JP3703594B2 - Temperature controller for combined hot water heating system - Google Patents

Description

【００３３】
なお、床単独運転の間にも、加熱用熱交換器１２で加熱された温水が室内機２の暖房用熱交換器１５にも循環するが、床単独運転では、対流ファン２００の作動は停止されていて、暖房用熱交換器１５の内部を通過する温水の熱が室内へ放出されにくくなっているため、暖房用熱交換器１５による暖房効果はほとんど得られない。
また、床暖房ホットダッシュ動作では、外気温度Ｔａと床暖房レベルＨｎに応じた上記表１の目標湯温ＴＯではなく、各床暖房レベルＨｎに応じた高温の目標湯温ＴＯ（例えば６５℃〜８５℃）に設定して、ガスバーナ１００の加熱量を高温水サーミスタ４０１の検知温度に基づいて制御する。
【００３４】
〔デュエット暖房運転（複合暖房運転）〕
デュエット暖房運転は、室内機２と床暖房パネル３とにより室内の暖房を行うものであるが、主に室内機２によって室内の温度を上昇させるもので、床暖房パネル３は、室内機２の補助として作用することになる。従って、上記の床単独運転において、制御に用いられたリモコン４により設定される床暖房レベルＨｎは、デュエット暖房運転では用いられず、暖房能力の制御には無関係となる。
以下、デュエット暖房運転について、図２に示すデュエット暖房運転に係わる制御装置４００の機能構成に基づいて説明する。
【００３５】
デュエット暖房運転でも、循環ポンプ１１を一定回転で駆動し、加熱用熱交換器１２で加熱される温水の温度が、決定された目標湯温ＴＯになるように、燃焼ファン１０１およびガス比例弁１０５を制御して、ガスバーナ１００の燃焼量を調節する。また、室内機２の対流ファン２００の駆動、停止を制御して、駆動時には、暖房用熱交換器１５に室内空気を通過させることによって、加熱して室内へ温風として吹き出す。
【００３６】
デュエット暖房運転の能力制御では、暖房能力として１速（最小暖房能力）から８速（最大暖房能力）までの８段階の能力が設けられていて、リモコン４によって設定された設定温度Ｔset と運転中に検知される検知室温Ｔｒとの温度差に基づいて温調制御が行われて、暖房能力が順次１段階ずつ変更される。
【００３７】
温調制御は、ある速数で運転した状態で検知室温Ｔｒを設定温度Ｔset と比較し、設定温度Ｔset に対する検知室温Ｔｒの温度差の程度に応じた周期時間だけ同じ速数の暖房能力を継続し、温度差に応じた周期時間が経過した後に、温度差が同じ温度差範囲内にある場合には、その速数Ｎを大きくまたは小さくする決定して、その決定に応じて現状の速数Ｎを上下させることによって、新たな速数Ｎを決定して、以後、同様に、温度差に応じた周期で検知室温Ｔｒを設定温度Ｔset と比較して、必要に応じて速数を変更する。
【００３８】
この決定のために、本実施例の温調制御では、検知室温Ｔｒが設定温度Ｔset と等しいとみなされる温度範囲として、検知室温Ｔｒが設定温度Ｔset に対して等しい状態から１℃までの範囲で低い状態を設定している。すなわち、
温度差ΔＴ＝検知室温Ｔｒ−設定温度Ｔset
で得られる温度差ΔＴが、−１≦ΔＴ≦０℃の場合を、検知室温Ｔｒが設定温度Ｔset と等しいと判断する。また、温度差ΔＴが、ΔＴ＜−１℃の場合には、検知室温Ｔｒが設定温度Ｔset より低く、１℃＜ΔＴの場合には、検知室温Ｔｒが設定温度Ｔset より高いとそれぞれ判断する。
【００３９】
上記の温度差判断を行うに当たって、通常は、対流ファン２００が作動して、室内空気が室内機２の上方に設けられた室内空気吸込口から吸い込まれるため、吸い込み位置サーミスタ４０３の検知する温度を、検知室温Ｔｒとして処理することで、設定温度Ｔset と検知室温Ｔｒとの温度差を正確に判断することができるが、例えば、温調制御によって対流ファン２００の作動が停止している場合には、室内機２内に室内空気の流れが生じないため、暖房用熱交換器１５内を流れる温水の熱が室内機２内に滞り、室内機２内の上方の吸い込み位置サーミスタ４０３はこの高温を検知するため、室内温度を正しく検知することができなくなる。
【００４０】
そこで、本実施例では、室内温度を正しく検知するための構成として、室温検知部４１０を設け、図３に示すように、対流ファン２００が作動している場合には（ステップ１０においてＹＥＳ）、吸い込み位置サーミスタ４０３の検知温度を室内温度として検知し（ステップ２０）、対流ファン２００が作動していない場合には（ステップ１０においてＮＯ）、空気吹出口側に設けられた吹き出し位置サーミスタ４０５の検知温度を室内温度として検知する（ステップ３０）ようにしている。これによって、対流ファン２００の作動の有無に拘らず、常に、正確な室内温度を検知することができる。
【００４１】
また、このように、２つのサーミスタを異なる場所に設けて、運転状態に応じて室温を検知するサーミスタを切替えることによって、例えば、従来の場合のように、吸い込み位置側だけに、室温検知のためのサーミスタを設けて置く場合には、この室温検知用のサーミスタによって室内温度を正確に検知するためには、対流ファン２００の作動が停止した状態では、室内機２による暖房が不要な場合であっても、必ず対流ファン２００を作動させなければならなかったために、過剰な暖房を行う結果を招いていたが、本実施例のように、２か所のサーミスタを切り替えて室温を検知する場合には、対流ファン２００が停止した状態であっても、正確に室内温度を検知することができるため、室内機２による暖房が不要な場合には対流ファン２００を作動させる必要がなく、過剰暖房を防止できる。
【００４２】
次に、上記の温度差判断に基づいた温調制御を行う暖房能力決定部４２０の作動について、図４に基づいて、以下に詳細に説明する。
まず、室温検知部４１０によって選択された検知室温Ｔｒを設定温度Ｔset と比較し、その温度差ΔＴが−１≦ΔＴ≦０℃の場合には（ステップ１００において▲１▼［−１〜０℃］）の場合には、検知室温Ｔｒが設定温度Ｔset と等しい状態であると判断して、現状維持として速数Ｎの変更を行わず、検知室温Ｔｒと設定温度Ｔset との比較を繰り返す（ステップ１００）。
【００４３】
検知室温Ｔｒを設定温度Ｔset と比較し、設定温度Ｔset に対して検知室温Ｔｒが１℃以上低く、その温度差ΔＴがΔＴ＜−１℃の場合には（ステップ１００において▲２▼［−１℃以下］）、そのときの速数Ｎで７分間待機し（ステップ１１０）、７分間経過した時点でも、なお設定温度Ｔset に対して検知室温Ｔｒが、１℃以上低い場合には（ステップ１１１においてＹＥＳ）、速数Ｎを１速上げて（ステップ１１２）、暖房能力を大きくする。
【００４４】
検知室温Ｔｒを設定温度Ｔset と比較した場合に、逆に設定温度Ｔset に対して検知室温Ｔｒが＋１℃までの範囲で高く、その温度差ΔＴがΔＴ≦１℃の場合には（ステップ１００において▲３▼［＋１℃以内］）、そのときの速数Ｎで５分間待機し（ステップ１２０）、５分間経過した時点でも、なお設定温度Ｔset に対して検知室温Ｔｒが、１℃までの範囲で高い場合には（ステップ１２１においてＹＥＳ）、速数Ｎを１速下げて（ステップ１２２）、暖房能力を小さくする。
【００４５】
検知室温Ｔｒを設定温度Ｔset と比較した場合に、設定温度Ｔset に対して検知室温Ｔｒが１℃以上高く、その温度差ΔＴが１℃＜ΔＴの場合には（ステップ１００において▲４▼［＋１℃以上］）、そのときの速数Ｎで３分間待機し（ステップ１３０）、３分間経過した時点でも、なお設定温度Ｔset に対して検知室温Ｔｒが、１℃以上高い場合には（ステップ１３１においてＹＥＳ）、対流ファン２００の作動を３分間停止する（ステップ１３２）。
【００４６】
このとき、室内機２の暖房用熱交換器１５にも温水が循環するが、暖房用熱交換器１５は対流ファン２００の作動によって内部を通過する温水の熱が室内へ放出される構造であるため、暖房用熱交換器１５による暖房効果はほとんど得られない。この対流ファン２００の停止時は、室内機２による暖房を停止させ、床暖房パネル３のみによって暖房を行うことになり、この場合は、大きな熱量で能動的に暖房を行うのではなく、室内温度が著しく低下することを防止するための熱量が室内に放出されるようなホットキープ動作を行う。
これによって、ホットキープ動作の３分間は、室内を暖める能力がさらに低下するため、室内温度の上昇を抑制でき、室内温度を下げることが可能となる。
【００４７】
なお、ホットキープ動作においては、対流ファン２００の作動が停止するため、暖房効率が下がるとともに、室内空気の循環が停止して吸い込み位置サーミスタ４０３では、検知室温Ｔｒの正しい検知ができなくなる。
このため、ホットキープ動作によって対流ファン２００が停止している間には、上記の室温検知部４１０によって、吹き出し位置サーミスタ４０５の検知温度が検知室温Ｔｒとして検知される。
従って、正しく室内温度を検知することができる。
【００４８】
対流ファン２００の作動停止の３分間が経過したとき、吹き出し位置サーミスタ４０５が検知する検知室温Ｔｒが、設定温度Ｔset よりまだ高い場合には、対流ファン２００の作動を再開せず、再び、ホットキープ動作を行って、対流ファン２００の作動を３分間停止する。従って、この間は、吹き出し位置サーミスタ４０５が、引き続き室内温度を検知する。
【００４９】
対流ファン２００の作動停止の３分間が経過したとき、吹き出し位置サーミスタ４０５が検知する検知室温Ｔｒが、設定温度Ｔset の＋１℃の温度より下がっていた場合には、ホットキープ動作を終了して、再び対流ファン２００を作動し、温調動作を行う。このとき、室内温度を検知するサーミスタは、吹き出し位置サーミスタ４０５から吸い込み位置サーミスタ４０３へと切り替わり、室内機２内へ吸い込まれる室内空気の温度を検知する。
この場合、吸い込み位置サーミスタ４０３へ切り替わった当初は、ホットキープ動作の間に、暖房用熱交換器１５を通過する温水によって吸い込み位置サーミスタ４０３の検知する温度は高いが、温調制御では、３分間は継続して同じ暖房能力での運転が行われるため、この３分間の間に、吸い込み位置サーミスタ４０３が吸い込まれる室内空気によって冷却されるため、３分間が経過して次の温度差判断を行う時点では、正しい室内温度を検知することができる。
【００５０】
以上の暖房能力決定部４２０によって決定される暖房能力（速数Ｎ）と、この暖房能力（速数Ｎ）に対応して、目標湯温決定部４３０において決定される目標湯温ＴＯとの関係を表２に示す。
【００５１】
【表２】

【００５２】
上記、ステップ１３２によって対流ファン２００が停止して、室内機２の暖房が停止しているホットキープ動作の間は、検知室温Ｔｒが設定温度Ｔset に対して十分に上昇している状態であり、室内に対する大きな加熱量が不要な状態である。従って、目標湯温決定部４３０では、ホットキープ動作の間には、加熱用熱交換器１２で加熱される温水の目標湯温ＴＯを、１速における目標湯温ＴＯではなく、外気温度サーミスタ４０４によって検知される外気温度Ｔａに基づいて決定する。本実施例時では、外気温度Ｔａに対応してあらかじめ設定されたホットキープ動作時の目標湯温ＴＯのデータがマイコンのメモリに記憶されており、外気温度サーミスタ４０４により検知された外気温度Ｔａが与えられると、その温度に対応した目標湯温ＴＯが決定される。
ホットキープ動作時において決定される目標湯温ＴＯの一例を表３に示す。
【００５３】
【表３】

【００５４】
表３に示すように、ホットキープ動作の場合には、例えば、外気温度Ｔａが０℃以下の場合には、目標湯温ＴＯが７０℃に決定され、２０℃以上の場合には目標湯温ＴＯが４０℃に決定されるなど、単純に固定された一定の温度の温水が床暖房パネル３に供給されないため、時節毎の暖房負荷に適した暖房能力が得られる。
【００５５】
制御装置４００において、燃焼制御部４４０は、加熱用熱交換器１２で加熱される温水の温度が、上記目標湯温決定部４４０において決定される目標湯温ＴＯになるように、高温水サーミスタ４０１の検知温度に基づいて燃焼ファン１０１およびガス比例弁１０５を制御して、ガスバーナ１００の燃焼量を調節する。
尚、対流ファン２００は、上記のとおり決定される目標湯温ＴＯの温水が暖房用熱交換器１５へ供給される場合に、室内機２から吹き出される温風の温度が最適になるように、各速数Ｎ毎に適切に設定された回転数にそれぞれ制御される。また、制御装置４００は、運転終了後には、ガスバーナ１００の燃焼停止後、２分を経過してから循環ポンプ１１の作動を停止することにより、余熱を利用して滑らかに暖房運転を停止させる。
【００５６】
以下、デュエット暖房運転における作動を説明する。
リモコン４により、デュエット暖房運転の開始が指示されると、室内温度の上昇を速やかに行うために、デュエット暖房運転の開始後の３０分間は、温水回路１０の床暖房パネル３への温水配管に設けられた床暖熱動弁１４を閉弁し、循環ポンプ１１を駆動するとともにガスバーナ１００の燃焼を開始し、加熱用熱交換器１２で加熱される温水の温度を、８速に対応した７５℃に調節する。
【００５７】
この結果、８速に応じた高温の温水が、室内機２および床暖房パネル３へ供給され、速やかに、室内の温度を上昇させる。
なお、ガスバーナ１００の所定の点火制御し、循環ポンプ１１の駆動を開始した後でも、室内温水サーミスタ４０２の検知温度が十分に高くなるまでは（例えば３０℃）、冷風の吹き出しを防止するために、対流ファン２００の駆動を開始せず、十分温度が上昇した後に、対流ファン２００による送風を開始する。
【００５８】
その後の温調制御では、リモコン４による設定温度Ｔset と吸い込み位置サーミスタ４０３の検知による検知室温Ｔｒとの温度差に基づいて決まる暖房能力としての速数Ｎに応じて加熱用熱交換器１２で加熱されて流出する温水の目標湯温ＴＯが決定される。
デュエット暖房運転の開始後の３０分間は、床暖熱動弁１４が閉弁されているため、温水回路１０内の温水は、室内機２の暖房用熱交換器１５のみへ供給され、対流ファン２００の作動によって温風が室内へ吹き出される。
【００５９】
デュエット暖房運転の開始して３０分が経過すると、閉弁されていた床暖熱動弁１４が開弁されて、加熱された温水が床暖房パネル３へも供給され、室内機２と床暖房パネル３とにより室内が暖房され、その後も温調運転が継続される。
なお、デュエット暖房運転の運転開始後３０分を経過するまでに、吸い込み位置サーミスタ４０３で検知される検知室温Ｔｒがリモコン４で設定された設定温度Ｔset より高くなると、上述のホットキープ動作に移行し、このホットキープ動作に移行する場合には、運転開始後３０分を経過していなくても床暖熱動弁１４は開弁される。
【００６０】
温調制御において、吸い込み位置サーミスタ４０３で検知される検知室温Ｔｒのリモコン４で設定された設定温度Ｔset に対する温度差が、＋１℃以内の間は、室内機２の対流ファン２００が作動して、床暖房パネル３と室内機２とによるデュエット暖房運転が継続される。
温調制御中に、吸い込み位置サーミスタ４０３で検知される検知室温Ｔｒがリモコン４で設定された設定温度Ｔset より＋１℃以上高くなって、それが３分間続くと、室内機２による暖房動作を休止して、床暖房パネル３のみにより暖房を行うホットキープ動作に入る。
【００６１】
ホットキープ動作になった場合には、温水回路１０の加熱用熱交換器１２で加熱される温水の目標湯温ＴＯを、外気温度サーミスタ４０４で検知される外気温度Ｔａに基づいて上記表３のとおり決定する。
また、３分間のホットキープ動作により対流ファン２００が停止している間には、室内温度を検知するためのサーミスタとして、室内機２の上方位置に設けられた吸い込み位置サーミスタ４０３ではなく、室内機２の下方位置に設けられた吹き出し位置サーミスタ４０５が選択される。
この３分間の対流ファン２００の作動停止が終了する時点では、まだ室内温度は、吹き出し位置サーミスタ４０５によって検知され、このホットキープ動作の３分間が終了する時点で、まだ検知室温Ｔｒが設定温度Ｔset より＋１℃以上高い場合には、再びホットキープ動作が行われ、対流ファン２００は上述のとおり、再び３分間だけ停止し、継続して吹き出し位置サーミスタ４０５によって室内温度が検知される。
【００６６】
逆に、ホットキープ動作の３分間が終了する時点で、吹き出し位置サーミスタ４０５の検知する検知室温Ｔｒの設定温度Ｔset 対する温度差が＋１℃以内の範囲であれば、ホットキープ動作が終了し、対流ファン２００が再び作動し、このとき、室内温度を検知するサーミスタは、吸い込み位置サーミスタ４０３へと切り替わる。
【００６７】
以上のとおり本発明によれば、デュエット暖房運転において、対流ファン２００の作動が停止している間には、室内温度を検知するためのサーミスタとして、室内機２の下方に配置された吹き出し位置サーミスタ４０５が用いられるため、対流ファン２００の作動停止中に室内機２内の暖房用熱交換器１５に温水が供給されて、その上方の吸い込み位置サーミスタ４０３が室内温度を正しく検知できない状態であっても、室内温度を正しく検知することができる。
従って、室内温度の検知のために、対流ファン２００を作動させる必要がないため、室内機２による過剰な暖房が行われることがなく、快適さが損なわれることがないとともに、無駄な暖房を行うことがないため、省力化を図ることができる。
【００６８】
上記実施例では、デュエット暖房運転の開始初期に、床暖房パネル３へ温水を供給する温水回路１０の床暖熱動弁１４を３０分間閉弁するものを示したが、床暖熱動弁１４の閉弁時間は、上記実施例に限定するものではなく、また、床暖熱動弁１４は半開状態あるいは開放状態などでもよい。
上記実施例では、デュエット暖房運転の温調運転中に床暖房パネル３のみによる暖房を行うホットキープ動作を行うものを示したが、ホットキープ動作を行わないで、室内温度が設定温度より低くなるまで室内機２及び床暖房パネル３の作動を共に停止するものでもよい。
上記実施例では、ガスバーナを加熱源としたものを示したが、石油バーナや電気加熱など、他の加熱源による温水暖房システムでもよい。
【図面の簡単な説明】
【図１】本発明の実施例を示す温水暖房式エアコンシステムの概略構成図である。
【図２】本発明の実施例を示す制御装置におけるデュエット暖房運転に係わる機能構成を説明するための機能ブロック図である。
【図３】本発明の実施例における室内温度を検知するサーミスタの切替え動作を説明するための流れ図である。
【図４】本発明の実施例におけるデュエット暖房運転の温調制御を説明するための流れ図である。
【符号の説明】
２ 室内機（室内暖房機）
３ 床暖房パネル
４ リモコン（室温設定器）
１０ 温水回路（温水循環回路）
１１ 循環ポンプ
１２ 加熱用熱交換器
１５ 暖房用熱交換器
１００ ガスバーナ（加熱手段）
２００ 対流ファン
４００ 制御装置（複合温水暖房システムの温度制御装置）
４０１ 高温水サーミスタ（加熱温度センサ）
４０３ 吸い込み位置サーミスタ（上方室温センサ）
４０４ 外気温度サーミスタ（外気温度センサ）
４０５ 吹き出し位置サーミスタ（下方室温センサ）
４１０ 室温検知部（室温検知手段）
４２０ 暖房能力決定部（暖房能力決定手段）
４３０ 目標湯温決定部（目標湯温決定手段）
４４０ 燃焼制御部（加熱制御手段）[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a temperature control device for a combined hot water heating system for heating a room by forming a hot water circulation circuit for circulating hot water heated by one heating source to a floor heating panel and an indoor heater, respectively.
[0002]
[Prior art]
In a combined hot water heating system that simultaneously heats the room with an indoor heater and a floor heating panel, the floor heating panel heats by radiating heat from the hot water that circulates in the interior. In the indoor heater, an internal heating heat exchanger Heating is performed by passing the room air through the heat exchanger for heating by the convection fan provided in the above, heating it with the heat of hot water, and blowing it out as room air.
In this case, in order to simplify the temperature control of the system, the temperature of the hot water heated by the heat exchanger for heating provided with the burner is set so that the heating capacity corresponding to the set temperature is obtained by the indoor heater. The hot water having the same temperature as the hot water supplied to the indoor heater is also supplied to the floor heating panel.
[0003]
As the heating capacity to be determined, a multi-stage capacity is set. For example, at the beginning of the heating operation, the maximum heating capacity is set in order to secure a large heating capacity as much as possible and quickly increase the room temperature. When the room temperature thermistor that detects the room temperature reaches the set temperature set by the remote controller or the like, the maximum heating capacity at the start of operation continues until the detected room temperature reaches the set temperature. When it reaches, the heating capacity is lowered by one stage, and thereafter, every time the detected room temperature reaches the set temperature, the heating capacity is sequentially lowered by one stage. Conversely, when the detected room temperature becomes lower than the set temperature, the heating capacity is reduced. There is one in which capacity control is performed so that the heating capacity is sequentially changed by increasing or decreasing the previous heating capacity so that it can be increased by one stage.
[0004]
Further, during operation, when the detected room temperature is sufficiently higher than the set temperature and the detected room temperature exceeds the set temperature, heating by the indoor heater is stopped.
Here, as a heating stop operation of the indoor heater, in order to simplify the configuration of the hot water circulation circuit, the heat exchange for heating is performed while the supply of hot water to the heating heat exchanger of the indoor heater is continued. There is one in which the heating effect of the indoor heater is stopped by stopping only the operation of the convection fan provided in the heater so that the indoor air is not heated by the heat of the heat exchanger for heating.
In this case, since hot water is supplied to the floor heating panel even while the operation of the convection fan is stopped, heating is stopped, but the heating effect is suppressed as a whole heating system.
[0005]
The room temperature thermistor for detecting the temperature in the room to perform the temperature control as described above is disposed above the heat exchanger for heating in the indoor heater, which is the intake side of the indoor air sucked by the operation of the convection fan. Has been.
[0006]
In the combined hot water heating system configured as described above, for example, when the indoor temperature sufficiently rises and the heating of the indoor heater is stopped, the operation of the convection fan is stopped, but the heat exchanger for heating is used. Therefore, the air in the vicinity of the heating heat exchanger is heated by heat radiation from the hot water in the heating heat exchanger and stays upward. For this reason, the detected temperature of the room temperature thermistor arranged on the upper side of the heat exchanger for heating is a temperature higher than the actual indoor temperature, and the indoor temperature cannot be detected correctly. Therefore, in the conventional hot water heating system, when the room temperature exceeds the set temperature, the convection fan is stopped for a certain period of time to suppress the heating, and after that, the convection fan is not restarted immediately. Is operated for a short time, the temperature of the air in the vicinity of the room temperature thermistor is lowered, the room temperature is correctly detected, and a new heating capacity is determined based on the newly detected room temperature. ing.
[0007]
[Problems to be solved by the invention]
As described above, after the convection fan has been stopped for a certain period of time, the convection fan is operated for a short time to detect the room temperature. Therefore, since the convection fan is always operated for a short time, heating by the indoor heater is performed with the operation of the convection fan. For this reason, even though the room temperature is sufficiently high and heating by the indoor heater is stopped, excessive heating is performed, which may increase the indoor temperature and impair comfort. There is also a problem that unnecessary heating is performed and unnecessary operation is performed.
[0008]
The present invention prevents wasteful heating at the time of combined heating operation in a combined hot water heating system provided with a hot water circulation circuit for supplying hot water of the same temperature heated by a single heating source to an indoor heater and a floor heating panel, The purpose is to perform stable room temperature control.
[0009]
[Means for Solving the Problems]
According to a first aspect of the present invention, there is provided a floor heating panel for heating a room by using heat water passing through the inside of the heat radiating pipe as a heat source, and a convection fan for circulating the room air. An indoor heater that passes hot air through the heat exchanger for heating, passes the indoor air downward from the upper side of the heating heat exchanger by the operation of the convection fan, and blows it into the room; A heating heat exchanger that heats water passing through the interior by heating, wherein the floor heating panel and the indoor heater are provided in parallel to the heating heat exchanger, and the heating heat exchanger In a combined hot water heating system in which a hot water circulation circuit for circulating hot water heated by the pump to the floor heating panel and the indoor heater is formed by a pump, the hot water heated by the heat exchanger for heating is used. A heating temperature sensor for detecting the temperature, a room temperature setting device for setting a target room temperature in the room, an upper room temperature sensor for detecting the room temperature above the heating heat exchanger, and a room temperature for the heating. Select the lower room temperature sensor to detect below the heat exchanger, and select the detection temperature of the upper room temperature sensor as room temperature when the convection fan is activated, and select the detection temperature of the lower room temperature sensor as room temperature when the convection fan is stopped. Room temperature detecting means for detecting the room temperature, and in the combined heating operation for heating the indoor water by circulating the hot water heated by the heat exchanger for heating to the indoor heater and the floor heating panel, the set temperature and the A heating capacity determining means for comparing the detected room temperature detected by the room temperature detecting means to determine a heating capacity including stopping of the convection fan, and the heating capacity determining means A target hot water determining means for determining a target hot water temperature to be heated by the heating heat exchanger in accordance with the capacity of the chamber; a target hot water temperature determined by the target hot water temperature determining means; and the heating temperature sensor Technical means includes a heating control means for controlling the heating amount of the heating means based on the detected hot water temperature.
[0010]
According to a second aspect of the present invention, as the technical means according to the first aspect, the upper room temperature sensor is a suction position thermistor provided inside a suction port for indoor air formed in an upper portion of the indoor unit.
According to a third aspect of the present invention, the technical point is that the lower room temperature sensor is a blowing position thermistor provided inside a warm air blowing port formed in a lower part of the indoor unit.
[0011]
With the above configuration, in claims 1 to 3 of the present invention, when the pump is operated and the heating means heats the heating heat exchanger, the hot water heated by the heating heat exchanger is heated in the room heating circuit in the hot water circulation circuit. Heat is supplied to the heat exchanger for floor heating and the floor heating panel, and the indoor air that is circulated by the operation of the convection fan is heated and blown out by the indoor heater, and the nearby air is radiated from the floor heating panel on the floor surface. Heated by.
The temperature of the hot water supplied to the floor heating panel and the indoor heater is the target hot water temperature corresponding to the heating capacity determined according to the temperature difference between the detected room temperature detected by the room temperature detecting means and the temperature set by the room temperature setter. As described above, the heating amount of the heating unit is controlled by the heating control unit, so that the control is performed based on the temperature detected by the heating temperature sensor.
[0012]
Here, when the heating capacity determination means operates the convection fan, the room temperature detection means is formed on the upper room temperature sensor above the heating heat exchanger, for example, the upper part of the indoor unit as in claim 2. If the detection temperature of the suction position thermistor provided inside the indoor air suction port is detected as the detection room temperature and the convection fan does not operate, the lower room temperature sensor below the heating heat exchanger, for example, As shown in FIG. 3, the detected temperature of the blowing position thermistor provided inside the warm air blowing port formed in the lower part of the indoor unit is detected as the detected room temperature.
Therefore, when the convection fan is activated and the room air is blown from the upper side to the lower side of the indoor heater, the temperature of the indoor air that circulates in the room and moves to the upper side of the indoor heater is detected. Therefore, if the convection fan stops and there is no room air movement, the upper room temperature sensor above the heating heat exchanger can be used for the heating heat exchanger. The ambient air is heated by the supplied hot water and the room temperature cannot be detected accurately. In this case, the room temperature is set by the lower room temperature sensor below the heat exchanger for heating in the indoor heater. Since it can be detected, the room temperature can be accurately detected.
[0013]
As a result, when the convection fan is stopped, it is not necessary to operate the convection fan in order to accurately detect the room temperature, and the room temperature is not increased due to unnecessary operation of the convection fan. Therefore, excessive heating can be prevented, comfort is not impaired, and the convection fan is not operated for room temperature detection, so that unnecessary heating operation can be prevented and labor saving is achieved. Can be planned.
[0014]
In Claim 4, in Claims 1 to 3, the heating capacity determination means stops the operation of the convection fan when a temperature difference of the detected room temperature with respect to the set temperature continues for a predetermined time or more. This is a technical means.
Thus, in claim 4, when the detected room temperature detected by the room temperature detecting means is higher than the set temperature of the room temperature setter by a predetermined temperature difference for a predetermined time, the operation of the convection fan is stopped and the room heating is performed. Heating by the machine is stopped. For this reason, even if the room temperature is temporarily higher than the set temperature, the convection fan does not stop and the detected temperature of the upper room temperature sensor is continuously detected as the detected room temperature.
[0015]
As a result, from the state where the convection fan is stopped and the room temperature is detected by the lower room temperature sensor, the sensor for detecting the room temperature by the room temperature detection means is switched from the lower room temperature sensor to the upper room temperature sensor as the convection fan is operated. In such a case, even if a high temperature is temporarily detected by the upper room temperature sensor due to the heat of hot water in the heating heat exchanger, the operation of the convection fan will not be continued and the operation of the convection fan will not stop. By continuing the operation of the convection fan, the room air is sufficiently convected, and the room temperature can be correctly detected by the upper room temperature sensor.
Therefore, a stable heating operation can be continued without causing an erroneous stop operation of the convection fan due to erroneous room temperature detection.
[0016]
A fifth aspect of the present invention is the technical means according to any one of the first to fourth aspects, wherein the heating capacity determining means continues the operation of the convection fan for a certain period of time.
Thus, in claim 5, when the detected room temperature of the upper room temperature sensor becomes higher than the set temperature during the operation of the convection fan and the operation of the convection fan is stopped, the operation is temporarily stopped. Then, the stop state continues for a certain time.
As a result, when the sensor for detecting the room temperature is switched from the upper room temperature sensor to the lower room temperature sensor when the operation of the convection fan is stopped, the lower room temperature sensor, for example, opens and closes windows and doors. Even if the temperature below the set temperature that fluctuates with it is temporarily detected, the convection fan does not immediately re-activate, so that overheating due to the operation of the convection fan can be prevented.
[0017]
In claim 6, in claim 1 to 5, the heating capacity determination means continuously operates with the same heating capacity for a period corresponding to a temperature difference between the set temperature and the detected room temperature. And
Thus, in claim 6, the heating capacity determined by the heating capacity determination means continues for a period corresponding to the temperature difference between the set temperature and the detected room temperature. Therefore, when the sensor for detecting the room temperature is switched from the lower room temperature sensor to the upper room temperature sensor when the convection fan is stopped and restarted, the air whose temperature has decreased in the room convects the room. Even if it is temporarily detected by the upper room temperature sensor, since the same heating capacity is continued, it is possible to prevent problems such as a decrease in the heating capacity due to erroneous room temperature detection.
[0018]
In Claim 7, in Claims 1 to 6, the target hot water temperature determining means includes an outside air temperature sensor for detecting an outside air temperature, and the convection fan is stopped by the heating capacity determining means. The technical means is to determine the target hot water temperature based on the outside air temperature detected by the outside air temperature sensor.
As a result, if the heating of the indoor heater is simply stopped with the same heating capacity, the amount of heat supplied to the room is greatly reduced because heating is performed only by the floor heating panel while the convection fan is stopped. However, in claim 7, since the target hot water temperature supplied to the floor heating panel is determined based on the outside air temperature while the convection fan is stopped, for example, the outside air temperature is low and the heating load is low. If it is large, the hot water heated to a higher hot water temperature is supplied to the floor heating panel to moderate the degree of room temperature decrease while the convection fan is stopped. When the temperature is small, by supplying a lower hot water temperature to the floor heating panel, excessive heating can be prevented and a decrease in the room temperature can be suppressed.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
Next, this invention is demonstrated based on the Example shown below.
FIG. 1 shows an embodiment of a hot water heating type air conditioner system according to the combined hot water heating system of the present invention.
In FIG. 1, 1 is an outdoor unit that has a heating source and a cooling source and is installed outdoors, 2 is an indoor unit that is disposed on the upper wall of the room, and 3 is an indoor floor that has a hot water pipe for heat dissipation. The indoor unit 2 is connected to the outdoor unit 1 by a hot water pipe and a cooling pipe, and the floor heating panel 3 is connected to the outdoor unit 1 by a hot water pipe. A hot water circuit 10 and a refrigeration cycle 20 are formed by the outdoor unit 1, the indoor unit 2, the floor heating panel 3, and hot water pipes and cooling pipes connecting them.
[0020]
The outdoor unit 1 is provided with a circulating pump 11 driven by constant rotation, a heat exchanger 12 for heating, and a pressure tank 13 as a configuration of the hot water circuit 10, and the heat exchanger 12 for heating has a gas burner as a heating source. 100 is provided.
In addition, a floor warming valve 14 is provided in the hot water piping toward the floor heating panel 3.
On the other hand, the refrigeration cycle 20 includes a compressor 21, a condenser 22, a strainer 23, and a capillary tube 24 that are driven by an inverter-controlled motor to compress refrigerant gas as a refrigerant. A heat dissipating fan 25 is provided.
[0021]
The indoor unit 2 is provided with a heating heat exchanger 15 as a configuration of the hot water circuit 10, and is provided with a cooling heat exchanger 26 as a configuration of the refrigeration cycle 20. A convection fan 200 that circulates air is provided. By the operation of the convection fan 200, indoor air is sucked from an indoor air inlet formed above the indoor unit 2, and the cooling heat exchanger 26 → heating heat The air that is passed through the exchanger 15 → the convection fan 200 in this order and heat-exchanged by the heat exchangers 15 and 26 is sent out indoors from an air outlet formed below the indoor unit 2.
Note that a louver (not shown) for changing the air blowing direction is provided in the air blowing port, and the air exchanged in the heating operation and the cooling operation is blown out in an appropriate direction.
[0022]
In the outdoor unit 1, the indoor unit 2, and the floor heating panel 3, the hot water circuit 10 has an inflow side of the heating heat exchanger 12 connected to the discharge side of the circulation pump 11, and a hot water pipe on the outflow side of the heating heat exchanger 12. Is branched into two, and one side is connected to the inflow side of the heating heat exchanger 15 of the indoor unit 2. The other branched hot water pipe is connected to the inflow side of the floor heating panel 3 via the floor warming valve 14.
The hot water piping on the outflow side of the heat exchanger 15 for heating and the hot water piping on the outflow side of the floor heating panel 3 merge and are connected to the suction side of the circulation pump 11 via the pressure tank 13.
[0023]
In the hot water circuit 10 having the above-described configuration, the circulation pump 11 is operated to operate in the circulation circuit of the circulation pump 11 → the heat exchanger 12 for heating → the heat exchanger 15 for heating → the pressure tank 13 → the circulation pump 11 or the circulation pump. 11 → Heat heat exchanger 12 → Floor warming valve 14 → Floor heating panel 3 → Pressure tank 13 → Circulating pump 11 circulates hot water heated by the gas burner 100.
[0024]
On the other hand, in the refrigeration cycle 20, the refrigerant circulates through the refrigerant compressor 21 → the condenser 22 → the strainer 23 → the capillary tube 24 → the cooling heat exchanger 26 → the refrigerant compressor 21. In the gas phase → liquid phase, the heat is released and the cooling heat exchanger 26 cools the room air by absorbing the heat in the liquid phase (mist) → gas phase. To do.
[0025]
A gas burner 100 as a heating source of the outdoor unit 1 supplies combustion air by a combustion fan 101. A fuel supply path 102 for supplying fuel gas to the gas burner 100 has two gas electromagnetic valves 103 and 104 and a gas. A proportional valve 105 is provided, and an ignition electrode 106 and a frame rod 107 are provided in the vicinity of the flame opening of the gas burner 100.
[0026]
The control device 400 controls various operations by the microcomputer in accordance with the remote controller 4 operated by the user. The control device 400 is provided separately for the outdoor unit 1 and the indoor unit 2 and transmits various signals to each other. To do.
[0027]
In order to perform various controls, the control device 400 includes a high-temperature water thermistor 401 that detects the temperature of hot water on the outflow side of the hot water 12 of the heating heat exchanger 12 of the outdoor unit 1, and the heating heat exchanger 15 of the indoor unit 2. An indoor hot water thermistor 402 for detecting the hot water temperature on the outflow side of the hot water, a suction position thermistor 403 for detecting the indoor temperature inside the indoor air intake port above the indoor unit 2, and the outdoor outdoor temperature at which the outdoor unit 1 is installed The outside air temperature thermistor 404 for detecting the air temperature, and the air outlet position thermistor 405 for detecting the indoor temperature inside the lower air air outlet in the indoor unit 2 are provided.
[0028]
The hot water heating type air conditioner system having the above-described configuration is controlled by the control device 400 as a heating operation, with the floor alone operation using only the floor heating panel 3, the duet heating operation using the floor heating panel 3 and the indoor unit 2, and the refrigeration cycle. With the operation 20, the dry operation only by the indoor unit 2, the duet dry operation by the floor heating panel 3 and the indoor unit 2, and the cooling operation by the indoor unit 2 are respectively controlled. In the cooling operation and each dry operation, the rotation speed of the compressor 21 is controlled as inverter control for driving the compressor 21.
Below, the floor independent operation and duet heating operation as heating operation are demonstrated.
[0029]
(Floor operation alone)
In the floor independent operation, the heating operation is performed only by the floor heating panel 3.
In the floor independent operation, the circulation pump 11 is driven at a constant rotation, and the combustion fan 101 and the gas proportional valve 105 are controlled to adjust the combustion amount of the gas burner 100 so that the determined hot water temperature TO is reached.
[0030]
In the floor independent operation, at the start of operation, the floor heating hot dash operation is performed for a certain period of time according to the on operation of the floor heating operation of the remote controller 4.
After the floor heating hot dash operation, the hot water heated by the heating heat exchanger 12 according to the floor heating level Hn set in seven stages by the remote controller 4 and the outside air temperature Ta detected by the outside air temperature thermistor 404. Determine the target hot water temperature TO.
[0031]
Each floor heating level set by the remote controller 4 is the highest so that the floor surface temperature is 26 ° C. at the first speed with the lowest heating capacity, and the floor surface temperature is 31 ° C. at the intermediate fourth speed. In the seventh speed, the floor surface temperature is set to 36 ° C., and at each floor heating level, the lower the outside air temperature Ta, the higher the temperature, and the lower the target hot water temperature TO is determined according to the outside air temperature Ta. To do.
Table 1 shows a part of the target hot water temperature TO determined in the floor single operation.
[0032]
[Table 1]

[0033]
Note that the hot water heated by the heating heat exchanger 12 also circulates in the heating heat exchanger 15 of the indoor unit 2 during the floor single operation, but the operation of the convection fan 200 is stopped in the floor single operation. Since the heat of the hot water passing through the inside of the heating heat exchanger 15 is difficult to be released into the room, the heating effect by the heating heat exchanger 15 is hardly obtained.
In the floor heating hot dash operation, the target hot water temperature TO corresponding to each floor heating level Hn (for example, 65 ° C. to 65 ° C.) is used instead of the target hot water temperature TO in Table 1 according to the outside air temperature Ta and the floor heating level Hn. 85 ° C.) and the heating amount of the gas burner 100 is controlled based on the detected temperature of the high temperature water thermistor 401.
[0034]
[Duet heating operation (combined heating operation)]
In the duet heating operation, the indoor unit 2 and the floor heating panel 3 are used to heat the room, but the indoor unit 2 mainly increases the temperature of the room. It will act as an aid. Therefore, the floor heating level Hn set by the remote controller 4 used for control in the above-described floor single operation is not used in the duet heating operation and is irrelevant to the control of the heating capacity.
Hereinafter, the duet heating operation will be described based on the functional configuration of the control device 400 related to the duet heating operation shown in FIG.
[0035]
Also in the duet heating operation, the combustion fan 101 and the gas proportional valve 105 are driven so that the temperature of the hot water heated by the heating heat exchanger 12 is driven to the determined target hot water temperature TO by driving the circulation pump 11 at a constant rotation. Is controlled to adjust the amount of combustion of the gas burner 100. In addition, the driving and stopping of the convection fan 200 of the indoor unit 2 are controlled, and at the time of driving, the room air is passed through the heating heat exchanger 15 to heat and blow out the room as warm air.
[0036]
In the capacity control of the duet heating operation, eight stages of capacity from 1st speed (minimum heating capacity) to 8th speed (maximum heating capacity) are provided as the heating capacity, and the set temperature Tset set by the remote controller 4 is in operation. The temperature control is performed based on the temperature difference from the detected room temperature Tr detected at, and the heating capacity is sequentially changed step by step.
[0037]
In the temperature control, the detected room temperature Tr is compared with the set temperature Tset while operating at a certain speed. If the temperature difference is within the same temperature difference range after the lapse of the cycle time according to the temperature difference, the speed N is determined to be increased or decreased, and the current speed is determined according to the determination. A new speed N is determined by raising and lowering N, and thereafter, similarly, the detected room temperature Tr is compared with the set temperature Tset in a cycle corresponding to the temperature difference, and the speed is changed as necessary. .
[0038]
For this determination, in the temperature control of the present embodiment, the temperature range in which the detected room temperature Tr is considered to be equal to the set temperature Tset is a range from the state in which the detected room temperature Tr is equal to the set temperature Tset to 1 ° C. A low state is set. That is,
Temperature difference ΔT = Detected room temperature Tr−Set temperature Tset
When the temperature difference ΔT obtained in step -1 ≦ ΔT ≦ 0 ° C., it is determined that the detected room temperature Tr is equal to the set temperature Tset. When the temperature difference ΔT is ΔT <−1 ° C., the detected room temperature Tr is lower than the set temperature Tset, and when 1 ° C. <ΔT, it is determined that the detected room temperature Tr is higher than the set temperature Tset.
[0039]
In making the above temperature difference determination, normally, the convection fan 200 is operated, and the indoor air is sucked from the indoor air suction port provided above the indoor unit 2, so the temperature detected by the suction position thermistor 403 is set. By processing as the detected room temperature Tr, the temperature difference between the set temperature Tset and the detected room temperature Tr can be accurately determined. For example, when the operation of the convection fan 200 is stopped by temperature control. Since the indoor air flow does not occur in the indoor unit 2, the heat of the hot water flowing in the heating heat exchanger 15 stagnates in the indoor unit 2, and the upper suction position thermistor 403 in the indoor unit 2 has this high temperature. As a result, the room temperature cannot be detected correctly.
[0040]
Therefore, in this embodiment, a room temperature detector 410 is provided as a configuration for correctly detecting the room temperature, and when the convection fan 200 is operating as shown in FIG. 3 (YES in step 10), When the detected temperature of the suction position thermistor 403 is detected as the room temperature (step 20) and the convection fan 200 is not operating (NO in step 10), the detection of the blowing position thermistor 405 provided on the air outlet side is performed. The temperature is detected as the room temperature (step 30). As a result, the accurate indoor temperature can always be detected regardless of whether or not the convection fan 200 is activated.
[0041]
In addition, by providing two thermistors in different places and switching the thermistor that detects the room temperature according to the operating state, for example, the room temperature is detected only on the suction position side as in the conventional case. When the thermistor is provided, the room temperature detection thermistor is required to accurately detect the room temperature when the operation of the convection fan 200 is stopped and heating by the indoor unit 2 is unnecessary. However, since the convection fan 200 had to be operated without fail, it resulted in excessive heating. However, when the room temperature is detected by switching two thermistors as in the present embodiment. Since the indoor temperature can be accurately detected even when the convection fan 200 is stopped, the convection fan 2 can be used when heating by the indoor unit 2 is unnecessary. 0 it is not necessary to operate the can prevent over heating.
[0042]
Next, the operation of the heating capacity determination unit 420 that performs the temperature control based on the temperature difference determination will be described in detail with reference to FIG.
First, the detected room temperature Tr selected by the room temperature detecting unit 410 is compared with the set temperature Tset, and when the temperature difference ΔT is −1 ≦ ΔT ≦ 0 ° C. (in step 100 (1) [−1 to 0 ° C. ]), It is determined that the detected room temperature Tr is equal to the set temperature Tset, and the comparison between the detected room temperature Tr and the set temperature Tset is repeated without changing the speed N to maintain the current state (step 100).
[0043]
The detected room temperature Tr is compared with the set temperature Tset, and when the detected room temperature Tr is lower by 1 ° C. or more than the set temperature Tset and the temperature difference ΔT is ΔT <−1 ° C. (in step 100 (2) [−1 ℃ or less]), and waits for 7 minutes at the speed N at that time (step 110). If the detected room temperature Tr is lower than the set temperature Tset by 1 ° C or more even after 7 minutes have passed (step 111) YES), the speed N is increased by 1 (step 112), and the heating capacity is increased.
[0044]
When the detected room temperature Tr is compared with the set temperature Tset, conversely, when the detected room temperature Tr is higher than the set temperature Tset in the range up to + 1 ° C. and the temperature difference ΔT is ΔT ≦ 1 ° C. (in step 100) (3) [within + 1 ° C.]), wait for 5 minutes at the speed N at that time (step 120), and even when 5 minutes have elapsed, the detected room temperature Tr is still within the range of 1 ° C. with respect to the set temperature Tset. If it is high (YES in step 121), the speed N is decreased by 1 (step 122) to reduce the heating capacity.
[0045]
When the detected room temperature Tr is compared with the set temperature Tset, if the detected room temperature Tr is higher than the set temperature Tset by 1 ° C. or more and the temperature difference ΔT is 1 ° C. <ΔT (4 in the step 100 [+1 More than [° C.]), the system waits for 3 minutes at the speed N at that time (step 130), and when the detected room temperature Tr is still 1 ° C. higher than the set temperature Tset even after 3 minutes have passed (step 131). In step 132, the operation of the convection fan 200 is stopped for 3 minutes.
[0046]
At this time, warm water circulates also in the heating heat exchanger 15 of the indoor unit 2, but the heating heat exchanger 15 has a structure in which the heat of the warm water passing through the interior is released into the room by the operation of the convection fan 200. Therefore, the heating effect by the heating heat exchanger 15 is hardly obtained. When the convection fan 200 is stopped, heating by the indoor unit 2 is stopped and heating is performed only by the floor heating panel 3. In this case, the room temperature is not actively heated by a large amount of heat. The hot keep operation is performed so that the amount of heat for preventing the temperature from being significantly reduced is released into the room.
As a result, the ability to warm the room further decreases for 3 minutes during the hot-keeping operation, so that an increase in the room temperature can be suppressed and the room temperature can be lowered.
[0047]
In the hot keep operation, since the operation of the convection fan 200 is stopped, the heating efficiency is lowered, and the circulation of the room air is stopped, so that the suction position thermistor 403 cannot correctly detect the detected room temperature Tr.
For this reason, while the convection fan 200 is stopped by the hot keep operation, the detected temperature of the blowing position thermistor 405 is detected as the detected room temperature Tr by the room temperature detector 410.
Therefore, the room temperature can be detected correctly.
[0048]
When the detected room temperature Tr detected by the blowout position thermistor 405 is still higher than the set temperature Tset when 3 minutes of the operation stop of the convection fan 200 have elapsed, the operation of the convection fan 200 is not resumed and is again kept hot. In operation, the operation of the convection fan 200 is stopped for 3 minutes. Accordingly, during this time, the blowing position thermistor 405 continues to detect the room temperature.
[0049]
When the detected room temperature Tr detected by the blowout position thermistor 405 is lower than the temperature + 1 ° C. of the set temperature Tset when 3 minutes of the operation stop of the convection fan 200 has elapsed, the hot keeping operation is terminated. The convection fan 200 is actuated again and the temperature adjustment operation is performed. At this time, the thermistor for detecting the room temperature is switched from the blowing position thermistor 405 to the suction position thermistor 403 and detects the temperature of the indoor air sucked into the indoor unit 2.
In this case, at the beginning of switching to the suction position thermistor 403, the temperature detected by the suction position thermistor 403 is high during the hot keeping operation by the hot water passing through the heating heat exchanger 15. Since the operation with the same heating capacity is continuously performed, the suction position thermistor 403 is cooled by the indoor air sucked in during the three minutes, and the next temperature difference determination is performed after three minutes have passed. At the time, the correct indoor temperature can be detected.
[0050]
The relationship between the heating capacity (speed N) determined by the heating capacity determination section 420 and the target hot water temperature TO determined by the target hot water determination section 430 corresponding to the heating capacity (speed N). Is shown in Table 2.
[0051]
[Table 2]

[0052]
During the hot keep operation in which the convection fan 200 is stopped in step 132 and the heating of the indoor unit 2 is stopped, the detected room temperature Tr is sufficiently increased with respect to the set temperature Tset. A large amount of heating for the room is unnecessary. Therefore, in the target hot water temperature determination unit 430, during the hot keeping operation, the target hot water temperature TO that is heated by the heating heat exchanger 12 is not the target hot water temperature TO in the first speed, but the outside air temperature thermistor 404. Is determined based on the outside air temperature Ta detected by. In this embodiment, data of the target hot water temperature TO at the time of the hot keep operation set in advance corresponding to the outside air temperature Ta is stored in the memory of the microcomputer, and the outside air temperature Ta detected by the outside air temperature thermistor 404 is stored. When given, the target hot water temperature TO corresponding to the temperature is determined.
Table 3 shows an example of the target hot water temperature TO determined during the hot keep operation.
[0053]
[Table 3]

[0054]
As shown in Table 3, in the case of the hot keep operation, for example, when the outside air temperature Ta is 0 ° C. or lower, the target hot water temperature TO is determined to be 70 ° C., and when it is 20 ° C. or higher, the target hot water temperature is determined. Since warm water with a fixed temperature that is simply fixed is not supplied to the floor heating panel 3, such as when TO is determined to be 40 ° C., a heating capacity suitable for the heating load for each time is obtained.
[0055]
In the control device 400, the combustion control unit 440 includes a high temperature water thermistor 401 so that the temperature of the hot water heated by the heating heat exchanger 12 becomes the target hot water temperature TO determined by the target hot water temperature determination unit 440. Based on the detected temperature, the combustion fan 101 and the gas proportional valve 105 are controlled to adjust the combustion amount of the gas burner 100.
The convection fan 200 is configured so that the temperature of the hot air blown out from the indoor unit 2 is optimized when the hot water having the target hot water temperature TO determined as described above is supplied to the heating heat exchanger 15. The number of revolutions is controlled appropriately for each speed N. In addition, after the operation is finished, the control device 400 stops the heating operation smoothly using residual heat by stopping the operation of the circulation pump 11 after 2 minutes have elapsed after the combustion of the gas burner 100 is stopped.
[0056]
Hereinafter, the operation in the duet heating operation will be described.
When the start of the duet heating operation is instructed by the remote controller 4, the hot water pipe to the floor heating panel 3 of the hot water circuit 10 is used for 30 minutes after the start of the duet heating operation in order to quickly increase the room temperature. The floor warming valve 14 provided is closed, the circulation pump 11 is driven, the combustion of the gas burner 100 is started, and the temperature of the hot water heated by the heating heat exchanger 12 is set to 75 corresponding to the eighth speed. Adjust to ℃.
[0057]
As a result, high-temperature hot water corresponding to the eighth speed is supplied to the indoor unit 2 and the floor heating panel 3 to quickly increase the indoor temperature.
In order to prevent the blowing of cold air until the temperature detected by the indoor hot water thermistor 402 becomes sufficiently high (for example, 30 ° C.) even after the predetermined ignition control of the gas burner 100 is started and the circulation pump 11 is started. The driving of the convection fan 200 is not started, and after the temperature has risen sufficiently, the convection fan 200 starts to blow air.
[0058]
In subsequent temperature control, heating is performed by the heat exchanger 12 for heating in accordance with the speed N as the heating capacity determined based on the temperature difference between the set temperature Tset by the remote controller 4 and the detected room temperature Tr detected by the suction position thermistor 403. Then, the target hot water temperature TO flowing out of the hot water is determined.
Since the floor warming valve 14 is closed for 30 minutes after the start of the duet heating operation, the warm water in the warm water circuit 10 is supplied only to the heating heat exchanger 15 of the indoor unit 2 and is a convection fan. The warm air is blown into the room by the operation of 200.
[0059]
When 30 minutes have passed since the start of the duet heating operation, the closed floor warming valve 14 is opened, and the heated hot water is also supplied to the floor heating panel 3. The room is heated by the panel 3, and the temperature control operation is continued thereafter.
When the detected room temperature Tr detected by the suction position thermistor 403 becomes higher than the set temperature Tset set by the remote controller 4 by 30 minutes after the start of the duet heating operation, the above-described hot keep operation is started. In the case of shifting to this hot keeping operation, the floor warming valve 14 is opened even if 30 minutes have not elapsed since the start of operation.
[0060]
In the temperature control, while the temperature difference between the detected room temperature Tr detected by the suction position thermistor 403 and the set temperature Tset set by the remote controller 4 is within + 1 ° C., the convection fan 200 of the indoor unit 2 operates, Duet heating operation by the floor heating panel 3 and the indoor unit 2 is continued.
During temperature control, if the detected room temperature Tr detected by the suction position thermistor 403 becomes + 1 ° C. higher than the set temperature Tset set by the remote controller 4 and continues for 3 minutes, the heating operation by the indoor unit 2 is stopped. Then, the hot keep operation for heating only by the floor heating panel 3 is started.
[0061]
In the case of the hot keep operation, the target hot water temperature TO heated by the heating heat exchanger 12 of the hot water circuit 10 is set based on the outside air temperature Ta detected by the outside air temperature thermistor 404 in Table 3 above. Decide as follows.
Further, while the convection fan 200 is stopped by the hot-keeping operation for 3 minutes, the thermistor for detecting the room temperature is not the suction position thermistor 403 provided above the indoor unit 2 but the indoor unit. 2 is selected as the blowing position thermistor 405 provided at the lower position.
The room temperature is still detected by the blowout position thermistor 405 when the operation stop of the convection fan 200 for 3 minutes is completed, and the detected room temperature Tr is still set to the set temperature Tset when 3 minutes of the hot keep operation is completed. When the temperature is higher than + 1 ° C., the hot keeping operation is performed again, and the convection fan 200 is stopped again for 3 minutes as described above, and the indoor temperature is continuously detected by the blowing position thermistor 405.
[0066]
Conversely, when the temperature difference with respect to the set temperature Tset of the detected room temperature Tr detected by the blowing position thermistor 405 is within + 1 ° C. at the time when the hot-keeping operation is completed for 3 minutes, the hot-keeping operation is terminated and the convection The fan 200 is activated again, and at this time, the thermistor for detecting the room temperature is switched to the suction position thermistor 403.
[0067]
As described above, according to the present invention, in the duet heating operation, while the operation of the convection fan 200 is stopped, as the thermistor for detecting the indoor temperature, the blowout position thermistor disposed below the indoor unit 2 405 is used, hot water is supplied to the heating heat exchanger 15 in the indoor unit 2 while the operation of the convection fan 200 is stopped, and the suction position thermistor 403 above it cannot detect the room temperature correctly. In addition, the room temperature can be detected correctly.
Therefore, since it is not necessary to operate the convection fan 200 for detecting the indoor temperature, excessive heating by the indoor unit 2 is not performed, comfort is not impaired, and unnecessary heating is performed. Therefore, labor saving can be achieved.
[0068]
In the said Example, although the floor warming valve 14 of the warm water circuit 10 which supplies warm water to the floor heating panel 3 is closed for 30 minutes at the beginning of the start of a duet heating operation, the floor warming valve 14 is shown. The valve closing time is not limited to the above embodiment, and the floor warming valve 14 may be in a half-open state or an open state.
In the above-described embodiment, the hot-keeping operation in which heating is performed only by the floor heating panel 3 during the temperature control operation of the duet heating operation is shown. However, the indoor temperature is lower than the set temperature without performing the hot-keeping operation. Both the operation of the indoor unit 2 and the floor heating panel 3 may be stopped.
In the above embodiment, the gas burner is used as the heating source, but a hot water heating system using another heating source such as an oil burner or electric heating may be used.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of a hot water heating type air conditioner system showing an embodiment of the present invention.
FIG. 2 is a functional block diagram for explaining a functional configuration related to a duet heating operation in a control device showing an embodiment of the present invention.
FIG. 3 is a flowchart for explaining the switching operation of the thermistor for detecting the room temperature in the embodiment of the present invention.
FIG. 4 is a flowchart for explaining temperature control of duet heating operation in the embodiment of the present invention.
[Explanation of symbols]
2 Indoor unit (indoor heater)
3 Floor heating panel
4 Remote control (room temperature setting device)
10 Hot water circuit (hot water circulation circuit)
11 Circulation pump
12 Heat exchanger for heating
15 Heat exchanger for heating
100 Gas burner (heating means)
200 Convection fan
400 control device (temperature control device for combined hot water heating system)
401 High temperature water thermistor (heating temperature sensor)
403 Suction position thermistor (upper room temperature sensor)
404 Outside temperature thermistor (outside temperature sensor)
405 Outlet position thermistor (lower room temperature sensor)
410 Room temperature detector (room temperature detector)
420 Heating capacity determination unit (heating capacity determination means)
430 Target hot water temperature determining unit (target hot water temperature determining means)
440 Combustion control unit (heating control means)

Claims (7)

A floor heating panel that heats the interior by heat radiation from the heat radiation pipe, using hot water that passes through the heat radiation pipe as a heat source,
Warm water is passed through a heating heat exchanger having a convection fan that circulates room air, and the room air is passed downward from above the heating heat exchanger by the operation of the convection fan to heat the room heat. An indoor heater that blows out indoors;
A heating heat exchanger for heating water passing through the inside by heating of the heating means, the floor heating panel and the indoor heater are provided in parallel to the heating heat exchanger, In a combined hot water heating system that forms a hot water circulation circuit for circulating hot water heated by a heat exchanger to the floor heating panel and the indoor heater by a pump,
A heating temperature sensor for detecting the temperature of hot water heated by the heating heat exchanger;
A room temperature setter for setting the target room temperature in the room;
An upper room temperature sensor for detecting an indoor temperature above the heating heat exchanger;
A lower room temperature sensor for detecting an indoor temperature below the heating heat exchanger;
Room temperature detection means for selecting the detection temperature of the upper room temperature sensor as room temperature when the convection fan is operating, and detecting the room temperature by selecting the detection temperature of the lower room temperature sensor as room temperature when the convection fan is stopped,
At the time of combined heating operation in which warm water heated by the heat exchanger for heating is circulated to the indoor heater and the floor heating panel to perform indoor heating, the set temperature and the detected room temperature detected by the room temperature detecting means Heating capacity determination means for determining the heating capacity including stopping the convection fan,
Target hot water determining means for determining a target hot water temperature of hot water heated by the heating heat exchanger according to the heating capacity determined by the heating capacity determining means;
A combined hot water comprising heating control means for controlling the heating amount of the heating means based on the target hot water temperature determined by the target hot water temperature determining means and the detected hot water temperature of the heating temperature sensor. Temperature control device for heating system. 2. The temperature control apparatus for a combined hot water heating system according to claim 1, wherein the upper room temperature sensor is a suction position thermistor provided inside an indoor air suction port formed in an upper portion of the indoor unit. . The temperature control of the combined hot water heating system according to claim 1 or 2, wherein the lower room temperature sensor is a blowing position thermistor provided inside a hot air blowing port formed in a lower part of the indoor unit. apparatus. The said heating capability determination means stops the driving | operation of the said convection fan, when the temperature difference of the said detection room temperature with respect to the said setting temperature continues more than predetermined temperature difference for a predetermined period of time. The temperature control apparatus of the composite hot water heating system in any one. 5. The temperature control device for a combined hot water heating system according to claim 4, wherein the heating capacity determination means continues the operation of the convection fan for a predetermined time. 6. The composite according to claim 1, wherein the heating capacity determining means continuously operates with the same heating capacity for a period corresponding to a temperature difference between the set temperature and the detected room temperature. Temperature control device for hot water heating system. The target hot water temperature determining means includes
It has an outside temperature sensor that detects the outside temperature,
The target hot water temperature is determined based on the outside air temperature detected by the outside air temperature sensor while the convection fan is stopped by the heating capacity determining means. The temperature control apparatus of the composite hot water heating system described in 1.

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