JP2004222476A - Automatic voltage regulator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To make it possible to supply a proper voltage with an automatic voltage regulator of one kind irrespective of power usage condition of its installation point. <P>SOLUTION: This automatic voltage regulator is provided with voltage controlling systems inside a controller 5 that outputs a control command to a tap changer 3 in such a way that a current secondary voltage V<SB>L</SB>for the installation point of the automatic voltage regulator is brought close to a reference voltage V<SB>S</SB>. In this regulator, a plurality of the voltage controlling systems are provided inside the controller and it is configured that one of the systems is selectable by an operating portion 14. The voltage controlling system is an integrated value-time value controlling system that outputs a control command when a voltage exceeds an operating set point of whichever controlling system of an integrated value controlling system and a time value controlling system. The voltage controlling system and the operating set point may be revised automatically based on a result of computer simulation. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

【００３１】
子局８は、図示しない親局と電圧調整継電装置７との間に介在し、電気通信回線で接続されており、親局と電圧調整継電装置７との間で情報を受け渡しできるように、送受信するものである。
【００３２】
別の実施形態としては図１１及び図１２に示すように、制御装置内に電圧制御方式を複数有すると共に、各電圧制御方式の動作設定値を複数有し、電圧制御方式及びその動作設定値の全パターンのうち一つを運転用設定の初期値として用いると共に、運転中に実測した過去の時系列データをシミュレーション用のデータとして利用し、電圧制御方式と動作設定値の全パターンで運転した場合のタップ切り換え状況をコンピュータで定期的にシミュレーションし、二次電圧が基準電圧を逸脱する時間が短いパターンをシミュレーション結果に基づいて選定し、その選定したパターンに運転用設定を自動的に更新するものが挙げられる。
【００３３】
シミュレーションの仕方の一例を以下に詳しく説明する。まず、電圧制御方式及びその動作設定値の運転用設定の全パターンを操作部１４で記憶装置（図示省略）に入力すると共に、そのうちの一つを運転用設定の初期値とし、全パターンを表示したテーブル１６を図１３に示すように作成する。初期値の状態で運転している自動電圧調整装置では、先の実施形態で説明したように、二次電圧、二次電流、それらの位相、タップ電圧の時系列データを一定時間（例えば１秒）毎にサンプリングしているので、それら時系列データ１７を図１４に示すように記憶装置に記憶しておく。そして、運転用設定の更新日になったか（例えば前回の更新日から３ヶ月経過したか）否かを判定し、更新日の場合は、記憶した時系列データ１７の全期間又は一定期間（例えば更新日よりも一週間前から前日までの一週間分）のデータを抽出する。その抽出データから以下の式、即ち、Ｖ_１＝Ｖ_２×Ｖｔａｐ／Ｖ_０により、１次電圧Ｖ_１の時系列データ１８を算出する。Ｖｔａｐ：タップ電圧（定格二次電圧に対応する一次電圧）。
【００３４】
続いて、テーブル１６に入力した全パターンについて、タップの切り換え状況をコンピュータでシミュレーションする。シミュレーションでは、抽出した各種の時系列データと各種の設定値を利用する。各種の設定値とは、図１５の表に示すように、電圧降下補償機能（ＬＤＣ）の計算に用いる定格二次電圧、定格二次電流、基準電圧、ＬＤＣ抵抗分、ＬＤＣリアクタンス分、不感帯用設定値、タップ動作時間等である。そして、図１６に示すように、パターン毎にタップ電圧、二次電圧、目標地点電圧、電圧偏差、及び電圧偏差の差分を算出すると共に、昇圧・降圧のタップ切り換えの有無等を計算する。二次電圧はＶ_２’＝Ｖ_１×Ｖ_０／Ｖｔａｐ’の式より求まるのでタップ電圧のデータが計算上必用とされるが、計算には抽出したタップ電圧のデータのうち最初のもののみ利用する。なお、Ｖ_２’及びＶｔａｐ’の「’」は、シミュレーション結果で算出した値という意味である。目標地点電圧の計算は、段落番号３０中で記載した数式１を用いる。シミュレーションするパターンが積分値制御方式の場合は、前述したように図４のフローチャートに示す手順に従って、昇圧側積分値、降圧側積分値を算出したり、符号が正か負で連続している電圧偏差の差分の、積分値（連続電圧超過偏差積分値）や時間（連続電圧超過時間）を算出し、算出したシミュレーション結果を記憶装置に記憶する。
【００３５】
二次電圧が基準電圧を逸脱する時間が短いパターンをシミュレーション結果に基づいて選定する仕方を、図１７のフローチャートを参照して説明する。選定前に、連続電圧超過偏差積分値の最大値（一週間分のデータのうちの最大値）の目標値を操作部から記憶装置に入力しておく。まず第一段階の判定としては、各パターンの連続電圧超過偏差積分値の最大値を抽出し、その最大値が目標値以下のパターンが存在するか否かを判定する。具体的には、各パターン毎に連続電圧超過偏差積分値の正、負のデータを絶対値とし、その絶対値の最大値を抽出し、各パターンの最大値を目標値と比較する。目標値以下のパターンが存在しない場合は、最大値が目標値に最も近いパターンが二つ以上存在するか否かを判定する。存在しない場合、即ち、最大値が目標値に最も近いパターンが一つしかない場合は、そのパターンを選定する。パターンが複数存在する場合、及び最大値が目標値以下のパターンが存在する場合は、第二段階の判定に移行する。
【００３６】
第二段階の判定では、該当する各パターンのタップ動作回数を算出し、タップ動作回数が最少のパターンが二つ以上存在するか否かの判定をする。具体的には該当する各パターンについてタップ動作回数（昇圧指令の回数と降圧指令の回数の合計値）を算出し、該当するパターンが複数の場合は、複数のパターンのうちタップ動作回数の最も少ないものを抽出する。但し、該当するパターンが一つしかない場合は、タップ動作回数を算出することなく、そのパターンを選定する。タップ動作回数が最少のパターンが二つ以上存在する場合は、第三段階の判定に移行する。
【００３７】
第三段階の判定では、それらパターンのうちの連続電圧超過時間の最大値を比較し、その最大値が最小のパターンが二つ以上存在するか否かを判定する。一つしかない場合は、そのパターンを選定する。連続電圧超過時間の最大値が最小のパターンが二つ以上存在する場合は、優劣がないので、そのうちの何れか一つのパターンを選定する。そして、その選定したパターンを運転用設定として、次の更新日まで使用する。
【００３８】
また、連続電圧超過時間の最大値が最小のパターンが二つ以上存在する場合に、そのうちの一つのパターンが運転用設定として現在使用中のパターンと同じ場合は、現在使用中のパターンを選定しても良い。同様に、連続電圧超過時間の最大値が最小のパターンが二つ以上存在する場合に、そのうちの一つのパターンの電圧制御方式が、運転用設定として現在使用中のパターンと同じ電圧制御方式のときには、現在使用中のパターンを選定しても良い。
【００３９】
全パターンについてのシミュレーション結果が、例えば図１８に示すように得られた場合に、上述した三段階の判定を用いて、運転用設定の更新用パターンを選定してみる。連続電圧超過偏差積分値の最大値の目標値を１０００（％・ｓ）と仮定すると、第一段階の判定では、連続電圧超過偏差積分値の最大値が１０００以下のパターンが三つ抽出され（積分値制御方式で動作設定値が２０と４０のもの、及び時間値制御方式で動作設定値が４０のもの）、第二段階の判定でタップ動作回数が最少のパターンが一つ（積分値制御方式で動作設定値が４０のもの（太枠で囲んだもの））選定される。
【００４０】
上述した要領で選定すれば、配電線の状況に応じて適正な電圧が供給できると共に、真空バルブ式タップ切換器を利用した場合に、タップ動作回数を抑えることができ、真空バルブの使用期間を延長できる。
【００４１】
別の選定の仕方としては、判定の対象として用いる目標値が連続電圧超過偏差積分値の最大値でなくても良い。つまり、前述した仕方では、抽出データが一週間分あれば、一週間分のデータのうちの最大値について、目標値を定めていたが、抽出した一週間分のデータについて一日ごとに最大値を抽出し、一週間分の最大値についての平均値を取ることにより、その平均値について目標値を定めても良い。また、一週間分のデータについて電圧偏差の差分の合計値を一日ごとに算出し、一週間分の合計値についての平均値を算出することにより、その平均値を目標値として定めても良い。なお、電圧偏差の差分の合計値を一日ごとに算出するには、一日分の電圧偏差の差分について正の分と負の分で別々に合計を出し、正の分の合計値と負の分の合計値のそれぞれの絶対値を合計することとする。
【００４２】
本発明は上記実施形態に限定されるものではない。例えば、制御装置５内に電圧制御方式を複数備える一例としては、積分値制御方式、時間値制御方式、積分値一時間値制御方式のうち少なくとも２つを備えるものであってもよい。また、電圧制御方式は、４つ以上を備えるものであっても良い。さらに、上述した電圧制御方式での計算をマイコンで計算するものに限らず、アナログ回路を用いて計算しても良い。
【００４３】
【発明の効果】
本発明は、複数の電圧制御方式を制御装置内に備え、操作部でそのうちの一方式を選択可能にしてあるので、設置点に最も適当と考えられる方式を選択できる。従って、一種類の自動電圧調整装置で設置点に対応した適正な電圧を供給できる。
【００４４】
請求項２記載の発明は、積分値制御方式と時間値制御方式のうち、いずれかの制御方式の動作設定値を超えたときに制御指令を出力する積分値一時間値制御方式を用いているので、緩やかな電圧変動の場合に、積分値制御方式では動作設定値を超えなくても、時間値制御方式での動作設定値（動作設定時間）を超えればタップ切り換え指令が出力される。また、急激な電圧変動があった場合は、時間値制御方式での動作設定時間を超えなくても、積分値制御方式で動作設定値を超えればタップ切り換え指令が出力される。従って、時間値制御方式や積分値制御方式のみ利用するものに比べて、タップの切り換えが迅速になり、適正な電圧を供給できるようなる。
【図面の簡単な説明】
【図１】本発明の積分値一時間値制御方式を示すフローチャートである。
【図２】積分値一時間値制御方式の積分値制御を示すフローチャートである。
【図３】積分値一時間値制御方式の時間値制御を示すフローチャートである。
【図４】積分値制御方式を示すフローチャートである。
【図５】時間値制御方式を示すフローチャートである。
【図６】差電圧を理解するグラフである。
【図７】積分値制御での積分の仕方を理解するグラフである。
【図８】時間値制御でのカウントの仕方を理解するグラフである。
【図９】自動電圧調整装置を示すブロック図である。
【図１０】電圧調整継電装置を示すブロック図である。
【図１１】運転用設定を自動的に更新するフローチャートである。
【図１２】シミュレーション実行部分等を詳細に書いたフローチャートである。
【図１３】電圧制御方式と動作設定値の全パターンを示すテーブルである。
【図１４】時系列データを示す表である。
【図１５】各種の設定値を示す表である。
【図１６】シミュレーション結果を示す表である。
【図１７】シミュレーション結果に基づいて所望のパターンを選定する仕方を示すフローチャートである。
【図１８】全パターンのシミュレーション結果を示す表である。
【符号の説明】
３ タップ切換器
５ 制御装置
１４ 操作部
Ｖ_Ｌ 二次電圧
Ｖ_Ｓ 基準電圧
Ｋ、Ｚ 不感帯
Ｔ、Ｙ 動作設定値[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an automatic voltage regulator that adapts to voltage fluctuations in distribution lines.
[0002]
[Prior art]
The automatic voltage regulator outputs a tap switching command to the tap changer so that the current secondary voltage for the installation point approaches the target reference voltage, and when the secondary voltage satisfies a certain condition. A switching command is output. As a voltage control method for satisfying the condition, three types of methods are known: integral value control, time value control, and moving average value control.
[0003]
The integral value control method uses the reference voltage V_SAnd the current secondary voltage V_LWhen the difference voltage deviates from a preset dead zone, the deviation is time-integrated, and a control command is output when the integrated value exceeds an operation set value. The dead zone is provided to prevent hunting, and the automatic voltage regulator does not operate with a certain voltage width around the reference voltage.
[0004]
The time value control method outputs a control command when the time during which the difference voltage continuously deviates from the dead zone exceeds an operation set value.
[0005]
In the moving average control method, an average of a difference when the difference voltage goes out of a dead zone is set within a set time, and a control command is output when the average exceeds an operation set value.
[0006]
[Problems to be solved by the invention]
When the integral value control method is used, since the control command is output based on the integral value, the operation time is short when the difference voltage between the reference voltage and the current secondary voltage is large, but is small when the difference voltage is small. , And thus deviates from the reference voltage continuously for a long time.
[0007]
When the time value control method is used, the control command is output when the time during which the difference voltage deviates from the dead zone continues for the operation set time or more, so that even if the difference voltage is large, it is not controlled unless the operation set time has elapsed, When the state where the difference voltage enters the dead zone and the state where it deviates in the + direction are repeated within the operation set time, or when the state where the difference voltage enters the dead zone and the state where the difference voltage deviates in the negative direction are repeated within the operation set time, There is a problem that the time for deviating from the reference voltage becomes long.
[0008]
When the moving average value control method is used, a control command is output based on the average value of the difference voltage, so that there is a problem that the time to deviate from the reference voltage generally becomes long.
[0009]
Conventional automatic voltage regulators use only one of the control methods described above. Therefore, when installing an automatic voltage regulator, it is desirable to select one that uses the most appropriate control method for the power usage status at the installation point. However, manufacturing and stocking a plurality of types of automatic voltage regulators is inconvenient in terms of cost and stock space. For this reason, there is a case where only an automatic voltage regulator of one control method is manufactured and installed irrespective of the power use condition. Then, the above-described problem occurs.
[0010]
The present invention has been developed in consideration of the above-described circumstances, and a problem to be solved is to make it possible to supply an appropriate voltage with one type of automatic voltage regulator, regardless of the power usage status of the installation location. .
[0011]
[Means for Solving the Problems]
According to the first aspect of the present invention, the current secondary voltage V with respect to the installation point of the automatic voltage regulator is provided._LIs the reference voltage V_SIn the automatic voltage regulator equipped with a voltage control method that outputs a control command to the tap changer so that it approaches the control device, the control device has a plurality of voltage control methods and one of them can be selected by the operation unit It is characterized by being provided.
[0012]
The voltage control method uses the current secondary voltage V_LIs the reference voltage V_S, The secondary voltage V_LAnd reference voltage V_SAny method may be used as long as it outputs a tap switching command under a constant condition based on the above, and examples thereof include an integral value control method, a time value control method, a moving average value control method, and an integral value-one-time value control method.
[0013]
According to a second aspect of the present invention, the voltage control method is an integral value-time value control that outputs a control command when an operation set value of one of the integral value control method and the time value control method is exceeded. The integral value control method obtains the difference voltage between the reference voltage and the current secondary voltage, and evaluates the difference voltage or a replacement value based on the difference voltage, and the evaluation object falls outside a preset dead zone. In this case, the difference is time-integrated, and a control command is output when the integrated value exceeds the operation set value.The time value control method operates when the evaluation target continuously deviates from the dead zone. It is characterized by outputting a control command when a set value is exceeded.
[0014]
When the evaluation target is a difference voltage, for example, the reference voltage: 4 V, the dead zone: ± 2 V, the sampling time of the secondary voltage: 1 second, and the sampled secondary voltages are: 8 V, 7 V, 6 V, 7 V, and 8 V in this order. Assuming that the difference voltage between the sampled secondary voltage and the reference voltage is 4 V, 3 V, 2 V, 3 V, and 4 V, and the difference in which the difference voltage is out of the dead band is 2 V, 1 V, 0 V, 1 V, and 2 V. The time integration value of the difference deviating is 6 (VS). In addition, the replacement value based on the difference voltage is set as an evaluation target, for example, a value obtained when the difference voltage is substituted as a variable into a certain function formula, and more specifically, a ratio of the difference voltage to the reference voltage, That is, a voltage deviation is an example. Furthermore, the dead zone for integral value control and the dead zone for time value control do not necessarily have to match.
[0015]
According to a third aspect of the present invention, there is provided an automatic voltage regulator including a voltage control method for outputting a control command to a tap changer so that a current secondary voltage at an installation point of the automatic voltage regulator approaches a reference voltage. In the control device, a plurality of voltage control methods are provided in the control device, and each voltage control method includes a plurality of operation setting values serving as conditions when outputting a control command, and among all patterns of the voltage control method and the operation setting values, One is used as the initial value of the operation setting, the time series data of the secondary voltage, the secondary current, the phase and the tap voltage are stored during the operation, and the voltage control method and the operation set value are based on the time series data. Computer simulation of the tap change situation in all patterns of the above, automatically updates the voltage control method and the operation setting of its operation set value based on the simulation result It is characterized in.
[0016]
BEST MODE FOR CARRYING OUT THE INVENTION
As shown in FIG. 9, the automatic voltage regulator according to the present invention includes a tap changer (hereinafter referred to as LTC) 3 and a voltage regulating transformer 20 between primary distribution lines 1a and 1b and secondary distribution lines 2a and 2b. And a voltage detection transformer (VT) 4 is connected in parallel to the secondary side distribution lines 2a and 2b, an output side wiring of the VT 4 is connected to the control device 5, and a current detection transformer (CT) for the secondary side distribution line is connected. 6) The secondary side wiring is connected to the control device 5. Further, the control device 5 is connected to the LTC3, receives a control command signal including a boost / step-down command or the like from the control device 5 at the LTC3, and transmits a state signal (for example, a tap voltage signal or the like) from the LTC3 to the control device. 5 receives.
[0017]
The control device 5 mainly includes a voltage adjustment relay device 7 and a slave station 8. As shown in FIG. 10, the voltage adjustment relay device 7 samples the input voltages from the CT 6 and the VT 4 by the analog circuit 9 and digitizes the voltage data by the A / D converter 10 into an arithmetic processing unit 11 comprising a microcomputer. And outputs a tap switching command to the LTC3 when certain conditions are satisfied. In addition, a signal (for example, ON / OFF of each tap) received by the photocoupler 12 for ON / OFF of the limit switch from the LTC 3, a signal received by the relay 13 for an input signal from the slave station 8, a signal from the operation unit 14 Is input to the arithmetic processing unit 11, and outputs the voltage, current, CPU error, and the like obtained by the arithmetic processing unit 11 to the display unit 15.
[0018]
The analog circuit 9 includes an amplifier circuit AMP, a filter circuit LPF, a sample-and-hold circuit S / H, and a multiplexer MPX. The analog circuit 9 amplifies the voltage obtained from the CT6 or VT4 and does not require an LPF that provides a large attenuation near the sampling frequency. The components are removed, sampled, and output to the A / D converter 10 via the multiplexer.
[0019]
The arithmetic processing unit 11 mainly has an automatic voltage adjustment function and a voltage drop compensation function.
[0020]
The automatic voltage adjustment function is used when the power is transmitted from the primary side distribution line to the secondary side distribution line._LIs the reference voltage V_S, Three voltage control systems for outputting a tap switching command to the LTC3 when a predetermined condition is satisfied, and any one of the three systems is provided to be selectable by the operation unit 14 described above. The operation unit 14 also inputs various settings required by the arithmetic processing unit 11, for example, various settings such as an operation setting value for tap switching, a dead band setting value, and a reference voltage.
[0021]
There are three voltage control methods: integral value control, time value control, and integral value-time value control. Although not shown, the operation unit 14 is provided with an ON / OFF switch for each control method, whereby one method can be selected. When the switches of two or more control methods are turned ON, only one method is used, and the integral value control method, the time value control method, and the integral value-time value control method are prioritized in this order.
[0022]
In the integral value-one-time value control method, as shown in the flowchart of FIG. 1, first, integral value control is performed, and then it is determined whether or not a flag is turned on. When the flag is ON, it means that a control command has been output to the LTC 3 by the integral value control, and the control command is a command for switching the tap by one tap in the step-up direction or a command for switching in the step-down direction. When the flag is output, the integral value control data and the time value control count are reset without performing the time value control, and the process returns to the integral value control. If the flag is not output, the process proceeds to the time value control, and it is determined whether the flag in the time value control has been turned ON. If the flag is not output here, the process returns to the integral value control again. When the flag is output, the integral value control data and the time value control count are reset, and the process returns to the integral value control.
[0023]
The integral value control is performed in the following manner. As shown in FIG. 6, the secondary voltage V_LmAnd reference voltage V_S, And then, as shown in FIG._S, Ie, the voltage deviation V_HmExceeds the dead zone K, the difference ΔV_mIs integrated over time, and a control command is output when the integrated value exceeds the operation set value. That is, the voltage deviation V_HmIs a target of evaluation as to whether or not exceeds the dead zone. Here, m means the order of the sampled secondary voltage. In FIG. 6, the current secondary voltage V_LIs the reference voltage V_SSince it rises more slowly than the secondary voltage V_LOutputs a command to reduce the voltage by one tap when the above condition is satisfied, and the tap switcher 3 switches the taps based on the command. The dead zone is set to K% on the step-down side (+) and the step-up side (-).
[0024]
The above procedure will be described in detail with reference to the flowchart of FIG._mAsk for. ΔV_mVoltage deviation V which is an element for determining_HmIs determined by the following equation.
V_Hm(%) = (V_Lm-V_S) × 100 / V_S
And ΔV_mIs obtained by subtracting the setting value K for the dead zone from the voltage deviation, and is obtained by the following equation.
ΔV_m= V_Hm-K
However, in the calculation, the numerical value to be substituted for K is V_HmIs determined to be positive or negative. If positive, a positive value is substituted for K, and if negative, a negative value is substituted for K as a set value.
Next, integration on the boost side is performed first. ΔV up to the previous time_mS, which is the integral of_Rm-1Is the difference ΔV_mIs added, and the current integrated value S_RAsk for. In the case of boosting, since the secondary voltage is lower than the reference voltage, V_HmIs negative, the addition process is performed by multiplying by minus. And the integral value S_RIs negative, the integral S_RTo 0, and S_RIs the m-th integration value S_RmRewrite to When the integral value is 0 or more, the integral value S_RIs the m-th integration value S_RmRewrite to Subsequently, the integral S_RmIs greater than or equal to the operation set value T. If it exceeds, an instruction to switch to the step-up side by one tap is output to the tap changer 3, and the process proceeds to the integration on the step-down side. Also, when the integral value does not exceed the operation set value T, the process directly proceeds to the step-down integration.
[0025]
The integration on the buck side is the difference ΔV_mS, which is the integral of_Lm-1Is the difference ΔV_mIs added, and the current integrated value S_LmAsk for. After that, the same procedure as the integration on the boost side is performed, and the integration value S_LmIt is determined whether or not exceeds the operation set value T, and if so, an instruction to switch to the step-down side by one tap is output to the tap changer 3.
[0026]
Time value control is performed in the following manner. As shown in FIG. 8, a dead zone Z for time value control independent of the dead zone K for integral value control is formed, and the time continuously exceeding the dedicated dead zone Z in the same direction is equal to the operation set value. When it exceeds, a tap switching command is output.
[0027]
Explaining with reference to the flowchart of FIG._HmIs obtained as described above, and then the voltage deviation V_HmIs greater than or equal to 0, and if greater than 0, the voltage deviation V_HmIs determined to be greater than + Z of the dedicated dead zone. If it has exceeded, the process proceeds to the determination as to whether or not the exceeding state is continuous. If not, the count is reset. If the difference is less than 0, the voltage deviation V_HmIs determined to exceed (below) the dedicated dead zone -Z, and if so, the process proceeds to determine whether the excess state is continuous or not. Resets the count. Here, a positive value is substituted for Z as a set value. If the state of exceeding the dead zone in the same direction is not continuous, counting is started. If the state is continuous, the process proceeds to determination as to whether or not the count exceeds the operation set value (operation set time) Y seconds. . If the count is less than Y seconds, the process moves to the flowchart of FIG. When the time is longer than Y seconds, the voltage deviation V_HmIs positive or negative, and outputs a step-down command if positive, and outputs a step-up command if negative.
[0028]
The pure integral value control method is shown in the flowchart of FIG. 4, and is similar to the integral value control in the integral value-one-time value control method described above. Integrated value S for boosting_RmAnd step-down integral S_LmIs reset immediately before the step-up command or the step-down command, or the step-down integration value S_LmΔV if No in the determination of whether or not is the operation set value_mTo the processing for obtaining ΔV._mThe process is different from the process described above.
[0029]
Similarly, the pure time value control method is shown in the flowchart of FIG. 5, and is similar to the time value control in the integral value-one time value control method described above. The process of resetting the count is immediately after the process of determining whether the count is less than Y seconds, or the voltage deviation V after the boost command and the step-down command._HmAnd the voltage deviation V after counting starts._HmThe process is different from the process described above.
[0030]
The voltage drop compensation function (LDC) compensates for the voltage drop due to the line impedance of the secondary distribution line, and is provided to switch the tap of the LTC3 to the step-up side by the voltage drop. The effective value of the voltage and current detected by CT6 and VT4 (V_rms, I_rms) And the phase (cos θ, sin θ) are calculated by the following equations. Voltage at target point: V_L, Resistance:% r, reactance:% x, rated secondary voltage V₀, Rated secondary current I₀And
(Equation 1)

[0031]
The slave station 8 is interposed between a master station (not shown) and the voltage adjustment relay device 7 and connected by a telecommunication line so that information can be transferred between the master station and the voltage adjustment relay device 7. In addition, it transmits and receives.
[0032]
As another embodiment, as shown in FIGS. 11 and 12, the control device has a plurality of voltage control methods, has a plurality of operation setting values of each voltage control method, and has the voltage control method and the operation setting value of the operation setting value. When one of all the patterns is used as the initial value of the operation setting and the past time series data measured during operation is used as the data for simulation, and the operation is performed with all the patterns of the voltage control method and the operation set value That periodically simulates the tap switching status of the computer with a computer, selects a pattern in which the secondary voltage deviates from the reference voltage in a short time based on the simulation result, and automatically updates the operating settings to the selected pattern. Is mentioned.
[0033]
An example of a simulation method will be described in detail below. First, all the patterns of the operation setting of the voltage control method and the operation set value are input to a storage device (not shown) by the operation unit 14, and one of them is set as the initial value of the operation setting, and all patterns are displayed The created table 16 is created as shown in FIG. In the automatic voltage regulator operating in the initial value state, as described in the previous embodiment, the time series data of the secondary voltage, the secondary current, their phase, and the tap voltage are stored for a certain time (for example, 1 second). ), The time series data 17 is stored in a storage device as shown in FIG. Then, it is determined whether or not the update date of the driving setting has been reached (for example, whether three months have elapsed since the last update date). In the case of the update date, the entire period of the stored time-series data 17 or a fixed period (for example, Data from one week before the update date to one week before the update date) is extracted. From the extracted data, the following equation:₁= V₂× Vtap / V₀The primary voltage V₁Is calculated. Vtap: tap voltage (primary voltage corresponding to rated secondary voltage).
[0034]
Subsequently, for all the patterns input to the table 16, the switching state of the tap is simulated by the computer. In the simulation, various extracted time-series data and various set values are used. The various set values are, as shown in the table of FIG. 15, a rated secondary voltage, a rated secondary current, a reference voltage, an LDC resistance component, an LDC reactance component, and a dead band for calculation of the voltage drop compensation function (LDC). The setting value, tap operation time, and the like. Then, as shown in FIG. 16, the tap voltage, the secondary voltage, the target point voltage, the voltage deviation, and the difference between the voltage deviations are calculated for each pattern, and the presence / absence of step-up / step-down tap switching is calculated. The secondary voltage is V₂’= V₁× V₀/ Vtap ', which is necessary for the calculation of tap voltage data, but only the first extracted tap voltage data is used for calculation. Note that V₂"" Of "and Vtap" means a value calculated based on a simulation result. The calculation of the target point voltage uses Equation 1 described in paragraph number 30. In the case where the pattern to be simulated is the integral value control method, as described above, the step-up side integral value and the step-down side integral value are calculated according to the procedure shown in the flowchart of FIG. An integral value (continuous voltage excess deviation integral value) and time (continuous voltage excess time) of the difference of the deviation are calculated, and the calculated simulation result is stored in the storage device.
[0035]
A method for selecting a pattern in which the secondary voltage deviates from the reference voltage in a short time based on the simulation result will be described with reference to the flowchart in FIG. Before the selection, the target value of the maximum value of the continuous voltage excess deviation integrated value (the maximum value of one week's data) is input from the operation unit to the storage device. First, as a determination in the first stage, the maximum value of the continuous voltage excess deviation integrated value of each pattern is extracted, and it is determined whether there is a pattern whose maximum value is equal to or less than the target value. Specifically, the positive and negative data of the continuous voltage excess deviation integrated value are set as absolute values for each pattern, the maximum value of the absolute value is extracted, and the maximum value of each pattern is compared with a target value. If there is no pattern below the target value, it is determined whether or not there are two or more patterns whose maximum value is closest to the target value. If there is no such pattern, that is, if there is only one pattern whose maximum value is closest to the target value, that pattern is selected. When there are a plurality of patterns, and when there is a pattern whose maximum value is equal to or less than the target value, the process proceeds to the second stage determination.
[0036]
In the determination of the second stage, the number of tap operations of each corresponding pattern is calculated, and it is determined whether or not there are two or more patterns having the minimum number of tap operations. Specifically, the number of tap operations (the total value of the number of times of the boost command and the number of times of the step-down command) is calculated for each applicable pattern, and when there are a plurality of applicable patterns, the number of tap operations is the least among the plurality of patterns. Extract things. However, when there is only one corresponding pattern, that pattern is selected without calculating the number of tap operations. If there are two or more patterns with the least number of tap operations, the process proceeds to the third-stage determination.
[0037]
In the determination of the third stage, the maximum value of the continuous voltage excess time among the patterns is compared, and it is determined whether or not there are two or more patterns having the minimum maximum values. If there is only one, select that pattern. If there are two or more patterns having the minimum continuous voltage excess time, there is no difference, so any one of the patterns is selected. Then, the selected pattern is used as an operation setting until the next update date.
[0038]
If there are two or more patterns with the minimum continuous voltage excess time, and one of the patterns is the same as the pattern currently used as the operation setting, select the pattern currently used. May be. Similarly, when there are two or more patterns having the minimum continuous voltage excess time minimum, and when the voltage control method of one of the patterns is the same voltage control method as the pattern currently used as the operation setting, Alternatively, the currently used pattern may be selected.
[0039]
When simulation results for all patterns are obtained, for example, as shown in FIG. 18, a pattern for updating the driving setting is selected using the above-described three-stage determination. Assuming that the target value of the maximum value of the continuous voltage excess deviation integrated value is 1000 (% · s), three patterns in which the maximum value of the continuous voltage excess deviation integrated value is 1000 or less are extracted in the first stage determination ( In the integral value control method, the operation set values are 20 and 40, and in the time value control method, the operation set value is 40). According to the method, an operation set value of 40 (enclosed in a thick frame) is selected.
[0040]
If selected in the manner described above, an appropriate voltage can be supplied according to the state of the distribution line, and when a vacuum valve tap changer is used, the number of tap operations can be reduced, and the usage period of the vacuum valve can be reduced. Can be extended.
[0041]
As another selection method, the target value used as the determination target may not be the maximum value of the integrated value of the continuous voltage excess deviation. In other words, in the method described above, if the extracted data is for one week, the target value is set for the maximum value of the data for one week, but the maximum value for the extracted data for one week is set for each day. May be extracted, and a target value may be determined for the average value by taking the average value of the maximum value for one week. Further, the total value of the difference between the voltage deviations for the data for one week may be calculated for each day, and the average value for the total value for one week may be calculated, so that the average value may be set as the target value. . In addition, in order to calculate the total value of the voltage deviation difference for each day, the difference of the voltage deviation for one day is summed up separately for positive and negative minutes, and the sum of the positive value and the negative value is calculated. The absolute value of each of the total values of the minutes is summed.
[0042]
The present invention is not limited to the above embodiment. For example, as an example in which a plurality of voltage control methods are provided in the control device 5, at least two of an integral value control method, a time value control method, and an integral value-time value control method may be provided. Further, the voltage control method may include four or more voltage control methods. Further, the calculation using the voltage control method described above is not limited to the calculation using a microcomputer, and the calculation may be performed using an analog circuit.
[0043]
【The invention's effect】
According to the present invention, a plurality of voltage control systems are provided in the control device, and one of them can be selected by the operation unit, so that the system most suitable for the installation point can be selected. Therefore, an appropriate voltage corresponding to the installation point can be supplied by one type of automatic voltage regulator.
[0044]
The invention according to claim 2 uses an integral value-time value control method that outputs a control command when an operation set value of any one of the integral value control method and the time value control method is exceeded. Therefore, in the case of a gradual voltage change, a tap switching command is output if the operation set value (operation set time) in the time value control method is exceeded even if the operation set value is not exceeded in the integral value control method. Also, when there is a sudden voltage change, a tap switching command is output if the operation set value in the integral value control method is exceeded, even if the operation set time in the time value control method is not exceeded. Therefore, compared with the method using only the time value control method or the integral value control method, the tap can be changed more quickly, and an appropriate voltage can be supplied.
[Brief description of the drawings]
FIG. 1 is a flowchart showing an integral value-one-time value control method according to the present invention.
FIG. 2 is a flowchart showing integral value control of an integral value one-time value control method.
FIG. 3 is a flowchart showing time value control of an integral value-time value control method.
FIG. 4 is a flowchart showing an integral value control method.
FIG. 5 is a flowchart showing a time value control method.
FIG. 6 is a graph for understanding a difference voltage.
FIG. 7 is a graph for explaining how to perform integration in integral value control.
FIG. 8 is a graph for explaining how to count in time value control.
FIG. 9 is a block diagram showing an automatic voltage regulator.
FIG. 10 is a block diagram illustrating a voltage adjustment relay device.
FIG. 11 is a flowchart for automatically updating operation settings.
FIG. 12 is a flowchart in which a simulation execution part and the like are described in detail.
FIG. 13 is a table showing all patterns of a voltage control method and an operation set value.
FIG. 14 is a table showing time-series data.
FIG. 15 is a table showing various set values.
FIG. 16 is a table showing simulation results.
FIG. 17 is a flowchart showing a method of selecting a desired pattern based on a simulation result.
FIG. 18 is a table showing simulation results of all patterns.
[Explanation of symbols]
3 tap changer
5 Control device
14 Operation unit
V_L  Secondary voltage
V_S  Reference voltage
K, Z dead zone
T, Y operation set value

Claims (3)

A voltage control method for outputting a control command to the tap changer (3) so that the current secondary voltage (V _L ) at the installation point of the automatic voltage regulator approaches the reference voltage (V _S ) is included in the control device (5). In the automatic voltage regulator provided for
An automatic voltage regulator, wherein a plurality of voltage control systems are provided in the control device (5), and one of them can be selected by an operation unit (14). A voltage control method for outputting a control command to the tap changer (3) so that the current secondary voltage (V _L ) at the installation point of the automatic voltage regulator approaches the reference voltage (V) is included in the control device (5). In the automatic voltage regulator provided,
The voltage control method is an integral value-time value control method that outputs a control command when an operation set value of any of the integral value control method and the time value control method is exceeded,
Integrated value control method, obtains the difference voltage of the reference voltage (V _S) and current of the secondary voltage (V _L), and evaluated the replacement value based on the difference voltage or difference voltage, the evaluation target preset When the deviation is outside the dead zone (± K), the difference is time-integrated, and a control command is output when the integrated value exceeds the operation set value (T).
The time value control method is to output a control command when an evaluation target exceeds an operation set value (Y) when a time continuously deviating from a dead zone (± Z) is provided. A voltage control method for outputting a control command to the tap changer (3) so that the current secondary voltage (V _L ) at the installation point of the automatic voltage regulator approaches the reference voltage (V _S ) is included in the control device (5). In the automatic voltage regulator provided for
The control device (5) includes a plurality of voltage control methods, and each voltage control method includes a plurality of operation setting values serving as conditions for outputting a control command, and among all patterns of the voltage control method and the operation setting values, Is used as the initial value of the operation setting, the time series data of the secondary voltage, the secondary current, the phase, and the tap voltage are stored during the operation, and the voltage control method and the operation setting are performed based on the time series data. An automatic voltage regulator, which simulates a tap switching situation in all value patterns by a computer and automatically updates a voltage control method and an operation setting of an operation set value based on the simulation result.

Images