JP4837191B2 - Solar power generation system simulator - Google Patents

Description

と表される。
ここで、θf：外気温度（℃），θ：太陽電池温度（℃），v：風速（ｍ／ｓ），αc：強制対流熱伝達率（ユルゲスの実験による式）
【００２９】
さらに、太陽電池モジュールＭにおける「発電電流（Ｉ）によりモジュール抵抗から発生するジュール熱」による熱量は、モジュール抵抗の抵抗値Ｒｓと、発電電流Ｉの２乗とによる「Ｒｓ・Ｉ²」に基づき求められる。
従来例においては、上述したジュール熱の発熱による熱量を、太陽電池温度の変化において考慮せずに、このジュール熱による熱量を日射エネルギーにより発生する熱量に含めて、太陽電池の吸収率を求めていたため、太陽電池の温度変化のシミュレーション値に大きな誤差が発生すると考えられる。
【００３０】
すなわち、図８に示すように、１秒間の太陽電池の熱量の変化（左辺）は、１秒間の太陽電池の変化した温度に太陽電池モジュールの比熱を乗じることで求まる。
そして、図８の右辺において、第１項が▲１▼上述したジュール損失（ジュール熱の発生）により１秒間に発生する熱量であり、第２項が▲２▼入射日射量（入射エネルギー）に吸収率を乗じた、日射エネルギーの吸収により１秒間に発生する熱量であり、第３項が▲３▼外気との温度差や周囲の風により１秒間に放熱する熱量である。
【００３１】
したがって、ジュール損失を考慮した吸収率を求める場合、図９に示す式の構成となる。
そして、吸収率演算部２は、図９の式に対応した演算を行い、太陽電池モジュールの吸収率を求める。
すなわち、吸収率は、吸収率演算部２において、１秒間の太陽電池の変化した温度に太陽電池モジュールの比熱を乗じて得られた熱量と、上記▲３▼の熱量とを加えた値から▲１▼のジュール損失による熱量を減算し、この減算結果を１秒間の入射日射量で除算して得ることができる。
【００３２】
このように、１度、吸収率演算部２により、各太陽電池モジュール毎の熱吸収率を求めることで、以後、太陽電池モジュールの温度特性のシミュレーションを正確に行うことが可能となる。
吸収率演算部２で用いる正確な吸収率算出の式は、以下に示す（6）式となる。 ε(ω)＝((5.8＋3.9v_(t))(θ_(t)−θf_(t))−Ｉ_(t)・Ｒs²＋C(θ_(t)−θ_(t-1)))
/It_(t) …(6)
【００３３】
ここで、上述の式は風速vが５ｍ／ｓ以下の場合に適用される。風速が５ｍ／ｓを超える場合、左辺の分子の第１項を（５）式に合わせて変更する必要がある。
（６）式において、ε(ω)が吸収率であり、Ｉt_(t)が日射強度（入射日射量）であり、θf_(t)が外気温であり、θ_(t)が太陽電池モジュールの温度であり、v_(t)が風速であり、Ｉ_(t)が太陽電池モジュールＭの発電電流であり、ｔが時刻であり、Ｒsが太陽電池モジュールのモジュール抵抗である。
【００３４】
吸収率演算部２で用いられる、吸収率ε(ω)を求める（６）式の各数値は、図１０に示す測定装置により、所定の時間毎（例えば、１秒単位）に測定される。
図１０において、測定器５０は、各時刻毎に、風速計２０により出力される風速ｖ_(t)の値を測定し、日射計２１により出力される受光面日射量Ｉt_(t)の値の測定し、熱電対２４により外気温θf_(t)を測定し、熱電対２５により太陽電池モジュールの温度θ_(t)の値を測定し、電流測定用シャント抵抗により発電電流Ｉ_{( t)}を測定し、これらの測定された各値を吸収率演算部２へ出力する。
【００３５】
ここで、電子負荷２６は、太陽電池モジュールＭの発電電力が、常にその時点での最大値（最大出力点）となるように、太陽電池モジュールＭの出力電圧を調整するため、内部の抵抗値の制御を行う。
そして、吸収率演算部２は、得られた受光面日射量Ｉt_(t)，風速ｖ_(t)，外気温θf_(t)，太陽電池モジュールの温度θ_(t)，発電電流Ｉ_(t)（発電電流Ｉ）に基づき、（２）式により吸収率ε(ω)を求める。
【００３６】
ここで、吸収率演算部２は、図１１に示すように、各時刻毎に測定された吸収率の平均値を求め、この平均値を最終的な吸収率ε(ω)として、吸収熱量演算部１へ出力する。
このとき、吸収熱量演算部１は、吸収率演算部２から入力される吸収率ε(ω)を、各太陽電池モジュールに対応させて、データベース６へ格納する。
【００３７】
次に、吸収熱量演算部１は、太陽電池モジュールに吸収される熱量をシミュレーションにより求めるとき、対応する太陽電池モジュールの吸収率ε(ω)を、データベース６から読み出し、読み出した吸収率ε(ω)を用いてシミュレーションを開始する。
このとき、吸収熱量演算部１は、データベース６に、シミュレーションを行う季節の平均的な１日の所定の時間範囲毎（例えば、午前７時〜午前８時，午前８時〜午前９，…等の１時間毎）に設定された日射量Ｉt_(t)を読み出し、この日射量Ｉt_(t)に吸収率ε(ω)を乗じ、各時刻毎（例えば、計算の時間単位である１秒ごとの時刻，午前８時１０分１秒の後は午前８時１０分２秒等）の日射エネルギーによる熱量を演算する。
【００３８】
また、吸収熱量演算部１は、「Ｉ_(t) ²・Ｒs_(t)」の式からジュール熱を求める。
ここで、吸収熱量演算部１は、シミュレーションの開始時点において、日の出前の太陽電池モジュールの温度に対応した発電電流Ｉ_(t)をデータベース６から読み出し、この発電電流Ｉ_(t)を初期値としてジュール熱を求める。
以降、吸収熱量演算部１は、温度演算部５において、シミュレーションから得られた温度に基づき演算される時間範囲毎の発電電流Ｉ_(t)により、時刻毎のジュール熱を求める。
【００３９】
このとき、発電量補正部５は、上述した(1)，(3)，(4)式により、太陽電池モジュールの温度に依存した発電電流Ｉ_(t)（発電電流I）を求める。
また、温度補正部３は、データベース６に、シミュレーションを行う季節の平均的な１日の所定の時間範囲毎（例えば、１時間毎）に設定された外気温θf_(t)及び風速ｖ_(t)を用い、（５）式により放射熱量ｑcを演算する。
【００４０】
そして、温度補正部３は、所定の時刻毎（例えば、１秒単位）に、発電量補正部５により求められた発電電流Iに基づき、吸収熱量演算部１により演算される上記吸収熱量「ε(ω)・Ｉt_(t)」及びジュール熱「Ｉ_(t) ²・Ｒs_(t)」を加算した結果から、放射熱量ｑcを減算して、この結果である、熱量収支を温度演算部５へ出力する。
そして、温度演算部５は、入力される上記熱量収支を、上記時間範囲毎に積分して、太陽電池モジュールの時間範囲毎における熱量の変化「Ｃ（θ_(t)−θ_(t-1)）」を求める。
【００４１】
すなわち、温度演算部５は、吸収熱量演算部１，放射熱量演算部３，温度変化演算部４の演算結果に基づき、以下の（７）式の演算を行う。
C(θ_(t)−θ_{(t ー 1)})＝∫[ε(ω)It_(t)＋I_(t) ²Rs_(t)−αc(θ−θf)]dt …(7)
ここで、Ｃは比熱である。
これにより、温度演算部５は、時刻毎に入力される熱量変化を時刻範囲毎に積分して、時間範囲毎の温度変化量ΔＴ（すなわち、（θ_(t)−θ_{(t ー 1)}））を、左辺を比熱Cで除算することにより求める。
そして、温度演算部５は、求めた温度変化量ΔＴを、順次、直前の時間範囲の温度に加えていくことにより、各時間範囲毎の太陽電池モジュールの温度を演算する。
【００４２】
ここで、本願発明の太陽電池発電システムシミュレータにおける温度演算部５は、ジュール熱を考慮した状態で、太陽電池モジュールの日射エネルギーの吸収率を求め、ジュール熱自体も吸収熱量に対する補正として考慮に入れたため、季節と天候とに対応した状態での温度変化を図１２に示すように、図１０の測定計により、実際に測定した太陽電池モジュールの温度とほぼ同様な温度変化の特性として得ることができる。
【００４３】
そして、発電量補正部５は、基準電流演算部４が（１）式に基づき算出した基準の発電電流Ｉに対して、日の出後の時刻範囲から、温度補正部３の求めた各時間範囲毎の温度を任意の温度Ｔ1として、（３），（４）式に用いて発電電流及び出力電圧の補正を行うことにより、各時刻における太陽電池モジュールＭの発電量（すなわち、電力であり、発電電流I及びそのときの出力電圧の電圧値の積）の計算を行う。
そして、温度補正部３は、順次、発電量補正部５の演算した上記発電電流Ｉに基づき吸収熱量演算部１の求めるジュール熱と、日射エネルギーによる吸収熱量との加算値から、放射熱量を差し引いて、各対応する時刻範囲の太陽電池モジュールＭの温度を上述のように算出する。
【００４４】
すなわち、本願発明の太陽電池発電量シミュレータにおいて、温度補正部３と発電量補正部５とは、互いに求めた現在の時刻範囲の太陽電池モジュールの温度，太陽電池モジュールの発電電流Ｉとを、相互にフィードバックを掛けることにより、次の時刻範囲の太陽電池モジュールＭの温度，太陽電池モジュールＭの発電電流を、順次、演算している。
そして、得られたＩ−Ｖカーブ値の検証として、温度補正部３の演算した発電電流及び出力電流に基づくＩ−Ｖカーブと、図１０に示す実験系により、実測により得られたＩ−Ｖカーブとの比較を行い、結果として、図１３に示すように、演算値と測定値との誤差は３％以内であった。
【００４５】
次に、太陽電池発電システムシミュレータが行う第２段階における予測発電量のシミュレーションの説明を行う。
発電量演算部８は、図１４のように、発電量補正部５から順次出力される発電量のデータ、すなわち発電量を示すＩ−Ｖカーブから太陽電池モジュールＭの最大出力点（太陽電池モジュールＭの出力する電力の最大値）を求める。
次に、発電量演算部８は、指定されたインバータの変換率のデータを、インバータデータベース７から読み出し、この変換率のデータと上記最大出力点における発電量（電力）との乗算を行い、これに太陽電池モジュールの数を乗算することにより、太陽電池発電システムの、季節毎，及び時間毎の予測発電量を演算する。
【００４６】
そして、発電量演算部８は、上述したフローにより得られた予測発電量を、図３に示す形式のテーブルで発電量データベース６に、太陽電池発電システムの種類に対応させて、季節毎，及び時間毎に順次格納する。
次に、発電量演算部８は、利用者が端末から要求する太陽電池発電システムに対応する図３のテーブルを図示しない表示部に表示する。
利用者は、上記表示部に表示された予測発電量により、指定した太陽電池発電システムが、設置する住宅または事業所などで使用する電力に対して、適切か否かの判断を行う。
これにより、利用者は、この予測発電量の数値に対応して、使用する電力が不適当な場合、設置する地域に応じて、季節及び時間毎の上記予測発電量を参考にして、他の種類の太陽電池発電システムを選択して、上述した太陽電池発電システムの予測発電量のシミュレーションを再度行う。
【００４７】
そして、本願発明の対応電池発電量シミュレータを用いることにより、太陽電池モジュールの温度変化を、時刻毎に正確に算出することができるため、太陽電池モジュールの発電量のシミュレーションを正確に行うことが出来る効果がある。
すなわち、本願発明の太陽電池発電量シミュレータは、季節と天候とに対応した状態での太陽電池モジュールの温度変化を演算し、これにより求まる各時刻範囲の太陽電池モジュールＭの温度に基づき、各時刻の発電電流Ｉを（３），（４）式（温度による補正式）により正確に求め、かつ、この発電電流Ｉに対応して太陽電池モジュールＭの温度が正確に算出されるため、この得られた太陽電池モジュールの温度を、次の時刻範囲において（３），（４）式の任意の温度Ｔ1として代入することにより、順次、正確な発電量を計算することが可能となる。
【００４８】
本願発明の太陽電池発電量シミュレータを用いることにより、発電量演算部８が、指定されたインバータの変換率のデータを、インバータデータベース７から読み出し、この変換率のデータと、発電量補正部５の出力する発電量から最大出力点における電力との乗算を行い、これに太陽電池モジュールの数を乗算することにより、太陽電池発電システムの、季節毎，及び時間毎の予測発電量を演算することができるため、従来例のように、正確に演算された太陽電池モジュールの発電量が得られないため、住宅や事業所等に設置する太陽電池発電システムの精度の高いシミュレーションが行えないということが無くなり、設置する住宅や事業所のある地域，設置する場所，季節及び時間毎に適切な太陽電池発電システム構成を得ることができ、設置された太陽電池発電システムが、設置して実際に運転した場合に、十分な発電能力が無い場合や、不必要に大きな発電能力を有する場合などの発生を防止させる効果がある。
【００４９】
次に、本発明の実施の形態によるコンピュータが実行するためのプログラムについて説明する。
図１における太陽電池モジュールの温度特性をシミュレーションする太陽電池温度特性シミュレータにおけるコンピュータシステムのＣＰＵが実行するためのプログラムは、本発明によるプログラムを構成する。
【００５０】
このプログラムを格納するための記録媒体としては、光磁気ディスク、光ディスク、半導体メモリ、磁気記録媒体等を用いることができ、これらをＲＯＭ、ＲＡＭ、ＣＤ−ＲＯＭ、フレキシブルディスク、メモリカード等に構成して用いてよい。
【００５１】
また上記記録媒体は、インターネット等のネットワークや電話回線等の通信回線を介してプログラムが送信された場合のサーバやクライアントとなるコンピュータシステム内部のＲＡＭ等の揮発性メモリのように、一定時間プログラムを保持するものも含まれる。
【００５２】
また上記プログラムは、このプログラムを記憶装置等に格納したコンピュータシステムから伝送媒体を介して、あるいは伝送媒体中の伝送波により他のコンピュータシステムに伝送されるものであってもよい。上記伝送媒体とは、インターネット等のネットワーク（通信網）や電話回線等の通信回線（通信線）のように情報を伝送する機能を有する媒体をいうものとする。
【００５３】
また、上記プログラムは、前述した機能の一部を実現するためであってもよい。さらに、前述した機能をコンピュータシステムに既に記録されているプログラムとの組み合わせで実現できるもの、いわゆる差分ファイル（差分プログラム）であってもよい。
【００５４】
従って、このプログラムを図１のシステム又は装置とは異なるシステム又は装置において用い、そのシステム又は装置のコンピュータがこのプログラムを実行することによっても、上記実施の形態で説明した機能及び効果と同等の機能及び効果を得ることができ、本発明の目的を達成することができる。
【００５５】
以上、本発明の一実施形態を図面を参照して詳述してきたが、具体的な構成はこの実施形態に限られるものではなく、本発明の要旨を逸脱しない範囲の設計変更等があっても本発明に含まれる。
【００５６】
【発明の効果】
本願発明の太陽電池発電システムシミュレータによれば、ジュール熱を考慮した状態で、太陽電池モジュールの日射エネルギーの吸収率を求め、この吸収率に基づき吸収熱量を求め、かつ太陽電池モジュールの発熱するジュール熱自体も吸収熱量に対する補正として考慮に入れたため、季節と天候とに対応した状態での温度変化を図１０に示すように、実際に測定した温度とほぼ同様な温度変化の特性として得ることができる。
【００５７】
また、本願発明の太陽電池発電システムシミュレータによれば、季節と天候とに対応した状態での太陽電池モジュールの温度変化を演算し、これにより求まる各時刻範囲の太陽電池モジュールＭの温度に基づき、各時刻の発電電流Ｉを（３），（４）式（温度による補正式）により正確に求め、かつ、この発電電流Ｉに対応して太陽電池モジュールＭの温度が正確に算出されるため、この得られた太陽電池モジュールの温度を、次の時刻範囲において（３），（４）式の任意の温度Ｔ1として代入することにより、順次、正確な発電量を計算することが可能となる。
【００５８】
さらに、本願発明の太陽電池発電量シミュレータによれば、発電量演算部が、指定されたインバータの変換率のデータを、インバータデータベースから読み出し、この変換率のデータと、発電量補正演算手段の出力する発電量から最大出力点における電力との乗算を行い、これに太陽電池モジュールの数を乗算することにより、太陽電池発電システムの、季節毎，及び時間毎の予測発電量を演算することができるため、従来例のように、正確に演算された太陽電池モジュールの発電量が得られないため、住宅や事業所等に設置する太陽電池発電システムの精度の高いシミュレーションが行えないということが無くなり、設置する住宅や事業所のある地域，設置する場所，季節及び時間毎に適切な太陽電池発電システム構成を得ることができ、設置された太陽電池発電システムが、設置して実際に運転した場合に、十分な発電能力が無い場合や、不必要に大きな発電能力を有する場合などの発生を防止させる効果がある。
【図面の簡単な説明】
【図１】 本発明の一実施形態による太陽電池発電量シミュレータの構成を示すブロック図である。
【図２】 予測発電量と、この予測発電量時の出力電圧との関係を示す、発電量データベース６に記憶されているテーブルの形式を示す図である。
【図３】 太陽電池発電量シミュレータの算出するＩ−Ｖカーブを示す図である（横軸：太陽電池の出力電圧値Ｖ，縦軸：太陽電池の発電電流Ｉ）。
【図４】 インバータの種類と、その変換効率との関係を示す、インバータデータベース７に記憶されたテーブルの形式を示す図である。
【図５】 太陽電池モジュールにおける１秒間における温度変化量の概念を示す図である。
【図６】 太陽電池モジュールの温度の計算の概要を示す概念図である。
【図７】 太陽電池モジュールの温度の時刻変化を示す概念図である。
【図８】 太陽電池モジュールに入射する日射エネルギーの吸収率を求めるの式の概念を示す図である。
【図９】 太陽電池モジュールに入射する日射エネルギーの吸収率を求めるの式の概念を示す図である。
【図１０】 太陽電池モジュールに入射する日射エネルギーの吸収率を求めるために必要なデータの測定を行う測定系の構成を説明する概念図である。
【図１１】 図１における吸収率演算部２の求めた各時刻毎の吸収率を示す図である。
【図１２】 本願発明の太陽電池発電システムシミュレータの計算結果によるＩ-Ｖ特性と、実測した太陽電池モジュールＭのＩ-Ｖ特性とを比較した図である。
【図１３】 本願発明の太陽電池温度特性シミュレータの計算結果による時刻毎の温度変化と、実測した太陽電池モジュールの時刻毎の温度変化とを比較した図である。
【図１４】 発電量補正部５の演算するＩ（発電電流）-Ｖ（出力電圧）カーブと、Ｉ（発電電流）-Ｐ（電力）カーブとの関係を示す図である。
【図１５】 （１）式の基本となる太陽電池の等価回路を示す図である。
【符号の説明】
１ 吸収熱量演算部
２ 吸収率演算部
３ 温度補正部
４ 基準電流演算部
５ 発電量補正部
６ 発電量データベース
７ インバータデータベース
８ 発電量演算部
２０ 風速計
２１ 日射計
２２ 太陽電池受光面
２３ 電流測定用シャント抵抗
２４，２５ 熱電対
２６ 電子負荷
５０ 測定器
Ｍ 太陽電池モジュール[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a solar cell system characteristic simulator that simulates the amount of power generated by a solar cell power generation system installed in a house or business office based on the data of each database of solar cell output and inverter conversion efficiency.
[0002]
[Prior art]
In recent years, energy diversification and dispersion have begun to reduce oil consumption and to obtain clean electrical energy for the environment.
Among them, in solar power generation as renewable energy, power generation using solar cells is progressing with increasing conversion efficiency to convert solar solar radiation energy into electrical energy, so it is especially prosperous in houses and offices, etc. It is designed to be used in other facilities.
[0003]
In other words, because conversion efficiency has been improved, miniaturization and weight reduction have progressed, and it has become possible to easily install facilities even in houses.
Therefore, when installing a solar cell power generation system in each home or office, etc., it is necessary to satisfy the power required for each home and office based on the output capacity of the solar cell and the inverter conversion efficiency in advance. It is necessary to calculate the power generation amount of the solar cell power generation system by the solar cell power generation system and determine the configuration of the solar cell power generation system.
At this time, the output capacity of the solar cell for each solar cell module and the conversion efficiency corresponding to the load factor of the inverter, respectively stored in the solar cell database and the inverter database, are used for the above calculation.
[0004]
[Problems to be solved by the invention]
The conventional solar cell power generation system simulator calculates the amount of power generated by the solar cell module stored in the solar cell database, which is used to determine the power generation capacity of the solar cell power generation system when installed in a house or business office. Is performed by the following equation (1) based on the equivalent circuit of the solar cell shown in FIG.
I = Iph−Io (exp ((V + IRs) / a) −1) − (V + IRs) / Rsh (1)
Here, Iph is a photo-induced current corresponding to incident energy, V is a solar cell voltage, Io is a reverse saturation current, I is a solar cell power generation current, and Rs is a module resistance (resistance). Rsh is (resistance value) of leakage resistance.
[0005]
That is, the current output from the solar cell is the photocurrent IPh generated by solar radiation energy and the diode current “Io (exp ((V + IRs) / a) − that flows in the reverse direction because it is a diode device composed of a PN junction”. 1) ”, the leakage current“ (V + IRs) / Rsh ”that flows in the part where the PN junction is not completely formed.
When these are represented by an equivalent circuit, as shown in FIG. 11, the photocurrent Iph is a current source, the leakage current is proportional to the operating voltage, and therefore the leakage current Rsh, the diode current is the diode d, and the module resistance of the solar cell. And the sum of the resistances of the electrodes is represented as resistance Rs.
[0006]
In addition, in equation (1),
a = (Tc × ar) / Tcr (2)
Here, Tc is the temperature of the solar cell module, ar and Tcr are characteristic values stored in the database, the solar cell module is 25 ° C., and the absorbed solar radiation energy is “1.0 kW / m”.²The value in
[0007]
However, in the conventional solar cell power generation system simulator, when the power generation amount simulation is performed using the above-described equation (1), the calculation result diverges depending on the temperature, and the solar cell module in the solar cell database is necessary. There is a disadvantage that the numerical value of the power generation of the part cannot be obtained.
In addition, in the conventional solar cell power generation system simulator, the temperature of the solar cell module is obtained from the incident solar radiation energy, the outside air temperature, and the wind speed of the wind hitting the solar cell module, but is generated by the power generation current of the solar cell. Since Joule heat is not taken into account, there is a drawback that it is not possible to accurately simulate the amount of power generation corresponding to the temperature of the solar cell module.
[0008]
Therefore, since the conventional solar cell power generation system simulator does not calculate the power generation amount of the solar cell module accurately calculated as described above, the accuracy of the solar cell power generation system installed in a house or business office is not improved. There is a problem that high simulation cannot be performed and an appropriate system configuration cannot be obtained.
As a result, in the conventional solar cell power generation system simulator, when the solar cell power generation system installed as appropriate in the simulation result is installed and actually operated, there is not enough power generation capacity or unnecessarily large There is a problem that occurs when it has power generation capability.
[0009]
The present invention has been made under such a background. For the characteristic simulation of the solar cell power generation system, the power generation amount of the solar cell (solar cell module) is not diverged, and the temperature of the solar cell module is accurately adjusted. Solar cell power generation that can simulate the predicted power generation amount of a solar cell power generation system in accordance with actual use by using a solar cell database storing the accurate power generation amount of a solar cell module obtained by simulation based on Provide a system simulator.
[0010]
[Means for Solving the Problems]
  The solar cell power generation system simulator of the present invention is a solar cell power generation system simulator that calculates the amount of power generated by the solar cell power generation system corresponding to the surrounding environment, based on the reference temperature and the solar radiation energy to be evaluated. Calculate the generated current ofGenerated currentCalculation means (for example, reference current calculation unit 4) and temperature calculation means for calculating the temperature of the solar cell based on the ambient temperature to be evaluated, the wind speed hitting the solar cell and the solar radiation energy (for example, absorption heat amount calculation unit 1, absorption rate calculation) Unit 2, temperature correction unit 3), power generation amount correction calculation means (for example, power generation amount correction unit 5) that corrects the generated current and the output voltage based on this temperature, and an inverter used in the solar cell power generation system Based on an inverter database (for example, inverter database 7) that stores conversion efficiency for each type of inverter, the corrected power generation current and output voltage, and the conversion efficiency stored in the inverter database, a solar cell A power generation amount calculation unit (for example, a power generation amount calculation unit 8) that calculates a predicted power generation amount of the power generation system; Power generation quantity database that kind every corresponding memory (e.g., the power generation quantity database 6) and the providedThe temperature calculating means corrects the temperature of the solar cell obtained from the ambient temperature, the wind speed, and the incident energy by using Joule heat generated by the generated current of the solar cell.It is characterized by that.
[0011]
  The solar cell power generation system simulator of the present invention is characterized in that the temperature calculation means calculates the amount of heat generated by the solar radiation energy using the absorption rate corrected by the Joule heat.
  In the solar cell power generation system simulator of the present invention, the temperature calculation means is based on the average ambient temperature, wind speed and incident energy for each season,The temperature of the solar cellCalculate by seasonThe power generation amount calculation unit calculates the predicted power generation amount for each season and for each time according to the type of solar cell based on the temperature of the corresponding battery for each season calculated by the temperature calculation means. And store it in the power generation amount database.It is characterized by that.
[0012]
  The solar cell power generation system power generation amount calculation method of the present invention is a solar cell power generation amount calculation method for calculating the solar cell power generation amount corresponding to the surrounding environment, based on the reference temperature and the solar radiation energy to be evaluated, Calculate the solar cell power generation current for each output voltageGenerated currentA calculation process, a temperature calculation process for determining the temperature of the solar cell based on the ambient temperature to be evaluated, the wind speed of the wind hitting the solar cell, and the solar radiation energy, and a power generation amount correction calculation for correcting the power generation current and the output voltage based on this temperature The conversion efficiency storage process of storing the process and the conversion efficiency of the inverter used in the solar cell power generation system in the inverter database for each type of the inverter, the corrected generation current and output voltage, and the inverter database A power generation amount calculation process for calculating a predicted power generation amount of the solar cell power generation system based on the conversion efficiency, and a power generation amount storage process for storing the predicted power generation amount in a power generation amount database corresponding to each type of solar cell. And haveIn the temperature calculation process, the temperature of the solar cell determined by the ambient temperature, the wind speed, and the incident energy is corrected using Joule heat generated by the generated current of the solar cell.It is characterized by that.
[0014]
  The solar cell power generation system power generation amount calculation program of the present invention is a solar cell power generation system power generation amount calculation program for operating the solar cell power generation system simulator and calculating the solar cell power generation amount, and wants to evaluate it as a reference temperature. Calculates solar cell power generation current for each output voltage based on solar radiation energyGenerated currentCalculation processing, temperature calculation processing for obtaining the temperature of the solar cell based on the ambient temperature to be evaluated, the wind speed of the wind hitting the solar cell, and the solar radiation energy, and the power generation amount correction calculation for correcting the power generation current and the output voltage based on this temperature Processing, conversion efficiency storage processing for storing the conversion efficiency of the inverter used in the solar battery power generation system in the inverter database for each type of the inverter, the corrected generation current and output voltage, and the inverter database stored in the inverter database A power generation amount calculation process for calculating a predicted power generation amount of the solar battery power generation system based on the conversion efficiency, and a power generation amount storage process for storing the predicted power generation amount in a power generation amount database corresponding to each type of solar cell. And haveIn the temperature calculation process, the temperature of the solar cell obtained from the ambient temperature, the wind speed, and the incident energy is corrected using Joule heat generated by the generated current of the solar cell.It is characterized by that.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing a configuration of a solar cell power generation system simulator according to an embodiment of the present invention.
In this figure, the amount of heat absorption calculation unit 1 is based on the absorption rate per unit area obtained from the absorption rate calculation unit 2 with respect to the absorption of solar energy obtained as incident energy per unit time obtained by the solar cell. Calculate the amount of heat absorbed.
Moreover, the absorbed heat amount calculation part 1 calculates the Joule heat which generate | occur | produces in a solar cell based on the electric power generation current of a solar cell, and the module resistance of a solar cell module.
[0016]
Although described in detail later, the absorptance calculating unit 2 calculates the absorptance in consideration of Joule heat generated based on the generated current of the solar cell.
That is, the absorptance calculating unit 2 includes a first heat amount corresponding to a temperature change of the solar cell measured per unit time (for example, every hour) and a second heat amount radiated per unit time. A value obtained by subtracting the third heat amount of the Joule heat per unit time from the added value is divided by the amount of solar radiation incident per unit time, whereby the above-mentioned used for temperature characteristic simulation for each unit time Calculate the absorption rate.
[0017]
The temperature correction unit 3 calculates the amount of radiant heat radiated per unit time radiated by the solar cell based on the temperature difference between the outside air and the solar cell.
Moreover, the temperature correction | amendment part 3 subtracts the said radiant heat amount from the said absorbed heat amount, and calculates the amount of temperature changes per unit time (heat amount balance).
Furthermore, the temperature correction part 3 adds the said temperature change amount to the temperature of a solar cell, and calculates | requires the temperature transition of the solar cell per unit time.
[0018]
The power generation amount database 6 stores the characteristics of each solar cell (solar cell module area, weight, module resistance Rs, release voltage, short-circuit current, series resistance, etc.) corresponding to each type of solar cell. Has been.
That is, the power generation amount database 6 stores parameters used in the equations (1) to (7) performed by the solar cell power generation system simulator.
In addition, in the power generation amount database 6, the predicted power generation amount for each hour calculated by the power generation amount calculation unit 8 shown in FIG. 2 and the output voltage in the predicted power generation amount correspond to the solar cell power generation system, It is memorized every season.
Further, the database 6 stores standard weather data (standard weather data) statistically determined for each season and hour.
Here, the standard meteorological data refers to the temperature of the outside air on the characteristic days (sunny day, cloudy day, rainy day, etc.) of spring, summer, autumn and winter, the wind speed of the blowing wind, and the solar radiation for each time range. Energy data is stored and used for power generation simulation.
[0019]
The reference current calculation unit 4 calculates the current value (current value of the generated current) and the voltage value (voltage value of the output voltage) shown in FIG. 3 when the temperature of the solar cell module is a reference temperature of 25 ° C. ) (IV curve).
For example, the reference current calculation unit 4 has a solar radiation energy of 1 kW / m.²When calculating the amount of power generation at each temperature, the solar energy to be evaluated is 1 kW / m²And an IV curve is obtained by setting the solar cell temperature to 25 ° C.
[0020]
That is, the reference current calculation unit 4 calculates the generated current I for each voltage value in the reference state described above.
At this time, as the solar radiation energy, a value stored in the database 6 is used corresponding to a standard day of the season when the simulation of the power generation amount is performed.
[0021]
The power generation amount correction unit 5 corrects the power generation current and voltage in the IV curve in accordance with the temperature at which the simulation is performed using the following equations (3) and (4).
V₁= V₂−β (25−T₁) −Rs (I₂−I₁) -K ・ I₂(25−T₁)… (3)
I₁= I₂-Isc (1000 / E₁) −α (25−T₁) …(Four)
Here, T1 is an arbitrary temperature, that is, the temperature of the solar cell module for which the amount of power generation is desired. I1 is a current corresponding to an arbitrary temperature, that is, a generated current corresponding to a desired temperature. I2 is the current in the reference state, that is, the generated current obtained by equation (1). V1 is a voltage corresponding to an arbitrary temperature, that is, a voltage corresponding to a desired temperature. V2 is a voltage corresponding to the current in the reference state.
[0022]
Α is the temperature coefficient of the short circuit current, β is the temperature coefficient of the open circuit voltage, and Isc is the short circuit current.
The above α, β, Isc are numerical values described in the catalog for each solar cell.
As described above, the power generation amount correction unit 5 calculates the relationship between the power generation current at the desired temperature and the voltage from the IV curve in the standard state of FIG. 3 using the above equations (3) and (4). Similarly, an IV curve in an arbitrary state (at a desired temperature) shown in FIG. 3 is generated and output.
[0023]
The power generation amount calculation unit 8 obtains the maximum output point from the IV curve for each season and time output from the power generation amount correction unit 5, and the power generation amount at the maximum output point and the conversion stored in the inverter database 7. Based on the power generation amount of the solar cell module used and the conversion efficiency of the inverter, the predicted power generation amount for each season and time of the solar cell power generation system is calculated.
The inverter database 7 stores the conversion efficiency of the inverter from direct current to alternating current for each type of inverter used in the solar cell power generation system in the form of the table shown in FIG.
[0024]
Next, with reference to FIG.1 and FIG.5, the operation example of the solar cell power generation system simulator by one Embodiment is demonstrated.
FIG. 5 is a conceptual diagram showing an outline of the calculation of the temperature of the solar cell module.
From a terminal (not shown), the user inputs the type of solar cell module M constituting the solar cell power generation system simulator, the number of solar cell modules M, and the type of inverter used.
And a solar cell power generation system simulator performs the calculation by simulation about the electric power generation amount of each solar cell module as a 1st step.
This power generation amount is simulated and output every season and every hour.
Next, as a second step, the solar cell power generation system simulator obtains the total power generation amount of the solar cell modules used in the solar cell power generation system and multiplies the conversion efficiency of the inverter used for this total power generation amount. The predicted power generation amount of the solar cell power generation system designated by the user is obtained.
[0025]
Hereinafter, the simulation of the power generation amount in the first stage performed by the solar cell power generation system simulator will be described.
As a basic operation, first, as shown in FIG. 6, the solar cell temperature power generation system simulator adds the amount of temperature change from sunrise to a certain time to the solar cell temperature before sunrise. The solar cell temperature at the time is obtained.
Here, as shown in FIG. 7, the temperature change amount (Δt) is determined by the balance between the amount of heat absorbed and the amount of heat radiated (the amount of heat) from time t1 to time t2.
Further, as shown in FIG. 7, the temperature before sunrise is assumed to be the same as the outside air temperature because only the heat exchange with the outside air temperature (the outside air temperature) is performed.
[0026]
Conventionally, as described above, when the temperature change amount (Δt) in FIG. 7 is obtained, the items (2) and (3) as the temperature change amount for 1 second (unit time) shown in FIG. It was considered as a balance between “amount of heat per second due to absorption of solar radiation energy” and “amount of heat released per second due to temperature difference of outside air and surrounding wind”.
However, in the solar cell power generation system simulator of one embodiment, the amount of heat due to “Joule heat generated from the module resistance by the power generation current (I)” in the solar cell module M is considered as item (1).
[0027]
Here, the amount of heat as heat generated by absorption of the amount of solar radiation (sunlight energy) of item (2) is generated by absorbing particularly the long wavelength component of the solar radiation energy as heat.
Then, the absorbed heat amount calculation unit 1 calculates the amount of heat generated by the solar radiation energy by multiplying the incident incident solar radiation amount by the absorption rate.
Further, the temperature difference from the outside air of item (3) and the amount of heat radiated by the surrounding wind are calculated in the radiant heat amount calculation unit 3 by the following formula.
That is, the amount of heat radiated by the temperature difference from the outside air of item (3) and ambient wind is due to forced convection heat transfer, and the amount of radiated heat radiated into the air is Newton's cooling law, It is represented by the following formula (5).
[0028]
If the amount of radiant heat is qc,

It is expressed.
Where, θf: outside air temperature (° C.), θ: solar cell temperature (° C.), v: wind speed (m / s), αc: forced convection heat transfer coefficient (Eurges's experimental formula)
[0029]
Further, the amount of heat generated by the “joule heat generated from the module resistance by the generated current (I)” in the solar cell module M is “Rs · I” based on the resistance value Rs of the module resistance and the square of the generated current I.²”Is required.
In the conventional example, the amount of heat generated by the Joule heat described above is not taken into account in the change in the temperature of the solar cell, and the amount of heat generated by the Joule heat is included in the amount of heat generated by solar radiation energy to obtain the absorption rate of the solar cell. Therefore, it is considered that a large error occurs in the simulation value of the temperature change of the solar cell.
[0030]
That is, as shown in FIG. 8, the change in the amount of heat of the solar cell for 1 second (left side) is obtained by multiplying the changed temperature of the solar cell for 1 second by the specific heat of the solar cell module.
On the right side of FIG. 8, the first term is (1) the amount of heat generated per second due to the Joule loss (generation of Joule heat) described above, and the second term is (2) the amount of incident solar radiation (incident energy). The amount of heat generated in 1 second by absorption of solar radiation energy multiplied by the absorption rate, and the third term is the amount of heat released in 1 second due to temperature difference from ambient air and ambient wind.
[0031]
Therefore, when obtaining the absorption rate in consideration of Joule loss, the configuration shown in FIG.
And the absorptance calculating part 2 performs the calculation corresponding to the formula of FIG. 9, and calculates | requires the absorptivity of a solar cell module.
That is, the absorption rate is calculated from the value obtained by adding the amount of heat obtained by multiplying the changed temperature of the solar cell for 1 second by the specific heat of the solar cell module and the amount of heat of the above (3) in the absorption rate calculation unit 2. The amount of heat due to Joule loss of 1 ▼ can be subtracted, and this subtraction result can be obtained by dividing by the amount of incident solar radiation for 1 second.
[0032]
In this way, once the absorption rate calculation unit 2 obtains the heat absorption rate for each solar cell module, it becomes possible to accurately perform the simulation of the temperature characteristics of the solar cell module thereafter.
The exact absorption rate calculation formula used in the absorption rate calculation unit 2 is the following formula (6). ε (ω) = ((5.8 + 3.9v_(t)) (θ_(t)−θf_(t)) -I_(t)・ Rs²+ C (θ_(t)−θ_(t-1)))
/ It_(t)… (6)
[0033]
Here, the above formula is applied when the wind speed v is 5 m / s or less. When the wind speed exceeds 5 m / s, it is necessary to change the first term of the numerator on the left side according to the equation (5).
In equation (6), ε (ω) is the absorption rate, and It_(t)Is the solar radiation intensity (incident solar radiation) and θf_(t)Is the outside temperature and θ_(t)Is the temperature of the solar cell module and v_(t)Is the wind speed, I_(t)Is the generated current of the solar cell module M, t is the time, and Rs is the module resistance of the solar cell module.
[0034]
Each numerical value of the equation (6) used to calculate the absorption rate ε (ω) used in the absorption rate calculation unit 2 is measured at predetermined time intervals (for example, in units of 1 second) by the measuring device shown in FIG.
In FIG. 10, the measuring instrument 50 includes a wind speed v output by the anemometer 20 at each time._(t)Is measured, and the amount of solar radiation It received on the light receiving surface output from the pyranometer 21_(t)The value of the outside temperature θf is measured by the thermocouple 24_(t)And the temperature θ of the solar cell module is measured by the thermocouple 25._(t)Of the generated current I by the shunt resistor for current measurement._{( t)}And the measured values are output to the absorptance calculating unit 2.
[0035]
Here, the electronic load 26 adjusts the output voltage of the solar cell module M so that the generated power of the solar cell module M always becomes the maximum value (maximum output point) at that time. Control.
Then, the absorptance calculation unit 2 calculates the amount of solar radiation It obtained_(t)Wind speed v_(t), Outside temperature θf_(t), Solar module temperature θ_(t), Generation current I_(t)Based on (generated current I), the absorption rate ε (ω) is obtained by the equation (2).
[0036]
Here, as shown in FIG. 11, the absorptance calculating unit 2 calculates an average value of the absorptance measured at each time, and uses this average value as a final absorptance ε (ω) to calculate the absorbed heat amount. Output to part 1.
At this time, the absorption heat amount calculation unit 1 stores the absorption rate ε (ω) input from the absorption rate calculation unit 2 in the database 6 in association with each solar cell module.
[0037]
Next, when the amount of heat absorbed by the solar cell module is obtained by simulation, the absorption heat amount calculation unit 1 reads the absorption rate ε (ω) of the corresponding solar cell module from the database 6 and reads the absorption rate ε (ω ) To start the simulation.
At this time, the absorbed heat amount calculation unit 1 stores in the database 6 every predetermined time range of an average day of the season in which the simulation is performed (for example, 7 am to 8 am, 8 am to 9 am, etc.). Of solar radiation It set to every hour_(t)Is read out and this amount of solar radiation It_(t)Is multiplied by the absorption rate ε (ω) and the solar radiation energy at each time (for example, time per second, which is the unit of time of calculation, 8: 10: 2 after 8:10:01) Calculate the amount of heat.
[0038]
Further, the absorption heat amount calculation unit 1 is “I_(t) ²・ Rs_(t)The Joule heat is calculated from the formula
Here, the absorbed heat amount calculation unit 1 generates the generated current I corresponding to the temperature of the solar cell module before sunrise at the start of the simulation._(t)Is read from the database 6 and the generated current I_(t)Is used as an initial value to determine Joule heat.
Thereafter, the heat absorption amount calculation unit 1 generates the generated current I for each time range calculated based on the temperature obtained from the simulation in the temperature calculation unit 5._(t)Thus, the Joule heat for each time is obtained.
[0039]
At this time, the power generation amount correction unit 5 generates the power generation current I depending on the temperature of the solar cell module according to the above-described equations (1), (3), and (4)._(t)Obtain (generated current I).
Further, the temperature correction unit 3 stores in the database 6 the outside air temperature θf set for each predetermined time range (for example, every hour) of the average day of the season in which the simulation is performed._(t)And wind speed v_(t)Is used to calculate the amount of radiant heat qc using equation (5).
[0040]
Then, the temperature correction unit 3 performs the absorption heat amount “ε” calculated by the absorption heat amount calculation unit 1 based on the generated current I obtained by the power generation amount correction unit 5 at every predetermined time (for example, in units of one second). (ω) ・ It_(t)And Joule heat "I"_(t) ²・ Rs_(t)The radiant heat quantity qc is subtracted from the result of adding “”, and the resulting heat quantity balance is output to the temperature calculation unit 5.
And the temperature calculation part 5 integrates the said calorie | heat amount balance input for every said time range, and changes "C ((theta) of the calorie | heat amount for every time range of a solar cell module"._(t)−θ_(t-1)) ”.
[0041]
That is, the temperature calculation unit 5 calculates the following equation (7) based on the calculation results of the absorption heat amount calculation unit 1, the radiant heat amount calculation unit 3, and the temperature change calculation unit 4.
C (θ_(t)−θ_{(t - 1)}) ＝ ∫ [ε (ω) It_(t)+ I_(t) ²Rs_(t)−αc (θ−θf)] dt (7)
Here, C is specific heat.
Thereby, the temperature calculation part 5 integrates the heat amount change input for every time for every time range, and the temperature change amount ΔT for each time range (that is, (θ_(t)−θ_{(t - 1)})) Is obtained by dividing the left side by the specific heat C.
Then, the temperature calculation unit 5 calculates the temperature of the solar cell module for each time range by sequentially adding the obtained temperature change amount ΔT to the temperature of the immediately preceding time range.
[0042]
Here, the temperature calculation unit 5 in the solar cell power generation system simulator of the present invention calculates the solar energy module absorption rate in consideration of the Joule heat, and the Joule heat itself is also taken into account as a correction for the absorbed heat amount. Therefore, as shown in FIG. 12, the temperature change in a state corresponding to the season and the weather can be obtained as a temperature change characteristic substantially similar to the actually measured temperature of the solar cell module by the meter of FIG. it can.
[0043]
Then, the power generation amount correction unit 5 is configured to calculate each time range obtained by the temperature correction unit 3 from the time range after sunrise with respect to the reference power generation current I calculated by the reference current calculation unit 4 based on the formula (1). Is set to an arbitrary temperature T1, and the generated current and output voltage are corrected by using the equations (3) and (4), so that the amount of power generated by the solar cell module M at each time (that is, electric power, The product of the current I and the voltage value of the output voltage at that time is calculated.
Then, the temperature correction unit 3 sequentially subtracts the radiant heat amount from the added value of the Joule heat calculated by the absorbed heat amount calculation unit 1 based on the generated current I calculated by the power generation amount correction unit 5 and the absorbed heat amount by solar radiation energy. Thus, the temperature of the solar cell module M in each corresponding time range is calculated as described above.
[0044]
That is, in the solar cell power generation amount simulator of the present invention, the temperature correction unit 3 and the power generation amount correction unit 5 mutually calculate the temperature of the solar cell module and the generated current I of the solar cell module in the current time range obtained from each other. , The temperature of the solar cell module M and the generated current of the solar cell module M in the next time range are sequentially calculated.
Then, as a verification of the obtained IV curve value, an IV curve obtained by actual measurement using the IV curve based on the generated current and the output current calculated by the temperature correction unit 3 and the experimental system shown in FIG. Comparison with the curve was performed, and as a result, as shown in FIG. 13, the error between the calculated value and the measured value was within 3%.
[0045]
Next, the simulation of the predicted power generation amount in the second stage performed by the solar cell power generation system simulator will be described.
As shown in FIG. 14, the power generation amount calculation unit 8 sequentially outputs the power generation amount data output from the power generation amount correction unit 5, that is, the maximum output point (solar cell module) of the solar cell module M from the IV curve indicating the power generation amount. (Maximum value of power output by M).
Next, the power generation amount calculation unit 8 reads the conversion rate data of the designated inverter from the inverter database 7 and multiplies the conversion rate data by the power generation amount (electric power) at the maximum output point. Is multiplied by the number of solar cell modules to calculate the predicted power generation amount for each season and each hour of the solar cell power generation system.
[0046]
And the electric power generation amount calculation part 8 makes the electric power generation amount database 6 correspond to the kind of solar cell electric power generation system by the table of the format shown in FIG. Store sequentially for each hour.
Next, the power generation amount calculation unit 8 displays the table of FIG. 3 corresponding to the solar cell power generation system requested by the user from the terminal on a display unit (not shown).
Based on the predicted power generation amount displayed on the display unit, the user determines whether or not the designated solar cell power generation system is appropriate for the electric power used in the house or office to be installed.
As a result, in response to this predicted power generation value, the user can use other power with reference to the predicted power generation for each season and time, depending on the area where the power is used. A type of solar cell power generation system is selected, and the above-described simulation of the predicted power generation amount of the solar cell power generation system is performed again.
[0047]
And since the temperature change of a solar cell module can be correctly calculated for every time by using the corresponding battery power generation amount simulator of this invention, the simulation of the power generation amount of a solar cell module can be performed correctly. effective.
That is, the solar cell power generation amount simulator of the present invention calculates the temperature change of the solar cell module in a state corresponding to the season and the weather, and based on the temperature of the solar cell module M in each time range obtained thereby, each time Since the generated current I of the solar cell module M is accurately obtained by the formulas (3) and (4) (correction formula based on temperature) and the temperature of the solar cell module M is accurately calculated corresponding to the generated current I, By substituting the obtained temperature of the solar cell module as an arbitrary temperature T1 in the equations (3) and (4) in the next time range, it becomes possible to calculate an accurate power generation amount sequentially.
[0048]
By using the solar cell power generation amount simulator of the present invention, the power generation amount calculation unit 8 reads the conversion rate data of the designated inverter from the inverter database 7, and the conversion rate data and the power generation amount correction unit 5 Multiplying the output power generation amount with the power at the maximum output point, and multiplying this by the number of solar cell modules, to calculate the predicted power generation amount for each season and time of the solar cell power generation system Therefore, unlike the conventional example, since the power generation amount of the solar cell module calculated accurately cannot be obtained, it is no longer possible to perform a highly accurate simulation of the solar cell power generation system installed in a house or business office. Appropriate solar cell power generation system configuration can be obtained for each area where the house or business is installed, where it is installed, the season, and the time. Installed solar cell power generation system, when operated actually installed, an effect of prevention and if there is not enough power generation capacity, the occurrence of a case with a large power generation capacity unnecessarily.
[0049]
Next, a program executed by the computer according to the embodiment of the present invention will be described.
The program executed by the CPU of the computer system in the solar cell temperature characteristic simulator that simulates the temperature characteristic of the solar cell module in FIG. 1 constitutes a program according to the present invention.
[0050]
As a recording medium for storing this program, a magneto-optical disk, an optical disk, a semiconductor memory, a magnetic recording medium, and the like can be used, and these are configured as a ROM, a RAM, a CD-ROM, a flexible disk, a memory card, and the like. May be used.
[0051]
In addition, the recording medium can store a program for a certain period of time, such as a volatile memory such as a RAM in a computer system serving as a server or a client when the program is transmitted via a network such as the Internet or a communication line such as a telephone line. The thing to hold is also included.
[0052]
The program may be transmitted from a computer system storing the program in a storage device or the like to another computer system via a transmission medium or by a transmission wave in the transmission medium. The transmission medium refers to a medium having a function of transmitting information, such as a network (communication network) such as the Internet or a communication line (communication line) such as a telephone line.
[0053]
The program may be for realizing a part of the functions described above. Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, what is called a difference file (difference program) may be sufficient.
[0054]
Therefore, even if this program is used in a system or apparatus different from the system or apparatus of FIG. 1 and the computer of the system or apparatus executes this program, the functions equivalent to the functions and effects described in the above embodiments are also provided. And the effect of the present invention can be achieved.
[0055]
As mentioned above, although one embodiment of the present invention has been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment, and there are design changes and the like without departing from the gist of the present invention. Are also included in the present invention.
[0056]
【The invention's effect】
According to the solar cell power generation system simulator of the present invention, in consideration of Joule heat, the solar energy module's solar energy absorption rate is obtained, the amount of heat absorbed is obtained based on this absorption rate, and the solar cell module generates heat. Since the heat itself is also taken into account as a correction for the amount of absorbed heat, the temperature change in a state corresponding to the season and the weather can be obtained as a temperature change characteristic almost similar to the actually measured temperature as shown in FIG. it can.
[0057]
Further, according to the solar cell power generation system simulator of the present invention, the temperature change of the solar cell module in a state corresponding to the season and the weather is calculated, and based on the temperature of the solar cell module M in each time range obtained thereby, Since the power generation current I at each time is accurately obtained by the formulas (3) and (4) (correction formula by temperature), and the temperature of the solar cell module M is accurately calculated corresponding to the power generation current I, By substituting the obtained temperature of the solar cell module as an arbitrary temperature T1 in the expressions (3) and (4) in the next time range, it becomes possible to calculate an accurate power generation amount sequentially.
[0058]
Furthermore, according to the solar cell power generation amount simulator of the present invention, the power generation amount calculation unit reads the conversion rate data of the designated inverter from the inverter database, and outputs the conversion rate data and the power generation amount correction calculation unit. By multiplying the power generation amount with the power at the maximum output point and multiplying this by the number of solar cell modules, the predicted power generation amount for each season and time of the solar cell power generation system can be calculated. Therefore, unlike the conventional example, since the power generation amount of the solar cell module calculated accurately cannot be obtained, it is not possible to perform a high-accuracy simulation of the solar cell power generation system installed in a house or business office, An appropriate solar cell power generation system configuration can be obtained for the area where the house or business is installed, the place where it is installed, the season, and the time, Location solar cell power generation system, when operated actually installed, an effect of prevention and if there is not enough power generation capacity, the occurrence of a case with a large power generation capacity unnecessarily.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a solar cell power generation amount simulator according to an embodiment of the present invention.
FIG. 2 is a diagram showing a format of a table stored in a power generation amount database 6 showing a relationship between a predicted power generation amount and an output voltage at the time of the predicted power generation amount.
FIG. 3 is a diagram showing an IV curve calculated by a solar cell power generation amount simulator (horizontal axis: output voltage value V of solar cell, vertical axis: power generation current I of solar cell).
FIG. 4 is a diagram showing the format of a table stored in an inverter database 7 showing the relationship between the type of inverter and its conversion efficiency.
FIG. 5 is a diagram showing a concept of a temperature change amount in one second in a solar cell module.
FIG. 6 is a conceptual diagram showing an outline of the calculation of the temperature of the solar cell module.
FIG. 7 is a conceptual diagram showing the time change of the temperature of the solar cell module.
FIG. 8 is a diagram showing a concept of an expression for obtaining an absorption rate of solar energy incident on a solar cell module.
FIG. 9 is a diagram showing a concept of an expression for obtaining an absorption rate of solar energy incident on a solar cell module.
FIG. 10 is a conceptual diagram illustrating a configuration of a measurement system that performs measurement of data necessary for obtaining an absorption rate of solar radiation incident on a solar cell module.
FIG. 11 is a diagram showing the absorption rate at each time obtained by the absorption rate calculation unit 2 in FIG. 1;
12 is a diagram comparing the IV characteristics obtained by the calculation results of the solar cell power generation system simulator of the present invention and the actually measured IV characteristics of the solar cell module M. FIG.
FIG. 13 is a diagram comparing a temperature change for each time according to a calculation result of the solar cell temperature characteristic simulator of the present invention and a temperature change for each time of an actually measured solar cell module.
FIG. 14 is a diagram showing a relationship between an I (generated current) -V (output voltage) curve and an I (generated current) -P (power) curve calculated by the power generation amount correction unit 5;
FIG. 15 is a diagram showing an equivalent circuit of a solar cell that is the basis of equation (1).
[Explanation of symbols]
1 Absorption calorie calculation part
2 Absorption rate calculator
3 Temperature correction part
4 Reference current calculator
5 Power generation correction part
6 Power generation database
7 Inverter database
8 Power generation amount calculation part
20 Anemometer
21 pyranometer
22 Photosensitive surface of solar cell
23 Shunt resistor for current measurement
24, 25 Thermocouple
26 Electronic load
50 measuring instrument
M solar cell module

Claims (5)

In the solar cell power generation system simulator that calculates the power generation amount of the solar cell power generation system corresponding to the surrounding environment,
Based on the reference temperature and the solar radiation energy to be evaluated, generated current calculating means for calculating the generated current of the solar cell for each output voltage,
Temperature calculation means for obtaining the temperature of the solar cell by the ambient temperature to be evaluated, the wind speed of the wind hitting the solar cell and the solar radiation energy;
A power generation amount correction calculating means for correcting the power generation current and the output voltage based on the temperature;
An inverter database for storing the conversion efficiency of the inverter used in the solar cell power generation system for each type of the inverter;
A power generation amount calculation unit that calculates a predicted power generation amount of the solar cell power generation system based on the corrected power generation current and output voltage and the conversion efficiency stored in the inverter database;
A power generation amount database that stores the predicted power generation amount corresponding to each type of solar cell , and
The solar cell power generation system simulator , wherein the temperature calculation means corrects the temperature of the solar cell obtained from the ambient temperature, the wind speed, and the incident energy using Joule heat generated by the power generation current of the solar cell. 2. The solar cell power generation system simulator according to claim 1, wherein the temperature calculation unit calculates an amount of heat generated by the solar radiation energy using an absorptance corrected by the Joule heat. The temperature calculating means calculates the temperature of the solar cell for each season based on the average ambient temperature, wind speed and incident energy for each season ,
Based on the temperature of the corresponding battery for each season calculated by the temperature calculation unit, the power generation amount calculation unit calculates the predicted power generation amount for each season and every time, corresponding to the type of solar cell, solar cell power generation system simulator according to claim 1 or claim 2, characterized in that to be stored in the power generation quantity database. In the calculation method of the solar cell power generation amount that calculates the power generation amount of the solar cell corresponding to the surrounding environment,
Based on the reference temperature and the solar radiation energy to be evaluated, a generation current calculation process for calculating the generation current of the solar cell for each output voltage,
A temperature calculation process for determining the temperature of the solar cell by the ambient temperature to be evaluated, the wind speed of the wind hitting the solar cell and the solar radiation energy;
A power generation amount correction calculation process for correcting the power generation current and the output voltage based on this temperature,
Conversion efficiency storage process of storing the conversion efficiency of the inverter used in the solar cell power generation system in the inverter database for each type of the inverter,
Based on the corrected power generation current and output voltage and the conversion efficiency stored in the inverter database, a power generation amount calculation process for calculating a predicted power generation amount of the solar cell power generation system,
In response to each type of solar cell, have a power generation amount memory process of storing the prospective power generation amount in the power generation quantity database,
In the temperature calculation process, the solar cell power generation amount generated by correcting the temperature of the solar cell determined by the ambient temperature, the wind speed, and the incident energy by using Joule heat generated by the power generation current of the solar cell. Calculation method. A solar cell power generation system power generation amount calculation program for operating the solar cell power generation system simulator according to claim 1 to calculate a solar cell power generation amount,
Based on the reference temperature and the solar radiation energy to be evaluated, the generated current calculation process for calculating the generated current of the solar cell for each output voltage,
A temperature calculation process for obtaining the temperature of the solar cell by the ambient temperature to be evaluated, the wind speed of the wind hitting the solar cell, and the solar radiation energy; and
Power generation amount correction calculation processing for correcting the power generation current and the output voltage based on this temperature;
Conversion efficiency storage processing for storing the conversion efficiency of the inverter used for the solar cell power generation system in the inverter database for each type of the inverter,
Based on the corrected power generation current and output voltage, and the conversion efficiency stored in the inverter database, a power generation amount calculation process for calculating a predicted power generation amount of the solar cell power generation system,
In response to each type of solar cell, it has a power generation amount storage process for storing the predicted power generation amount of the power generation quantity database,
In the temperature calculation process, the temperature of the solar cell obtained by the ambient temperature, the wind speed, and the incident energy is corrected using Joule heat generated by the power generation current of the solar cell. Power generation amount calculation program.

Images