transformers as interconnecting transformers, four 20MVA ShRs (shunt reactors), and 20 MVA SCs (electric power generators). 2 units and 30 MVA SC (electric power plant) are installed.
In addition, the tap of the interconnection transformer of A substation 1 and B substation 2 is normally operated with the same tap in order to prevent the circulation of reactive power.

  The voltage reactive power control system has a configuration as shown in FIG. 2, and measuring units A1 and B1 that measure the bus voltage and reactive power in each of the A substation 1 and the B substation 2. And state grasping parts A2 and B2 for grasping the on / off state of the adjusting equipment and grasping the tap value of the transformer, information on the bus voltage and reactive power measured by these measuring parts A1 and B1, and the state The information on the state of the adjustment equipment and the transformer tap value grasped by the grasping units A2 and B2 is transmitted to the arithmetic / control device 10 via the transmitting units A3 and B3.

  The calculation / control apparatus 10 receives information sent from the A substation 1 and the B substation 2 at the reception unit 11 and performs calculation processing according to a predetermined program at the calculation unit 12 based on the received information. The selection unit 13 selects the most suitable operation point (phase adjusting equipment or transformer tap) for adjusting the bus voltage or reactive power, and sends an operation command signal to the selected operation point. To send through.

  Each substation receives the operation command signal transmitted from the transmission unit 14 of the calculation / control apparatus 10 at the reception units A4 and B4, and the devices to be operated at the operation device distribution units A5 and B5 (conditioning equipment, transformer) If the device to be operated is a transformer, the control of the transformer tap is automatically controlled based on the operation command signal. Then, on / off control of the phase adjusting equipment is automatically performed based on the operation command signal.

Next, a method of adjusting reactive power in the above configuration will be described based on the flowchart shown in FIG.
First, in the calculation unit 12 of the calculation / control apparatus 10, information on the bus voltage measured by the measurement units A1 and B1 of each substation is input as needed, and a preset voltage target value (target set voltage) is obtained. Whether it has deviated or not is monitored (step 50), and if it is determined that the target set voltage has been deviated, a power transmission loss simulation and a voltage change simulation in the loop system are performed (step 52).

  Here, the simulation of power transmission loss is carried out in the case where one phase-adjusting equipment is separately “on” in each substation (A substation, B substation), and each substation (A substation). , B substation) in the case where the “down” of the transformer tap on the primary side of the interconnection transformer is separately performed, and therefore the voltage simulation is also performed for each transmission loss simulation. (A voltage simulation is performed when the phase-adjusting equipment of each substation is separately turned on, and a voltage simulation is performed when the transformer tap of each substation is separately lowered.) ing.

  Then, after completing the simulation of step 52, ranking is performed for all simulations in descending order of the power transmission loss reduction effect (step 54).

  Thereafter, it is possible to reduce power transmission loss and determine whether there is a simulation in which the bus voltage is within the target set voltage range (step 56). If it is determined that there is a simulation in which the voltage falls within the target set voltage range, the corresponding state is set so that the highest priority (highest power loss reduction effect) is set based on the priority in step 54. The phase adjusting equipment or transformer tap is controlled (step 58).

  On the other hand, when there is no simulation that can reduce power transmission loss or when it is determined that there is no simulation that can keep the voltage within the target set voltage range even when power transmission loss can be reduced Proceeds to step 60 and starts a simulation of the voltage change when the transformer taps of both substations are lowered at the same time, and then determines whether or not the bus voltage falls within the target set voltage range (step 62).

  As a result, when it is determined that the bus voltage falls within the target set voltage range, control is performed to lower the taps of the transformers in both substations without considering the reduction of power transmission loss (step 64), Thereafter, the process returns to step 50 for monitoring the bus voltage. On the other hand, when it is determined in step 62 that the bus voltage does not fall within the target set voltage range, the operator is notified (step 66), and then the process returns to step 50 for monitoring the bus voltage. When it is determined that the bus voltage still deviates from the target voltage, the above-described processing is repeated.

When the operator receives the notification in step 66, the operator sets the voltage to the target set voltage by controlling the excitation adjustment of the generator of the power plant connected to the corresponding system and the phase adjusting equipment of another power generation substation. Adjust to fit inside.
Further, in the control of the phase adjusting equipment and the transformer tap in step 58 and the control of the transformer taps in both substations in step 64, the state after the control is grasped by the state grasping units A2 and B2, and the calculation / control device 10 Since it is sent to the calculation unit 12, it is possible to check whether the command value calculated by the calculation unit 12 matches the actually controlled state, and the control state can be monitored.

  Therefore, according to the above-described control, it is determined that the transmission loss is reduced after the simulation of the transmission loss in the case where the phase adjusting equipment and the transformer tap of the substation in the loop system are separately controlled. In addition, when there is a simulation in which the voltage is determined to be within the target voltage setting range, the on / off control of the phase adjusting equipment or the transformer tap is set so that the simulation setting state with the highest effect of reducing the transmission loss is obtained. Since the raising / lowering control is performed, the system voltage can be controlled within the target set voltage while reducing the power transmission loss.

  Next, a specific method of adjusting the voltage within the target set voltage while reducing the power transmission loss in the above configuration will be described.

  When the voltage deviates from the target set voltage, conventionally, the voltage is adjusted by turning on the phase adjusting equipment at the substation where the voltage error has occurred. Among them, when ShR is turned on, reactive power flows from the A substation to the B substation.

For this reason, the transmission loss due to reactive power is adjusted by turning on / off control of the phase adjusting equipment and tap switching of the interconnection transformer, and the transmission loss due to reactive power is reduced to zero or as low as possible for the entire loop system. It is preferable to keep the voltage within the target set voltage so as to be close to.
That is, ideally
PL = Σ (% rn × Qn ^ 2) = 0 (1)
Is desirable.
Where, PL: Effective loss of reactive power
% Rn:% ohm of each transmission line
Qn: Reactive power of each transmission line

  Therefore, when simulating how the reactive power changes by turning on the phase-adjusting equipment, first, how much the reactive power changes when the phase-adjusting equipment at the A substation and the B substation are turned on separately. In order to know whether or not there is, the impedance of the transmission line is examined from the system diagram, and the amount of change in the reactive power is estimated (A substation 220 kV bus standard).

When one ShR of B substation is introduced, the ratio of the% impedance around each transmission line and the% impedance of the entire system is, for example,
Σ% Z around 110kV transmission line / Σ% Z of entire system ≒ 0.7
Σ% Z around 220kV transmission line / Σ% Z of entire system ≒ 0.3
As shown in FIG. 4, the ratio of the amount of change in reactive power around the 220 kV transmission line and the amount of change in reactive power around the 110 kV transmission line is estimated to be 7: 3 (inverse ratio).

In addition, when one phase adjusting equipment (ShR) of the A substation is introduced, the ratio between the% impedance around each transmission line and the% impedance of the entire system is, for example,
Σ% Z around 110kV transmission line / Σ% Z of entire system ≒ 0.5
A substation transformer% Z / whole system Σ% Z ≒ 0.5
As shown in FIG. 5, the ratio of the amount of change in reactive power down the A substation transformer and the amount of change in reactive power around the 110 kV transmission line is estimated to be 5: 5.

  Here, since it is assumed that the transmission line for which the transmission loss is to be reduced is that the line impedance of the 110 kV transmission line is very large compared to the impedance of the 220 kV transmission line, the transmission loss of the 110 kV transmission line is reduced. Think of it.

  Therefore, the reactive power on the B substation side is the sum of the reactive powers on the AB line and the C line, and the reactive power on the A substation side is the sum of the reactive powers on the AB line and the AC line. Conditions for reducing transmission loss by turning on phase equipment, that is, conditions for reducing transmission loss due to reactive power shown in the above equation (1) [(transmission loss when A substation ShR is turned on) − (B substation ShR is turned on) (Transmission loss at time) = 0], the transmission loss at the time of turning on the phase adjusting equipment (ShR) of the A substation and the transmission loss at the time of turning on the phase adjusting equipment (ShR) of the B substation (A substation) Power transmission loss when the station ShR is turned on = power transmission loss when the B substation ShR is turned on). The condition that the transmission loss at the time of turning on the phase adjusting equipment (ShR) at the A substation and the power transmission loss at the turning on of the phase adjusting equipment (ShR) at the B substation is more This means finding a critical condition that cannot be adjusted.

Therefore, Q1: Reactive power on the A substation side
Q2: Reactive power at B substation
Qs: Reactive power with ShR input (= 20MVA)
Then,
(Transmission loss when the A substation ShR is turned on) = (Transmission loss when the B substation ShR is turned on) is
(Q1 + 0.5Qs) ^ 2 ・% R ＋ (Q2−0.5Qs) ^ 2 ・% R
＝ （Q1－0.3Qs） ^ 2 ・% R ＋ （Q2 + 0.3Qs) ^ 2 ・% R
Than,
Q2 = Q1 + 0.2Qs
= Q1 + 0.2 × 20
= Q1 + 4
It becomes.
Here, the direction of the reactive power flowing from the 110 kV bus of the substation to the transmission line is a “minus” sign, and the direction of flowing from the transmission line to the 110 kV bus of the substation is a “plus” sign.

In fact, when this relational expression (characteristic expression) is added to a chart plotting points at which power transmission loss can be reduced from past power supply records, it is as shown in FIG.
In addition, extraction of the point which can reduce the power transmission loss in FIG. 6 was performed in the following manner.
(A) Subtract reactive power for ShR input from power supply record (b) Calculate power transmission loss due to reactive power in that state (c) Calculate power transmission loss due to reactive power when ShR of B substation is input A Calculate transmission loss due to reactive power when substation ShR is turned on (d) Compare (b) and (c), and plot if transmission loss can be reduced by turning on ShR.

  As is clear from this figure, the points where the transmission loss can be reduced by the ShR input (□) of the B substation and the ShR input (△) of the A substation are distributed around the straight line of Q2 = Q1 + 4. Therefore, if the phase adjusting equipment is controlled so as to be along (closer to) this characteristic line, that is, the absolute value of the difference between the right side and the left side (| Q2-Q1-4 |) is calculated based on the above characteristic equation. If it can be made as small as possible (preferably, it can be made zero), the power transmission loss due to reactive power can be reduced. In other words, the smaller the absolute value, the greater the effect of reducing power transmission loss.

The voltage change due to the introduction of the phase adjusting equipment is as follows.
The voltage change when the phase adjusting equipment (ShR) is turned on at the B substation is as follows. [X1 = 0.253% Z ÷ 100 = 0.00253PU, X2 = 0.5558% Z ÷ 100 = 0.005558PU]
△ V = X1 ・ X2 ÷ (X1 + X2) ・ △ q = 0.00253 × 0.005558 ÷ (0.00253 + 0.005558) × 2.0 = 0.00001406 ÷ 0.008088 × 2.0 = 0.00347PU [Input location]
In this case, B substation 110kV bus voltage change is
△ V110 = 0.00347−0.00347 × (-0.025 ÷ 0.5558) = 0.00347 + 0.00015 = 0.00362PU (0.39kV)
A substation 110kV bus voltage change is
ΔV110 = 0.00347−0.00347 × (0.404 ÷ 0.5558) = 0.00347−0.00252 = 0.00095 PU (0.10 kV).

Moreover, the voltage change when the phase adjusting equipment (ShR) is turned on at the A substation is as follows.
△ V = X1 ・ X2 ÷ (X1 + X2) ・ △ q = 0.00413 × 0.003958 ÷ (0.00413 + 0.003958) × 2.0
= 0.00001634 ÷ 0.008088 × 2.0 = 0.004PU [Input location]
In this case, A substation 110kV bus voltage change is
△ V110 = 0.004−0.004 × (−0.035 ÷ 0.413) = 0.4 + 0.084 = 0.00484PU (0.44kV)
B substation 110kV bus voltage change is
△ V110 = 0.004−0.004 × (0.1708 ÷ 0.3958) = 0.004−0.0017 = 0.0023PU (0.21kV)
It is.

  The above is the case where the taps of the interconnection transformer are operated in the same way and the transmission loss is reduced only by the phase adjusting equipment. However, the reactive power is circulated to the loop system by changing the primary side tap of the interconnection transformer. Thus, the reactive power before the tap change can be reduced.

When there is power on the primary side and secondary side of the interconnection transformer, if the primary tap of the transformer is lowered (lowering the secondary voltage), the reactive power is transferred from the secondary side of the transformer to the primary side. When the primary tap is raised (secondary voltage is raised), reactive power flows from the primary side to the secondary side of the transformer.
Therefore, when the tap of the interconnection transformer of the A substation is lowered, as shown in FIG. 7, reactive power flows from the B substation toward the A substation on the 110 kV transmission line, and before the tap change, the A It becomes possible to reduce the reactive power flowing from the substation to the B substation.

Therefore, when calculating the reactive power circulation amount when the tap is changed, the reactive power change amount ΔQ when the tap is changed is obtained as follows.
△ Q = △ N / Z
Here, ΔN is the voltage change width [PU] per tap, and Z is the impedance of the loop system. In addition, the taps are numbered 1 to 13, and the number 1 is set to 235 kV and the number 13 is set to 199 kV.
△ N = 36kV ÷ {220kV × (13-1)} = 0.0135 [PU] (12 taps)
Z = Σ% Z ÷ 100 = 0.0.888 ÷ 100 [PU]
Therefore, ΔQ = ΔN ÷ Z = 0.0135 ÷ (0.8088 ÷ 100) ≒ 1.67 [PU] (∴ 16.7MVar)

Therefore, by changing the tap, the reactive power of 16.7 MVar circulates. Therefore, if the reactive power of about 16 MVar flows around the 110 kV transmission line (AB line, AC line, C line), the tap can be switched. It becomes possible to cancel the reactive power before adjustment, and to effectively reduce the transmission loss.
In other words, when the best result is obtained, the transformer tap is “lowered” at the A substation when 16.7 Mvar of reactive power flows from the A substation to the B substation on the 110 kV transmission line. The transmission loss in this case is
(Transmission loss that occurs before adjustment) = (Transmission loss when the transformer tap is changed by one stage)
From the relational expression of
(Q1 + 16.7) ^ 2 ・% R ＋ (Q2−16.7) ^ 2 ・% R
＝ （Q1−16.7) ^ 2 ・% R ＋ （Q2 + 16.7) ^ 2 ・% R
Q2 = Q1
It is represented by Therefore, from this relationship, if the absolute value (| Q2-Q1 |) of the difference between the right and left sides can be made as small as possible (preferably, it can be made zero), transmission loss due to reactive power can be reduced. The smaller the absolute value, the greater the effect of reducing power transmission loss.

Note that the voltage change caused by changing the tap is
When the tap is changed by one step at B substation,
The 110kV bus voltage change at B substation is
△ V110 ＝ △ n × X2 ÷ (X1 ＋ X2) ＝ 0.0135PU × 0.5813 ÷ 0.8088
= 0.0097PU (1.06kV),
And the change in the 110 kV bus voltage at substation A is
△ V110 ＝ △ n × X2 ÷ (X1 + X2) ＝ 0.0135PU × 0.404 ÷ 0.8088
= 0.0067PU (0.74kV)
It becomes. Also, when the tap is changed by one step at the A substation,
The change in the 110 kV bus voltage at the A substation is
△ V110 ＝ △ n × X2 ÷ (X1 ＋ X2) ＝ 0.0135PU × 0.5813 ÷ 0.8088
= 0.0097PU (1.06kV)
And the change in 110 kV bus voltage at the B substation is
△ V110 ＝ △ n × X2 ÷ (X1 + X2) ＝ 0.0135PU × 0.404 ÷ 0.8088
0.0067PU (0.74kV)
It becomes.

  Based on the above, the reactive power (Q2) on the B substation side measured by the measuring unit B1 and the direction thereof are +5 MVar (5 MVar reactive power flows from the transmission line to the 110 kV bus of the B substation) Yes, if the reactive power (Q1) on the A substation side measured by the measuring unit A1 and the direction thereof is +10 MVar (10 MVar reactive power flows from the transmission line to the 110 kV bus of the A substation) A simulation of the case of adjustment by equipment and the case of adjustment by transformer tap is as follows.

[In case of adjustment by phase adjusting equipment]
Before adjustment by the phase adjusting equipment, if you look at the absolute value of the difference between both sides based on Q2 = Q1 + 4,
| Α | = | Q2- (Q1 + 4) |
= | 5- (10 + 4) |
= 9
It is. From this state, when one ShR (20 MVA) of the A substation is inserted, the reactive power on the A substation side is calculated, and Q1 = 10 + 20 × 0.5 = 20, and the reactive power on the B substation side is calculated. When calculated, Q2 = 5−20 × 0.5 = −5, and therefore | α |
| Α | = | −5− (20 + 4) |
= | -5-24 | = 29
It becomes. Therefore, when ShR is introduced at the A substation, the absolute value of the difference between the right side and the left side of the characteristic equation changes greatly from 9 to 29, and it can be predicted that the transmission loss cannot be reduced.

On the other hand, when one unit of ShR (20 MVA) of B substation is inserted, if the reactive power on the A substation side is calculated, Q1 = 10−20 × 0.3 = 4, and the B substation side When the reactive power is calculated, Q2 = 5 + 20 × 0.3 = 11, and therefore | α |
| Α | = | 11− (4 + 4) |
= | 11-8 | = 3
It becomes. Therefore, when ShR is introduced at the B substation, it can be predicted that the power transmission loss can be reduced by a small change from 9 to 3 (see FIG. 8).

[In case of adjustment by transformer tap]
Next, before the adjustment by the transformer tap, with reference to Q2 = Q1, the absolute value of the difference between both sides is
| Α | = | Q2-Q1 |
= | 5-10 |
= 5
It is. From this state, when the transformer tap of the A substation is lowered by one stage, the reactive power on the A substation side is Q1 = 10 + 16.7 = 26.7, and the reactive power on the B substation side is Q2 = 5- 16.7 = −11.7, so | α |
| Α | = | −11.7-26.7 |
= 38.4
It becomes. Therefore, when the transformer tap of the A substation is lowered, the absolute value of the difference between the right side and the left side of the characteristic equation changes greatly from 5 to 38.4, and it can be predicted that the transmission loss cannot be reduced.

Assuming that the transformer tap of B substation is lowered by one stage, the reactive power on the A substation side is Q1 = 10-16.7 = −6.7, and the reactive power on the B substation side is Q2 = 5 + 16.7 = 21.7, so | α |
| Α | = | 21.7 − (− 6.7) |
= 28.4
It becomes. Therefore, when the transformer tap of the B substation is lowered, the absolute value of the difference between the right side and the left side of the characteristic equation changes greatly from 5 to 28.4, and it can be predicted that the transmission loss cannot be reduced.

Therefore, after performing the above simulation in step 52, in step 54, when priorities are given,
(1) Adjustment by the phase adjusting equipment at B substation (9 → 3 and decrease of 6)
(2) Adjustment by adjusting equipment at A substation (9 → 29, increasing 20)
(3) Transformer tap down at B substation (5 → 28.4, 23.4 increase)
(4) Substation transformer tap down at A substation (5 → 38.4, increasing 33.4)
Thus, only (1) can reduce power transmission loss.
As a result of the voltage simulation performed in step 52, if it is determined in step 56 that the bus voltage is within the target set voltage range, the control (1) is executed in step 58 and must be within the voltage range. For example, since there is no other simulation that can reduce power transmission loss, the process proceeds to step 60, and a simulation is performed when the transformer taps of both substations are lowered.

  Also, assuming that 16.7 MVar reactive power is flowing from the A substation to the B substation, the reactive power measured by the measuring unit A1 and its direction are Q1 = −16.7 (A substation). 16.7 MVar reactive power flows from the 110 kV bus line toward the transmission line), and the reactive power measured by the measuring unit B1 and its direction are Q2 = + 16.7 (110 kV from the transmission line to the B substation) The reactive power of 16.7 MVar flows toward the bus), and the simulation of adjustment by the phase adjusting equipment and adjustment by the transformer tap is as follows.

[In case of adjustment by phase adjusting equipment]
Before adjustment by the phase adjusting equipment, if you look at the absolute value of the difference between both sides based on Q2 = Q1 + 4,
| Α | = | Q2- (Q1 + 4) |
= | 16.7 − (− 16.7 + 4) |
= 29.4
It is. From this state, when one ShR (20 MVA) of A substation is inserted, when calculating the reactive power on the A substation side, Q1 = −16.7 + 20 × 0.5 = −6.7, and B substation When the reactive power on the side is calculated, Q2 = 16.7−20 × 0.5 = 6.7, and therefore | α |
| Α | = | 6.7 − (− 6.7 + 4) |
= 9.4
It becomes. Therefore, when ShR is introduced at the A substation, the absolute value of the difference between the right side and the left side of the characteristic formula changes as small as 29.4 → 9.4, and it can be predicted that power transmission loss can be reduced.

On the other hand, assuming that one ShR (20 MVA) of the B substation is inserted, when calculating the reactive power on the A substation side, Q1 = −16.7−20 × 0.3 = −22. 7 and calculating the reactive power on the B substation side, Q2 = 16.7 + 20 × 0.3 = 22.7, and | α |
| Α | = | 22.7 − (− 22.7 + 4) |
= 41.4
It becomes. Therefore, if ShR of B substation is turned on, it will change largely from 29.4 to 41.4, and it can estimate that power transmission loss cannot be reduced.

[In case of adjustment by transformer tap]
Next, before the adjustment by the transformer tap, with reference to Q2 = Q1, the absolute value of the difference between both sides is
| Α | = | Q2-Q1 |
= | 16.7 − (− 16.7) |
= 33.4
It is. From this state, when the transformer tap of the A substation is lowered by one stage, the reactive power on the A substation side is Q1 = −16.7 + 16.7 = 0, and the reactive power on the B substation side is Q2 = 16 .7−16.7 = 0, so | α |
| Α | = | 0-0 | = 0
It becomes. Therefore, when the transformer tap of the A substation is lowered, the absolute value of the difference between the right side and the left side of the characteristic equation changes from 33.4 to 0, and it can be predicted that the power transmission loss can be reduced.

Also, assuming that the transformer tap at B substation is lowered by one stage, the reactive power at A substation side is Q1 = -16.7-16.7 = -33.4, and the invalidity at B substation side The power is Q2 = 16.7 + 16.7 = 33.4, so | α |
| Α | = | 33.4 − (− 33.4) |
= 66.8
It becomes. Therefore, when the transformer tap of the B substation is lowered, the absolute value of the difference between the right side and the left side of the characteristic equation changes greatly from 33.4 to 66.8, and it can be predicted that the transmission loss cannot be reduced.

Therefore, after performing the above simulation in step 52, in step 54, when priorities are given,
(1) Transformer tap lowering at substation A (33.4 → 0, 33.4 decrease)
(2) Adjustment by adjusting equipment at substation A (29.4 → 9.4, 20.0 decrease)
(3) Adjustment by phase adjusting equipment at substation B (29.4 → 41.4, an increase of 12.0)
(4) Transformer tap lowering at B substation (33.4 → 66.8, increasing 33.4)
Thus, (1) and (2) can reduce power transmission loss. Among them, the effect of reducing power transmission loss is greatest when the transformer tap lowering of A substation (1) is performed. Therefore, as a result of the voltage simulation performed in step 52, if it is determined in step 56 that the bus voltage is within the target set voltage range, the control (1) is executed in step 58, and is within the target set voltage range. If it is determined that it does not fit, the control (2) having the next highest power transmission loss reduction effect is selected, and if the bus voltage is within the target set voltage range, the control (2) is performed. In step 58, it is executed. In the control of (2), if it is determined that the bus voltage does not fall within the target set voltage range, there is no other simulation that can reduce power transmission loss. A simulation is performed when the transformer tap is lowered.

  Therefore, according to the above control, when the bus voltage deviates from the target set voltage, first, the transformer taps are changed separately from the case where the phase adjusting equipment of each substation is controlled separately. Simulation is performed, and the voltage change of the bus voltage in each case is simulated. As a result of these simulations, there is a simulation in which the transmission loss can be reduced and the voltage falls within the target set voltage. Among them, the phase adjusting equipment or transformer tap is controlled so that it becomes the simulation setting state with the highest power loss reduction effect, and there is no simulation that can reduce power transmission loss, or power transmission loss can be reduced, If there is no simulation where the bus voltage is within the target set voltage, the taps of both transformers can be changed at the same time. When a voltage change simulation is performed and it is determined that the bus voltage can be within the target voltage range, control is performed to change the transformer taps at both substations, and the bus voltage is within the target voltage range. If it is determined that it does not fall within the range, it is not possible to cope with the control of the phase adjusting equipment or the transformer tap, so the operator is notified.

Therefore, by performing the above control,
(I) Power transmission loss can be reduced by adjusting the voltage within the voltage operating range.
(Ii) Reduction of power transmission loss can reduce generator output and fuel cost.
(Iii) CO2 emissions can be reduced by reducing transmission loss.
(Iv) The power loss of the equipment itself can be reduced by the appropriate timing of phase adjustment equipment (capacitor, reactor).
It is possible to obtain the effects as described above.

  In the above-described embodiment, the different voltage loop system (annular system) has been described. However, the above-described configuration may be applied to a loop system (annular system) of the same voltage class. When applied to a loop system (annular system) of the same voltage class, there is no transformer, so control is performed to maintain the bus voltage at the target set voltage while reducing power transmission loss only by the above-mentioned phase adjusting equipment. When the bus voltage cannot be kept within the nominal setting voltage range or when the power transmission loss cannot be reduced, the operator should be notified.

1 A Substation 2 B Substation 3 B Connection Line 4 AB Line 5 C Substation 6 AC Line 7 C Line

Claims (5)

A voltage reactive power control system that maintains a bus line voltage of a loop system configured to supply power by configuring a transmission line in a loop shape via a plurality of power substations,
A bus voltage measuring means for measuring a bus voltage for each power generation substation;
Reactive power measuring means for measuring reactive power and its direction for each power generation substation;
Phase adjustment equipment state detection means for detecting the state of the phase adjustment equipment provided for each of the substations,
When the bus voltage exceeds the target set voltage range, the reactive power amount calculating means for calculating the reactive power amount when separately turning on or opening the phase adjusting equipment of each generating substation of the loop system,
Based on the reactive power calculated by the reactive power calculation means, a power transmission loss simulation means for simulating the presence or absence of reduction of power transmission loss,
Voltage simulation means for simulating whether or not the bus voltage falls within a target set voltage range when the phase adjusting equipment of each power generation substation is turned on or opened;
Setting in which the simulation is performed when there is a simulation in which it is determined that the transmission loss can be reduced by the transmission loss simulation unit and the bus voltage is determined to be within a target set voltage range by the voltage simulation unit. A voltage reactive power control system comprising: control means for controlling the phase adjusting equipment so as to be in a state. A tap state detection means for detecting a tap state of a transformer provided for each power generation substation,
The reactive energy calculation means includes means for calculating the reactive energy when the bus voltage exceeds a target set voltage range and the transformer taps of each generating substation of the loop system are changed separately,
The power transmission loss simulation means includes means for simulating the presence or absence of a reduction in power transmission loss based on the reactive power amount when the transformer tap calculated by the reactive power amount calculation means is changed,
The voltage simulation means includes means for determining whether the bus voltage falls within a target set voltage range when the transformer tap is changed,
The control means determines that the power transmission loss can be reduced after the tap change by the power transmission loss simulation means, and a simulation in which the bus voltage is determined to be within the target set voltage range after the tap change by the voltage simulation means. 2. The voltage reactive power control system according to claim 1, further comprising a control for switching the transformer tap so as to be in a setting state in which the simulation is performed.   The control means controls the power transmission loss simulation means so that when there are a plurality of simulations capable of reducing the power transmission loss, the control means performs a simulation setting state having the highest power transmission loss reduction effect. Or the voltage reactive power control system of 2. As a result of simulation by the power transmission loss simulation means, it is determined that power transmission loss can be reduced, and as a result of simulation by the voltage simulation means, there is no simulation determined that the bus voltage falls within the target set voltage range The second voltage simulation means for simulating whether or not the bus voltage is within the target set voltage range when the primary taps of the transformers of the power generation substations of the loop system are simultaneously lowered or raised. When,
When it is determined by the simulation of the second voltage simulation means that the bus voltage is within the target set voltage range, the transformer of each substation in the loop system is set so that the simulation is performed. The voltage reactive power control system according to any one of claims 1 to 3, further comprising: a second control unit that switches the primary side tap. 5. The voltage according to claim 4, further comprising notification means for notifying an operator when it is determined that the bus voltage does not fall within the target set voltage range as a result of simulation by the second voltage simulation means. Reactive power control system.

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