JP3851859B2 - Fire phase management device and fire phase management method - Google Patents

Description

【００２２】
（（１）式）において、熱伝達率ｈ_ｋは、天井材の熱の伝わりやすさを示すパラメータであり、（（２）式）で表すことができる。
【００２３】
【数２】

【００２４】
さらに、（（１）式）に（（２）式）を用いた上で、（（１）式）を出火後の経過時間ｔについて解くと（（３）式）で表すことができる。
【００２５】
【数３】

【００２６】
ここで、所要時間Δｔ_ｆを測定したい温度区間について、その下限値及び上限値をトリガー温度Ｔ_ｓ１、Ｔ_ｓ２ として設定し、天井面近傍の煙層温度がトリガー温度Ｔ_ｓ１、Ｔ_ｓ２ に達する時間をｔ_１、ｔ_２ と設定すると、（（３）式）より温度区間を上昇通過する際に要する所要時間Δｔは、（（４）式）で表すことができる。
【００２７】
【数４】

【００２８】
つまり、（（４）式）に示す所要時間Δｔ_ｆ が、トリガー温度Ｔ_ｓ１、Ｔ_ｓ２ を下限値及び上限値とする温度区間について、上昇通過する際に要する基準時間となるフェイズ進展基準時間Ｔ_ｆ の算定式となる。ここで、（（４）式）は、感知器２が設けられている部屋の諸元情報として、室の用途、床面積Ａ_Ｔ、及び天井材の材料の熱貫性（ｋρｃ）^１／２とともに、部屋の開口面積Ａや開口高さＨがパラメータとして用いられている。しかし、火災の進展状況の段階的なモニタリングは、火災の初期段階を対象とすることから、部屋の窓や扉等、開口部の開閉条件の影響は少ないと考えられるため、本実施の形態では、部屋の開口部として一般的な扉を１カ所配置された状況を想定し、これが開放されているものとして条件設定できる。
【００２９】
これにより、（（４）式）を火災成長率（α）について解くと（（５）式）で表すことができる。
【００３０】
【数５】

【００３１】
つまり、火災成長率αは、火災が発生している部屋について、その床面積Ａ_Ｔと天井材の材料の熱貫性（ｋρｃ）^１／２を把握していれば、トリガー温度Ｔ_ｓ１、Ｔ_ｓ２ に達する時間ｔ_１、ｔ_２ をもとに算出できることがわかる。
したがって、感知器２が設けられている部屋について、部屋の用途に応じた標準的な火災成長率αと、天井の材料に応じた熱貫性（ｋρｃ）^１／２をあらかじめ与えておき、熱貫性（ｋρｃ）^１／２とトリガー温度Ｔ_ｓ１、Ｔ_ｓ２ とを用いて、（（４）式）を用いてフェイズ進展基準時間Ｔ_ｆが算定されることとなる。
【００３２】
ところで、図１に示すように、前記記憶装置６のデータ領域６ａには少なくとも、諸元情報データベース７、室用途別火災成長率データベース８、天井材等による材料別熱貫性データベース９、及びフェイズ進展基準時間データベース１０が格納されている。
これらは、中央処理装置３における処理速度の迅速化、及びシステム構成の簡略化を考慮して構築されたもので、天井の材料に応じた熱貫性（ｋρｃ）^１／２を材質別熱貫性データベース９、部屋の用途毎で、部屋の床面積Ａ_Ｔに応じた火災成長率αを室用途別火災成長率データベース８として構築している。また、諸元情報データベース７は、フェイズ進展基準時間Ｔ_ｆ を算定する上で必要となる、室の用途、室の床面積、天井材の材質の少なくとも３つの諸元情報７ａを、その部屋に設置されている感知器２のアドレス及び室名と併せてデータベース化したものである。
【００３３】
したがって、感知器２各々について、諸元情報データベース７から感知器２が設置されている部屋の諸元情報７ａを取り出し、これを用いて材質別熱貫性データベース９、室用途別火災成長率データベース８に照合させることにより、感知器２が設置された部屋に最適な熱貫性（ｋρｃ）^１／２及び火災成長率αを決定した上で、感知器２毎のフェイズ進展基準時間Ｔ_ｆを算定でき、この算定結果をフェイズ進展基準時間データベース１０として構築できるものである。
なお、室用途別火災成長率データベース８、材質別熱貫性データベース９は、汎用性を持たせて構築することができるものであるが、諸元情報データベース７は、建築物によって個々に異なるものである。このため、諸元情報データベース７については、火災フェイズ管理装置１を設ける建築物に応じて、適宜入力装置１２を介して部屋の諸元情報７ａを前記記憶装置６のデータ領域６ａに格納し、諸元情報データベース７を構築するインターフェイス型とすれば、どのような建築物にも火災フェイズ管理装置１を適用することができ、火災フェイズ管理装置１の汎用性が高まるものである。
【００３４】
上述する構成の火災フェイズ管理装置１の処理の流れを図２に示す。
まず、建築物の管理対象となる各部屋に設けられている感知器２にアドレスを与えた上で、該感知器２が設けられている部屋の諸元情報７ａを中央処理装置３の入力装置１２により入力し、諸元情報データベース７として記憶装置６のデータ領域６ａに格納する。
次に、感知器２毎で、演算装置５を用いて諸元情報データベース７に格納された部屋の諸元情報７ａに対応した火災成長率α、及び熱貫性（ｋρｃ）^１／２を、データ領域６ａにあらかじめ格納されている室用途別火災成長率データベース８、及び材料別熱貫性データベース９より選定する。この火災成長率α、及び熱貫性（ｋρｃ）^１／２とプログラム領域６ｂに格納された演算式（（４）式を参照）を用いてフェイズ進展基準時間Ｔ_ｆを算定し、算定結果をフェイズ進展基準時間データベース１０としてデータ領域６ａに格納する（ステップＳ１）。
【００３５】
火災が発生すると、前記感知器２の煙感知機能が作動して、前記中央処理装置３の受信装置４が、感知器２のアドレス（固定番号）及び時間を付加された火災信号を受信する。これが演算装置５に伝送されてモニタ等の出力装置１１に火災信号を表示するとともに、演算装置５は、受信装置４を介して非常放送設備１３に発報放送の鳴動指令を伝送する（ステップＳ２）。
【００３６】
一方で、徐々に室内の煙層温度が上昇すると、感知器２の熱検知機能が作動して、あらかじめ設定した温度区間を構成するトリガー温度の下限値Ｔ_ｓ１及び上限値Ｔ_ｓ２の両者を検知した後、アドレス（固定番号）及び時間を付加された火災信号及び設定した温度区間を上昇通過した際に要した所要時間Δｔを、中央処理装置３の受信装置４を介して演算装置５に伝送する（ステップＳ３）。
【００３７】
前記演算装置５において、伝送された所要時間Δｔについて、同時に伝送された火災信号から、感知器２のアドレス（固定番号）を照合し、前記データ領域６ａに格納したフェイズ進展基準時間データベース１０を用いて、感知器２のアドレスに対応したフェイズ進展基準時間Ｔ_ｆを選定した上で、所要時間Δｔと最適なフェイズ進展基準時間Ｔ_ｆとを比較する。所要時間Δｔが、フェイズ進展基準時間Ｔ_ｆより短い場合には、前記感知器２の煙感知機能の作動により火災発報信号が表示されているかを確認した上で、演算装置５より受信装置４に火災フェイズ進展警報を伝送し、非常放送設備１３、及び防排煙設備１４を作動させる。
このとき、火災信号に付加された感知器２のアドレスを、諸元情報データベース７と照合することにより、火災信号が伝送された感知器２の位置や室名等が把握できることから、上述の算定結果と併せて、出力装置１１に、建築物のどの箇所でどの程度の火災が成長しているかを表示させてもよい。また、感知器２及び中央処理装置３の作動内容と時刻とを対応させた火災フェイズ管理装置の作動履歴を出力装置１１に、出力させても良い（ステップＳ４）。
【００３８】
先にも述べたように、建築物に対する避難施設や排煙設備などの避難安全対策は、部屋の用途に応じた火災成長率αを設計段階の条件のもとであらかじめ設定しておき、これらの設定値に対応して設計されるものである。したがって、火災が発生した際に天井面付近の煙層温度が所定の温度区間を上昇通過する際に要する基準時間であるフェイズ進展基準時間Ｔ_ｆ と比較して、所要時間Δｔが早い場合には、建築物に施されている避難安全対策の性能が、避難安全性を確保する上で十分ではなくなる状態に達していることを意味する。このように、火災フェイズ進展警報は、建築物個々の避難安全対策の性能を考慮した上で、火災の進展状況に応じてリアルタイムに対策の制御を行うために発報されるものである。
【００３９】
なお、火災フェイズ進展警報は、設定した温度区間を上昇通過する際に要する所要時間Δｔが、フェイズ進展基準時間Ｔ_ｆより短く、加えて感知器２の煙感知機能の作動により火災発報信号が表示されている状況下で発報される構成としている。一般に、非火災報を防止することを目的に、火災報を発する場合には、感知器からの煙層温度情報、もしくは煙濃度情報より火災信号が発せられると、建築物管理者が現場において火災確認を行う、また複数の感知器による火災信号が確認されることが必要条件とされている。
これらを考慮し、火災フェイズ管理装置１では、感知器２が煙感知機能と煙層温度検知機能の両者を保有することを利用し、煙層温度検知機能を利用したフェイズ進展基準時間Ｔ_ｆ と所要時間Δｔとの比較結果に加えて、煙感知機能による火災発報信号の発報の両者を必要条件とすることにより、１つの感知器２１のみで、非火災報の防止手段を講じている。
【００４０】
また、ステップＳ４において、所要時間Δｔが、フェイズ進展基準時間Ｔ_ｆより長い場合には、トリガー温度Ｔ_ｓ１、Ｔ_ｓ２、よりも高温側に新たなトリガー温度Ｔ_ｓ３ を設置し、下限値をＴ_ｓ２、上限値をＴ_ｓ３ として設定される温度区間に対して、ステップＳ３、ステップＳ４の作業を繰り返すものである。なお、温度区間は２区間以上を設定してもよく、温度区間についても必ずしも連続して設定する必要はない。
【００４１】
上述する火災フェイズ管理装置１を用いた火災フェイズ管理方法を図３から図８に示すフローに従い詳述する。
なお、本実施の形態では、建築物には、その監視対象となる複数の部屋各々の天井に、アドレスが与えられた感知器２が取り付けられており、中央処理装置３は建築物の建物管理室に配置されていることを想定している。
【００４２】
（ステップＳ１）
ステップＳ１は、火災フェイズ管理方法の中でも、火災発生前の通常時における火災フェイズ管理装置１の設定方法を示している。図３に示すように、まず、初期段階における火災の進展状況を把握すべく、温度上昇に要する所要時間Δｔ_１、Δｔ_２を計測するための温度区間を設定する。本実施の形態では、連続する２区間を設定することとし、中央処理装置３側で低温側からＴ_ｓ１、Ｔ_ｓ２、Ｔ_ｓ３の３点を設定し、トリガー温度として感知器２に通知しておく。
【００４３】
また、本実施の形態では、図１０に示すように、トリガー温度Ｔ_ｓ１、Ｔ_ｓ２、Ｔ_ｓ３として60℃、73℃、88℃の３点を適用している。これは、60℃が定温式スポット型熱感知器の公称作動温度、73℃がスプリンクラーヘッドの一般的な標示温度、88℃が一般的な事務所等の火災成長率αを考慮した場合に、60℃から73℃まで温度上昇する場合とほぼ同様の所要時間を要する温度、であることを考慮したものである。また、73℃〜88℃は、消火器またはスプリンクラー設備により初期消火可能な火災の段階から、室内に火災が拡大する段階の境界に当たる温度である。
このように、火災の特徴を考慮した温度をトリガー温度として設定をしておくことにより、例えば、２区間目の73℃〜88℃において、所要時間Δｔ_２がフェイズ進展基準時間Ｔ_ｆよりも火災の進展が早い、つまりフェイズ進展警報を発すべき段階に移行した際には、感知器２が設置されている部屋の状態は、消火器等による初期消火は困難な状態であり、この時点での在館者の避難安全性を確保する上で最適な対応行動が、早期の避難誘導や、防火戸等の防排煙設備の閉鎖等、上層階への煙伝搬防止対策である、といった火災の進展状況に対応した最適な対策を容易に判断できるものである。
【００４４】
これらを鑑みると、トリガー温度Ｔ_ｓ１、Ｔ_ｓ２、Ｔ_ｓ３は、火災初期の拡大する段階に当たる60〜100℃の温度区間を対象とし、火災発生の確度、及び熱検知機能の耐熱性能度等を考慮すれば、何れの温度に設定しても良いが、トリガー温度Ｔ_ｓ１、Ｔ_ｓ２、Ｔ_ｓ３として上述する60℃、73℃、88℃近傍の温度を用いることがもっとも好ましい。
なお、温度上昇に要する所要時間Δｔを検知する温度区間は、必ずしも連続する２区間である必要はなく、トリガー温度を１つ増加しても良い。また、区間についても２区間である必要はなく、２区間以上であれば必要に応じて複数区間設定しても良い。また、必ずしもトリガー温度Ｔ_ｓ１からＴ_ｓ２、Ｔ_ｓ２からＴ_ｓ３ の２区間両者で、所要時間Δｔがほぼ同時となるようにトリガー温度を設定する必要はないが、システム構成の簡略化等を鑑みると、２区間の温度区間両者で、所要時間Δｔがほぼ同時となるようなトリガー温度を設定が好ましい。
【００４５】
次に、感知器２毎に対応するフェイズ進展基準時間Ｔ_ｆを算定し、データベースとして構築しておく。フェイズ進展基準時間Ｔ_ｆの算定は中央処理装置３側で行われ、図９に示すように、第１に、感知器２毎のアドレス番号、室名、室用途、床面積、及び天井材の材料の５つの情報からなる諸元情報７ａを格納した諸元情報データベース７を構築する。次に、あらかじめ構築された室用途別火災成長率データベース８、材料別熱貫性データベース９に、諸元情報データベース７を照合して、感知器２毎で、火災成長率α、及び熱貫性（ｋρｃ）^１／２を選定した上で、感知器２毎のフェイズ進展基準時間Ｔ_ｆ を算定し、これをフェイズ進展基準時間データベース１０として構築しておく。
【００４６】
（ステップＳ２）
ステップＳ２以降は、火災発生が想定される状況下での火災フェイズ管理装置を用いた火災フェイズ管理方法を示すものである。
火災が発生すると、室内には徐々に煙層が蓄積されていく。図４に示すように、煙層の煙濃度が規定値を越えて火災信号レベルに到達すると、感知器２の煙感知機能が規定以上の煙濃度を検知し、中央処理装置３に通知する。通知を受けた中央処理装置３は、火災発報信号を表示するとともに、非常放送設備１３に火災発報信号を伝送する。これを受けて非常放送設備１３は、建築物の全館に感知器発報放送を鳴動する。
【００４７】
（ステップＳ３）
火災の進展による室内における煙層の蓄積に伴い、煙層温度が上昇を始める。天井面近傍の煙層温度がトリガー温度Ｔ_ｓ１に達すると、図５に示すように、感知器２の熱検知機能が作動して、感知器２のアドレスを付加した火災信号情報を割り込み信号として中央処理装置３に転送する。
中央処理装置３は割り込み信号を受けて、煙層温度がトリガー温度Ｔ_ｓ２に達するまでの所要時間Δｔ_１のアナログ値を問い合わせる。
感知器２は、トリガー温度Ｔ_ｓ１の検知と同時に時間測定を開始しており、トリガー温度Ｔ_ｓ２を検知した時点で中央処理装置３に、トリガー温度Ｔ_ｓ２の検知を通知する火災信号情報を転送するとともに、所要時間Δｔ_１をアナログ値として通知する。
【００４８】
ところで、火災初期段階では、可燃物間の延焼拡大状況により、煙層温度の変化にある程度のばらつきが生じるため、煙層温度は常に上昇するとは限らず、温度が一端上昇した後に停滞、または下降する場合もあることが考えられる。したがって、感知器２には、あらかじめトリガー温度Ｔ_ｓ１を検知してからトリガー温度Ｔ_ｓ２を検知するまでの所要時間に時限Δｔ_ｌｉｍを持たせるとともに、検知する温度がトリガー温度Ｔ_ｓ１と比較して高温であるかを常に監視させる構成とする。なお、時限Δｔ_ｌｉｍは、感知器２毎の基準時間となるフェイズ進展基準時間Ｔ_ｆを超過する時間を設定しておく。
これにより、トリガー温度Ｔ_ｓ１を検知した直後からトリガー温度Ｔ_ｓ２を検知するまでの間に所要時間Δｔ_１が時限Δｔ_ｌｉｍを超過すると、感知器２は中央処理装置３に煙層温度が停滞していることを通知する。一方で、感知器２は、時限Δｔ_ｌｉｍを超過しても所要時間Δｔ_１の計測を継続する。
また、感知器２は、トリガー温度Ｔ_ｓ１を検知した直後からトリガー温度Ｔ_ｓ２を検知するまでの間に、煙層温度Ｔがトリガー温度Ｔ_ｓ１を下回ったことを確認した場合には、所要時間Δｔ_１の計測を中止する。
【００４９】
（ステップＳ４）
図６に示すように、天井面付近の煙層温度がトリガー温度Ｔ_ｓ２に到達し、中央処理装置３に所要時間Δｔ_１が通知されると、中央処理装置３は既に時限Δｔ_ｌｉｍ超過の通知を受けているかを確認し、通知を受けていない場合には、先に通知された感知器２のアドレスを用いて、所要時間Δｔ_１ を検知した感知器２に対応するフェイズ進展基準時間Ｔ_ｆをフェイズ進展基準時間データベース１０から選定し、これと所要時間Δｔ_１ とを比較して火災の進展状況を把握する。所要時間Δｔ_１ がフェイズ進展基準時間Ｔ_ｆと比較して早い場合には、中央処理装置３の煙管理側が火災発報信号を表示しているかを問い合わせ、表示している場合には、火災フェイズ進展警報を発報し、非常放送設備１３及び防排煙設備１４に対して火災放送、及び防排煙設備全階閉鎖等の火災フェイズ進展警報が発報された温度区間から想定される火災の進展状況に応じた指令を伝送する。
一方で、フェイズ進展基準時間Ｔ_ｆと所要時間Δｔ_１ とを比較し、所要時間Δｔ_１ が遅い場合には、非常放送設備１３や防排煙設備１４等への伝送は行わず、２区目の温度区間に対して火災の進展状況をモニタリングする次のステップＳ３’に進む。
また、中央処理装置３に所要時間Δｔ_１が通知された時点で、既に時限Δｔ_ｌｉｍ超過の通知を受けている場合には、上述するフェイズ進展基準時間Ｔ_ｆとの比較作業を行わず、次のステップＳ３’に進む。
【００５０】
（ステップＳ３’）
トリガー温度Ｔ_ｓ１、Ｔ_ｓ２より構成される温度区間において、所要時間Δｔ_１ がフェイズ進展基準時間Ｔｆ、及びΔｔ_ｌｉｍと比較して遅く、火災の進展状況が設計段階で予測された進展状況より遅い場合について、次にトリガー温度Ｔ_ｓ２、Ｔ_ｓ３より構成される温度区間を用いて再度火災の進展状況をモニタリングする。なお、感知器２は、熱検知機能がトリガー温度Ｔ_ｓ２を検知した時点で、既にトリガー温度Ｔ_ｓ２の検知を通知する火災信号情報を割り込み信号としてを中央処理装置３に転送しており、同時に時間測定ΔＴ_２を開始している。
図７に示すように、火災確定報、もしくは火災フェイズ進展警報を表示していない中央処理装置３は、感知器２に煙層温度がトリガー温度Ｔ_ｓ３に達するまでの所要時間Δｔ_２を問い合わせる。
感知器２は、トリガー温度Ｔ_ｓ３を検知した時点で中央処理装置３に、トリガー温度Ｔ_ｓ３の検知を通知する火災信号情報を転送するとともに、所要時間Δｔ_２をアナログ値として通知する。
【００５１】
このとき、感知器２はステップＳ３と同様に、トリガー温度Ｔ_ｓ２を検知した直後からトリガー温度Ｔ_ｓ３を検知するまでの間に所要時間Δｔ_２が時限Δｔ_ｌｉｍを越えると、感知器２は中央処理装置３に煙層温度が停滞していることを通知する。一方で、感知器２は、時限Δｔ_ｌｉｍを越えても所要時間Δｔ_２の計測を継続する。
また、感知器２は、トリガー温度Ｔ_ｓ２を検知した直後からトリガー温度Ｔ_ｓ３を検知するまでの間に、煙層温度Ｔがトリガー温度Ｔ_ｓ２を下回ったことを確認した場合には、所要時間Δｔ_２の計測を中止する。
【００５２】
（ステップＳ４’）
天井面付近の煙層温度がトリガー温度Ｔ_ｓ３に到達し、中央処理装置３に所要時間Δｔ_２が通知されると、図８に示すように、中央処理装置３は既に時限Δｔ_ｌｉｍ超過の通知を受けているかを確認し、通知を受けていない場合には、先に通知された感知器２のアドレスを用いて、所要時間Δｔ_２ を検知した感知器２に対応するフェイズ進展基準時間Ｔ_ｆをフェイズ進展基準時間データベース１０から選定し、これと所要時間Δｔ_２ とを比較して火災の進展状況を把握する。
【００５３】
所要時間Δｔ_２ がフェイズ進展基準時間Ｔ_ｆと比較して早い場合には、中央処理装置３の煙管理側が火災発報信号を表示しているかを問い合わせ、表示している場合には、火災フェイズ進展警報を発報し、非常放送設備１３及び防排煙設備１４に対して火災放送、及び防排煙設備全階閉鎖等の火災フェイズ進展警報が発報された温度区間から想定される火災の進展状況に応じた指令を伝送する。
一方で、フェイズ進展基準時間Ｔ_ｆと所要時間Δｔ_２ とを比較し、所要時間Δｔ_２ が遅い場合には、中央処理装置３にタイムアウト、及び規定の注意報、もしくは火災報を表示する。
なお、火災の進展状況をモニタリングする温度区間を２区以上設けている場合には、ステップＳ３’及びステップＳ４’の行程を繰り返すことにより、火災の進展状況のモニタリングを継続すればよい。
【００５４】
上述する構成によれば、少なくとも２区間の温度区間において火災の進展状況をモニタリングすることから、火災の進展状況を段階的に把握することができるとともに、火災成長率αの急激な変化をも見逃すことがなく、火災フェイズ管理の信頼性を高めることが可能となる。
さらに、中央処理装置３が火災現場より遠隔地に配置されている場合にも、管理者が火災現場に駆けつけることなく、火災の進展状況に応じた警報を発することが可能となり、迅速でかつ火災の進展状況に最適な防火対策を実施することが可能となる。
【００５５】
中央処理装置３に出力装置１１を備えることから、出力装置１１には、感知器２より中央処理装置３が受信した火災信号、及び中央処理装置３による火災の進展状況のモニタリング結果を基に、建築物のどの箇所でどの程度の火災が成長しているか等のマップ情報を表示、もしくは感知器及び中央処理装置３の作動内容と時刻とを対応させた火災フェイズ管理装置１の作動履歴を表示させることもできるため、建築物の管理者は、火災現場に駆けつけることなく、消防隊の到着時に的確な火災情報をリアルタイムで報告することが可能となる。
また、消防隊は、建築物に駆けつけた段階で、中央処理装置３が設置された場所において出力結果を用いて火災の拡大状況を瞬時に把握することができるため、適切な消火活動の方法をあらかじめ計画することが可能となる。
【００５６】
中央処理装置３が非常放送設備１３、及び防排煙設備１４と連動されていることから、非常放送設備１３、及び防排煙設備１４は、中央処理装置３による火災の進展状況のモニタリングにより発報された火災確定信号や火災フェイズ進展警報等に基づき連動制御されるため、その信頼性が高く、かつ火災の進展状況に応じた非常放送設備１３、及び防排煙設備１４の適切な対策行動を実施することが可能となる。
【００５７】
また、中央処理装置３には、感知器２毎にフェイズ進展基準時間Ｔ_ｆを設定する際に、感知器２毎で異なる設定条件を入力する入力装置１２が設けられることから、何れの部屋に設けられた感知器２に対しても容易にフェイズ進展基準時間Ｔ_ｆを設定することができるとともに、既に感知器２が設置された部屋について、竣工後のリニューアル等により床面積や用途など、条件が変更した際にも、これらを容易に変更することが可能となり、火災フェイズ管理装置１の汎用性を向上させることが可能となる。
【００５８】
感知器２毎に設けられるフェイズ進展基準時間Ｔ_ｆ は、中央処理装置３で管理されるとともに、感知器２が設置されている部屋の用途、面積及び天井の材料の簡略な諸元情報７のみを用いているため、部屋の用途変更やリニューアルが生じた際にも、中央処理装置３において容易にフェイズ進展基準時間Ｔ_ｆ を変更することが可能である。
【００５９】
【発明の効果】
請求項１記載の火災フェイズ管理装置によれば、少なくとも２区間の温度区間において火災の進展状況をモニタリングすることから、火災の進展状況を段階的に把握することができるとともに、火災成長率αの急激な変化をも見逃すことがなく、火災フェイズ管理の信頼性を高めることが可能となる。
【００６０】
請求項２記載の火災フェイズ管理装置によれば、前記中央処理装置に、フェイズ進展基準時間を設定するための設定条件を入力する入力装置が備えられることから、何れの部屋に設けられた感知器に対しても容易にフェイズ進展基準時間を設定することができるとともに、既に感知器が設置された部屋について、竣工後のリニューアル等により床面積や用途など、条件が変更した際にも、これらを容易に変更することが可能となり、火災フェイズ管理装置の汎用性を向上させることが可能となる。
【００６１】
請求項３記載の火災フェイズ管理方法によれば、請求項１または２に記載の火災フェイズ管理装置を用いた火災フェイズ管理方法であって、感知器が所要時間を検知する温度区間を構成する上限温度及び下限温度を設定するとともに、中央処理装置を用いて設定した温度区間の温度上昇に要する基準時間を設定する第１の行程と、前記部屋の天井面近傍の温度が、第１の行程で設定された温度区間を上昇通過する際に要した所要時間を、感知器により検知する第２の行程と、中央処理装置を用いて、第２の行程において検知される所要時間を、第１の行程で設定した基準時間と比較することにより火災の進展状況を把握し、進展状況に応じて警報信号を発する第３の行程とにより構成されることから、中央処理装置が火災現場より遠隔地に配置されている場合にも、管理者が火災現場に駆けつけることなく、火災の進展状況に応じた警報を発することが可能となり、迅速でかつ火災の進展状況に最適な防火対策行動を実施することが可能となる。
【００６２】
請求項４記載の火災フェイズ管理方法によれば、第１の行程において設定した基準時間が、少なくとも前記感知器が設置されている部屋の用途、床面積、及び天井材の材料を設定条件とし、これに基づき設定されることから、部屋の用途変更やリニューアルが生じた際にも、中央処理装置において容易に基準時間を変更することが可能となる。
【図面の簡単な説明】
【図１】 本発明の火災フェイズ管理装置を示す図である。
【図２】 本発明の火災フェイズ管理装置の流れを示す図である。
【図３】 本発明の火災フェイズ管理方法のステップＳ１を示す図である。
【図４】 本発明の火災フェイズ管理方法のステップＳ２を示す図である。
【図５】 本発明の火災フェイズ管理方法のステップＳ３を示す図である。
【図６】 本発明の火災フェイズ管理方法のステップＳ４を示す図である。
【図７】 本発明の火災フェイズ管理方法のステップＳ３’を示す図である。
【図８】 本発明の火災フェイズ管理方法のステップＳ４’を示す図である。
【図９】 本発明のフェイズ基準時間データベースの構築方法を示す図である。
【図１０】 本発明の火災の進展状況を把握するための温度区間の概念図を示す図である。
【符号の説明】
１ 火災フェイズ管理装置
２ 感知器
３ 中央処理装置
４ 受信装置
５ 演算装置
６ 記憶装置
６ａ データ領域
６ｂ プログラム領域
７ 諸元情報データベース
７ａ 諸元情報
８ 室用途別火災成長率データベース
９ 材料別熱貫性データベース
１０ フェイズ進展基準時間データベース
１１ 出力装置
１２ 入力装置
１３ 非常放送設備
１４ 防排煙設備[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a fire phase management device and a fire phase management method for grasping the progress of a fire in a building in stages.
[0002]
[Prior art]
The automatic fire alarm equipment that has been adopted in buildings has been monitoring the status of indoor temperature rise and smoke concentration, and whether or not a fire has occurred depending on whether these values exceed preset thresholds. It has a function to judge whether or not to notify the stay limit state.
[0003]
[Patent Document 1]
JP 2002-8155 A
[0004]
Each of these has a threshold value of 1, so it is possible to determine the occurrence of a fire and detect the limit of stay, etc., but the progress of the staged fire in the building after the fire breaks out, that is, the fire phase I can't figure out.
[0005]
[Problems to be solved by the invention]
For this reason, in order for fire prevention managers to grasp the progress of a fire step by step, it is necessary to rush directly to the room where the fire appears to have occurred, which may delay response actions at the beginning of the fire. .
In addition, when a fire is detected at an early stage, many actions such as fire extinguishing and smoke control need to be performed in a short time as response actions. Therefore, it is difficult to appropriately control countermeasures according to the extent of damage.
[0006]
In view of the above circumstances, the present invention provides a fire phase management device capable of grasping the progress of a fire in a room in a stepwise manner while staying in a remote place such as a building management room, and a fire phase. The purpose is to provide a management method.
[0007]
[Means for Solving the Problems]
The fire phase management device according to claim 1 is provided on a ceiling of a room to be monitored in a building and has both a smoke detection function and a heat detection function, and a heat detection function of the sensor. Each of the predetermined temperature sections detected by the above and the temperature in the vicinity of the ceiling surface of the room is set for at least two sections, A storage device having a database for storing a phase advance reference time, and an arithmetic device for performing a comparison operation on the phase advance reference time related to a temperature rise in the same temperature interval as the required time. A central processing unit, the central processing unit Phase progress It is characterized by having a configuration for issuing an alarm signal in accordance with the progress of the fire ascertained by comparison with the reference time.
[0008]
The fire phase management device according to claim 2, wherein the central processing unit includes: Phase progress An input device for inputting a setting condition for setting the reference time is provided.
[0009]
The fire phase management method according to claim 3 is a fire phase management method using the fire phase management device according to claim 1 or 2, wherein an upper limit temperature constituting a temperature interval in which the sensor detects a required time, and A first step of setting a lower limit temperature and a reference time required for temperature rise in the temperature section set by using the central processing unit, and a temperature near the ceiling surface of the room are set in the first step. The second process in which the required time required to pass through the rising temperature section is detected by the sensor, and the required time detected in the second process using the central processing unit is determined in the first process. It is characterized by comprising a third process of grasping the progress of the fire by comparing it with the set reference time and issuing an alarm signal according to the progress.
[0010]
In the fire phase management method according to claim 4, the reference time set in the first step is set to at least the usage of the room in which the sensor is installed, the floor area, and the material of the ceiling material. It is characterized by being set based on.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the fire phase management device and the fire phase management method of the present invention are shown in FIGS.
Generally, in the design stage, the degree of fire progress (hereinafter referred to as the fire growth rate α) is set in advance at the design stage according to the use of the room, and these settings are used for evacuation facilities and smoke exhaust facilities. Design evacuation safety measures. However, when the room is being used, the amount of combustible material in the room is not necessarily the same as the set value at the time of design. On the other hand, the fire growth rate α when a fire occurs tends to greatly depend on the weight per unit area of the combustible material in the room, the material and arrangement of the combustible material, and the like. For this reason, it is important to compare the actual fire growth rate α with the predicted value at the design stage in the early stage of fire, and to grasp the magnitude of it, considering the evacuation safety of residents in the building. One of the most important indicators.
By the way, it is known that the temperature of the smoke layer accumulated near the ceiling rises rapidly at the initial stage of the fire, and when the time required for the temperature rise is short, it can be predicted that the progress of the fire is rapid, When the time required for the temperature rise is relatively long, it can be predicted that the progress of the fire is slow.
[0012]
Therefore, the fire phase management device and the fire phase management method of the present invention apply a sensor having both a smoke detection function and a heat detection function to the detector installed on the ceiling of the room to be monitored, From the temperature information in the vicinity of the ceiling surface obtained by the heat detection function, the required time Δt required for passing through a predetermined temperature section in the initial stage of the fire is detected. On the other hand, the required time Δt required to pass through the same temperature section from the temperature information in the vicinity of the ceiling surface when a fire occurs in the room assuming the design stage _f Is calculated in advance, and this is referred to as a reference time (hereinafter referred to as phase progress reference time T _f It is set as
As a result, the manager of the building uses a central processing unit that receives information detected by the sensor, for example, in a building management room of the building. Based on the temperature information obtained by the heat detection function, the required time Δt required for the smoke layer temperature in the vicinity of the ceiling surface to rise and pass through a predetermined temperature section is determined as the phase progress reference time T _f By comparing with, the progress of fire is monitored.
[0013]
However, as a feature of the fire, when the smoke layer temperature near the ceiling rises through a predetermined temperature section set in the initial stage of the fire, even if the fire growth rate α is slow, it suddenly increases thereafter. There are cases where the temperature rises and the fire growth rate α rises. For this reason, at least two or more predetermined temperature sections are set, and the phase progress reference time T based on the temperature information obtained by the thermal detection function of the sensor for each of the plurality of sections. _f Required time Δt required for the smoke layer temperature near the ceiling surface to rise and pass through a predetermined temperature section ₁ , Δt ₂ , ... are monitored.
[0014]
As a result, the required time Δt for ascending and passing through the temperature section on the low temperature side for the temperature sections set in a plurality of sections. ₁ Phase progress reference time T _f Even if it is slow compared to, in order to monitor the progress of the smoke layer temperature near the ceiling surface again in the temperature zone on the high temperature side, capture the situation even when the fire growth rate α progresses rapidly It becomes possible. Therefore, the manager can monitor the progress of the fire step by step for each set temperature interval without having to be present at the site, so that the rapid change in the fire growth rate α is not overlooked. It is possible to improve the reliability of the system.
[0015]
As described above, the required time Δt required for the smoke layer temperature near the ceiling surface of the room where a fire is expected to occur to rise through a predetermined temperature section is expressed as a phase progress reference time T. _f FIG. 1 shows a fire phase management device 1 that monitors the progress of a fire step by step.
The fire phase management device 1 includes a sensor 2 and a central processing unit 3. The sensor 2 uses an analog heat / smoke combined type having both a smoke detection function and a heat detection function that have been used conventionally, and is provided on the ceiling of a room to be monitored by a building. ing. The analog heat / smoke sensor 2 can distinguish between the heat and smoke generated from fire that people use on a daily basis and the abnormal heat and smoke generated by fire. It is generally known as a sensor 2 that can be accurately grasped. The sensor 2 detects smoke layer density information formed in the upper layer of the room with a smoke detection function when a fire occurs, and detects smoke layer temperature information of the smoke layer with a heat detection function. Is transmitted to the central processing unit 3.
[0016]
The central processing unit 3 includes a receiving device 4, a computing device 5, a storage device 6, an output device 11, and an input device 12. The receiving device 4 receives a fire signal such as smoke density information and smoke layer temperature information detected by the sensor 2, and in this embodiment, a relay device (not shown) receives the fire signal from the sensor 2. Thus, an R type is used which is converted into fire signal information to which an address given to each sensor 2 is added and received by a transmission signal. As described above, the R-type receiving device 4 receives the fire signal from the sensor 2 as fire signal information to which the address of the sensor 2 is added. Not only the position can be recognized, but also the operation time can be recognized.
The fire signal information to which the address received by the receiving device 4 is added is stored in the storage device 6 via the arithmetic device 5 or used for arithmetic processing by the arithmetic device 5. The receiving device 4 is connected to the emergency broadcasting facility 13 and the smoke prevention facility 14, and receives transmission signals from the arithmetic device 5 and activates them. Here, the smoke prevention facility 14 indicates a general facility installed in a building for the purpose of fire prevention and smoke removal such as a fire door, a fire shutter, and a smoke exhaust facility.
[0017]
The arithmetic device 5 performs arithmetic processing on the data received from the receiving device 4 and the data stored in the data area 6 a of the storage device 6 using the arithmetic expression stored in the program area 6 b of the storage device 6. Is. The output device 11 outputs data stored in the data area 6a of the storage device 6 and a calculation result obtained by performing arithmetic processing using an arithmetic expression stored in the program area 6b. Any of a monitor and a printer may be used. The arithmetic device 5 includes an input device 12 such as a scanner or a keyboard, and can input data into the data area 6a from the input device 12 as well as the receiving device 4. It has become.
[0018]
In the present embodiment, when the progress of the fire is monitored step by step using the fire phase management device 1 described above, the program area 6b of the arithmetic device 5 constituting the central processing unit 3 as shown in FIG. Phase reference time T corresponding to the room in which at least the sensor 2 is provided _f Formula for calculating phase, calculated phase progress reference time T _f And an arithmetic expression for calculating the difference between the required time Δt required for an actual fire and the like.
[0019]
Here, the phase progress reference time T, which is the reference time for monitoring the progress of fire _f An arithmetic expression for calculating the value will be described.
Phase progress reference time T _f In the room where the sensor 2 is installed, the smoke layer temperature in the vicinity of the ceiling surface is within the specified temperature range with the assumption of the specifications at the design stage without depending on the current usage situation. Required time to pass up the road _f An example of the calculation is shown below. In addition, the calculation method shown below is only one example, and is not necessarily limited to this.
[0020]
When a fire occurs in a room where the sensor 2 is provided, a smoke layer is formed in the upper layer and a fresh air layer is formed in the lower layer, and it is assumed that the temperature in the smoke layer is uniform. The smoke layer temperature can be expressed by (Equation (1)).
[0021]
[Expression 1]

[0022]
(Equation (1)), heat transfer coefficient h _k Is a parameter indicating the ease of transmission of heat from the ceiling material, and can be expressed by (Equation (2)).
[0023]
[Expression 2]

[0024]
Furthermore, when (Equation (2)) is used for (Equation (1)) and (Equation (1)) is solved for the elapsed time t after the fire breaks out, it can be expressed as (Equation (3)).
[0025]
[Equation 3]

[0026]
Here, the required time Δt _f The lower and upper limit values for the temperature interval for which you want to measure the trigger temperature T _s1 , T _s2 And the smoke layer temperature near the ceiling surface is the trigger temperature T _s1 , T _s2 Time to reach t ₁ , T ₂ Is set to (Expression (3)), the required time Δt required to pass through the temperature section can be expressed by (Expression (4)).
[0027]
[Expression 4]

[0028]
That is, the required time Δt shown in (Expression (4)) _f Is the trigger temperature T _s1 , T _s2 Phase progression reference time T, which is the reference time required to pass through the temperature range with the lower limit value and the upper limit value as the reference value _f This is the calculation formula. Here, (Expression (4)) is used as the room information in which the sensor 2 is provided, and the usage of the room, the floor area A _T , And thermal conductivity of the ceiling material (kρc) ^1/2 In addition, the opening area A and the opening height H of the room are used as parameters. However, since the staged monitoring of the progress of the fire is targeted at the initial stage of the fire, it is considered that the opening and closing conditions of the openings such as the windows and doors of the room are less affected. Assuming a situation in which one general door is arranged as the opening of the room, the condition can be set assuming that this is open.
[0029]
Thereby, (Equation (4)) can be expressed by (Equation (5)) by solving for the fire growth rate (α).
[0030]
[Equation 5]

[0031]
That is, the fire growth rate α is the floor area A of the room where the fire is occurring. _T And thermal conductivity of ceiling materials (kρc) ^1/2 If we know the trigger temperature T _s1 , T _s2 Time t ₁ , T ₂ It can be seen that it can be calculated based on
Therefore, for the room in which the sensor 2 is provided, the standard fire growth rate α according to the use of the room and the thermal conductivity (kρc) according to the material of the ceiling ^1/2 Is given in advance and thermal conductivity (kρc) ^1/2 And trigger temperature T _s1 , T _s2 And the phase progression reference time T using (Equation (4)) _f Will be calculated.
[0032]
By the way, as shown in FIG. 1, the data area 6a of the storage device 6 includes at least a specification information database 7, a fire growth rate database 8 by room usage, a thermal conductivity database 9 by material such as a ceiling material, and a phase. A progress reference time database 10 is stored.
These are constructed in consideration of speeding up of the processing speed in the central processing unit 3 and simplification of the system configuration, and thermal conductivity (kρc) corresponding to the material of the ceiling. ^1/2 The material-specific heat-permeability database 9, the room floor area A for each use of the room _T The fire growth rate α corresponding to the above is constructed as the fire growth rate database 8 by room usage. In addition, the specification information database 7 includes a phase progress reference time T _f The information of the room, the floor area of the room, and the material of the ceiling material, at least three pieces of information 7a necessary for calculating the value, together with the address of the sensor 2 installed in the room and the room name It is a database.
[0033]
Therefore, for each sensor 2, the specification information 7 a of the room in which the sensor 2 is installed is extracted from the specification information database 7, and the material-specific thermal conductivity database 9 and the room-use fire growth rate database are used. 8 to match the thermal conductivity (kρc) optimal for the room where the sensor 2 is installed. ^1/2 After determining the fire growth rate α, the phase progress reference time T for each sensor 2 _f The calculation result can be constructed as the phase progress reference time database 10.
In addition, although the fire growth rate database 8 by room use and the thermal conductivity database 9 by material can be constructed with general versatility, the specification information database 7 is different depending on the building. It is. For this reason, with respect to the specification information database 7, the specification information 7a of the room is appropriately stored in the data area 6a of the storage device 6 via the input device 12 according to the building in which the fire phase management device 1 is provided. If the interface type for constructing the specification information database 7 is used, the fire phase management device 1 can be applied to any building, and the versatility of the fire phase management device 1 is enhanced.
[0034]
FIG. 2 shows a processing flow of the fire phase management device 1 having the above-described configuration.
First, after giving an address to the sensor 2 provided in each room to be managed by the building, the specification information 7a of the room in which the sensor 2 is provided is input to the input device of the central processing unit 3. 12 and stored in the data area 6 a of the storage device 6 as the specification information database 7.
Next, for each sensor 2, the fire growth rate α corresponding to the room specification information 7 a stored in the specification information database 7 using the arithmetic device 5, and the thermal conductivity (kρc) ^1/2 Are selected from the room-specific fire growth rate database 8 and the material-specific thermal conductivity database 9 stored in advance in the data area 6a. This fire growth rate α and thermal conductivity (kρc) ^1/2 And the arithmetic expression stored in the program area 6b (see equation (4)), the phase progress reference time T _f And the calculation result is stored in the data area 6a as the phase progress reference time database 10 (step S1).
[0035]
When a fire occurs, the smoke detection function of the sensor 2 is activated, and the receiver 4 of the central processing unit 3 receives a fire signal to which the address (fixed number) of the sensor 2 and the time are added. This is transmitted to the arithmetic device 5 to display a fire signal on the output device 11 such as a monitor, and the arithmetic device 5 transmits an alarm broadcast sounding command to the emergency broadcast equipment 13 via the receiver 4 (step S2). ).
[0036]
On the other hand, when the indoor smoke layer temperature gradually rises, the heat detection function of the sensor 2 is activated, and the lower limit value T of the trigger temperature constituting the preset temperature section _s1 And upper limit T _s2 After detecting both, the fire signal to which the address (fixed number) and time are added and the required time Δt required to pass through the set temperature section are calculated via the receiver 4 of the central processing unit 3 The data is transmitted to the device 5 (step S3).
[0037]
In the arithmetic unit 5, the address (fixed number) of the sensor 2 is collated from the fire signal transmitted at the same time for the required time Δt transmitted, and the phase progress reference time database 10 stored in the data area 6a is used. Phase advance reference time T corresponding to the address of sensor 2 _f And select the required time Δt and the optimal phase progression reference time T _f And compare. The required time Δt is the phase progress reference time T _f If it is shorter, the fire detection signal is displayed by the operation of the smoke detection function of the sensor 2, and then a fire phase progress warning is transmitted from the arithmetic unit 5 to the receiver 4 to send an emergency broadcast. The equipment 13 and the smoke prevention equipment 14 are operated.
At this time, by comparing the address of the sensor 2 added to the fire signal with the specification information database 7, the position and room name of the sensor 2 to which the fire signal is transmitted can be grasped. Together with the result, the output device 11 may display how much fire is growing at which part of the building. Moreover, you may make the output device 11 output the operation | movement log | history of the fire phase management apparatus which matched the operation content of the sensor 2 and the central processing unit 3, and time (step S4).
[0038]
As mentioned earlier, evacuation safety measures such as evacuation facilities and smoke evacuation facilities for buildings are set in advance under the design stage conditions for the fire growth rate α according to the usage of the room. It is designed corresponding to the set value. Therefore, when the fire breaks out, the phase progress reference time T, which is the reference time required for the smoke layer temperature near the ceiling surface to rise through the predetermined temperature section _f If the required time Δt is earlier than that, it means that the performance of the evacuation safety measures applied to the building has reached a state where it is not sufficient to ensure the evacuation safety. As described above, the fire phase progress warning is issued in order to control measures in real time according to the progress of fire in consideration of the performance of evacuation safety measures for each building.
[0039]
It should be noted that the fire phase progress warning indicates that the required time Δt required to pass through the set temperature section is the phase progress reference time T _f In addition, it is configured such that the alarm is issued in a situation where a fire alarm signal is displayed due to the operation of the smoke detection function of the sensor 2 being shorter. Generally, when a fire report is issued for the purpose of preventing non-fire reports, the building manager fires at the site when a fire signal is issued from smoke layer temperature information or smoke concentration information from the sensor. It is necessary to confirm and confirm fire signals from multiple sensors.
Considering these, the fire phase management device 1 uses the fact that the sensor 2 possesses both the smoke detection function and the smoke layer temperature detection function, and uses the smoke layer temperature detection function as a phase progress reference time T. _f In addition to the comparison result between the required time Δt and the fire detection signal by the smoke detection function, both measures are taken as a necessary condition, and only one sensor 21 is used to prevent non-fire information. Yes.
[0040]
In step S4, the required time Δt is equal to the phase progress reference time T. _f If longer, trigger temperature T _s1 , T _s2 , A new trigger temperature T on the higher temperature side _s3 And set the lower limit to T _s2 , The upper limit is T _s3 The operations in steps S3 and S4 are repeated for the temperature interval set as. Two or more temperature intervals may be set, and the temperature interval is not necessarily set continuously.
[0041]
A fire phase management method using the above-described fire phase management apparatus 1 will be described in detail according to the flow shown in FIGS.
In the present embodiment, the sensor is provided with an addressed sensor 2 on the ceiling of each of the plurality of rooms to be monitored, and the central processing unit 3 manages the building management of the building. It is assumed that it is placed in the room.
[0042]
(Step S1)
Step S1 shows a setting method of the fire phase management device 1 at a normal time before the occurrence of a fire among the fire phase management methods. As shown in FIG. 3, first, in order to grasp the progress of the fire in the initial stage, the time required for temperature rise Δt ₁ , Δt ₂ Set the temperature interval to measure. In the present embodiment, two consecutive sections are set, and the central processing unit 3 side starts from the low temperature side. _s1 , T _s2 , T _s3 These three points are set and notified to the sensor 2 as the trigger temperature.
[0043]
In the present embodiment, as shown in FIG. _s1 , T _s2 , T _s3 Three points of 60 ° C, 73 ° C and 88 ° C are applied. This is because 60 ℃ is the nominal operating temperature of the constant temperature spot type heat sensor, 73 ℃ is the general indication temperature of the sprinkler head, and 88 ℃ is the general office fire etc. It takes into account that the temperature required for the time is almost the same as when the temperature rises from 60 ° C to 73 ° C. Moreover, 73 degreeC-88 degreeC is the temperature which hits the boundary of the stage where a fire spreads in a room from the stage of the fire which can be extinguished by the fire extinguisher or the sprinkler equipment.
In this way, by setting the temperature in consideration of the characteristics of the fire as the trigger temperature, for example, the required time Δt at 73 ° C. to 88 ° C. in the second section ₂ Phase progress reference time T _f When the stage of the fire progresses faster than before, that is, when the phase progress warning should be issued, the state of the room in which the sensor 2 is installed is in a state where initial fire extinguishing with a fire extinguisher or the like is difficult. The most appropriate action to ensure the evacuation safety of the residents at the time is measures to prevent smoke propagation to upper floors, such as early evacuation guidance and the closure of smoke prevention equipment such as fire doors. Therefore, it is possible to easily determine the optimum countermeasures corresponding to the progress of fire.
[0044]
Considering these, the trigger temperature T _s1 , T _s2 , T _s3 Covers the temperature range of 60 to 100 ° C, which corresponds to the stage of expansion at the beginning of the fire, and can be set to any temperature, considering the accuracy of fire occurrence and the heat resistance performance of the heat detection function, Trigger temperature T _s1 , T _s2 , T _s3 As mentioned above, it is most preferable to use the temperatures in the vicinity of 60 ° C., 73 ° C., and 88 ° C. described above.
Note that the temperature interval for detecting the required time Δt required for temperature rise is not necessarily two consecutive intervals, and the trigger temperature may be increased by one. Also, the section need not be two sections, and a plurality of sections may be set as necessary as long as there are two or more sections. Also, the trigger temperature T is not necessarily _s1 To T _s2 , T _s2 To T _s3 It is not necessary to set the trigger temperature so that the required time Δt is almost the same in both of the two sections, but considering the simplification of the system configuration, the required time Δt is almost the same in both of the two temperature sections. It is preferable to set a trigger temperature such that
[0045]
Next, the phase progress reference time T corresponding to each sensor 2 _f Is calculated and constructed as a database. Phase progress reference time T _f Is calculated on the central processing unit 3 side, and as shown in FIG. 9, first, from five pieces of information of the address number, room name, room use, floor area, and ceiling material for each sensor 2 The specification information database 7 storing the specification information 7a is constructed. Next, the specification information database 7 is collated with the fire growth rate database 8 for each room and the thermal conductivity database 9 for each material that has been built in advance, and the fire growth rate α and the thermal conductivity are detected for each sensor 2. (Kρc) ^1/2 Phase selection reference time T for each sensor 2 _f And is constructed as the phase progress reference time database 10 in advance.
[0046]
(Step S2)
Step S2 and subsequent steps show a fire phase management method using a fire phase management device under a situation where a fire is expected to occur.
When a fire breaks out, a smoke layer gradually accumulates in the room. As shown in FIG. 4, when the smoke density of the smoke layer exceeds the specified value and reaches the fire signal level, the smoke detecting function of the sensor 2 detects the smoke density exceeding the specified value and notifies the central processing unit 3. Upon receiving the notification, the central processing unit 3 displays the fire alarm signal and transmits the fire alarm signal to the emergency broadcast facility 13. In response to this, the emergency broadcast facility 13 sounds a sensor notification broadcast throughout the building.
[0047]
(Step S3)
As the smoke layer accumulates in the room due to the progress of the fire, the smoke layer temperature begins to rise. The smoke layer temperature near the ceiling is the trigger temperature T _s1 As shown in FIG. 5, the heat detection function of the sensor 2 is activated, and fire signal information to which the address of the sensor 2 is added is transferred to the central processing unit 3 as an interrupt signal.
The central processing unit 3 receives the interrupt signal, and the smoke layer temperature becomes the trigger temperature T _s2 Required time to reach ₁ Queries the analog value of.
The sensor 2 has a trigger temperature T _s1 Time measurement is started at the same time as the detection of the trigger temperature T _s2 When the central processing unit 3 is detected, the trigger temperature T _s2 The fire signal information to notify the detection of the fire is transferred and the required time Δt ₁ As an analog value.
[0048]
By the way, in the initial stage of fire, the smoke layer temperature changes to some extent due to the spread of fire spread between combustibles, so the smoke layer temperature does not always rise, but stagnates or falls after the temperature rises once. It may be possible to do this. Therefore, the sensor 2 has a trigger temperature T in advance. _s1 Trigger temperature T after detecting _s2 The time limit Δt for the time required to detect _lim And the detected temperature is the trigger temperature T _s1 It is configured to always monitor whether the temperature is high compared to The time limit Δt _lim Is the phase progress reference time T, which is the reference time for each sensor 2 _f Set a time that exceeds.
As a result, the trigger temperature T _s1 Trigger temperature T immediately after detecting _s2 Required time until t is detected ₁ Is the time limit Δt _lim Is exceeded, the sensor 2 notifies the central processing unit 3 that the smoke layer temperature is stagnant. On the other hand, the sensor 2 has a time limit Δt _lim Even if it exceeds the required time Δt ₁ Continue measuring.
In addition, the sensor 2 has a trigger temperature T _s1 Trigger temperature T immediately after detecting _s2 Until the smoke layer temperature T is detected as the trigger temperature T _s1 If it is confirmed that the time is less than ₁ Stop measuring.
[0049]
(Step S4)
As shown in FIG. 6, the smoke layer temperature near the ceiling surface is the trigger temperature T _s2 To the central processing unit 3 and the required time Δt ₁ Is notified, the central processing unit 3 has already set the time limit Δt. _lim It is confirmed whether or not the notification of excess has been received. ₁ Phase progress reference time T corresponding to sensor 2 that detected _f Is selected from the phase progress reference time database 10 and the required time Δt ₁ To understand the progress of fire. Time required Δt ₁ Phase progress reference time T _f If it is earlier, the smoke management side of the central processing unit 3 inquires whether the fire alarm signal is displayed. If it is displayed, the fire phase progress warning is issued and the emergency broadcast equipment 13 And a command corresponding to the progress status of the fire assumed from the temperature section where the fire phase progress warning such as the fire broadcasting and the smoke prevention equipment all floors closed is transmitted to the smoke prevention equipment 14.
On the other hand, phase progress reference time T _f And required time Δt ₁ And the required time Δt ₁ If it is late, transmission to the emergency broadcasting facility 13 or smoke prevention facility 14 is not performed, and the process proceeds to the next step S3 ′ for monitoring the progress of the fire in the second temperature zone.
Further, the central processing unit 3 requires a required time Δt. ₁ Is notified at the time Δt _lim If the notification of excess is received, the above-mentioned phase progress reference time T _f Is not performed, and the process proceeds to the next step S3 ′.
[0050]
(Step S3 ′)
Trigger temperature T _s1 , T _s2 The required time Δt in the temperature section composed of ₁ Is the phase progression reference time Tf and Δt _lim If the progress of the fire is slower than that predicted at the design stage, then the trigger temperature T _s2 , T _s3 The progress of the fire is monitored again using the temperature section composed of the above. Note that the sensor 2 has a trigger temperature T _s2 Trigger temperature T is already detected when _s2 The fire signal information notifying the detection of the event is transferred to the central processing unit 3 as an interrupt signal, and at the same time the time measurement ΔT ₂ Has started.
As shown in FIG. 7, the central processing unit 3 not displaying the fire confirmation report or the fire phase progress warning indicates that the smoke layer temperature is the trigger temperature T on the sensor 2. _s3 Required time to reach ₂ Inquire.
The sensor 2 has a trigger temperature T _s3 When the central processing unit 3 is detected, the trigger temperature T _s3 The fire signal information to notify the detection of the fire is transferred and the required time Δt ₂ As an analog value.
[0051]
At this time, the sensor 2 detects the trigger temperature T as in step S3. _s2 Trigger temperature T immediately after detecting _s3 Required time until t is detected ₂ Is the time limit Δt _lim The sensor 2 notifies the central processing unit 3 that the smoke layer temperature is stagnant. On the other hand, the sensor 2 has a time limit Δt _lim Required time Δt ₂ Continue measuring.
In addition, the sensor 2 has a trigger temperature T _s2 Trigger temperature T immediately after detecting _s3 Until the smoke layer temperature T is detected as the trigger temperature T _s2 If it is confirmed that the time is less than ₂ Stop measuring.
[0052]
(Step S4 ′)
The smoke layer temperature near the ceiling is the trigger temperature T _s3 To the central processing unit 3 and the required time Δt ₂ As shown in FIG. 8, the central processing unit 3 has already received the time limit Δt. _lim It is confirmed whether or not the notification of excess has been received. ₂ Phase progress reference time T corresponding to sensor 2 that detected _f Is selected from the phase progress reference time database 10 and the required time Δt ₂ To understand the progress of fire.
[0053]
Time required Δt ₂ Phase progress reference time T _f If it is earlier, the smoke management side of the central processing unit 3 inquires whether the fire alarm signal is displayed. If it is displayed, the fire phase progress warning is issued and the emergency broadcast equipment 13 And a command corresponding to the progress status of the fire assumed from the temperature section where the fire phase progress warning such as the fire broadcasting and the smoke prevention equipment all floors closed is transmitted to the smoke prevention equipment 14.
On the other hand, phase progress reference time T _f And required time Δt ₂ And the required time Δt ₂ When the time is late, the central processing unit 3 displays a timeout and a specified warning or fire report.
When two or more temperature sections for monitoring the progress of the fire are provided, the progress of the fire may be continuously monitored by repeating the steps S3 ′ and S4 ′.
[0054]
According to the configuration described above, since the progress of the fire is monitored in at least two temperature sections, the progress of the fire can be grasped step by step, and a sudden change in the fire growth rate α is also overlooked. This makes it possible to improve the reliability of fire phase management.
Furthermore, even when the central processing unit 3 is located at a location remote from the fire site, the manager can issue an alarm according to the progress of the fire without rushing to the fire site. It is possible to implement fire prevention measures that are optimal for the progress of the project.
[0055]
Since the central processing unit 3 includes the output device 11, the output device 11 includes the fire signal received by the central processing unit 3 from the sensor 2 and the monitoring result of the progress of the fire by the central processing unit 3. Displays map information such as how much fire is growing in which part of the building, or displays the operation history of the fire phase management device 1 that correlates the operation contents and time of the sensor and the central processing unit 3 Therefore, the manager of the building can report accurate fire information in real time when the fire brigade arrives without rushing to the fire site.
In addition, when the fire brigade rushes to the building, it can instantly grasp the fire expansion status using the output result at the place where the central processing unit 3 is installed. It is possible to plan in advance.
[0056]
Since the central processing unit 3 is linked to the emergency broadcast facility 13 and the smoke prevention facility 14, the emergency broadcast facility 13 and the smoke prevention facility 14 are generated by monitoring the progress of the fire by the central processing unit 3. Because it is linked and controlled based on the reported fire confirmation signal, fire phase progress warning, etc., it is highly reliable and appropriate countermeasure action of emergency broadcasting equipment 13 and smoke prevention equipment 14 according to the progress of fire Can be carried out.
[0057]
Further, the central processing unit 3 includes a phase progress reference time T for each sensor 2. _f Since the input device 12 for inputting different setting conditions for each sensor 2 is provided when the sensor 2 is set, the phase progress reference time T can be easily set for the sensor 2 provided in any room. _f It is possible to easily change the room where the sensor 2 has already been installed even if the conditions such as floor area and usage have changed due to renewal after completion, etc. The versatility of the fire phase management device 1 can be improved.
[0058]
Phase progress reference time T provided for each sensor 2 _f Is managed by the central processing unit 3 and uses only the simple specification information 7 of the room where the sensor 2 is installed, the area, and the material of the ceiling. Even when it occurs, the central processing unit 3 easily makes the phase progress reference time T _f It is possible to change.
[0059]
【The invention's effect】
According to the fire phase management device of claim 1, since the progress of the fire is monitored in at least two temperature sections, the progress of the fire can be grasped step by step, and the fire growth rate α It is possible to increase the reliability of fire phase management without overlooking sudden changes.
[0060]
According to the fire phase management device of claim 2, the central processing unit, Phase progress Equipped with an input device that inputs setting conditions for setting the reference time, so it is easy for any sensor installed in any room Phase progress It is possible to set a reference time, and it is possible to easily change the room where the sensor has already been installed even if the conditions such as floor area and usage have changed due to renewal after completion. The versatility of the fire phase management device can be improved.
[0061]
According to the fire phase management method according to claim 3, the fire phase management method using the fire phase management device according to claim 1 or 2, wherein the detector constitutes an upper limit constituting a temperature interval in which the required time is detected. The first step of setting the temperature and the lower limit temperature, and setting the reference time required for the temperature rise in the temperature section set using the central processing unit, and the temperature in the vicinity of the ceiling surface of the room in the first step A second process in which the time required for passing through the set temperature section is detected by the sensor, and a required time detected in the second process using the central processing unit, Comparing with the reference time set in the process, the progress of the fire is grasped, and the third process that issues a warning signal according to the progress is configured. Arrangement It is possible for an administrator to issue a warning according to the progress of a fire without rushing to the fire site, and to implement fire prevention measures that are optimal for the progress of the fire quickly. It becomes possible.
[0062]
According to the fire phase management method of claim 4, the reference time set in the first step is set to at least the usage of the room in which the sensor is installed, the floor area, and the material of the ceiling material, Since the setting is made based on this, it is possible to easily change the reference time in the central processing unit even when the usage of the room is changed or the renewal occurs.
[Brief description of the drawings]
FIG. 1 is a diagram showing a fire phase management device of the present invention.
FIG. 2 is a diagram showing a flow of the fire phase management device of the present invention.
FIG. 3 is a diagram showing step S1 of the fire phase management method of the present invention.
FIG. 4 is a diagram showing step S2 of the fire phase management method of the present invention.
FIG. 5 is a diagram showing step S3 of the fire phase management method of the present invention.
FIG. 6 is a diagram showing step S4 of the fire phase management method of the present invention.
FIG. 7 is a diagram showing step S3 ′ of the fire phase management method of the present invention.
FIG. 8 is a diagram showing step S4 ′ of the fire phase management method of the present invention.
FIG. 9 is a diagram showing a method for constructing a phase reference time database according to the present invention.
FIG. 10 is a diagram showing a conceptual diagram of a temperature section for grasping the progress of a fire according to the present invention.
[Explanation of symbols]
1 Fire Phase Management Device
2 Sensor
3 Central processing unit
4 receivers
5 Arithmetic unit
6 Storage device
6a Data area
6b Program area
7 Specification information database
7a Specification information
8 Fire Growth Rate Database by Room Usage
9 Thermal conductivity database by material
10 Phase progress reference time database
11 Output device
12 Input devices
13 Emergency broadcasting equipment
14 Smoke prevention equipment

Claims (4)

A sensor provided on the ceiling of a room to be monitored in the building, and having both a smoke detection function and a heat detection function;
Stores the time required for rising each predetermined temperature section detected by the heat detection function of the sensor and set at least two sections in the vicinity of the ceiling surface of the room, and sets the phase progress reference time A storage device having a database to store;
Comparing the phase progress reference time related to the temperature rise in the same temperature interval as the required time, and a central processing unit having a central processing unit,
A fire phase management device comprising: a configuration in which the central processing unit issues an alarm signal in accordance with a fire progress state grasped by a comparison operation between a required time and a phase progress reference time. In the fire phase management device according to claim 1,
A fire phase management device, wherein the central processing unit is provided with an input device for inputting a setting condition for setting a phase progress reference time. A fire phase management method using the fire phase management device according to claim 1 or 2,
A first step of setting an upper limit temperature and a lower limit temperature constituting a temperature interval in which the sensor detects a required time, and setting a reference time required for temperature rise in the temperature interval set using the central processing unit;
A second stroke in which a sensor detects a time required for the temperature in the vicinity of the ceiling surface of the room to pass through the temperature section set in the first stroke.
Using the central processing unit, the progress time of the fire is grasped by comparing the required time detected in the second process with the reference time set in the first process, and an alarm signal is issued according to the progress condition. A fire phase management method comprising: a third step. In the fire phase management method using the fire phase management device according to claim 3,
A fire phase characterized in that the reference time set in the first step is set based on at least the usage of the room in which the sensor is installed, the floor area, and the material of the ceiling material. Management method.

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