JP4730578B2 - Hot water storage water heater - Google Patents

Description

【００５３】
ここで第１項の「最新データ」は、現在の一秒間の貯湯部２内の湯温平均であり、現在の湯温を表す。
そして第２項、第３項が付加される補正値である。
ここで第２項の「最新データ−５秒前データ」は、貯湯部２の湯温と時間との関係曲線（温度曲線）の微分値に相当する数値であり、過去の第一温度センサ３２の検知値に基づいて演算された温度の変化の傾向に関する情報である。なお「５秒前データ」とは、５秒前における１００ｍｓごとのサンプリングデータを１０回加算平均したものである。
【００５４】
また第３項の「（最新データ−５秒前データ）−（５秒前データ−１０秒前データ）」は、温度曲線の二回微分値に相当する数値であり、過去の第一温度センサ３２の検知値に基づいて演算された温度の変化の傾向に関する情報である。なお「１０秒前データ」とは、１０秒前における１００ｍｓごとのサンプリングデータを１０回加算平均したものである。
【００５５】
こうして演算された微分データをＯＮ・ＯＦＦ制御の指標とする。例えば４０°Ｃの出湯を得ようとすると、式１で演算された微分データの値が３０°Ｃを下回った時に燃焼部６に点火指令を発信して燃焼部６を燃焼させる。また式１で演算された微分データの値が３１°Ｃを上回った時にバーナを消火する。
【００５６】
なお、式１は、次の式２の様に変形して演算してもよい。
【００５７】
【数２】

【００５８】
式２は、式１の第３項の「（最新データ−５秒前データ）−（５秒前データ−１０秒前データ）」を「（最新データ−５秒前データ）＋（５秒前データ−１０秒前データ）」として式をまとめたものである。「（最新データ−５秒前データ）＋（５秒前データ−１０秒前データ）」は、厳密には二回微分値ではないが、最終項をこの様に変形することにより、値の変位量が増大し、制御の応答性が向上する。
【００５９】
また上記した式１の第２項及び第３項に適当な定数を乗じてもよい。
【００６０】
さらに前記した様に、本実施形態の貯湯式給湯器１では、ＯＮ・ＯＦＦ制御の切り替え基準値が第二温度センサ３３の検知値によって補正される。
すなわち本実施形態の制御装置では、第二温度センサ３３の検知値を利用して次の演算が行われ、補正係数αが算出される。
【００６１】
【数３】

【００６２】
上記した式２は、第二温度センサ３３の検知値と設定温度の偏差に関する情報であり、設定温度と第二温度センサ３３の検知値の偏差を積算するものである。
すなわち本実施形態では、設定温度と第二温度センサ３３の検知値の偏差に一定の定数βを掛けて積算し、これに一定の定数γを掛けたものである。前記した定数β及びγは、経験則によって得られる数値であるが、定数βは１／１０〜１／３０程度、定数γは１／２〜１／４程度が適当である。本実施形態では、定数βは１／２０、定数γは１／３を採用している。
「Σγ（設定温度−出湯温度）」は、その絶対値が１以上の場合のみカウントする。本実施形態では、定数γが１／３であるから、「（設定温度−出湯温度）」が３以上となった時のみαが０以外の数となる。
【００６３】
このように本実施形態では、「（設定温度−出湯温度）」の値、すなわち第二温度センサ３３の検知値と設定温度の偏差が一定未満である場合には積算の対象としない。
僅かな偏差についても積算の対象とすると、長期間使用する内に偏差の積算値が累積され、動作が不安定になるためである。
【００６４】
本発明の貯湯式給湯器１では、第二温度センサ３３の検知値とリモートコントローラ３６によって設定された設定温度の偏差が一定未満である場合には偏差積算手段は積算の対象としない。そのため補正値が安定する。
【００６５】
補正係数αは、第一温度センサ３２の検知温度が、実際の出湯温度（第二温度センサの検知温度）に対して高めであるか低めであるかを示す指標となる。
【００６６】
上記した補正係数αの算出は、燃焼部６のバーナがＯＮ・ＯＦＦされて燃焼制御がなされている間、連続的に演算される。しかしながら一般に貯湯式給湯器１では、給湯を停止した後に燃焼室２０に残留する熱によって貯湯部２の湯水の温度が上昇する。これは後沸きと称される現象であり、このような後沸き時の温度上昇を積算することは好ましくない。すなわち後沸きは、給湯が停止された際に起こる現象であり、この時は、貯湯式給湯器１の貯湯部２への水の流入は無い。そのため貯湯部２内に残留した湯水は、通常の制御範囲を越えて温度上昇する。したがってこの様な後沸き時の温度上昇を積算データに加えると、積算値が歪なものとなり、前記した補正係数αが過度に小さくなる。
【００６７】
また同様に、長時間に渡って運転を停止した後に燃焼部６に点火した場合についても積算データに加えるべきではない。
すなわち運転スイッチや電源スイッチを停止した場合の様に、長時間に渡って燃焼制御が行われていない状態が続くと、貯湯部２内の湯水の温度がすっかり低下してしまい、燃焼の初期においては第一温度センサ３２の検知値と設定温度の偏差が極めて大きなものとなる。そのため貯湯部２の湯水の温度が低下している際における第一温度センサ３２の検知値と設定温度の偏差を積算することは好ましくない。
【００６８】
そこで本発明は、後沸き時や点火初期の立ち上げ時における特異な状態の時を積算から除外する制御プログラムを採用している。
本実施形態が採用する補正係数αを演算するプログラムは、図２の通りである。
すなわち運転の最中においては、ステップ１によってリモートコントローラ３６によって設定された設定温度を取得する。そしてステップ２に移行し、実際の出湯温度を取得する。本実施形態においては第二温度センサ３３の検知温度を実際の出湯温度として取得する。
【００６９】
そしてステップ３に移行し、燃焼部６がＯＮ状態であるか否かを確認する。すなわち燃焼部６のバーナに点火された状態であるか否かを確認する。
ステップ３で燃焼部６がＯＮ状態であるか否かを確認したのは、前記した様に後沸き時と初期の立ち上げ時を除外するためである。
すなわちもし初期の立ち上げ時であるならば、少なくとも燃焼部６がＯＮ状態であるはずであり、もし後沸き時であるならば、少なくとも燃焼部６はＯＦＦ状態であるはずである。
【００７０】
そこでステップ３でまず燃焼部６がＯＮ状態であるか否かを確認し、ステップ３で燃焼部６がＯＮ状態であるならばステップ４へ移行して初期の立ち上げ状態であるか否かを検討し、ステップ３で燃焼部６がＯＦＦ状態であるならばステップ５へ移行して後沸き状態であるか否かを検討する。
【００７１】
たとえばステップ３で燃焼部６がＯＮ状態であることが分かると、ステップ４に移行して出湯温度（第二温度センサ３２の検知温度）と設定温度の差を調べる。ここで通常運転時であって燃焼部６がＯＮ状態であるならば、言い換えると、通常のＯＮ・ＯＦＦ制御がなされている状態で燃焼部６がＯＮ状態であるならば、出湯温度が設定温度に比べてさほど低くなることはない。すなわち燃焼部６が通常運転されていれば、出湯温度は設定温度に比べて数度の範囲で振幅しているはずであるから、少なくとも燃焼部６がＯＮ状態であるならば出湯温度が設定温度を大きく下回ることはない。
【００７２】
したがってもし燃焼部６がＯＮ状態であるにもかかわらず、出湯温度が設定温度を大きく下回っているならば、貯湯部２内の湯水の温度が相当に低いと考えられ、初期の立ち上げ状態であると予想される。
ここで出湯温度がどの程度、設定温度よりも下であれば初期の立ち上げ状態であると推定するかは、機器の制御能力等によって判断すべき事項であるが、通常３°Ｃから８°Ｃ程度下であれば初期の立ち上げ状態であると考えてよい。本実施形態では、出湯温度が「設定温度−５°Ｃ」以下であれば、初期の立ち上げ状態であると判断し、最終ステップに移行する。
【００７３】
またステップ４で出湯温度が「設定温度−５°Ｃ」より高ければ、ステップ６以降に移行して温度上昇の積算を行う。すなわち燃焼部６がＯＮ状態であって、出湯温度が設定温度に比べて一定の温度（設定温度−５°Ｃ）以上であるならば設定温度と第二温度センサ３３の検知値の偏差を積算する。また燃焼部６がＯＮ状態であって、出湯温度が設定温度に比べて一定の高さに満たない場合は、設定温度と第二温度センサ３３の検知値の偏差積算から除外する。
【００７４】
一方、ステップ３で燃焼部６がＯＦＦ状態であることが分かると、ステップ５に移行して出湯温度（第二温度センサ３３の検知温度）と設定温度の差を調べる。前記した様に通常運転時であって燃焼部６が０ＦＦ状態であるならば、言い換えると、通常のＯＮ・ＯＦＦ制御がなされている状態で燃焼部６がＯＦＦ状態であるならば、出湯温度が設定温度に比べてさほど高くなることはない。前記した様に燃焼部６が通常運転されていれば、出湯温度は設定温度に比べて数度の範囲で振幅しているはずであるから、少なくとも燃焼部６がＯＦＦ状態であるならば出湯温度が設定温度を大きく上回ることはない。
【００７５】
したがってもし燃焼部６がＯＦＦ状態であるにもかかわらず、出湯温度が設定温度を大きく上回っているならば、貯湯部２内に新しい水が入水していないと考えられ、後沸き状態であると予想される。
ここで出湯温度がどの程度、設定温度よりも上回れば後沸き状態であると推定するかは、機器の制御能力等によって判断すべき事項であるが、通常３°Ｃから８°Ｃ程度上であれば後沸き状態であると考えてよい。本実施形態では、出湯温度が「設定温度＋５°Ｃ」より高ければ後沸きであると判断し、最終ステップに移行する。
【００７６】
またステップ４で出湯温度が「設定温度＋５°Ｃ」未満であれば、ステップ６以降に移行して温度上昇の積算を行う。すなわち燃焼部６がＯＦＦ状態であって、出湯温度が設定温度に比べて一定温度（設定温度＋５°Ｃ）未満であるならば設定温度と第二温度センサ３３の検知値の偏差を積算する。また燃焼部６がＯＮ状態であって、出湯温度が設定温度に比べて一定の高さ以上であれば、設定温度と第二温度センサ３３の検知値の偏差積算から除外する。
【００７７】
ステップ６に移行すると、前記した式３によって補正係数αを演算する。
そしてステップ７によって補正係数を加算してゆく。ステップ６，７によって設定温度と第二温度センサ３３の検知値の偏差を積算される。またステップ６，７によって設定温度と第二温度センサ３３の検知値の偏差の積分値が得られる。
【００７８】
そしてステップ８に移行し、制御装置のメモリーに格納されたデータテーブルを読み出し、補正係数αに対する適正補正量を決定する。
ここで設定温度と第二温度センサ３３の検知値の偏差の積算値（積分値）が一定の値に達している場合は、ステップ９でデータテーブルに従って燃焼部６のＯＮ・ＯＦＦ温度を変更する。すなわちＯＮ又はＯＦＦの基準温度を上下にずらす。
例えばそれまでは第一温度センサ３２の検知温度（微分による補正を含む）が３０°Ｃの時に点火が開始され、３０．５°Ｃで消火されていたものを補正係数αの値に応じて上下にずらし、３０．５°Ｃで点火が開始され、３１．５°Ｃで消火される様に変更する。
補正係数αの値が小さい場合は、ＯＮ・ＯＦＦの基準温度は従来のものがそのまま維持される。
そして最終ステップに移行し、以後、上記した制御を繰り返す。
【００７９】
次に、本実施形態の貯湯式給湯器１の全体的な動作について説明する。
本実施形態の貯湯式給湯器１では、基本的に第一温度センサ３２の検知値によってバーナがＯＮ・ＯＦＦ制御されるが、前記した様に第一温度センサ３２の検知値に、微分演算によって補正値が付加され、さらに、ＯＮ・ＯＦＦ制御の切り替え基準値が補正係数αに基づいて所定量だけずれる。
すなわち本実施形態の貯湯式給湯器１は、第二温度センサ３３の検知値と設定温度の偏差に関する情報に基づいて燃焼状態の補正がなされ、且つ過去の第一温度センサ３２の検知値に基づいて温度の変化の傾向に関する情報が演算されてこの情報に基づいて燃焼状態が補正される。本実施形態の貯湯式給湯器１は、このように特殊な補正処理がなされているので、全体的な動作についてもこれに合致したものとする配慮が必要である。
【００８０】
特に本実施形態では、第一温度センサ３２の検知値に、微分演算によって補正値が付加されているが、式１の第３項たる「（最新データ−５秒前データ）−（５秒前データ−１０秒前データ）」は、温度曲線の二回微分値に相当する数値であり、温度変化に対する数値の変化は数倍に拡大される。また補正後の値の変化は、第一温度センサ３２の温度変化よりも位相が進んだものとなる。
【００８１】
そのため第一温度センサ３２の検知値の変化によって補正後の数値（式１による補正）が大きく変化し、数値がＯＮ・ＯＦＦの切り替え基準値近傍で脈動する危険がある。
したがって本実施形態では、数１の様に微分的な演算処理をしているため、チャタリングが生じやすい。
そこで本実施形態の制御手段を採用する際には、チャタリングを防止する機能を付与しておくことが望ましい。
【００８２】
またチャタリングが生じないまでも短周期でＯＮ・ＯＦＦを繰り返すこととなるためにノズル２８に燃えかすのタール等が付着しやすいという問題がある。特に、灯油等の液体燃料を使用する燃焼装置では、燃焼に先立って送風機を運転してプリパージを行う必要があり、さらにプリイグニッション動作や点火動作に時間がかかる。そのためこれらの燃焼に先立って行われる動作の長短によっても実燃焼時間が左右されてしまう。
その結果、実際に燃焼する時間がごく短いものとなってしまう場合もあり、ノズル２８へのタール付着が懸念される。
【００８３】
そこで本実施形態では、チャタリングを防止するため、点火するべき温度と消火すべき温度の間に差異を設けた。たとえば３０°Ｃ未満の温度を第一温度センサ３２が検知したとき（微分による補正量を含む）に燃焼部６が点火ＯＮとなり、３１°Ｃ以上の温度を第一温度センサ３２が検知すると（微分による補正量を含む）燃焼部６が消火されるという様に、点火のＯＮとＯＦＦの間に幅が設けられている。ただしこのＯＮすべき温度の値とＯＦＦすべき温度の値は、第二温度センサ３３と設定値との偏差によって補正される。
【００８４】
またチャタリングやタールの付着を防止するため、最短の実燃焼時間や、最短の総燃焼時間（プリパージ等の時間を含めた燃焼時間）を設定しておき、一旦燃焼指令が発せられた場合は、この時間のいずれかが経過する前には燃焼を停止しない構成とした。また同様に、一旦消火指令が発せられた場合は、相当の時間が経過する前には点火されない構成とした。
【００８５】
以下、図３を参照しつつ、本実施形態の全体的な動作について説明する。
本実施形態の貯湯式給湯器１で採用する制御のプログラムは、図３に示すステップ１〜１４を高速で繰り返し、第一温度センサ３２の温度を監視して当該温度（補正値）がＯＮ・ＯＦＦの基準温度（補正値）になるか否かを確認している。また第一温度センサ３２がＯＮすべき温度を検知した後、プリパージ等を含めて十分な時間が経過するか否か、あるいは点火後に所定の時間が経過したか否かを確認し、これらのいずれかの時間が経過するまでは消火とならない。
さらに第一温度センサ３２がＯＦＦとなるべき温度を検知した後、所定の時間が経過したか否かを確認し、所定の時間が経過するまでは再点火とならない。
【００８６】
図３に沿って説明すると、例えば今、燃焼部６が消火状態であるとすると、先にステップ１０で設定されていた最短燃焼ＯＦＦ指令時間が経過しているか否かを確認する。
そしてステップ１で給湯モードが「燃焼以外であるか」否かが確認される。より具体的には点火された状態であるか否かが確認される。
前記した様に消火状態であればステップ２に移行し、最短実燃焼時間タイマをセットする。本実施形態で、最短実燃焼時間タイマは、タール等の付着を防止するために連続燃焼させるべき最低の時間であり、４秒の時間がセットされる。
【００８７】
そして続いてステップ３で第二温度センサ３３が正常に作動しているか否かを確認する。第二温度センサ３３が正常であればステップ４に移行し、第二温度センサ３３の温度が９０℃未満であるか否かを確認する。
本実施形態では、前記した様に、最短実燃焼時間の設定や、最短の総燃焼時間（プリパージ等の時間を含めた燃焼時間）を設定しているから、貯湯部内の水温が予期しない高温となる場合もある。そこで本実施気形態では第二温度センサ３３の温度を監視し、９０℃未満でないならばステップ９に移行して給湯燃焼指令をＯＦＦし、燃焼停止や異常表示等の異常時の動作を行なう。
【００８８】
一方、第二温度センサ３３の温度が９０℃未満であればステップ５に移行して給湯燃焼指令がＯＮであるか否かを確認する。前記した仮定の様に燃焼部６が消火状態であれば給湯燃焼指令はＯＮではないから、ステップ５はＮＯとなり、ステップ１１に移行する。
【００８９】
また前記したステップ３で第二温度センサ３３が不良である事が分かると、ステップ４を飛ばしてステップ５に移行し、さらにステップ１１に移行する。
【００９０】
ステップ１１では第一温度センサ３２の温度が燃焼部６を点火すべき温度まで下がっているか否かを確認する。ここで第一温度センサ３２の温度とは、前記した式１によって補正された値である。また燃焼部６を点火すべき温度についても補正係数αによって補正された値である。
【００９１】
実際に貯湯部２内の湯水の温度が高い場合には、ステップ１４に移行し、最短燃焼指令ＯＮ時間タイマをセットする。そして最終ステップに移行し、再度同様のフローが再開される。
再度のフロー動作では、前回と同一の工程をたどり、ステップ１１至る。そしてまだ貯湯部２内の湯水の温度が高い場合には、再度ステップ１４に移行し、最短燃焼指令ＯＮ時間タイマを再セットする。そして最終ステップに移行し、再度同様のフローが再開される。
そのため実質的に、ステップ１１において、第一温度センサ３２の検知温度が燃焼部６の燃焼を点火すべき温度以下になることを待つ結果となる。
【００９２】
そして時間が経過し、貯湯部２内の湯水の温度が低下してステップ１１で第一温度センサ３２の温度が燃焼部６を点火すべき温度に至っていることが分かると、ステップ１２に移行し、最短燃焼ＯＦＦ指令時間が経過しているか否かを確認する。
最短燃焼ＯＦＦ指令時間が経過していれば、チャタリングの危険性は無いので、ステップ１３に移行し、給湯燃焼指令をＯＮする。すなわち燃焼部６への点火指令を出す。
そして最終ステップに移行し、再度ステップ１からのステップを繰り返す。
【００９３】
また最短燃焼ＯＦＦ指令時間が経過していなければチャタリングの危険があるので、ステップ１４に移行し、最短燃焼指令ＯＮ時間タイマを再セットし、最終ステップに移行し、再度同様のフローが再開されてステップ１４に至る。
こうしてステップ１〜ステップ１４までの動作を繰り返す内、最短燃焼ＯＦＦ指令時間が経過するとステップ１２がＹＥＳとなり、ステップ１３へ移行して給湯燃焼指令をＯＮする。すなわち燃焼部６への点火指令を出す。
【００９４】
次回のフローでは、先のフローのステップ２で設定された最短実燃焼時間が計時されている。なお、最短実燃焼時間の計時が開始されたのは、理論的にステップ１３の給湯燃焼指令が発せられた後であるが、実際の制御装置では電気的速度でフローチャートの工程を行なっているので、実質上は給湯燃焼の指令と最短実燃焼時間の計時は同時である。
【００９５】
今回のフローでは、先のフローのステップ１３で給湯燃焼指令がＯＮされているが、実際に点火されているか否か不明である。もし点火がなされていなければステップ２に移行し最短実燃焼時間のタイマをリセットする。
そしてステップ３で第二温度センサ３３の動作が確認され、さらにステップ４、ステップ５と進む。
ステップ５では、前記した通り、給湯燃焼指令がＯＮであるか否かを確認するが、先のフローにおけるステップ１３で給湯燃焼指令がＯＮとなっているので、ステップ５ではＹＥＳと判定される。そのため必然的にステップ５からステップ６に移行する。
【００９６】
そしてここで第一温度センサ３２の検知温度（補正値）が燃焼部６の燃焼をＯＦＦすべき温度以上であるか否かを確認する。
しかしながら、今の状態は、ステップ１１で燃焼部６の燃焼をＯＮすべき温度以下であることが確認され、さらに燃焼装置への点火なされていない段階であるから、必然的にステップ６はＮＯであり、ステップ１０に移行して最短燃焼ＯＦＦ指令時間のタイマをセットし、最終ステップに移行する。そして再度フローを繰り返してステップ１に至り、燃焼モードが燃焼以外であるか否かを確認する。そのため結果的に、ステップ２において最短実燃焼時間のタイマをリセットし続けて燃焼モードが燃焼になることを待つ。
【００９７】
そして燃焼部６に点火されたならば、ステップ１がＮＯと判定され、ステップ２を飛ばしてステップ３に移行する。すなわち実際に点火されているならば、最短実燃焼時間のタイマをリセットすることは好ましくないのでステップ２を飛ばしてステップ３に移行する。そのため先のフローで計時が開始された最短実燃焼時間の計時がそのまま続行される。すなわち最短実燃焼時間のタイマは、点火の直前にリセットされ、以後、実際に燃焼している時間を計時することとなる。
【００９８】
そしてステップ３で第二温度センサ３３の動作が確認され、さらにステップ４、ステップ５と進む。
ステップ５では、前記した通り、給湯燃焼指令がＯＮであるか否かを確認するが、先のフローにおけるステップ１３で給湯燃焼指令がＯＮとなっているので、ステップ５ではＹＥＳと判定される。そのため必然的にステップ５からステップ６に移行する。
【００９９】
そしてここで第一温度センサ３２の検知温度（補正後）が燃焼部６の燃焼をＯＦＦすべき温度以上であるか否かを確認する。
もしここで第一温度センサ３２の検知温度が燃焼部６の燃焼をＯＦＦすべき温度以上でないならばステップ１０に移行し、最短燃焼ＯＦＦ指令時間のタイマをセットし、最終ステップに移行する。そして三回目のフロー動作を行なうが、この場合は、先の２回目と同一の工程をたどり、ステップ６に至る。
【０１００】
そのため実質的に、ステップ６において、第一温度センサ３２の検知温度が燃焼部６の燃焼をＯＦＦすべき温度以上になることを待つ結果となる。この間、燃焼部６は燃焼を続け、貯湯部２内の湯水の温度が上昇する。そして第一温度センサ３２の検知温度が燃焼部６の燃焼をＯＦＦすべき温度以上になると、ステップ６がＹＥＳとなり、ステップ７に移行して最短燃焼ＯＮ指令時間が経過したか否かを確認する。すなわち前記したステップ１４でセットされた最短燃焼ＯＮ指令時間のタイマが満了したか否かを確認する。
【０１０１】
もしステップ１４でセットされた最短燃焼ＯＮ指令時間のタイマが満了していれば、チャタリングやタールが固着する心配はないのでステップ９に移行して給湯燃焼指令をＯＦＦする。具体的には燃焼部６の燃焼を停止する。
【０１０２】
一方ステップ１４でセットされた最短燃焼ＯＮ指令時間のタイマが満了していなければ、ステップ８に移行し、最短実燃焼時間が経過しているか否かを確認する。すなわちステップ２で計時を開始した最短実燃焼時間のタイマを確認する。ここで最短実燃焼時間が所定の時間を経過していればチャタリングやタールが固着する心配はないのでステップ９に移行して給湯燃焼指令をＯＦＦする。
その一方、ステップ２でセットされた最短実燃焼時間のタイマが満了していなければ、ステップ９を飛ばして最終ステップに移行し、再度同様の工程を実行する。
そして最短燃焼ＯＮ指令時間が所定の時間を越えるか、あるいは最短実燃焼時間が経過するかいずれかの条件が整うと、ステップ９に移行し、給湯燃焼指令をＯＦＦする。すなわち最短燃焼ＯＮ指令時間が所定の時間を越えた場合はステップ７がＹＥＳとなってステップ９に移行し、最短実燃焼時間が経過した場合はステップ８がＹＥＳとなってステップ９に移行する。
【０１０３】
そして再度新たにフローが実行されるが、この時にはステップ１０で最短燃焼ＯＦＦ指令時間がリセットされた状態であり、最短燃焼ＯＦＦ指令時間を計時しつつ、ステップ１を実行する。
以後は、最初に説明した通りのフローを繰り返す。
【０１０４】
本実施形態の貯湯式給湯器１は、第一温度センサ３２の検知温度に基づいて燃焼部６をＯＮ・ＯＦＦするものであり、さらに式１の演算によって第一温度センサ３２の値がより鋭敏にＯＮ・ＯＦＦ制御に反映される。そのため第一温度センサ３２が故障すると正確な制御ができないばかりでなく、第一温度センサ３２が固着する等により、正規の温度よりも低い温度を示す信号を出した場合に燃焼手段は燃焼状態を維持し続けることとなり危険である。
そこで本実施形態の貯湯式給湯器１では、第一温度センサ３２の故障を検知する機能を備えている。
ここで第一温度センサ３２の故障には、大きく断線、ショート及び固着に大別される。ここで断線及びショートは、明らかに異常な抵抗値を示す。そのため本実施形態では、第一温度センサ３２が異常な抵抗値となった場合には直ちに第一温度センサ３２の故障と判断する。本実施形態では第一温度センサ３２にサーミスタを使用するが、熱電対の様な他の形式のセンサを採用する場合には、異常な電圧が検知されるといった、異常な温度に相当する信号が発せられた時に故障であると判断する。
【０１０５】
上記した断線やショートに比べて、第一温度センサ３２が固着した場合は、故障の判断がしにくい。特に貯湯式給湯器１が通常運転をしている最中は、湯温の変化自体が小さいから、第一温度センサ３２の固着を発見しづらい。
そこで本実施形態では、燃焼開始から一定時間の間に渡って第一温度センサ３２の温度変化を監視し、一定時間内において所定時間の間、連続的に温度上昇を検知しなかった場合であって、第二温度センサ３３が一定の温度を検知した時に第一温度センサ３２が固着していると判断することとした。
具体的には、３０秒を検査時間とし、その内の２０秒間の間、第一温度センサ３２が上昇を示さなければセンサの固着であると判断する。より具体的には、３０秒を検査時間とし、その間、２秒ごとに第一温度センサ３２の温度を検知する。そして第一温度センサ３２が一定（１°Ｃ）の上昇を示さなければ、１をカウントし、これを３０秒間繰り返し、カウント数を積算してゆく。
【０１０６】
またこの間に第一温度センサ３２が上昇を示せばカウントの積算をリセットし、再度カウントする。
また検査中に第一温度センサ３２が温度低下を示すと、前記したカウント数をリセットする。そして最も温度が低下した時の温度を新たな開始基準とし、第一温度センサ３２が新たな開始温度から一定（１°Ｃ）の上昇を示さなければ、１をカウントする。また第一温度センサ３２が上昇を示せばカウントの積算をリセットして再度カウントする。
この様に、第一温度センサ３２が温度低下を示した時にカウント数をリセットするのは、少なくとも温度の変化を示したためであり、故障の可能性が幾分減少したからである。
【０１０７】
また第一温度センサ３２が温度低下を示した時に最も温度が低下した時の温度を新たな開始基準とするのは、第一温度センサ３２の上昇傾向を検査するためである。すなわち第一温度センサ３２が温度低下を示したにも係わらず、検査の開始基準を前のままに据え置くと、３０秒間における上昇幅が小さいときに上昇が確認できない。
また安全性の面から、第一温度センサ３２が上昇を示すことを確認することが必須であり、第一温度センサ３２が温度低下を示した時には最も温度が低下した時の温度を新たな開始基準として検査を行なうこととした。
【０１０８】
そして本実施形態では、さらに第二温度センサ３３が所定の温度以上を検知したことを条件として第一温度センサ３２が故障であると判断する。すなわち第二温度センサ３３が相当の温度を示しているのに、第一温度センサ３２が温度上昇を示さないのは明らかに矛盾している。そのため両者の条件が揃ったところで第一温度センサ３２が故障であると判断する。
以下、第一温度センサ３２の固着を検知する制御について図４を参照しつつ説明する。
【０１０９】
本フローチャートに示された制御は、燃焼が開始されたことを条件に開始される。すなわち点火指令があって燃焼部６への点火が確認された時にコールされ、ステップ１が開始する。なお点火動作を行なうと同時に検査時間を計時するタイマーが計時を開始する。本実施形態では、３０秒の時間を計時する。
第一温度センサ３２の固着を検知する制御では、最初のステップ１で検査時間を確認する。計時を確認するのは、前記した点火動作に伴って計時を開始したタイマーである。
【０１１０】
そして３０秒の時間が経過していなければステップ２に移行し、２秒経過したか否かを判断する。２秒が経過していると、ステップ３に移行し、２秒タイマを再リセットする。そしてステップ３に移行し、第一温度センサ３２の検知温度を確認する。
そしてステップ５に移行し、当初の温度と現在の温度を比較する。
ここで現在の温度が当初の温度に比べて低くない場合は、ステップ１３に移行し、現在の温度と当初の温度の差が１°Ｃ以上であるか否かを確認する。
そして現在の温度と当初の温度の差が１°Ｃ以上であるならばカウンタをリセットしてステップ７に移行する。
一方、現在の温度と当初の温度の差が１°Ｃ未満である場合は、カウンタを１プラスしてステップ７に移行する。
【０１１１】
そしてステップ７でカウンタの数を確認する。カウンタ数が１０を越えているならば、２０秒間観測した結果、連続的に１°Ｃの温度上昇が認められなかったことになり、明らかに不自然である。そこでステップ７がＹＥＳであった場合は、ステップ８に移行し、第一温度センサ３２が固着であることを確認する。具体的には、所定のフラグをセットする。
【０１１２】
そして検査を終了するために検査時間を計時するタイマーをクリアする。続いてステップ１０に移行して先のステップ８で設定したフラグを確認し、第一温度センサ３２が固着であるか否かを判断する。
【０１１３】
今回の制御の流れでは、フラグがセットされた状態であるから第一温度センサ３２が固着していると判断される。そのためステップ１０はＹＥＳと判断され、ステップ１１に移行する。そしてステップ１１で第二温度センサ３３の温度を検知し、これが５０°Ｃを越えているか否かを見る。
第二温度センサ３３の温度を検知し、これが５０°Ｃを越えていれば、第一温度センサ３２が温度上昇を示さないことと矛盾する。そこでステップ１２に移行し、燃焼停止や異常表示等の異常時の動作を行なう。
【０１１４】
またステップ７でカウンタの数を確認した結果、カウンタ数が１０以下である場合は、第一温度センサ３２が故障であるとは言えない。そこでステップ７でカウンタ数が１０未満である場合は、ステップ８，９を飛ばしてステップ１０に移行する。今回の流れでは、フラグがセットされていない状態であるから第一温度センサ３２が固着しているとは言えない。そのためステップ１０はＮＯと判断され、最終ステップに移行して先の制御を繰り返す。
繰り返し動作の場合であって、先のフローの際に１°Ｃ以上の温度上昇が認められた場合は、前回の時の検知値を基準として今回の温度と比較される。
こうして、３０秒間の間、フローを繰り返し、最終的にカウンタ数が１０未満である場合は、第一温度センサ３２が正常であるとして検査を終了する。
【０１１５】
また貯湯部２に急激に水が導入された場合の様に、検査中に第一温度センサ３２の検知値が低下した場合は、ステップ５の段階でＹＥＳと判断され、カウンタがリセットされ、さらに前回の温度が現在の温度に変更され、前記の制御が行なわれる。
【０１１６】
以上説明した実施形態では、第二温度センサ３３の検知値と設定温度の偏差を積算するのに際して、後沸き状態の時と、運転開始時の立ち上げ時を積算しない方策を採用したが、機種によっては、後沸き状態の時等を区別する必要がないものもある。
図５は、後沸き状態の時等を区別しない場合の制御フローである。
【０１１７】
以上説明した実施形態では、第二温度センサ３３を貯湯式給湯器の貯湯部に設けたが、第二温度センサ３３は、できるだけ出湯温度に近い温度を検知できる場所であればよく、例えば貯湯式給湯器の貯湯部を出た直後の位置に設けてもよい。
【０１１８】
また上記した実施形態では、第一温度センサ３２の検知値に、微分演算によって補正値を付加してＯＮ・ＯＦＦ制御の点火・消火が行われる温度を補正したが、微分演算による演算値によってＯＮ・ＯＦＦ制御の切り替え基準値を変更してもよい。
逆に上記した実施形態では、燃焼部６のバーナに点火されるべき温度や消火される際の温度を、第二温度センサ３３の検知値によってずらしたが、第二温度センサ３３の検知値に基づいて第一温度センサ３２の検知値に所定の値を付加してもよい。
【０１１９】
【発明の効果】
以上説明した様に、請求項１に記載の貯湯式給湯器は、第二温度検知手段の検知値と設定温度の偏差に関する情報に基づいて燃焼状態を補正するので出湯温度に近い第二温度検知手段の検知値が加味され、出湯温度のコントロールがし易く、目的の温度に近い温度を出湯させることができる。
【０１２０】
同じく請求項３に記載の燃焼制御手段は、第二温度検知手段の検知値と設定温度の偏差に関する情報に基づいて燃焼状態を点火・消火させる温度を補正するので出湯温度に近い部位の温度情報を加味して点火や消火の制御が行われ、出湯温度のコントロールがし易く、目的の温度に近い温度を出湯させることができる効果がある。
【０１２１】
また請求項４に記載の貯湯式給湯器では、第二温度検知手段が第一温度検知手段よりも出湯口に近い部位に設けられている。そのため第一温度検知手段よりも出湯温度に近い温度を検知することができる。
【０１２２】
また請求項５に記載の貯湯式給湯器は偏差積算手段を備え、第二温度検知手段の検知値と設定温度の偏差を積算する。この積算値は、第一温度検知手段の検知温度が、実際の出湯温度（第二温度検知手段の検知温度）に対して高めであるか低めであるかを示す指標となり、出湯温度を目標値に近づけることができる。
【０１２３】
また請求項６に記載の貯湯式給湯器は、後沸き時や点火初期における特異な状態の際を積算から除外して目的の温度に近い温度を出湯させることができる効果がある。
【０１２４】
また請求項７に記載の貯湯式給湯器は、一定未満の第二温度検知手段の検知値と設定温度の偏差を積算の対象としないこととしたので、補正値が安定し、目的の温度に近い温度を出湯させることができる効果がある。
【０１２５】
また請求項８に記載の貯湯式給湯器は、第一温度検知手段の故障を検知することができる効果があり、安全性が高い。
【０１２６】
また請求項９，１０に記載の発明は、さらに第二温度検知手段が所定の温度以上を検知したことを条件として第一温度検知手段が故障であると判断するので、故障検知の信頼性が高いという効果がある。
【図面の簡単な説明】
【図１】 本発明の実施形態の貯湯式給湯器の概念図である。
【図２】 図１の貯湯式給湯器のＯＮ・ＯＦＦの切り替え基準値を補正する制御手段のフローチャート図である。
【図３】 図１の貯湯式給湯器の全体的な動作を示すフローチャート図である。
【図４】 図１の貯湯式給湯器の第一温度センサの異常を検知する制御のフローチャート図である。
【図５】 本発明の他の実施形態における貯湯式給湯器のＯＮ・ＯＦＦの切り替え基準値を補正する制御手段のフローチャート図である。
【符号の説明】
１ 貯湯式給湯器
２ 貯湯部
６ 燃焼部
３２ 第一温度センサ
３３ 第二温度センサ
３５ コントローラ
３６ リモートコントローラ[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a hot water storage type water heater.
[0002]
[Prior art]
  A hot water storage type water heater is known as one type of water heater. A hot water storage type hot water heater is composed of a combustion section provided with a burner and a hot water storage can body in which water is stored. The hot water storage can passes a combustion gas through a combustion gas passage provided in the hot water storage can body. It heats the water in the body.
[0003]
  Combustion control of a hot water storage type hot water heater is often based on ON / OFF control. That is, a temperature sensor is attached to the hot water storage can body, and the combustion section is turned ON / OFF based on the temperature detected by the temperature sensor.
[0004]
[Problems to be solved by the invention]
  However, the hot water storage type water heater has a problem that it is difficult to control the temperature of the hot water, and the temperature of the hot water varies greatly.
  That is, the hot water storage type water heater generally has a vertically long shape, and the hot water storage can body has a certain height. And there is a water inlet near the lower part of the hot water storage part, and a hot water outlet is provided on the upper side.
[0005]
  In the hot water storage type hot water heater, cold water is introduced and stored from the above-described water inlet, and the internal hot water is heated by the combustion gas passage that penetrates the hot water storage can body. Therefore, in the hot water storage type water heater, water entering from the lower part is gradually warmed and discharged from the hot water outlet on the upper part side. Therefore, in the hot water storage type water heater, the temperature variation in the hot water storage section is large, and the hot water temperature varies even if the ON / OFF control is performed for any part of the temperature. The temperature of the hot water in the vicinity of the hot water outlet is close to the temperature of the hot water to be discharged, but if the hot water temperature in the vicinity of the hot water outlet is controlled for ON / OFF control, the amplitude of the hot water temperature change is extremely large. End up.
[0006]
  That is, in the hot water storage type water heater, the amount of hot water stored in the hot water storage unit is larger than that in other hot water heaters, and the residence time of the hot water is long. For this reason, when water that has newly entered the hot water storage section is heated by ON / OFF control for the hot water temperature, the control is delayed and an overshoot occurs. Therefore, in order to prevent overshoot, a temperature sensor is provided near the water inlet, and ON / OFF control is performed based on a signal from the temperature sensor.
  As described above, the temperature of the hot water near the water inlet is greatly different from the temperature of the hot water. For example, when trying to obtain a hot water of 40 ° C, the temperature sensor is turned on under the condition that it shows 30 ° C.・ OFF control was performed. More specifically, in order to obtain 40 ° C. hot water, an ignition command is transmitted to the combustion portion when the temperature detected by the temperature sensor falls below 30 ° C., and the combustion portion is combusted. When the temperature exceeded 31 ° C, the burner was extinguished.
[0007]
  Since the hot water storage type hot water heater of the prior art has performed the combustion control as described above, the hot water temperature cannot be accurately controlled, so that the hot water temperature is in a state of being left to the right.
  Accordingly, the present invention focuses on the above-mentioned problems of the prior art, and an object of the present invention is to develop a hot water storage type hot water heater that can accurately control the temperature of the hot water.
[0008]
[Means for Solving the Problems]
  And invention of Claim 1 for solving an above-mentioned subject is a hot water storage part which has a water inlet and a hot water outlet, and stores hot water inside, a combustion means which carries out combustion heating of the hot water of a hot water storage part, It has a first temperature detection means for detecting the temperature of hot water and a tapping temperature setting means for setting the tapping temperature, and comprises a combustion control means for controlling the combustion means based on information relating to the temperature detected by the first temperature detection means. The hot water storage type water heater has a second temperature detecting means for detecting the hot water temperature downstream of the first temperature detecting means, and the combustion control means has a detection value of the second temperature detecting means and a hot water temperature setting means. The hot water storage type hot water heater is characterized in that the ON / OFF switching reference value is corrected on the basis of the information on the deviation of the set temperature set by.
[0009]
  Here, “controlling the combustion means based on the information about the detected temperature” includes ON / OFF control based on the detected temperature, and control such as proportionality and differentiation. It also includes the case where ignition or extinguishing is performed based on numerical values after processing such as multiplying or differentiating the detected temperature by a coefficient.
  “Correcting the combustion state” includes changing the switching temperature when performing ON / OFF control, and adding a correction value to the temperature detection value side.
[0010]
  The hot water storage type water heater of the present invention includes second temperature detection means in addition to the first temperature detection means. The second temperature detecting means detects the hot water temperature downstream of the first temperature detecting means. Therefore, the second temperature detecting means can detect a temperature closer to the tapping temperature than the first temperature detecting means.
  And in the hot water storage type hot water heater of the present invention, the combustion control means corrects the combustion state based on the information regarding the deviation between the detected value of the second temperature detecting means and the set temperature. Therefore, in the hot water storage type water heater of the present invention, the detection value of the second temperature detecting means close to the hot water temperature is taken into account, the hot water temperature can be easily controlled, and the hot water temperature can be made close to the target temperature.
[0011]
  According to a second aspect of the present invention, there is provided a hot water storage section having a water inlet and a hot water outlet for storing hot water therein, combustion means for combusting and heating the hot water in the hot water storage section, and first temperature detection of the hot water in the hot water storage section. In a hot water storage type hot water heater having a temperature detection means and a hot water temperature setting means for setting a hot water temperature, and comprising a combustion control means for controlling the combustion means based on information relating to the detected temperature of the first temperature detection means, A second temperature detecting means for detecting the temperature of the hot water downstream of the temperature detecting means, and the combustion control means comprises a deviation between a detection value of the second temperature detecting means and a set temperature set by the tapping temperature setting means. A hot water storage type hot water heater characterized by changing the switching temperature when performing ON / OFF control based on the information on or adding a correction value to the temperature detection value side.
[0012]
  According to a third aspect of the present invention, there is provided a hot water storage part having a water inlet and a hot water outlet and storing hot water therein, a combustion means for burning and heating the hot water in the hot water storage part, and a first detecting the temperature of the hot water in the hot water storage part. In a hot water storage type water heater having a temperature control means and a hot water temperature setting means for setting the hot water temperature, and having a combustion control means for igniting and extinguishing the combustion means based on information on the detected temperature of the first temperature detection means, The second temperature detection means for detecting the temperature of the hot water downstream from the first temperature detection means, and the combustion control means is a set temperature set by the detected value of the second temperature detection means and the tapping temperature setting means. The hot water storage type hot water heater is characterized in that the temperature at which ignition and extinguishing are performed is corrected based on information on the deviation of the hot water.
[0013]
  Here, “ignite / extinguish the combustion means based on the information on the detected temperature” is not only when the ON / OFF control is performed based on the detected temperature, but also after processing such as multiplying or differentiating the detected temperature by a coefficient This includes the case where ignition or extinguishing is performed based on the numerical value of.
  Further, “correcting the temperature at which ignition and extinguishing are performed” includes both cases where the reference temperature for ignition and extinguishing is raised and lowered and when a correction value is added to the temperature detection value side.
[0014]
  The hot water storage type water heater of the present invention has first temperature detection means, and the first temperature detection means ignites and extinguishes the combustion means.
  And the hot water storage type water heater of the present invention also includes second temperature detection means in addition to the first temperature detection means. The second temperature detection means can detect a temperature closer to the tapping temperature than the first temperature detection means.
  In the hot water storage type water heater according to the present invention, the combustion control means corrects the temperature at which the combustion state is ignited and extinguished based on the information regarding the deviation between the detection value of the second temperature detection means and the set temperature. Therefore, the combustion apparatus controls ignition and extinguishing in consideration of temperature information of a portion close to the hot water temperature, makes it easy to control the hot water temperature, and allows the hot water to be discharged at a temperature close to the target temperature.
[0015]
  The invention according to claim 4 is characterized in that the second temperature detecting means detects the temperature of the hot water in the hot water storage portion at a portion closer to the outlet than the first temperature detecting means. It is a hot water storage type water heater according to any one of 1 to 3.
[0016]
  In the hot water storage type water heater of the present invention, the second temperature detection means detects the hot water temperature in the hot water storage section at a location closer to the hot water outlet than the first temperature detection means. Therefore, the temperature closer to the tapping temperature than the first temperature detecting means can be detected.
[0017]
  The invention described in claim 5 is characterized by having a deviation integration means for integrating the deviation between the detection value of the second temperature detection means and the set temperature, and performing correction according to the integration value of the deviation integration means. A hot water storage type water heater according to any one of claims 1 to 4.
[0018]
  In the hot water storage type water heater of the present invention, the deviation integrating means integrates the deviation between the detected value of the second temperature detecting means and the set temperature. Here, the integrated value of the deviation between the detected value of the second temperature detecting means and the set temperature is such that the detected temperature of the first temperature detecting means is higher than the actual hot water temperature (detected temperature of the second temperature detecting means). It becomes an index that shows whether it is low or low.
  In the present invention, the correction is made according to the integrated value of the deviation integrating means, so that the tapping temperature can be brought close to the target value.
[0019]
  The invention according to claim 6 is a period in which combustion is scheduled, and when the detected value of the second temperature detecting means is lower than a set temperature set by the tapping temperature setting means or when combustion is scheduled 6. The deviation integrating means is not subject to integration when the detected value of the second temperature detection means is higher than a set temperature set by the tapping temperature setting means during a period when the temperature is not set. It is a hot water storage type water heater described in 1.
[0020]
  The hot water storage type water heater of the present invention eliminates problems caused by adopting the deviation integrating means. That is, as described above, the integrated value of the deviation between the detection value of the second temperature detection means and the set temperature is such that the detection temperature of the first temperature detection means is relative to the actual tapping temperature (detection temperature of the second temperature detection means). This is an index indicating whether the temperature is higher or lower, and the hot water temperature can be brought close to the target value by performing correction according to the integrated value.
  However, in a hot water storage type water heater, the hot water stored in the hot water storage part is heated by the heat remaining in the combustion part after the hot water supply is stopped, and the hot water temperature often rises (so-called post-boiling). However, it is not preferable to integrate the temperature increase during such post-boiling.
  Further, when the combustion section is ignited after the operation is stopped for a long time, the temperature of the hot water in the hot water storage section is low, and the deviation between the detected value of the second temperature detecting means and the set temperature becomes extremely large. Therefore, it is not preferable to integrate the deviation between the detection value of the second temperature detection means and the set temperature when the temperature of the hot water in the hot water storage section is decreasing.
  In view of this, the present invention excludes the case of a peculiar state at the time of post-boiling or the initial stage of ignition from the integration and discharges a temperature close to the target temperature.
  Here, considering “when the combustion part is ignited after stopping operation for a long time”, this state is “the period when combustion is scheduled and the detection value of the second temperature detection means is set to the hot water temperature setting. It can be said that this is a case where the temperature is lower than a certain level compared to the set temperature set by the means. Further, when “after-boiling” is considered, this state is “when combustion is not scheduled and the detection value of the second temperature detection means is higher than a set temperature set by the tapping temperature setting means”. You can say that.
  Therefore, in the hot water storage type water heater of the present invention, it is a period during which combustion is scheduled and the detected value of the second temperature detection means is lower than a set temperature of the hot water temperature setting means by a certain level or during a period when combustion is not scheduled. If the detected value of the second temperature detecting means is higher than a set temperature of the tapping temperature setting means by a certain level or more, the deviation integrating means is not subject to integration.
[0021]
  In the invention according to claim 7, the deviation integrating means is not subject to integration when the deviation between the detected value of the second temperature detecting means and the set temperature set by the tapping temperature setting means is less than a certain value. It is a hot water storage type water heater according to claim 5 or 6.
[0022]
  In the hot water storage type water heater of the present invention, the deviation integrating means is not subject to integration when the deviation between the detected value of the second temperature detecting means and the set temperature set by the tapping temperature setting means is less than a certain value. Therefore, the correction value is stabilized.
[0023]
  In the invention according to claim 8, the temperature change of the first temperature detecting means is monitored for a predetermined time from the start of combustion, and no temperature rise is detected for a predetermined time within the predetermined time. The hot water storage type hot water heater according to any one of claims 1 to 7, further comprising a failure determination function for determining that the first temperature detection means is failed on the condition of
[0024]
  The hot water storage type water heater of the present invention is obtained by adding a function of detecting a failure of the first temperature detecting means to the above-described invention.
  That is, since all of the above-described inventions control the combustion means based on the temperature detected by the first temperature detection means, accurate control cannot be performed if the first temperature detection means fails. In particular, when a signal indicating a temperature lower than the normal temperature is output due to the first temperature detection means being fixed, the combustion means is in danger of maintaining the combustion state.
  Therefore, it is important to check whether or not the first temperature detecting means is operating normally. Normally, a temperature sensor typified by a thermistor is used as the first temperature detection means, but failure of the thermistor is roughly divided into disconnection, short circuit, and adhesion. Here, since the disconnection and the short circuit clearly show an abnormal resistance value, it can be immediately judged as a failure. On the other hand, the sticking is a phenomenon in which the resistance value does not change in a state where a normal temperature is shown, and is difficult to judge. Especially when the water heater is in normal operation, the temperature change itself is small, so it is difficult to detect the thermistor sticking.
  Therefore, the present invention monitors the temperature change of the first temperature detecting means over a certain time from the start of combustion, and if the temperature rise is not detected for a predetermined time within a certain time, the temperature detecting means fails. It was decided that it was.
  In the hot water storage type water heater of the present invention, the temperature change of the first temperature detection means is monitored over a certain time from the start of combustion. During a certain time from the start of combustion, since the temperature change is generally severe, if the first temperature detecting means is normal, it will show some temperature rise, and if it has failed due to sticking or the like, it will not show a temperature rise.
  Therefore, in the present invention, it is determined that the temperature detecting means is in failure when no temperature rise is detected for a predetermined time within a certain time.
[0025]
  The invention according to claim 9 is characterized in that, in addition, it is determined that the first temperature detecting means is malfunctioning on the condition that the second temperature detecting means detects a predetermined temperature or more. It is a hot water storage type water heater described in 1.
[0026]
  The hot water storage type water heater according to the present invention is dependent on the preceding claim and has a failure determination means. In the present invention, it is further determined that the first temperature detecting means is malfunctioning on condition that the second temperature detecting means detects a predetermined temperature or higher. That is, it is clearly contradictory that the second temperature detecting means shows a considerable temperature, but the first temperature detecting means does not show an increase in temperature. For this reason, it is determined that the first temperature detecting means is faulty when both conditions are met.
[0027]
  The above-described series of configurations relating to failure determination can be applied to other types of water heaters. The invention according to claim 10 is an application of the invention relating to the failure determination described above to another type of water heater, and the invention cited as a reference example of the invention has one or more temperature detection means, In a hot water storage type water heater provided with a combustion control means for controlling the combustion means based on the temperature detected by the temperature detection means, the temperature change of the temperature detection means is monitored over a predetermined time from the start of combustion, and the predetermined time A water heater having a failure determination function for determining that the temperature detection means is defective when a temperature rise is not detected for a predetermined time.
[0028]
  The invention according to claim 10 further comprises combustion stop means for stopping the combustion when the failure determination means detects a failure of the first temperature detection means and the second temperature detection means detects a predetermined temperature or higher. The hot water storage type water heater according to claim 8 or 9, wherein
[0029]
  According to the eleventh aspect of the present invention, the control value is calculated by adding a numerical value obtained by differential operation to the current detected value of the first temperature detecting means based on the detected value of the first and current temperature detecting means. 11. The hot water storage type hot water heater according to claim 1, wherein the combustion control means corrects the temperature at which ignition and extinguishing are performed based on the control value.
[0030]
  AlsoRelated to these inventionsThe invention samples the detection value of the first temperature detecting means, averages the sampled detection value, and calculates the control value using the average value.It can be.
[0031]
DETAILED DESCRIPTION OF THE INVENTION
  Embodiments of the present invention will be further described below.
  FIG. 1 is a conceptual diagram of a hot water storage type water heater according to an embodiment of the present invention. FIG. 2 is a flowchart of the control means for correcting the ON / OFF switching reference value of the hot water storage type water heater of FIG. FIG. 3 is a flowchart showing the overall operation of the hot water storage type water heater of FIG. FIG. 4 is a flowchart of control for detecting an abnormality of the first temperature sensor of the hot water storage type water heater of FIG. FIG. 5 is a flowchart of the control means for correcting the ON / OFF switching reference value of the hot water storage water heater in another embodiment of the present invention.
[0032]
  The hot water storage type water heater 1 of this embodiment is characterized by the control means, but prior to the description of the control means, the mechanical structure and its operation will be briefly described.
[0033]
  The structure of the hot water storage type water heater 1 of this embodiment is as shown in FIG. 1, and is largely composed of a main body portion 5, a combustion portion 6 and a silencer 7. The main body 5 is largely divided into a combustion space portion 10 and a heat exchange portion 11.
  That is, the main body 5 has a cylindrical shape as a whole, has a double structure, and the hot water storage 2 is formed inside. More specifically, the main body 5 has an outer cylinder 13 and an inner cylinder 12, and has a structure in which the interior is hollow and water is stored. In particular, the upper half of the main body 5 is formed with a large-capacity water chamber 17 surrounded by an upper end plate 15 and a lower end plate 16.
[0034]
  The hot water storage type water heater 1 of the present embodiment has a structure in which hot water is stored in the gap between the outer cylinder 13 and the inner cylinder 12 as described above. Although much hot water is stored in the water chamber 17, the hot water storage water heater 1 of the present embodiment has a structure in which water is also stored in the side surface portion of the combustion space portion 10.
  A water inlet 30 is provided near the lower end of the water chamber 17. A hot water outlet 31 is provided near the upper end of the water chamber 17.
[0035]
  A plurality of combustion gas passages 3 are formed in the water chamber 17 described above.
  The combustion gas passage 3 is specifically a hole that penetrates the water chamber 17 in the upper part of the hot water storage section 2 in the axial direction, and more specifically, is formed by penetrating a circular pipe 18 through the water chamber 17. .
[0036]
  On the other hand, a relatively large space is provided in the combustion space portion 10 located below the main body portion 5. The space functions as the combustion chamber 20.
  The bottom of the main body 5 is closed by the bottom plate 21.
[0037]
  On the other hand, a silencer 7 is provided on the upper part of the main body 5. The silencer 7 has a cylindrical or rectangular parallelepiped appearance and has a labyrinth structure inside to reduce combustion noise (labyrinth structure not shown).
[0038]
  The combustion unit 6 includes a so-called burner that burns liquid fuel such as kerosene, and includes a fuel injection nozzle 28.
  A blower 27 is integrated with the combustion unit 6.
[0039]
  In the hot water storage type water heater 1, water is introduced from the water inlet 30 and enters the gap portion between the outer cylinder 13 and the inner cylinder 12 described above.
  Then, fuel gas is injected from the burner body 25 of the combustion unit 6, a flame is generated in the combustion chamber 20 by the fuel gas, and the combustion gas flows in the combustion gas passage 3 that penetrates the water chamber 17.
  The combustion gas flows to the silencer 7 provided further downstream and is discharged to the outside.
[0040]
  When the combustion gas flows through the combustion gas passage 3, the hot water in the water chamber 17 is heated to raise the temperature of the hot water in the interior. The heated hot water is discharged to the outside from a hot water outlet 31 provided near the upper end of the water chamber 17.
[0041]
  The structure of the hot water storage type water heater 1 of the present embodiment is generally as described above, but has a unique configuration and includes the first temperature sensor 32 and the second temperature sensor 33 in the hot water storage section 2.
  Both the first temperature sensor 32 and the second temperature sensor 33 are thermistors. As for the 1st temperature sensor 32 and the 2nd temperature sensor 33, the temperature detection part is inserted in the water chamber 17 so that all can measure the temperature of the hot water in the water chamber 17. FIG.
[0042]
  When attention is paid to the attachment positions of the first temperature sensor 32 and the second temperature sensor 33, the first temperature sensor 32 is in a position close to the water inlet 30, and the second temperature sensor 33 is in a position close to the hot water outlet 31. Therefore, the second temperature sensor 33 can detect a temperature close to the tapping temperature.
[0043]
  Moreover, it can be said that the attachment position of the 1st temperature sensor 32 is the middle height of the part in which the hot water is stored. That is, the first temperature sensor 32 is provided at a position at an intermediate height of the hot water storage section 2 of the hot water storage type water heater 1.
  When the mounting position of the first temperature sensor 32 is expressed by a numerical value, the mounting position of the first temperature sensor 32 is from the lowermost position LL to the uppermost position HL when the hot water storage part 2 is filled with hot water. The height is H, and the range is 0.3H centering on the center height CL from the position of LL to the uppermost position. Further, the first temperature sensor 32 is preferably located above the water inlet 30 (on the side of the hot water outlet 31) and in the range of 0.3H around the center height CL of the hot water storage section 2.
[0044]
  In the hot water storage type hot water heater 1 of the present embodiment, the first temperature sensor 32 is provided at the center of the hot water storage section 2, so that the average temperature of the hot water storage section 2 can be detected by the first temperature sensor 32. .
  As will be described later, the hot water storage type water heater 1 according to the present embodiment basically turns ON / OFF the combustion of the combustion section according to the temperature detected by the first temperature sensor 32, and the first temperature sensor 32 is the hot water storage section 2. Therefore, the tendency of the entire temperature rise curve of the hot water storage unit 2 can be accurately detected.
[0045]
  Next, the combustion control means of the hot water storage type water heater 1 of this embodiment will be described. The combustion control means of the hot water storage type hot water heater 1 is realized by a CPU or the like built in the controller 35, the remote controller 36, or the like. Each of the controller 35 and the remote controller 36 has a touch switch or the like (not shown), and can set the hot water temperature of the hot water storage type hot water heater 1. Accordingly, both the controller 35 and the remote controller 36 serve as a hot water temperature setting means for setting the hot water temperature.
  Further, the controller 35 stores a data table of appropriate correction amounts for correction coefficients α described later.
[0046]
  The controller 35 of the hot water storage type hot water heater 1 of the present embodiment realizes deviation integrating means and a failure determination function, and stores a control program for performing the following control. Hereinafter, the function of the hot water storage type hot water heater 1 will be described in detail.
  Regarding the combustion control of the hot water storage type hot water heater 1 of the present embodiment, the burner of the combustion unit 6 is basically turned on and off by the first temperature sensor 32 as in the conventional technology. In the hot water heater 1, the temperature at which the ON / OFF control ignition / extinguishing is performed is corrected.
[0047]
  Specifically, a correction value is added to the detection value of the first temperature sensor 32 by differential calculation, and as a result, the temperature at which ignition / extinguishment of ON / OFF control is performed is corrected.
  In the hot water storage type water heater 1 of the present embodiment, the switching reference value for the ON / OFF control is also corrected by the detection value of the second temperature sensor 33. Specifically, the temperature at which the burner of the combustion unit 6 is to be ignited and the temperature at which the burner 6 is extinguished are shifted by the detection value of the second temperature sensor 33. As a result, the temperature at which the ON / OFF control ignition / extinguishing is performed is corrected.
[0048]
  As explained in the section of the problem to be solved, the temperature of the hot water near the first temperature sensor 32 provided near the water inlet is greatly different from the temperature of the hot water. Then, it is necessary to perform ON / OFF control on condition that the first temperature sensor 32 indicates 30 ° C., for example. The hot water storage type water heater 1 of the present embodiment is basically the same in this respect, and in order to obtain 40 ° C. hot water, when the temperature detected by the temperature sensor falls below 30 ° C., an ignition command is sent to the combustion unit 6. , The combustion unit 6 is combusted, and the burner is extinguished when the temperature detected by the temperature sensor exceeds 31 ° C. In this embodiment, the detected value of the first temperature sensor 32 includes a differential component. Is added.
[0049]
  That is, in the hot water storage type water heater 1 of the present embodiment, a control value is calculated by adding a numerical value obtained by differential calculation to the detected value of the first temperature sensor 32, and the burner is ignited or extinguished by the control value.
[0050]
  Specifically, the temperature data of the first temperature sensor 32 is sampled at regular intervals. In this embodiment, the temperature data of the first temperature sensor 32 is sampled every 100 ms.
  These are averaged a certain number of times. In the present embodiment, 10 sampling data are added and averaged to create data every second.
[0051]
  Then, it is substituted into the following formula to obtain a control value.
[0052]
[Expression 1]

[0053]
  Here, the “latest data” in the first term is the average hot water temperature in the hot water storage section 2 for the current one second, and represents the current hot water temperature.
  The second and third terms are correction values to be added.
  Here, the second term “latest data—5 seconds before data” is a numerical value corresponding to a differential value of a relationship curve (temperature curve) between the hot water temperature and time of the hot water storage section 2, and the past first temperature sensor 32. It is the information regarding the tendency of the change of the temperature calculated based on the detected value. The “data before 5 seconds” is obtained by adding and averaging 10 times of sampling data every 100 ms before 5 seconds.
[0054]
  In addition, “(Latest data−5 seconds before data) − (5 seconds before data−10 seconds before data)” in the third term is a numerical value corresponding to the twice differential value of the temperature curve, and the past first temperature sensor. It is the information regarding the tendency of the change of the temperature calculated based on 32 detection values. The “data before 10 seconds” is obtained by averaging the sampling data every 100 ms 10 seconds ago by adding 10 times.
[0055]
  The differential data calculated in this way is used as an index for ON / OFF control. For example, when trying to obtain 40 ° C. hot water, when the value of the differential data calculated by Equation 1 falls below 30 ° C., an ignition command is transmitted to the combustion section 6 to burn the combustion section 6. The burner is extinguished when the value of the differential data calculated by Equation 1 exceeds 31 ° C.
[0056]
  Note that Equation 1 may be modified and calculated as in Equation 2 below.
[0057]
[Expression 2]

[0058]
  In Equation 2, “(Latest data−5 seconds before data) − (5 seconds before data−10 seconds before data)” in the third term of Equation 1 is changed to “(Latest data−5 seconds before data) + (5 seconds before). Data-data before 10 seconds) ". "(Latest data-5 seconds before data) + (5 seconds before data-10 seconds before data)" is not strictly a differential value twice, but by changing the last term in this way, the displacement of the value The amount is increased, and the control responsiveness is improved.
[0059]
  Further, an appropriate constant may be multiplied to the second term and the third term of the above formula 1.
[0060]
  Further, as described above, in the hot water storage type water heater 1 of the present embodiment, the switching reference value for the ON / OFF control is corrected by the detection value of the second temperature sensor 33.
  That is, in the control device of the present embodiment, the following calculation is performed using the detection value of the second temperature sensor 33, and the correction coefficient α is calculated.
[0061]
[Equation 3]

[0062]
  Formula 2 described above is information relating to the deviation between the detected value of the second temperature sensor 33 and the set temperature, and integrates the deviation between the set temperature and the detected value of the second temperature sensor 33.
  In other words, in the present embodiment, the deviation between the set temperature and the detected value of the second temperature sensor 33 is multiplied by a constant constant β and integrated, and this is multiplied by a constant constant γ. The constants β and γ described above are numerical values obtained based on empirical rules, and it is appropriate that the constant β is about 1/10 to 1/30 and the constant γ is about 1/2 to 1/4. In this embodiment, the constant β is 1/20 and the constant γ is 1/3.
  “Σγ (set temperature−hot water temperature)” is counted only when the absolute value is 1 or more. In the present embodiment, since the constant γ is 1/3, α is a number other than 0 only when “(set temperature−hot water temperature)” is 3 or more.
[0063]
  As described above, in this embodiment, when the value of “(set temperature−hot water temperature)”, that is, the deviation between the detected value of the second temperature sensor 33 and the set temperature is less than a certain value, it is not subject to integration.
  If a slight deviation is also subject to integration, the integrated value of the deviation is accumulated over a long period of use, and the operation becomes unstable.
[0064]
  In the hot water storage type water heater 1 of the present invention, the deviation integrating means is not subject to integration when the deviation between the detected value of the second temperature sensor 33 and the set temperature set by the remote controller 36 is less than a certain value. Therefore, the correction value is stabilized.
[0065]
  The correction coefficient α is an index indicating whether the detected temperature of the first temperature sensor 32 is higher or lower than the actual hot water temperature (detected temperature of the second temperature sensor).
[0066]
  The calculation of the correction coefficient α is continuously performed while the burner of the combustion unit 6 is turned on / off and combustion control is performed. However, in general, in the hot water storage type water heater 1, the temperature of the hot water in the hot water storage section 2 rises due to the heat remaining in the combustion chamber 20 after the hot water supply is stopped. This is a phenomenon called post-boiling, and it is not preferable to integrate the temperature increase during such post-boiling. That is, the post-boiling is a phenomenon that occurs when hot water supply is stopped. At this time, there is no inflow of water into the hot water storage section 2 of the hot water storage type hot water heater 1. Therefore, the temperature of the hot water remaining in the hot water storage unit 2 rises beyond the normal control range. Therefore, when such a temperature increase during post-boiling is added to the integrated data, the integrated value becomes distorted, and the correction coefficient α described above becomes excessively small.
[0067]
  Similarly, when the combustion section 6 is ignited after the operation is stopped for a long time, it should not be added to the integrated data.
  That is, if the combustion control is not performed for a long time as in the case where the operation switch or the power switch is stopped, the temperature of the hot water in the hot water storage section 2 is reduced completely, and in the initial stage of combustion. The difference between the detected value of the first temperature sensor 32 and the set temperature is extremely large. Therefore, it is not preferable to integrate the deviation between the detected value of the first temperature sensor 32 and the set temperature when the temperature of the hot water in the hot water storage section 2 is decreasing.
[0068]
  In view of this, the present invention employs a control program that excludes the time of a specific state at the time of post-boiling or at the start of the initial ignition from the integration.
  A program for calculating the correction coefficient α employed in the present embodiment is as shown in FIG.
  That is, during the operation, the set temperature set by the remote controller 36 in step 1 is acquired. And it transfers to step 2 and acquires actual hot-water temperature. In the present embodiment, the temperature detected by the second temperature sensor 33 is acquired as the actual hot water temperature.
[0069]
  And it transfers to step 3 and it is confirmed whether the combustion part 6 is an ON state. That is, it is confirmed whether or not the burner of the combustion unit 6 is ignited.
  The reason why it is confirmed in step 3 whether or not the combustion section 6 is in an ON state is to exclude the time of post-boiling and the initial startup as described above.
  That is, if it is an initial start-up, at least the combustion section 6 should be in the ON state, and if it is after boiling, at least the combustion section 6 should be in the OFF state.
[0070]
  In step 3, first, it is confirmed whether or not the combustion unit 6 is in an ON state. If the combustion unit 6 is in an ON state in step 3, the process proceeds to step 4 to determine whether or not the combustion unit 6 is in an initial startup state. In step 3, if the combustion unit 6 is in the OFF state, the process proceeds to step 5 to determine whether it is in the post-boiling state.
[0071]
  For example, if it is determined in step 3 that the combustion unit 6 is in the ON state, the process proceeds to step 4 to check the difference between the hot water temperature (the temperature detected by the second temperature sensor 32) and the set temperature. If the combustion section 6 is in the ON state during normal operation, in other words, if the combustion section 6 is in the ON state with normal ON / OFF control, the tapping temperature is set to the set temperature. It will not be much lower than That is, if the combustion section 6 is normally operated, the tapping temperature should have an amplitude within a range of several degrees compared to the set temperature. Therefore, if at least the combustion section 6 is in the ON state, the tapping temperature will be the set temperature. Is not much lower than
[0072]
  Therefore, if the temperature of the hot water in the hot water storage section 2 is considerably lower than the set temperature even though the combustion section 6 is in the ON state, the temperature of the hot water in the hot water storage section 2 is considered to be considerably low. Expected to be.
  Here, how much the hot water temperature is lower than the set temperature is estimated to be in the initial start-up state, which should be determined by the control ability of the device, etc., but usually from 3 ° C to 8 ° If it is about C or less, it may be considered that the initial startup state. In this embodiment, if the tapping temperature is equal to or lower than “set temperature −5 ° C.”, it is determined that the startup state is in the initial state, and the process proceeds to the final step.
[0073]
  If the tapping temperature is higher than “set temperature−5 ° C.” in step 4, the process proceeds to step 6 and thereafter, and the temperature rise is integrated. That is, if the combustion section 6 is in the ON state and the tapping temperature is equal to or higher than a set temperature (set temperature −5 ° C.), the difference between the set temperature and the detected value of the second temperature sensor 33 is integrated. To do. In addition, when the combustion unit 6 is in the ON state and the tapping temperature is lower than the set temperature, it is excluded from the deviation integration of the set temperature and the detected value of the second temperature sensor 33.
[0074]
  On the other hand, if it is determined in step 3 that the combustion unit 6 is in the OFF state, the process proceeds to step 5 to check the difference between the hot water temperature (the temperature detected by the second temperature sensor 33) and the set temperature. As described above, if the combustion section 6 is in the 0FF state during normal operation, in other words, if the combustion section 6 is in the OFF state with the normal ON / OFF control, the tapping temperature is It will not be much higher than the set temperature. As described above, if the combustion section 6 is normally operated, the tapping temperature should oscillate within a range of several degrees compared to the set temperature, so that at least the tapping temperature if the combustion section 6 is in the OFF state. Does not greatly exceed the set temperature.
[0075]
  Therefore, if the hot water temperature is much higher than the set temperature even though the combustion unit 6 is in the OFF state, it is considered that no new water has entered the hot water storage unit 2 and the post-boiling state. is expected.
  Here, how much the hot water temperature is higher than the set temperature is estimated to be a post-boiling state, which should be judged by the control ability of the equipment, etc., but is usually about 3 to 8 ° C. If there is, it can be considered that it is in a post-boiling state. In this embodiment, if the tapping temperature is higher than “set temperature + 5 ° C.”, it is determined that the boiling is after boiling, and the process proceeds to the final step.
[0076]
  If the tapping temperature is less than “set temperature + 5 ° C.” in step 4, the process proceeds to step 6 and the subsequent steps to integrate the temperature rise. That is, if the combustion section 6 is in the OFF state and the tapping temperature is lower than the set temperature (set temperature + 5 ° C.), the deviation between the set temperature and the detected value of the second temperature sensor 33 is integrated. Further, if the combustion section 6 is in the ON state and the tapping temperature is equal to or higher than the set temperature, it is excluded from the integrated deviation of the set temperature and the detected value of the second temperature sensor 33.
[0077]
  When the process proceeds to step 6, the correction coefficient α is calculated by the above-described equation 3.
  In step 7, correction coefficients are added. In steps 6 and 7, the deviation between the set temperature and the detected value of the second temperature sensor 33 is integrated. Further, in steps 6 and 7, an integrated value of the deviation between the set temperature and the detected value of the second temperature sensor 33 is obtained.
[0078]
  Then, the process proceeds to step 8 where the data table stored in the memory of the control device is read and an appropriate correction amount for the correction coefficient α is determined.
  If the integrated value (integrated value) of the deviation between the set temperature and the detected value of the second temperature sensor 33 has reached a certain value, the ON / OFF temperature of the combustion unit 6 is changed in step 9 according to the data table. . That is, the reference temperature of ON or OFF is shifted up and down.
  For example, until that time, when the temperature detected by the first temperature sensor 32 (including correction by differentiation) is 30 ° C., ignition is started and extinguished at 30.5 ° C. according to the value of the correction coefficient α. Shift up and down and change so that ignition starts at 30.5 ° C and extinguishes at 31.5 ° C.
  When the value of the correction coefficient α is small, the conventional ON / OFF reference temperature is maintained as it is.
  Then, the process proceeds to the final step, and thereafter the above-described control is repeated.
[0079]
  Next, the overall operation of the hot water storage type water heater 1 of the present embodiment will be described.
  In the hot water storage type water heater 1 of the present embodiment, the burner is basically controlled to be turned ON / OFF by the detection value of the first temperature sensor 32. As described above, the detection value of the first temperature sensor 32 is obtained by differential operation. A correction value is added, and the switching reference value for ON / OFF control is shifted by a predetermined amount based on the correction coefficient α.
  That is, in the hot water storage type water heater 1 of the present embodiment, the combustion state is corrected based on the information regarding the deviation between the detected value of the second temperature sensor 33 and the set temperature, and based on the detected value of the first temperature sensor 32 in the past. Thus, information on the tendency of temperature change is calculated, and the combustion state is corrected based on this information. Since the hot water storage type water heater 1 of the present embodiment has been subjected to the special correction processing as described above, it is necessary to consider that the overall operation is consistent with this.
[0080]
  In particular, in the present embodiment, a correction value is added to the detection value of the first temperature sensor 32 by differential calculation. However, “(latest data−5 seconds before data) − (5 seconds before) is the third term of the expression 1. "Data-10 seconds before data)" is a numerical value corresponding to the second derivative value of the temperature curve, and the change of the numerical value with respect to the temperature change is expanded several times. Further, the change in the value after the correction has a phase advanced from the temperature change of the first temperature sensor 32.
[0081]
  For this reason, the numerical value after correction (correction according to Equation 1) greatly changes due to a change in the detection value of the first temperature sensor 32, and there is a risk that the numerical value pulsates in the vicinity of the ON / OFF switching reference value.
  Therefore, in the present embodiment, since the differential calculation process is performed as in Equation 1, chattering is likely to occur.
  Therefore, when adopting the control means of the present embodiment, it is desirable to provide a function for preventing chattering.
[0082]
  Further, since the ON / OFF is repeated in a short period until chattering does not occur, there is a problem in that burned tar or the like easily adheres to the nozzle 28. In particular, in a combustion apparatus that uses liquid fuel such as kerosene, it is necessary to perform a pre-purge by operating a blower prior to combustion, and it takes time for pre-ignition operation and ignition operation. Therefore, the actual combustion time depends on the length of the operation performed prior to the combustion.
  As a result, the actual combustion time may become very short, and there is a concern about tar adhesion to the nozzle 28.
[0083]
  Therefore, in this embodiment, in order to prevent chattering, a difference is provided between the temperature to be ignited and the temperature to be extinguished. For example, when the first temperature sensor 32 detects a temperature of less than 30 ° C. (including a correction amount by differentiation), the combustion unit 6 is turned on and when the first temperature sensor 32 detects a temperature of 31 ° C. or more ( A width is provided between ON and OFF of ignition so that the combustion section 6 (including the correction amount by differentiation) is extinguished. However, the temperature value to be turned on and the temperature value to be turned off are corrected by the deviation between the second temperature sensor 33 and the set value.
[0084]
  In addition, in order to prevent chattering and tar adhesion, the shortest actual combustion time and the shortest total combustion time (combustion time including time such as pre-purge) are set, and once a combustion command is issued, The combustion is not stopped before any one of these times elapses. Similarly, once a fire extinguishing command is issued, the ignition is not performed before a considerable time has elapsed.
[0085]
  The overall operation of this embodiment will be described below with reference to FIG.
  The control program employed in the hot water storage type hot water heater 1 of the present embodiment repeats steps 1 to 14 shown in FIG. 3 at high speed, monitors the temperature of the first temperature sensor 32, and turns on the temperature (correction value). It is confirmed whether or not the reference temperature (correction value) is OFF. In addition, after detecting the temperature at which the first temperature sensor 32 should be turned on, it is confirmed whether a sufficient time has elapsed including pre-purge or the like, or whether a predetermined time has elapsed after ignition. The fire is not extinguished until such time has passed.
  Furthermore, after the temperature at which the first temperature sensor 32 is to be turned off is detected, it is confirmed whether or not a predetermined time has elapsed, and reignition is not performed until the predetermined time has elapsed.
[0086]
  If it demonstrates along FIG. 3, if the combustion part 6 is a fire extinguishing state now, for example, it will be confirmed whether the shortest combustion OFF instruction | command time previously set by step 10 has passed.
  In step 1, it is confirmed whether or not the hot water supply mode is “other than combustion”. More specifically, it is confirmed whether or not it is in an ignited state.
  If the fire is extinguished as described above, the process proceeds to step 2 and the shortest actual combustion time timer is set. In the present embodiment, the shortest actual combustion time timer is the minimum time to be continuously burned in order to prevent adhesion of tar or the like, and a time of 4 seconds is set.
[0087]
  Subsequently, in step 3, it is confirmed whether or not the second temperature sensor 33 is operating normally. If the 2nd temperature sensor 33 is normal, it will transfer to step 4 and will check whether the temperature of the 2nd temperature sensor 33 is less than 90 degreeC.
  In this embodiment, as described above, the setting of the shortest actual combustion time and the shortest total combustion time (combustion time including time such as pre-purge) are set. Sometimes it becomes. Therefore, in the present embodiment, the temperature of the second temperature sensor 33 is monitored, and if it is not less than 90 ° C., the routine proceeds to step 9 where the hot water supply combustion command is turned off and the operation at the time of abnormality such as combustion stop or abnormality display is performed.
[0088]
  On the other hand, if the temperature of the 2nd temperature sensor 33 is less than 90 degreeC, it will transfer to step 5 and it will be confirmed whether the hot water supply combustion command is ON. If the combustion unit 6 is in the fire extinguishing state as described above, the hot water supply combustion command is not ON, so step 5 is NO and the routine proceeds to step 11.
[0089]
  If it is found in step 3 that the second temperature sensor 33 is defective, step 4 is skipped and step 5 is entered, and step 11 is further entered.
[0090]
  In step 11, it is confirmed whether or not the temperature of the first temperature sensor 32 has dropped to a temperature at which the combustion unit 6 should be ignited. Here, the temperature of the first temperature sensor 32 is a value corrected by Equation 1 described above. Further, the temperature at which the combustion unit 6 should be ignited is also a value corrected by the correction coefficient α.
[0091]
  When the temperature of the hot water in the hot water storage section 2 is actually high, the routine proceeds to step 14 where the shortest combustion command ON time timer is set. Then, the process proceeds to the final step and the same flow is resumed again.
  In the flow operation again, the same process as the previous time is followed and step 11 is reached. And when the temperature of the hot water in the hot water storage part 2 is still high, it transfers to step 14 again and resets the shortest combustion command ON time timer. Then, the process proceeds to the final step and the same flow is resumed again.
  Therefore, in step 11, the result waits for the detected temperature of the first temperature sensor 32 to be equal to or lower than the temperature at which the combustion of the combustion unit 6 should be ignited.
[0092]
  Then, when time passes and the temperature of the hot water in the hot water storage section 2 decreases and it is found in step 11 that the temperature of the first temperature sensor 32 has reached the temperature at which the combustion section 6 should be ignited, the routine proceeds to step 12. Then, it is confirmed whether or not the shortest combustion OFF command time has elapsed.
  If the shortest combustion OFF command time has elapsed, there is no risk of chattering, so the routine proceeds to step 13 and the hot water supply combustion command is turned ON. That is, an ignition command to the combustion unit 6 is issued.
  And it transfers to the last step and repeats the step from step 1 again.
[0093]
  If the shortest combustion OFF command time has not elapsed, there is a risk of chattering, so the routine proceeds to step 14, the shortest combustion command ON time timer is reset, the final step is performed, and the same flow is resumed again. Step 14 is reached.
  While repeating the operations from step 1 to step 14 in this way, when the shortest combustion OFF command time has elapsed, step 12 becomes YES, and the routine proceeds to step 13 to turn on the hot water supply combustion command. That is, an ignition command to the combustion unit 6 is issued.
[0094]
  In the next flow, the shortest actual combustion time set in step 2 of the previous flow is measured. Note that the time measurement of the shortest actual combustion time is theoretically started after the hot water supply combustion command in Step 13 is issued. However, in the actual control device, the process of the flowchart is performed at the electric speed. In practice, the hot water combustion command and the shortest actual combustion time are measured at the same time.
[0095]
  In this flow, the hot water supply combustion command is turned on in step 13 of the previous flow, but it is unclear whether or not it is actually ignited. If ignition has not been performed, the process proceeds to step 2 to reset the timer for the shortest actual combustion time.
  In step 3, the operation of the second temperature sensor 33 is confirmed, and the process proceeds to step 4 and step 5.
  In step 5, as described above, it is confirmed whether or not the hot water supply combustion command is ON. However, since the hot water supply combustion command is ON in step 13 in the previous flow, it is determined as YES in step 5. Therefore, the process inevitably shifts from step 5 to step 6.
[0096]
  Then, it is confirmed whether or not the detected temperature (correction value) of the first temperature sensor 32 is equal to or higher than the temperature at which the combustion of the combustion section 6 should be turned off.
  However, since the current state is confirmed to be lower than the temperature at which the combustion of the combustion section 6 should be turned on in step 11, and further, the combustion device is not ignited, so step 6 is inevitably NO. Yes, the process proceeds to step 10, the timer for the shortest combustion OFF command time is set, and the process proceeds to the final step. Then, the flow is repeated again to reach step 1, and it is confirmed whether or not the combustion mode is other than combustion. Therefore, as a result, the timer of the shortest actual combustion time is continuously reset in step 2 and waits for the combustion mode to become combustion.
[0097]
  If the combustion unit 6 is ignited, step 1 is determined to be NO, step 2 is skipped, and the process proceeds to step 3. That is, if it is actually ignited, it is not preferable to reset the timer of the shortest actual combustion time, so step 2 is skipped and the routine proceeds to step 3. Therefore, the time measurement of the shortest actual combustion time that was started in the previous flow is continued. In other words, the timer for the shortest actual combustion time is reset immediately before ignition, and thereafter, the time for actual combustion is counted.
[0098]
  In step 3, the operation of the second temperature sensor 33 is confirmed, and the process proceeds to step 4 and step 5.
  In step 5, as described above, it is confirmed whether or not the hot water supply combustion command is ON. However, since the hot water supply combustion command is ON in step 13 in the previous flow, it is determined as YES in step 5. Therefore, the process inevitably shifts from step 5 to step 6.
[0099]
  Here, it is confirmed whether or not the temperature detected by the first temperature sensor 32 (after correction) is equal to or higher than the temperature at which the combustion of the combustion section 6 should be turned off.
  If the temperature detected by the first temperature sensor 32 is not equal to or higher than the temperature at which the combustion of the combustion section 6 is to be turned off, the process proceeds to step 10, the timer for the shortest combustion OFF command time is set, and the process proceeds to the final step. Then, the third flow operation is performed. In this case, the same process as the second time is followed, and step 6 is reached.
[0100]
  Therefore, in step 6, the result of waiting for the detected temperature of the first temperature sensor 32 to be equal to or higher than the temperature at which the combustion of the combustion unit 6 should be turned off is obtained. During this time, the combustion section 6 continues to burn, and the temperature of the hot water in the hot water storage section 2 rises. When the temperature detected by the first temperature sensor 32 is equal to or higher than the temperature at which the combustion of the combustion unit 6 should be turned off, step 6 becomes YES, and the process proceeds to step 7 to check whether the shortest combustion ON command time has elapsed. . That is, it is confirmed whether or not the timer for the shortest combustion ON command time set in step 14 has expired.
[0101]
  If the timer for the shortest combustion ON command time set in step 14 has expired, there is no fear of chattering or tar sticking, so the routine proceeds to step 9 and the hot water supply combustion command is turned OFF. Specifically, the combustion of the combustion unit 6 is stopped.
[0102]
  On the other hand, if the timer for the shortest combustion ON command time set in step 14 has not expired, the process proceeds to step 8 to check whether the shortest actual combustion time has elapsed. That is, the timer of the shortest actual combustion time that has started timing in step 2 is confirmed. Here, if the shortest actual combustion time has passed the predetermined time, there is no fear of chattering or tar sticking, so the routine proceeds to step 9 and the hot water supply combustion command is turned off.
  On the other hand, if the timer of the shortest actual combustion time set in step 2 has not expired, step 9 is skipped and the process proceeds to the final step, and the same process is executed again.
  When either the shortest combustion ON command time exceeds a predetermined time or the shortest actual combustion time elapses, the process proceeds to step 9 to turn off the hot water supply combustion command. That is, when the shortest combustion ON command time exceeds a predetermined time, step 7 is YES and the routine proceeds to step 9, and when the shortest actual combustion time has elapsed, step 8 is YES and the routine proceeds to step 9.
[0103]
  Then, the flow is newly executed again. At this time, the shortest combustion OFF command time is reset in Step 10, and Step 1 is executed while measuring the shortest combustion OFF command time.
  Thereafter, the flow as described first is repeated.
[0104]
  The hot water storage type water heater 1 of the present embodiment turns the combustion unit 6 on and off based on the temperature detected by the first temperature sensor 32, and the value of the first temperature sensor 32 is more sensitive by the calculation of Equation 1. Is reflected in the ON / OFF control. For this reason, when the first temperature sensor 32 fails, not only accurate control cannot be performed, but also when the first temperature sensor 32 is fixed and a signal indicating a temperature lower than the normal temperature is output, the combustion means changes the combustion state. It is dangerous because it will continue to be maintained.
  Therefore, the hot water storage type water heater 1 of the present embodiment has a function of detecting a failure of the first temperature sensor 32.
  Here, the failure of the first temperature sensor 32 is roughly divided into disconnection, short-circuiting, and adhesion. Here, the disconnection and the short clearly show an abnormal resistance value. Therefore, in this embodiment, when the first temperature sensor 32 has an abnormal resistance value, it is immediately determined that the first temperature sensor 32 has failed. In this embodiment, a thermistor is used for the first temperature sensor 32. However, when another type of sensor such as a thermocouple is employed, a signal corresponding to an abnormal temperature such as an abnormal voltage is detected. When it is issued, it is judged as a failure.
[0105]
  Compared to the disconnection or short circuit described above, it is difficult to determine a failure when the first temperature sensor 32 is fixed. In particular, during the normal operation of the hot water storage type water heater 1, since the change in the hot water temperature itself is small, it is difficult to find the first temperature sensor 32 sticking.
  Therefore, in the present embodiment, the temperature change of the first temperature sensor 32 is monitored for a certain time from the start of combustion, and the temperature rise is not continuously detected for a predetermined time within the certain time. Thus, when the second temperature sensor 33 detects a certain temperature, it is determined that the first temperature sensor 32 is fixed.
  Specifically, the inspection time is 30 seconds, and if the first temperature sensor 32 does not show an increase for 20 seconds, it is determined that the sensor is fixed. More specifically, the inspection time is 30 seconds, and the temperature of the first temperature sensor 32 is detected every 2 seconds during that time. If the first temperature sensor 32 does not show a constant (1 ° C.) increase, 1 is counted, this is repeated for 30 seconds, and the count number is accumulated.
[0106]
  During this time, if the first temperature sensor 32 shows an increase, the count integration is reset and counted again.
  Further, when the first temperature sensor 32 indicates a temperature drop during the inspection, the above-described count number is reset. Then, the temperature at which the temperature has decreased most is set as a new start reference, and 1 is counted unless the first temperature sensor 32 shows a constant (1 ° C.) increase from the new start temperature. If the first temperature sensor 32 shows an increase, the count integration is reset and counted again.
  Thus, the reason why the count number is reset when the first temperature sensor 32 indicates a decrease in temperature is because it indicates at least a change in temperature, and the possibility of failure is somewhat reduced.
[0107]
  The reason why the temperature at which the temperature has decreased most when the first temperature sensor 32 shows a decrease in temperature is used as a new starting reference is to check the rising tendency of the first temperature sensor 32. That is, although the first temperature sensor 32 indicates a temperature drop, if the inspection start reference is left unchanged, the rise cannot be confirmed when the rise width in 30 seconds is small.
  Also, from the aspect of safety, it is essential to confirm that the first temperature sensor 32 shows an increase, and when the first temperature sensor 32 shows a temperature decrease, the temperature at the time when the temperature has decreased most is newly started. We decided to inspect as a standard.
[0108]
  In this embodiment, it is further determined that the first temperature sensor 32 is malfunctioning on the condition that the second temperature sensor 33 detects a predetermined temperature or higher. That is, it is clearly contradictory that the first temperature sensor 32 does not show a temperature rise while the second temperature sensor 33 shows a considerable temperature. For this reason, it is determined that the first temperature sensor 32 is out of order when both conditions are met.
  Hereinafter, control for detecting sticking of the first temperature sensor 32 will be described with reference to FIG.
[0109]
  The control shown in this flowchart is started on the condition that combustion is started. That is, it is called when an ignition command is given and ignition to the combustion section 6 is confirmed, and step 1 starts. At the same time as the ignition operation is performed, a timer that measures the inspection time starts timing. In this embodiment, the time of 30 seconds is counted.
  In the control for detecting the sticking of the first temperature sensor 32, the inspection time is confirmed in the first step 1. It is the timer that has started measuring the time in accordance with the ignition operation described above.
[0110]
  If the time of 30 seconds has not elapsed, the process proceeds to step 2 to determine whether 2 seconds have elapsed. If 2 seconds have elapsed, the process proceeds to step 3 to reset the 2-second timer again. Then, the process proceeds to step 3 where the temperature detected by the first temperature sensor 32 is confirmed.
  Then, the process proceeds to step 5 where the initial temperature is compared with the current temperature.
  If the current temperature is not lower than the initial temperature, the process proceeds to step 13 to check whether the difference between the current temperature and the initial temperature is 1 ° C. or more.
  If the difference between the current temperature and the initial temperature is 1 ° C. or more, the counter is reset and the process proceeds to step 7.
  On the other hand, if the difference between the current temperature and the initial temperature is less than 1 ° C., the counter is incremented by 1 and the process proceeds to step 7.
[0111]
  In step 7, the number of counters is confirmed. If the number of counters exceeds 10, as a result of observing for 20 seconds, a temperature rise of 1 ° C was not continuously observed, which is clearly unnatural. Therefore, if step 7 is YES, the process proceeds to step 8, and it is confirmed that the first temperature sensor 32 is fixed. Specifically, a predetermined flag is set.
[0112]
  Then, the timer for measuring the inspection time is cleared to end the inspection. Subsequently, the process proceeds to step 10 where the flag set in the previous step 8 is confirmed to determine whether or not the first temperature sensor 32 is fixed.
[0113]
  In the current control flow, since the flag is set, it is determined that the first temperature sensor 32 is fixed. Therefore, step 10 is determined as YES, and the process proceeds to step 11. In step 11, the temperature of the second temperature sensor 33 is detected, and it is checked whether or not it exceeds 50 ° C.
  If the temperature of the 2nd temperature sensor 33 is detected and this exceeds 50 degreeC, it contradicts that the 1st temperature sensor 32 does not show a temperature rise. Therefore, the process proceeds to step 12, and the operation at the time of abnormality such as combustion stop or abnormality display is performed.
[0114]
  If the number of counters is 10 or less as a result of checking the number of counters in step 7, it cannot be said that the first temperature sensor 32 is out of order. Therefore, if the number of counters is less than 10 in step 7, steps 8 and 9 are skipped and the process proceeds to step 10. In this flow, since the flag is not set, it cannot be said that the first temperature sensor 32 is fixed. Therefore, it is judged as NO in step 10, and it shifts to the last step and repeats the previous control.
  In the case of repetitive operation, if a temperature increase of 1 ° C. or more is recognized during the previous flow, it is compared with the current temperature based on the previous detected value.
  In this way, the flow is repeated for 30 seconds, and when the number of counters is finally less than 10, the inspection is terminated assuming that the first temperature sensor 32 is normal.
[0115]
  Further, when the detected value of the first temperature sensor 32 decreases during the inspection, such as when water is suddenly introduced into the hot water storage section 2, it is determined YES in the step 5 and the counter is reset. The previous temperature is changed to the current temperature, and the above control is performed.
[0116]
  In the embodiment described above, when integrating the deviation between the detected value of the second temperature sensor 33 and the set temperature, a policy is adopted in which the time of the post-boiling state and the start-up time at the start of operation are not integrated. Some of them do not need to be distinguished when they are in a post-boiling state.
  FIG. 5 is a control flow when no distinction is made between the time of the post-boiling state and the like.
[0117]
  In the embodiment described above, the second temperature sensor 33 is provided in the hot water storage section of the hot water storage type hot water heater, but the second temperature sensor 33 may be any place that can detect a temperature as close to the hot water temperature as possible. You may provide in the position immediately after leaving the hot water storage part of a water heater.
[0118]
  Further, in the above-described embodiment, a correction value is added to the detected value of the first temperature sensor 32 by the differential calculation to correct the temperature at which the ON / OFF control is ignited / extinguished, but the ON value is calculated by the differential calculation. -Switching reference value for OFF control may be changed.
  Conversely, in the above-described embodiment, the temperature at which the burner of the combustion unit 6 should be ignited and the temperature at which the burner 6 is extinguished are shifted by the detection value of the second temperature sensor 33. Based on this, a predetermined value may be added to the detection value of the first temperature sensor 32.
[0119]
【The invention's effect】
  As described above, the hot water storage type water heater according to claim 1 corrects the combustion state based on the information about the deviation between the detected value of the second temperature detecting means and the set temperature, and therefore detects the second temperature close to the tapping temperature. The detection value of the means is taken into account, the temperature of the hot water is easily controlled, and the temperature close to the target temperature can be discharged.
[0120]
  Similarly, the combustion control means according to claim 3 corrects the temperature at which the combustion state is ignited and extinguished based on the information about the deviation between the detected value of the second temperature detecting means and the set temperature, so that the temperature information of the part close to the tapping temperature In consideration of the above, ignition and fire extinguishing are controlled, the temperature of the hot water is easily controlled, and the temperature close to the target temperature can be discharged.
[0121]
  Further, in the hot water storage type water heater according to claim 4, the second temperature detecting means is provided in a portion closer to the hot water outlet than the first temperature detecting means. Therefore, the temperature closer to the tapping temperature than the first temperature detecting means can be detected.
[0122]
  Further, the hot water storage type water heater according to claim 5 includes a deviation integrating means, and integrates the deviation between the detected value of the second temperature detecting means and the set temperature. This integrated value is an index indicating whether the detected temperature of the first temperature detecting means is higher or lower than the actual hot water temperature (the detected temperature of the second temperature detecting means), and the hot water temperature is set to the target value. Can be approached.
[0123]
  In addition, the hot water storage type water heater according to claim 6 has an effect of allowing hot water to be discharged at a temperature close to the target temperature by excluding from the integration the case of a peculiar state at the time of post-boiling or early ignition.
[0124]
  Further, in the hot water storage type water heater according to claim 7, since the deviation between the detected value of the second temperature detecting means less than a certain value and the set temperature is not subject to integration, the correction value is stabilized and the target temperature is reached. There is an effect that can bring out a near temperature.
[0125]
  Moreover, the hot water storage type water heater according to claim 8 has an effect of being able to detect a failure of the first temperature detecting means, and has high safety.
[0126]
  Further, the inventions according to claims 9 and 10 further determine that the first temperature detection means is faulty on the condition that the second temperature detection means detects a predetermined temperature or higher, so that the reliability of fault detection is high. High effect.
[Brief description of the drawings]
FIG. 1 is a conceptual diagram of a hot water storage type water heater according to an embodiment of the present invention.
FIG. 2 is a flowchart of control means for correcting an ON / OFF switching reference value of the hot water storage type water heater of FIG. 1;
FIG. 3 is a flowchart showing the overall operation of the hot water storage type water heater shown in FIG. 1;
4 is a flowchart of control for detecting an abnormality in a first temperature sensor of the hot water storage type water heater shown in FIG. 1;
FIG. 5 is a flowchart of control means for correcting an ON / OFF switching reference value of a hot-water storage water heater in another embodiment of the present invention.
[Explanation of symbols]
    1 Hot water storage water heater
    2 Hot water storage
    6 Combustion section
  32 First temperature sensor
  33 Second temperature sensor
  35 controller
  36 Remote controller

Claims (11)

  A hot water storage part having a water inlet and a hot water outlet for storing hot water therein, a combustion means for burning and heating the hot water in the hot water storage part, a first temperature detecting means for detecting the temperature of the hot water in the hot water storage part, and a hot water temperature are set. In the hot water storage type hot water heater having a hot water temperature setting means and having a combustion control means for controlling the combustion means based on information relating to the temperature detected by the first temperature detection means, the hot water downstream of the first temperature detection means It has a second temperature detection means for detecting the hot water temperature, and the combustion control means switches between ON and OFF based on the detected value of the second temperature detection means and information on the deviation of the set temperature set by the tapping temperature setting means. Hot water storage type water heater characterized by correcting the reference value.   A hot water storage part having a water inlet and a hot water outlet for storing hot water therein, a combustion means for burning and heating the hot water in the hot water storage part, a first temperature detecting means for detecting the temperature of the hot water in the hot water storage part, and a hot water temperature are set. In the hot water storage type hot water heater having a hot water temperature setting means and having a combustion control means for controlling the combustion means based on information relating to the temperature detected by the first temperature detection means, the hot water downstream of the first temperature detection means A second temperature detecting means for detecting the hot water temperature, and the combustion control means performs the ON / OFF control based on the detected value of the second temperature detecting means and the information regarding the deviation of the set temperature set by the tapping temperature setting means. A hot water storage type water heater characterized by changing the switching temperature when adding or adding a correction value to the temperature detection value side.   A hot water storage part having a water inlet and a hot water outlet for storing hot water therein, a combustion means for burning and heating the hot water in the hot water storage part, a first temperature detecting means for detecting the temperature of the hot water in the hot water storage part, and a hot water temperature are set. In a hot water storage type hot water heater having a hot water temperature setting means and having a combustion control means for igniting and extinguishing the combustion means based on information relating to the temperature detected by the first temperature detection means, A second temperature detecting means for detecting the hot water temperature, the combustion control means igniting / extinguishing based on information about a deviation between a detected value of the second temperature detecting means and a set temperature set by the tapping temperature setting means; A hot water storage type water heater characterized by correcting the temperature at which the heat is performed.   The hot water storage device according to any one of claims 1 to 3, wherein the second temperature detection means detects the hot water temperature in the hot water storage section at a location closer to the outlet than the first temperature detection means. Type water heater.   5. The apparatus according to claim 1, further comprising a deviation integration unit that integrates a deviation between the detection value of the second temperature detection unit and the set temperature, and performing correction according to the integration value of the deviation integration unit. The hot-water storage water heater described.   It is a period during which combustion is scheduled and the detected value of the second temperature detection means is lower than a set temperature set by the tapping temperature setting means by a certain level or when the combustion is not scheduled and the second temperature detection means 6. The hot water storage type hot water heater according to claim 5, wherein when the detected value is higher than a set temperature set by the tapping temperature setting means by a certain level or more, the deviation integrating means is not subject to integration.   The deviation integrating means is not subject to integration when the deviation between the detected value of the second temperature detecting means and the set temperature set by the tapping temperature setting means is less than a certain value. Hot water storage water heater.   The temperature change of the first temperature detection means is monitored over a certain time from the start of combustion, and the first temperature detection means fails on the condition that no temperature rise is detected for a predetermined time within the predetermined time. The hot water storage type hot water heater according to any one of claims 1 to 7, further comprising a failure determination function for determining that   The hot water storage type water heater according to claim 8, wherein in addition, it is determined that the first temperature detecting means is malfunctioning on the condition that the second temperature detecting means detects a predetermined temperature or more.   10. A combustion stop means for stopping combustion when the failure determination means detects a failure of the first temperature detection means and the second temperature detection means detects a temperature above a predetermined temperature. The hot-water storage water heater described.   Based on the detected value of the first and current temperature detecting means in the past and the current detected value of the first temperature detecting means, the control value is calculated by adding a numerical value by differential operation, and the combustion control means is based on the control value. The hot water storage type water heater according to claim 1, wherein the temperature at which ignition and extinguishing are performed is corrected.

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