JP3731110B2 - Demand control monitoring method and apparatus - Google Patents

Description

【００３６】
前記予測電力演算部１３は、例えば、予め設定されているパルス重み×パルス積算値×（６０÷デマンド時限［分］）の演算を行って現在電力を算出し、この現在電力を用いて、現在電力＋（過去Δｔ分間の電力変化量÷サンプリング時間Δｔ）×（残り時間）の演算を行って予測電力を算出する。
【００３７】
前記制御要否判定部１６は、例えば、目標電力÷デマンド時限×経過時間の演算を行って目標現在電力を算出し、経過時間＞Ｔロック時間（時限開始直後の、遮断指令出力を禁止すべき時間）、かつ予測電力≧目標電力、かつ現在電力≧目標現在電力である場合に、遮断指令出力を行って、最大レベルになるまで遮断レベルを１つ上げ、逆に、予測電力＜目標電力、かつ現在電力＜目標現在電力である場合に、復帰指令出力を行って、遮断レベル＝０になるまで遮断レベルを１つ下げる。これら以外の場合には、遮断指令出力、復帰指令出力の何れも行わない。
【００３８】
上記の予測電力は時限開始直後に大きな値が算出され易いという問題があるが、このようにＴロック時間を制御要否の判定式に加えることで、時限開始直後に不要な遮断指令が出力されるのを阻止している。
【００３９】
前記負荷制御部１７は、各遮断レベル毎に行う制御を予め設定しておき、制御要否判定部１６からの遮断レベルを入力として、この遮断レベルに対応して負荷群（例えば、空気調和機、照明器具など）を制御するための処理を行い、負荷制御データを出力する。ここで、制御としては、空気調和機の圧縮機の能力抑制、設定温度のシフト、空気調和機の室内機の強制サーモオフ（送風運転）、設備の停止などが例示できる。また、遮断レベルが高いほど、強い電力抑制がかかるように遮断レベル毎の制御が設定されている。
【００４０】
前記遮断レベル発生時間内訳算出部２は、予め設定された期間（累積時間算出期間であり、例えば、３０分〜数ヶ月の範囲で任意に設定される期間）、および表示様式を保持する期間＆表示様式記憶部２２と、残り時間、遮断レベルを示す判定結果、および累積時間算出期間を入力として、遮断レベル毎の累積時間、および各累積時間の累積時間算出期間に対する割合（遮断レベルの発生割合）を算出する遮断レベル累積時間算出部２１と、累積時間算出期間に対応して算出された遮断レベル毎の累積時間、および表示様式を入力として表示のための作画処理を行って画像データを生成する表示用作画部２３とを有している。
【００４１】
前記遮断レベル累積時間算出部２１は、図２に示すフローチャートの処理を行って遮断レベル毎の累積時間、および各累積時間の累積時間算出期間に対する割合を算出する。なお、Ｓが遮断レベルを、ＮＳが遮断レベルＳの発生回数を、それぞれ示している。
【００４２】
ステップＳＰ１において、累積時間算出期間、制御履歴（遮断レベル）に基づいて、残り時間演算部１２からの残り時間演算結果を用いてｉ番目（ｉは正の整数）の遮断レベルの開始時間ＴＳｓｔａｒｔｉおよび終了時間ＴＳｅｎｄｉの抽出を行い、ステップＳＰ２において、遮断レベルＳの累積時間ＴＳを数１の演算を行うことにより算出し、ステップＳＰ３において、遮断レベルＳの発生割合ＰＳを数２の演算を行うことにより算出し、ステップＳＰ４において、遮断レベルＳの累積時間ＴＳおよび／または遮断レベルＳの発生割合ＰＳを表示用作画部２３に供給し、そのまま元の処理に戻る。
【００４３】
【数１】

【００４４】
【数２】

【００４５】
上記のデマンド制御監視装置の作用は次のとおりである。
【００４６】
デマンド制御部１によってデマンド制御を行うことにより、例えば、表１に示す制御履歴が得られ、制御履歴記憶部１８に保持される。
【００４７】
そして、予め設定されている累積時間算出期間に対応させて、遮断レベル累積時間算出部２１によって、遮断レベル毎の累積時間および発生割合を算出し、予め設定されている表示様式に対応させて、表示用作図部２３によって画像データを作成し、表示装置３によって可視的に表示することができる。
【００４８】
具体的には、各負荷に対応するデマンド制御のための遮断レベルが表２に示すように設定されているとともに、表示様式として横向きの棒グラフが設定されている場合において、目標電力（デマンド目標電力）が１０５ｋＷに設定されていれば、遮断レベル毎の累積時間が表３に示すように得られ、遮断レベル毎の発生割合が図３に示すように表示される。
【００４９】
【表２】

【００５０】
【表３】

【００５１】
また、デマンド目標電力が１１０ｋＷに設定されていれば、遮断レベル毎の累積時間が表４に示すように得られ、遮断レベル毎の発生割合が図４に示すように表示される。
【００５２】
【表４】

【００５３】
表示様式として円グラフが設定されていれば、デマンド目標電力が１０５ｋＷ、１１０ｋＷのそれぞれに対応して図５、図６に示すように表示される。
【００５４】
表示様式として円板グラフが設定されていれば、デマンド目標電力が１０５ｋＷ、１１０ｋＷのそれぞれに対応して図７、図８に示すように表示される。
【００５５】
これらのグラフを見れば、デマンド目標電力を１１０ｋＷに設定した場合には、遮断レベルが低い方に偏りすぎているのに対して、デマンド目標電力を１０５ｋＷに設定した場合には、遮断レベルが低い方から高い方に向かって徐々に減少していることが分かる。したがって、１１０ｋＷは適切なデマンド目標電力ではないのに対して、１０５ｋＷは適切なデマンド目標電力であることが分かる。
【００５６】
また、遮断レベルの偏りに着目すれば、デマンド目標電力が不適切である場合に、デマンド目標電力を増加させるべきか、減少させるべきかを簡単に判定することができる。さらに説明する。
【００５７】
遮断レベルの低い方から順に発生割合が少なくなっていく分布が適切な状態で、遮断レベルの高い方の発生割合が多くなっている場合はデマンド目標電力が低すぎ、室内環境が厳しい状態になっていると推定される。逆に、遮断レベルの低いものしかない場合はデマンド目標電力が高すぎ、契約電力が高すぎて基本電力料金の節約の機会を逃していると考えられる。したがって、このようなことを考慮して遮断レベルの発生割合の多少を判定することによってデマンド目標電力の適否を精度よく判定することができる。
【００５８】
また、この実施態様においては、可視的な表示を目視で確認することによってデマンド目標電力の適否を判定するようにしているが、各遮断レベル、もしくは特定の遮断レベルの累積時間、もしくは発生割合を所定の閾値と比較することによってデマンド目標電力の適否を自動的に判定することが可能である。ただし、この場合における閾値は、例えば、室内環境維持、および契約電力低減を考慮して経験的に定めればよい。
【００５９】
さらに、図１のデマンド制御監視装置は、デマンド制御対象であるビルなどに組み込まれたものとして説明しているが、図９に示すように、遠隔監視センター４により複数のデマンド制御対象５を監視するシステムに適用することができる。
【００６０】
この場合には、デマンド制御部１を各デマンド制御対象５に組み込み、遮断レベル発生時間内訳算出部２、および表示装置３を遠隔監視センター４に組み込み、遠隔監視センター４と各デマンド制御対象５との間をネットワーク６を介して接続すればよい。ここで、ネットワーク６としては、有線のネットワーク、無線のネットワークの何れであっても採用することができる。
【００６１】
この構成を採用した場合には、各デマンド制御対象においてデマンド目標電力に基づくデマンド制御を行いながら制御履歴記憶部１８に制御履歴を保持させる。
【００６２】
そして、各デマンド制御対象５からネットワーク６を通して制御履歴を遠隔監視センター４に伝送する。
【００６３】
遠隔監視センター４においては、伝送された制御履歴に基づいて、各デマンド制御対象毎に、各遮断レベルの累積時間、および遮断レベル発生割合を算出し、可視的に表示する。
【００６４】
そして、遠隔監視センター４から該当するデマンド制御対象５に対して、算出した各遮断レベルの累積時間、および遮断レベル発生割合を伝送し、もしくは各遮断レベルの累積時間、および／または遮断レベル発生割合に基づいて推定される適切なデマンド目標電力を供給する。
【００６５】
この場合には、各デマンド制御対象５における処理負荷を低減できるとともに、遠隔監視センター４において各デマンド制御対象５におけるデマンド目標電力の適否を集中的に判定することができる。
【００６６】
図１０はこの発明のデマンド制御監視装置の他の実施態様を示すブロック図である。
【００６７】
このデマンド制御監視装置が図１のデマンド制御監視装置と異なる点は、遮断レベル発生時間内訳算出部２として、時限毎の遮断レベル累積時間算出結果を保持する時限毎算出結果記憶部２４をさらに有するものを採用した点、および時限毎の遮断レベル累積時間算出結果に基づいてデマンド突出の原因となる原因設備情報を抽出する原因設備抽出部７をさらに有する点のみである。
【００６８】
前記原因設備抽出部７は、時限毎の遮断レベル累積時間算出結果を入力としてデマンド突出時間帯を抽出するデマンド突出時間帯抽出部７１と、設備運転履歴を保持する設備運転履歴記憶部７２と、デマンド突出時間帯に対応する設備運転履歴を抽出する設備運転履歴抽出部７３とを有している。
【００６９】
前記デマンド突出時間帯抽出部７１は、単位時限毎に算出された、遮断レベルの高い時限、すなわちデマンドが突出した時限を検出することによって、デマンド突出時間帯を抽出する。そして、遮断レベルの高さの程度は、各遮断レベルの発生時間もしくは発生割合に遮断レベル毎の重みをかけて加算することにより検出する。こうして求めた値が、前後Ｎ時限（Ｎは正の整数）の中で最大で、しかも所定の値を超えていて、かつ所定の割合以上他を上回っている時、この時限をデマンドが突出した時限とする。そして、デマンドが突出した全ての時限から、デマンド突出時間帯を抽出する。
【００７０】
前記設備運転履歴抽出部７３は、設備の起動や設定温度の変更が行われてから、実際に消費電力が増加するまでに、遅延（数分〜３０分程度）があることを考慮して、デマンド突出時間帯の開始時刻の１時間程度前からデマンド突出時間帯の終了時刻までの時間帯における設備運転履歴を抽出し、抽出された設備運転履歴の中から、設備の起動と設定温度の変更（冷房運転時には設定温度を下げ、暖房運転時には設定温度を上げる設定温度の変更）に関する運転履歴を、契約電力を押し上げる原因になり得る不適切な設備運用として抽出し、記録する。ただし、契約電力の押し上げが軽微なものを除外すべく、設定温度の変更幅が所定幅以上のもの、設定温度変更後の設定温度が第１所定温度以下（冷房運転時）（暖房運転時であれば、第２所定温度以上）のもののみを抽出することが好ましい。
【００７１】
この実施態様を採用した場合には、前記の実施態様と同様にデマンド目標電力の適否を判定することができるほか、デマンド制御後の値からは非制御時のデマンド値が突出しているか否かを判定できないにも拘わらず、デマンド突出時間帯抽出部７１によってデマンド値が突出していた時間帯を抽出することができ、この時間帯に基づいて定まる時間帯における設備運転履歴からデマンド値を突出させる原因となる設備を抽出することができる。そして、デマンド値を突出させる原因となる設備の運転を変更することによって、デマンド値の突出を防止し、もしくは抑制することができ、ひいては、デマンド制御を行った場合における室内環境の悪化を抑制することができるとともに、デマンド目標電力の低減を達成することもできる。
【００７２】
図１１はこの発明のデマンド制御監視装置のさらに他の実施態様を示すブロック図である。
【００７３】
このデマンド制御監視装置が図１のデマンド制御監視装置と異なる点は、遮断レベル発生時間内訳算出部２と表示装置３との間に目標電力適否判定部８をさらに設けた点、表示用作画部２３を省略した点、および表示装置３として、適否判定結果を表示するものを採用した点のみである。
【００７４】
前記目標電力適否判定部８は、室内環境維持、および契約電力低減を考慮して経験的に定めた閾値（例えば、遮断レベル毎に設定された閾値）を保持する閾値記憶部８２と、遮断レベル累積時間算出部２１により算出された遮断レベル累積時間と対応する閾値とを比較してデマンド目標電力の適否を判定する適否判定部８３とを有している。
【００７５】
したがって、この実施態様であれば、適否判定部８３によって客観的にデマンド目標電力の適否を判定することができ、この客観的な判定結果を表示装置３によって表示することができる。もちろん、この表示装置３によって遮断レベル累積時間を表示することも可能である。
【００７６】
図１２はこの発明のデマンド制御監視装置のさらに他の実施態様を示すブロック図である。
【００７７】
このデマンド制御監視装置が図１１のデマンド制御監視装置と異なる点は、目標電力適否判定部８として、遮断レベル累積時間割合算出部８１をさらに含むものを採用した点のみである。
【００７８】
前記遮断レベル累積時間割合算出部８１は、遮断レベル累積時間算出部２１により算出された遮断レベル累積時間を入力として各遮断レベル累積時間の割合を算出し、適否判定部８３に供給する。
【００７９】
前記閾値記憶部８２には、割合の判定基準となる閾値を保持する。
【００８０】
前記適否判定部８３は、各遮断レベル累積時間の割合と対応する閾値とを比較してデマンド目標電力の適否を判定する。
【００８１】
したがって、この実施態様であれば、適否判定部８３によって客観的にデマンド目標電力の適否を判定することができ、この客観的な判定結果を表示装置３によって表示することができる。もちろん、この表示装置３によって遮断レベル累積時間の割合を表示することも可能である。
【００８３】
【発明の効果】
請求項１の発明は、目標電力の適否をより精度よく判定することができ、この結果、目標電力を適切な値にすることがより簡単になり、ひいては契約電力低減と室内環境維持とを両立させることができるという特有の効果を奏する。
【００８４】
請求項２の発明は、目標電力の適否を簡単に、かつ、より精度よく判定することができ、この結果、目標電力を適切な値にすることがより簡単になり、ひいては契約電力低減と室内環境維持とを両立させることができるという特有の効果を奏する。
【００８５】
請求項３の発明は、目標電力の適否をより簡単に、かつ、より精度よく判定することができ、この結果、目標電力を適切な値にすることがより簡単になり、ひいては契約電力低減と室内環境維持とを両立させることができるという特有の効果を奏する。
【００８７】
請求項４の発明は、目標電力の適否を簡単に、かつ、より精度よく判定することができ、この結果、目標電力を適切な値にすることがより簡単になり、ひいては契約電力低減と室内環境維持とを両立させることができるという特有の効果を奏する。
【００８８】
請求項５の発明は、目標電力の適否を簡単に、かつ、より精度よく判定することができ、この結果、目標電力を適切な値にすることがより簡単になり、ひいては契約電力低減と室内環境維持とを両立させることができるという特有の効果を奏する。
【００８９】
請求項６の発明は、グラフ表示を見ることによって目標電力の適否を簡単に、かつ、より精度よく判定することができ、この結果、目標電力を適切な値にすることがより簡単になり、ひいては契約電力低減と室内環境維持とを両立させることができるという特有の効果を奏する。
【図面の簡単な説明】
【図１】この発明のデマンド制御監視方法が適用されるデマンド制御監視装置の一実施態様を示すブロック図である。
【図２】遮断レベル累積時間算出部における処理を説明するフローチャートである。
【図３】遮断レベル毎の発生割合の表示の一例を示す図である。
【図４】遮断レベル毎の発生割合の表示の一例を示す図である。
【図５】遮断レベル毎の発生割合の表示の他の例を示す図である。
【図６】遮断レベル毎の発生割合の表示の他の例を示す図である。
【図７】遮断レベル毎の発生割合の表示のさらに他の例を示す図である。
【図８】遮断レベル毎の発生割合の表示のさらに他の例を示す図である。
【図９】遠隔監視センターにより複数のデマンド制御対象を監視するシステムを示す概略図である。
【図１０】この発明のデマンド制御監視方法が適用されるデマンド制御監視装置の他の実施態様を示すブロック図である。
【図１１】この発明のデマンド制御監視方法が適用されるデマンド制御監視装置のさらに他の実施態様を示すブロック図である。
【図１２】この発明のデマンド制御監視方法が適用されるデマンド制御監視装置のさらに他の実施態様を示すブロック図である。
【符号の説明】
１ デマンド制御部 ３ 表示装置
１８ 制御履歴記憶部 ２１ 遮断レベル累積時間算出部
８３ 適否判定部[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a novel demand control monitoring method and apparatus for determining suitability of target power based on a demand control result.
[0002]
[Prior art]
Conventionally, in order to reduce contract power, the target power is set in advance, and the load group is operated so as not to exceed this target power and to reduce the unfairness of the room subject to demand control. Demand control methods for controlling are known and widely adopted (see, for example, Japanese Patent Application Laid-Open No. 11-215700).
[0003]
In performing demand control, a demand control method is proposed in which a plurality of shut-off levels are set in advance, and each shut-off level is sequentially executed according to the degree to which the predicted power exceeds the target power (for example, a special control method). (See Kaisho 57-19538).
[0004]
[Problems to be solved by the invention]
However, regardless of which demand control method is adopted, the load group is only controlled so as not to exceed the predetermined target power, and whether or not the target power is set appropriately. It cannot be judged. As a result, there is no guarantee that both reduction of contract power and maintenance of the indoor environment can be achieved.
[0005]
Further explanation will be given.
[0006]
Conventionally, when performing demand control, the provisional target power is set in consideration of the back calculation from the target value for contract power reduction (basic power charge reduction) or the capacity of the target electrical equipment. Demand control is based on this.
[0007]
Even if the set target power is protected and the unfairness of the room subject to demand control is resolved, all rooms can be used as long as the power is absolutely insufficient. In this case, the environmental degradation will exceed acceptable limits, which will hinder business operations, and in turn, there is a high possibility that approval will not be obtained for demand control.
[0008]
On the other hand, if the target power is set with fear of environmental deterioration more than necessary, the contract power reduction effect becomes low, and the economic effect and energy saving effect due to the introduction of demand control will occur.
[0009]
Therefore, it is extremely difficult to set the target power so that both contract power reduction and indoor environment maintenance can be achieved. Usually, the target power setting is usually inappropriate. Any maintenance of the indoor environment will be impaired.
[0010]
OBJECT OF THE INVENTION
The present invention has been made in view of the above-described problems, and an object of the present invention is to provide a demand control monitoring method and apparatus capable of determining the suitability of a target power set for demand control.
[0012]
[Means for Solving the Problems]
  Claim1The demand control monitoring method performs load demand control based on the target power, detects and stores the interruption level resulting from demand control and the duration of the interruption level, and accumulates the interruption time within a predetermined period. Is calculated, and the suitability of the target power is determined based on the calculated accumulated time.
[0013]
  Claim2The demand control monitoring method performs load demand control based on the target power, detects and stores the interruption level resulting from demand control and the duration of the interruption level, and accumulates the interruption time within a predetermined period. Is calculated, the ratio of the cumulative time of each cutoff level to the predetermined period is calculated, and the suitability of the target power is determined based on the calculated ratio.
[0014]
  The demand control monitoring method according to claim 3 performs load demand control based on the target power, detects and stores a cutoff level caused by demand control and a duration of the cutoff level, and stores each cutoff level within a predetermined period. The cumulative time is calculated, the ratio of the cumulative time of each blocking level to the predetermined period is calculated, and the calculated ratio is graphedindicateIs the method.
[0016]
  Claim4The demand control monitoring apparatus includes a demand control unit that performs load demand control based on the target power, a control history storage unit that detects and stores a cutoff level caused by demand control and a duration of the cutoff level, It includes an accumulated time calculating means for calculating the accumulated time of each shut-off level within the period, and an appropriateness determining means for determining the appropriateness of the target power based on the calculated accumulated time.
[0017]
  Claim5The demand control monitoring apparatus includes a demand control unit that performs load demand control based on the target power, a control history storage unit that detects and stores a cutoff level caused by demand control and a duration of the cutoff level, A cumulative time calculating means for calculating a cumulative time of each blocking level within a period; a ratio calculating means for calculating a ratio of a cumulative time of each blocking level to a predetermined period;A suitability judging unit for judging suitability of the target power by comparing the calculated ratio with a predetermined threshold value.Is.
[0018]
  Claim6The demand control monitoring apparatus includes a demand control unit that performs load demand control based on the target power, a control history storage unit that detects and stores a cutoff level caused by demand control and a duration of the cutoff level, A cumulative time calculating means for calculating the cumulative time of each blocking level within the period; a ratio calculating means for calculating a ratio of the cumulative time of each blocking level to a predetermined period; and a display means for displaying the calculated ratio in a graph. It is a waste.
[0020]
[Action]
  Claim1The demand control monitoring method of the present invention performs load demand control based on the target power, detects and stores the interruption level resulting from demand control and the duration of the interruption level, and stores each interruption level within a predetermined period. Since the cumulative time is calculated and the suitability of the target power is determined based on the calculated cumulative time, the suitability of the target power can be determined with higher accuracy. As a result, it becomes easier to set the target power to an appropriate value, and as a result, both contract power reduction and indoor environment maintenance can be achieved.
[0021]
  Claim2The demand control monitoring method of the present invention performs load demand control based on the target power, detects and stores the interruption level resulting from demand control and the duration of the interruption level, and stores each interruption level within a predetermined period. Since the cumulative time is calculated, the ratio of the cumulative time of each cutoff level to the predetermined period is calculated, and the suitability of the target power is determined based on the calculated ratio. It can be determined with high accuracy. As a result, it becomes easier to set the target power to an appropriate value, and as a result, both contract power reduction and indoor environment maintenance can be achieved.
[0022]
  Claim3The demand control monitoring method of the present invention performs load demand control based on the target power, detects and stores the interruption level resulting from demand control and the duration of the interruption level, and stores each interruption level within a predetermined period. Calculate the cumulative time, calculate the ratio of the cumulative time of each blocking level to the predetermined period, and display the calculated ratio in a graphBecause you doThe suitability of the target power can be determined more easily and with higher accuracy. As a result, it becomes easier to set the target power to an appropriate value, and as a result, both contract power reduction and indoor environment maintenance can be achieved.
[0025]
  Claim4If the demand control monitoring device of the present invention, the demand control means performs load demand control based on the target power, and the control history storage means detects the interruption level resulting from the demand control and the duration of this interruption level. Remember. Then, the cumulative time calculation means can calculate the cumulative time of each cutoff level within a predetermined period, and the suitability determination means can determine whether the target power is appropriate based on the calculated cumulative time.
[0026]
Therefore, the suitability of the target power can be determined with higher accuracy. As a result, it becomes easier to set the target power to an appropriate value, and as a result, both contract power reduction and indoor environment maintenance can be achieved.
[0027]
  Claim5If the demand control monitoring device of the present invention, the demand control means performs load demand control based on the target power, and the control history storage means detects the interruption level resulting from the demand control and the duration of this interruption level. Remember. Then, the cumulative time calculating means calculates the cumulative time of each blocking level within the predetermined period, and the ratio calculating means calculates the ratio of the cumulative time of each blocking level to the predetermined period,The suitability determination unit can determine the suitability of the target power based on the calculated ratio.
[0028]
Therefore, the suitability of the target power can be determined easily and more accurately. As a result, it becomes easier to set the target power to an appropriate value, and as a result, both contract power reduction and indoor environment maintenance can be achieved.
[0029]
  Claim6If the demand control monitoring device of the present invention, the demand control means performs load demand control based on the target power, and the control history storage means detects the interruption level resulting from the demand control and the duration of this interruption level. Remember. Then, the cumulative time calculating means calculates the cumulative time of each blocking level within the predetermined period, the ratio calculating means calculates the ratio of the cumulative time of each blocking level to the predetermined period, and the display means calculates the ratio Can be displayed in a graph.
[0030]
Therefore, the suitability of the target power can be easily and more accurately determined by looking at the graph display. As a result, it becomes easier to set the target power to an appropriate value, and as a result, both contract power reduction and indoor environment maintenance can be achieved.
[0031]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of a demand control monitoring method and apparatus according to the present invention will be described below in detail with reference to the accompanying drawings.
[0032]
FIG. 1 is a block diagram showing an embodiment of a demand control monitoring apparatus to which the demand control monitoring method of the present invention is applied.
[0033]
The demand control monitoring apparatus includes a demand control unit 1, a cutoff level occurrence time breakdown calculation unit 2, and a display device 3.
[0034]
The demand control unit 1 includes a pulse counter 11 that integrates demand pulses with a demand pulse as an input, a remaining time calculation unit 12 that calculates a remaining time by subtracting an elapsed time from a demand time limit, a demand pulse count value, and a remaining time. The predicted power calculation unit 13 that calculates the predicted power using the input, the target power storage unit 15 that holds the target power, and determines whether the control is necessary or not by inputting the target power and the calculated predicted power and outputs the determination result Control necessity determination unit 16 to perform, load control unit 17 that performs processing for load control using the determination result as an input, and control history (for example, as shown in Table 1) using the determination result from control necessity determination unit 16 as an input As described above, the control history storage unit 18 stores an output time of an interruption / return command, an output interruption level, and the like.
[0035]
[Table 1]

[0036]
For example, the predicted power calculation unit 13 calculates a current power by calculating a preset pulse weight × pulse integrated value × (60 ÷ demand time limit [minute]), and uses the current power to calculate the current power The predicted power is calculated by calculating power + (power change amount in the past Δt ÷ sampling time Δt) × (remaining time).
[0037]
The control necessity determination unit 16 calculates, for example, target power / demand time limit × elapsed time to calculate the target current power, and elapsed time> T lock time (shock command output immediately after the start of time limit should be prohibited. Time), and when predicted power ≧ target power and current power ≧ target current power, a shut-off command is output and the shut-off level is increased by 1 until the maximum level is reached. If the current power is smaller than the target current power, a return command is output and the cut-off level is lowered by one until the cut-off level = 0. In other cases, neither shut-off command output nor return command output is performed.
[0038]
The above predicted power has a problem that a large value is easily calculated immediately after the start of the time limit. Thus, by adding the T lock time to the determination formula for necessity of control, an unnecessary cutoff command is output immediately after the start of the time limit. Is blocked.
[0039]
The load control unit 17 presets control to be performed for each cutoff level, receives the cutoff level from the control necessity determination unit 16 as an input, and corresponds to the cutoff level (for example, an air conditioner). , Lighting equipment, etc.), and load control data is output. Here, examples of the control include suppression of the capacity of the compressor of the air conditioner, shift of the set temperature, forced thermo-off (air blowing operation) of the indoor unit of the air conditioner, and stop of the equipment. Moreover, the control for every interruption | blocking level is set so that strong electric power suppression may be applied, so that the interruption | blocking level is high.
[0040]
The cutoff level occurrence time breakdown calculation unit 2 is configured to store a preset period (a cumulative time calculation period, for example, a period arbitrarily set in a range of 30 minutes to several months), and a period & The display format storage unit 22, the remaining time, the determination result indicating the blocking level, and the cumulative time calculation period are input, and the cumulative time for each blocking level and the ratio of each cumulative time to the cumulative time calculation period (the blocking level occurrence ratio) The cut-off level cumulative time calculation unit 21 for calculating the cut-off level), the cumulative time for each cut-off level calculated corresponding to the cumulative time calculation period, and the display style are input to generate image data for display. And a display drawing unit 23.
[0041]
The blocking level accumulated time calculation unit 21 performs the processing of the flowchart shown in FIG. 2 to calculate the accumulated time for each blocking level and the ratio of each accumulated time to the accumulated time calculation period. Note that S indicates the cutoff level, and NS indicates the number of occurrences of the cutoff level S.
[0042]
In step SP1, based on the accumulated time calculation period and the control history (interruption level), the start time TSstarti of the i-th (i is a positive integer) interception level using the remaining time computation result from the remaining time computation unit 12 and The end time TSendi is extracted, and in step SP2, the cumulative time TS of the cutoff level S is calculated by performing the calculation of Formula 1, and in Step SP3, the occurrence rate PS of the cutoff level S is calculated by Formula 2. In step SP4, the cumulative time TS of the blocking level S and / or the generation rate PS of the blocking level S is supplied to the display drawing unit 23, and the process returns to the original process.
[0043]
[Expression 1]

[0044]
[Expression 2]

[0045]
The operation of the demand control monitoring apparatus is as follows.
[0046]
By performing demand control by the demand control unit 1, for example, the control history shown in Table 1 is obtained and held in the control history storage unit 18.
[0047]
Then, in correspondence with the preset cumulative time calculation period, the cutoff level cumulative time calculation unit 21 calculates the cumulative time and occurrence rate for each cutoff level, and corresponds to the preset display format, Image data can be created by the display drawing unit 23 and can be visually displayed by the display device 3.
[0048]
Specifically, when the cutoff level for demand control corresponding to each load is set as shown in Table 2 and a horizontal bar graph is set as the display style, the target power (demand target power) is set. ) Is set to 105 kW, the accumulated time for each blocking level is obtained as shown in Table 3, and the generation rate for each blocking level is displayed as shown in FIG.
[0049]
[Table 2]

[0050]
[Table 3]

[0051]
Also, if the demand target power is set to 110 kW, the accumulated time for each cutoff level is obtained as shown in Table 4, and the generation rate for each cutoff level is displayed as shown in FIG.
[0052]
[Table 4]

[0053]
If a pie chart is set as the display format, the demand target power is displayed as shown in FIGS. 5 and 6 corresponding to 105 kW and 110 kW, respectively.
[0054]
If a disk graph is set as the display format, the demand target power is displayed as shown in FIGS. 7 and 8 corresponding to 105 kW and 110 kW, respectively.
[0055]
According to these graphs, when the demand target power is set to 110 kW, the cutoff level is too biased toward the lower side, whereas when the demand target power is set to 105 kW, the cutoff level is low. It can be seen that there is a gradual decrease from higher to higher. Therefore, it can be seen that 110 kW is not an appropriate demand target power, whereas 105 kW is an appropriate demand target power.
[0056]
If attention is paid to the deviation of the cutoff level, it is possible to easily determine whether the demand target power should be increased or decreased when the demand target power is inappropriate. Further explanation will be given.
[0057]
If the distribution in which the occurrence rate decreases in order from the lowest shut-off level is appropriate and the occurrence rate in the higher shut-off level increases, the demand target power is too low and the indoor environment becomes severe. It is estimated that On the other hand, if there is only a low cutoff level, the demand target power is too high, and the contract power is too high, and it is considered that the opportunity for saving the basic power rate is missed. Therefore, it is possible to accurately determine whether or not the demand target power is appropriate by determining the degree of occurrence of the cutoff level in consideration of the above.
[0058]
Further, in this embodiment, whether or not the demand target power is appropriate is determined by visually confirming a visible display. However, the accumulated time or occurrence rate of each interruption level or a specific interruption level is determined. It is possible to automatically determine whether the demand target power is appropriate or not by comparing with a predetermined threshold value. However, the threshold value in this case may be determined empirically in consideration of, for example, maintaining the indoor environment and reducing contract power.
[0059]
Further, although the demand control monitoring apparatus in FIG. 1 is described as being incorporated in a building or the like that is a demand control target, as shown in FIG. 9, a plurality of demand control targets 5 are monitored by the remote monitoring center 4. Can be applied to the system.
[0060]
In this case, the demand control unit 1 is incorporated in each demand control target 5, the cutoff level occurrence time breakdown calculation unit 2, and the display device 3 are incorporated in the remote monitoring center 4, and the remote monitoring center 4 and each demand control target 5 May be connected via the network 6. Here, the network 6 can be a wired network or a wireless network.
[0061]
When this configuration is adopted, a control history is held in the control history storage unit 18 while performing demand control based on demand target power in each demand control target.
[0062]
Then, the control history is transmitted from each demand control target 5 to the remote monitoring center 4 through the network 6.
[0063]
In the remote monitoring center 4, based on the transmitted control history, for each demand control target, the cumulative time of each blocking level and the blocking level occurrence rate are calculated and displayed visually.
[0064]
Then, the calculated cumulative time of each blocking level and the blocking level occurrence rate are transmitted from the remote monitoring center 4 to the corresponding demand control target 5, or the accumulated time and / or blocking level occurrence rate of each blocking level is transmitted. An appropriate demand target power estimated based on the above is supplied.
[0065]
In this case, the processing load on each demand control target 5 can be reduced, and the appropriateness of the demand target power in each demand control target 5 can be intensively determined in the remote monitoring center 4.
[0066]
FIG. 10 is a block diagram showing another embodiment of the demand control monitoring apparatus of the present invention.
[0067]
The demand control monitoring device is different from the demand control monitoring device of FIG. 1 in that it further includes a timed calculation result storage unit 24 for holding the interruption level accumulated time calculation result for each time period as the interruption level occurrence time breakdown calculation unit 2. The point which employ | adopted thing and the point which further has the cause installation extraction part 7 which extracts the cause installation information which causes a demand protrusion based on the interruption | blocking level accumulation time calculation result for every time limit are only.
[0068]
The cause facility extraction unit 7 receives a demand projection time zone extraction unit 71 that extracts an interruption level cumulative time calculation result for each time period as an input, a facility projection time zone extraction unit 71 that holds a facility operation history, And an equipment operation history extraction unit 73 that extracts equipment operation history corresponding to the demand protrusion time zone.
[0069]
The demand protrusion time zone extraction unit 71 extracts a demand protrusion time zone by detecting a time period with a high shut-off level calculated for each unit time period, that is, a time period when the demand protrudes. The degree of the level of the interruption level is detected by adding the occurrence time or occurrence ratio of each interruption level to the weight for each interruption level. When the value obtained in this way is the largest in the front and back N time periods (N is a positive integer), exceeds the predetermined value, and exceeds the other than the predetermined ratio, the demand has exceeded this time period. Timed. And the demand protrusion time slot | zone is extracted from all the time periods when the demand protruded.
[0070]
The facility operation history extraction unit 73 takes into account that there is a delay (a few minutes to 30 minutes) until the power consumption actually increases after the start of the facility or the change of the set temperature is performed. The equipment operation history in the time period from about 1 hour before the start time of the demand extruding time period to the end time of the demand extruding time period is extracted, and the start of equipment and change of the set temperature from the extracted equipment operating history The operation history related to (changing the set temperature that lowers the set temperature during cooling operation and raises the set temperature during heating operation) is extracted and recorded as inappropriate facility operation that can cause the contract power to be pushed up. However, in order to exclude those with a slight increase in contracted power, the set temperature change range is greater than or equal to the predetermined range, and the set temperature after the set temperature change is the first predetermined temperature or less (during cooling operation) (during heating operation) If there is, it is preferable to extract only those having a temperature equal to or higher than the second predetermined temperature.
[0071]
When this embodiment is adopted, whether or not the demand target power is appropriate can be determined in the same manner as in the above embodiment, and whether or not the demand value at the time of non-control protrudes from the value after demand control. Although demand cannot be determined, it is possible to extract the time zone in which the demand value has been projected by the demand projection time zone extraction unit 71, and cause the demand value to project from the equipment operation history in the time zone determined based on this time zone Can be extracted. And by changing the operation of the equipment that causes the demand value to protrude, it is possible to prevent or suppress the protrusion of the demand value, and thus suppress the deterioration of the indoor environment when demand control is performed. And a reduction in demand target power can be achieved.
[0072]
FIG. 11 is a block diagram showing still another embodiment of the demand control monitoring apparatus of the present invention.
[0073]
The demand control monitoring device is different from the demand control monitoring device of FIG. 1 in that a target power suitability determination unit 8 is further provided between the cutoff level occurrence time breakdown calculation unit 2 and the display device 3, and a display drawing unit. Only the point that 23 is omitted and the display device 3 that employs a display device that displays the suitability determination result are used.
[0074]
The target power suitability determining unit 8 includes a threshold storage unit 82 that holds a threshold (for example, a threshold set for each cutoff level) determined empirically in consideration of maintenance of the indoor environment and reduction of contract power. The apparatus includes a suitability determining unit 83 that compares the cutoff level accumulated time calculated by the accumulated time calculating unit 21 with a corresponding threshold value to determine whether the demand target power is appropriate.
[0075]
Therefore, according to this embodiment, the suitability determination unit 83 can objectively determine whether the demand target power is appropriate, and can display the objective determination result on the display device 3. Of course, the display device 3 can also display the interruption level accumulated time.
[0076]
FIG. 12 is a block diagram showing still another embodiment of the demand control monitoring apparatus of the present invention.
[0077]
The demand control monitoring device is different from the demand control monitoring device of FIG. 11 only in that a target power suitability determination unit 8 that further includes an interruption level cumulative time ratio calculation unit 81 is adopted.
[0078]
The blocking level accumulated time ratio calculating unit 81 calculates the ratio of each blocking level accumulated time using the blocking level accumulated time calculated by the blocking level accumulated time calculating unit 21 as an input, and supplies the calculated blocking level accumulated time to the suitability determining unit 83.
[0079]
The threshold value storage unit 82 holds a threshold value that is a criterion for determining a ratio.
[0080]
The suitability determination unit 83 determines the suitability of the demand target power by comparing the ratio of each interruption level accumulated time and the corresponding threshold value.
[0081]
Therefore, according to this embodiment, the suitability determination unit 83 can objectively determine whether the demand target power is appropriate, and can display the objective determination result on the display device 3. Of course, it is also possible to display the ratio of the interruption level accumulated time by the display device 3.
[0083]
【The invention's effect】
  Claim1According to the present invention, the suitability of the target power can be determined with higher accuracy. As a result, it becomes easier to set the target power to an appropriate value, and it is possible to achieve both reduction of contract power and maintenance of the indoor environment. There is a unique effect of being able to.
[0084]
  Claim2According to the present invention, the suitability of the target power can be determined easily and more accurately, and as a result, it becomes easier to set the target power to an appropriate value, thereby reducing the contract power and maintaining the indoor environment. There is a unique effect that it is possible to achieve both.
[0085]
  Claim3According to the present invention, it is possible to more easily and accurately determine whether or not the target power is appropriate. As a result, it becomes easier to set the target power to an appropriate value, and thus contract power reduction and indoor environment maintenance can be achieved. There is a peculiar effect that both can be achieved.
[0087]
  Claim4According to the present invention, the suitability of the target power can be determined easily and more accurately, and as a result, it becomes easier to set the target power to an appropriate value, thereby reducing the contract power and maintaining the indoor environment. There is a unique effect that it is possible to achieve both.
[0088]
  Claim5According to the present invention, the suitability of the target power can be determined easily and more accurately, and as a result, it becomes easier to set the target power to an appropriate value, thereby reducing the contract power and maintaining the indoor environment. There is a unique effect that it is possible to achieve both.
[0089]
  Claim6According to the present invention, it is possible to easily and more accurately determine whether or not the target power is appropriate by looking at the graph display. As a result, it becomes easier to set the target power to an appropriate value, and thus contract power. There is a peculiar effect that both reduction and maintenance of the indoor environment can be achieved.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an embodiment of a demand control monitoring apparatus to which a demand control monitoring method of the present invention is applied.
FIG. 2 is a flowchart for explaining processing in an interruption level cumulative time calculation unit.
FIG. 3 is a diagram illustrating an example of a display of an occurrence rate for each cutoff level.
FIG. 4 is a diagram illustrating an example of a display of an occurrence rate for each blocking level.
FIG. 5 is a diagram illustrating another example of the display of the occurrence rate for each blocking level.
FIG. 6 is a diagram illustrating another example of the display of the occurrence ratio for each blocking level.
FIG. 7 is a diagram showing still another example of the display of the occurrence rate for each blocking level.
FIG. 8 is a diagram showing still another example of the display of the occurrence ratio for each blocking level.
FIG. 9 is a schematic diagram showing a system for monitoring a plurality of demand control objects by a remote monitoring center.
FIG. 10 is a block diagram showing another embodiment of a demand control monitoring apparatus to which the demand control monitoring method of the present invention is applied.
FIG. 11 is a block diagram showing still another embodiment of a demand control monitoring apparatus to which the demand control monitoring method of the present invention is applied.
FIG. 12 is a block diagram showing still another embodiment of a demand control monitoring apparatus to which the demand control monitoring method of the present invention is applied.
[Explanation of symbols]
1 Demand control unit 3 Display device
18 Control history storage unit 21 Blocking level cumulative time calculation unit
83 Suitability determination unit

Claims (6)

  Perform load demand control based on the target power, detect and store the interruption level due to demand control and the duration of this interruption level, calculate the accumulated time of each interruption level within a predetermined period, and calculate A demand control monitoring method characterized by determining whether or not a target power is appropriate based on an accumulated time.   Performs load demand control based on the target power, detects and stores the interruption level resulting from demand control and the duration of this interruption level, calculates the accumulated time of each interruption level within a predetermined period, and calculates each interruption level The demand control monitoring method characterized by calculating the ratio of the accumulation time of and determining the suitability of the target power based on the calculated ratio. Perform load demand control based on the target power, detect and store the interruption level resulting from demand control and the duration of this interruption level, calculate the accumulated time of each interruption level within a predetermined period, and calculate each interruption level The demand control monitoring method characterized by calculating the ratio of the accumulation time of and displaying the calculated ratio in a graph .   Demand control means (1) that performs load demand control based on the target power, control history storage means (18) that detects and stores the interruption level resulting from demand control and the duration of the interruption level, and a predetermined period Demand time means (21) for calculating the cumulative time of each shut-off level, and suitability judgment means (83) for judging suitability of the target power based on the calculated cumulative time. Control monitoring device. Demand control means (1) that performs load demand control based on the target power, control history storage means (18) that detects and stores the interruption level resulting from demand control and the duration of the interruption level, and a predetermined period The cumulative time calculating means (21) for calculating the cumulative time of each shut-off level, the ratio calculating means (21) for calculating the ratio of the cumulative time of each shut-off level, and comparing the calculated ratio with a predetermined threshold. The demand control monitoring apparatus characterized by including the suitability determination means (83) for determining the suitability of the target power .   Demand control means (1) that performs load demand control based on the target power, control history storage means (18) that detects and stores the interruption level resulting from demand control and the duration of the interruption level, and a predetermined period Cumulative time calculating means (21) for calculating the cumulative time of each shut-off level, ratio calculating means (21) for calculating the ratio of the cumulative time of each shut-off level, and display means for displaying the calculated ratio in a graph ( And 3) a demand control monitoring device.

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