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JP3260476B2 - Water supply device - Google Patents

Water supply device

Info

Publication number
JP3260476B2
JP3260476B2 JP11309693A JP11309693A JP3260476B2 JP 3260476 B2 JP3260476 B2 JP 3260476B2 JP 11309693 A JP11309693 A JP 11309693A JP 11309693 A JP11309693 A JP 11309693A JP 3260476 B2 JP3260476 B2 JP 3260476B2
Authority
JP
Japan
Prior art keywords
water supply
water
building
pump
signal
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Fee Related
Application number
JP11309693A
Other languages
Japanese (ja)
Other versions
JPH06322799A (en
Inventor
茂雄 小坂
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Panasonic Electric Works Co Ltd
Original Assignee
Matsushita Electric Works Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Matsushita Electric Works Ltd filed Critical Matsushita Electric Works Ltd
Priority to JP11309693A priority Critical patent/JP3260476B2/en
Publication of JPH06322799A publication Critical patent/JPH06322799A/en
Application granted granted Critical
Publication of JP3260476B2 publication Critical patent/JP3260476B2/en
Anticipated expiration legal-status Critical
Expired - Fee Related legal-status Critical Current

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Description

【発明の詳細な説明】DETAILED DESCRIPTION OF THE INVENTION

【0001】[0001]

【産業上の利用分野】この発明は、マンション、アパー
ト、ビルあるいは工場等の建物が複数隣接して立設され
たときの各建物内への給水を行う給水装置に関するもの
である。
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water supply device for supplying water to buildings such as condominiums, apartments, buildings or factories when a plurality of buildings are erected adjacently.

【0002】[0002]

【従来の技術】一般には、この種の複数隣接して立設さ
れた建物は、市水道から水が供給される共通の受水槽に
対し、各建物毎に交互に動作する一対の給水ポンプを設
け、この給水ポンプにより水を個々の建物内へ供給して
いる。この建物内への給水の仕方には、建物の屋上に高
架水槽を設けて、この高架水槽に給水ポンプにより送出
された水をいったん貯めておきこの水の位置エネルギー
によって建物内へ水を供給する方法と、給水ポンプが送
出する水を圧力槽に蓄積しこの圧力槽の水圧を利用して
建物内へ水を供給する方法とがある。
2. Description of the Related Art Generally, a plurality of such standing buildings are provided with a pair of water supply pumps which operate alternately for each building with respect to a common water receiving tank to which water is supplied from city water supply. The water pump is used to supply water into individual buildings. In order to supply water into this building, an elevated water tank is provided on the roof of the building, the water sent by the water supply pump is temporarily stored in this elevated water tank, and water is supplied into the building by the potential energy of this water. There is a method and a method of accumulating water delivered by a water supply pump in a pressure tank and supplying water into the building using the water pressure of the pressure tank.

【0003】前者の方法では、高架水槽の水位が減水レ
ベルまで降下したときに給水要求信号発生手段をセット
して給水要求信号を発生させるようにし、高架水槽の水
位が満水レベルまで到達したときに給水要求信号発生手
段をリセットして給水要求信号を消滅させるようにし
て、給水要求信号が発生している期間中給水ポンプを動
作させ、給水要求信号が消滅したときに給水ポンプを停
止させるという構成を採用することで、各建物の高架水
槽の水位を減水レベルから満水レベルまでの範囲に保つ
ようにしている。
In the former method, when the water level in the elevated water tank falls to the reduced water level, the water supply request signal generating means is set to generate a water supply request signal, and when the water level in the elevated water tank reaches the full water level. A configuration in which the water supply request signal generating means is reset to make the water supply request signal disappear, the water supply pump is operated during the period when the water supply request signal is generated, and the water supply pump is stopped when the water supply request signal disappears. By using, the water level of the elevated water tank in each building is kept in the range from the reduced water level to the full water level.

【0004】後者の方法では、圧力槽の水圧が減水レベ
ルまで降下したときに給水要求信号発生手段をセットし
て給水要求信号を発生させるようにし、圧力槽の水圧が
満水レベルまで到達したときに給水要求信号発生手段を
リセットして給水要求信号を消滅させるようにして、給
水要求信号が発生している期間中給水ポンプを動作さ
せ、給水要求信号が消滅したときに給水ポンプを停止さ
せるという構成を採用することで、各建物の圧力槽の圧
力を減水レベルから満水レベルまでの範囲に保つように
している。
In the latter method, when the water pressure in the pressure tank drops to the reduced water level, the water supply request signal generating means is set to generate a water supply request signal, and when the water pressure in the pressure tank reaches the full water level. A configuration in which the water supply request signal generating means is reset to make the water supply request signal disappear, the water supply pump is operated during the period when the water supply request signal is generated, and the water supply pump is stopped when the water supply request signal disappears. By using, the pressure in the pressure tank of each building is maintained in the range from the reduced water level to the full water level.

【0005】上記したように、高架水槽を用いたものお
よび圧力槽を用いたものの何れの場合でも、給水要求信
号の有無によって給水ポンプを駆動制御するもので、両
者で給水ポンプの動作・停止の時間の幅は変わるもの
の、ともに給水ポンプは間欠動作となる。また、この水
を汲み上げる給水ポンプは、生活する上で必須の水を欠
かさないようにするため、一方が故障した場合に他方で
その動作を補わせるため、一対を用意してあり、上述し
た間欠動作に対して複数の給水ポンプは交互に動作を行
うようにし、両者の給水ポンプを常に動作状態を保た
せ、錆や劣化が少なくなるようにしている。
As described above, in both the case using the elevated water tank and the one using the pressure tank, the drive of the water supply pump is controlled by the presence or absence of a water supply request signal. Although the width of the time changes, both feed pumps operate intermittently. In addition, a pair of water supply pumps are provided to keep the water essential for daily life, and to supplement the operation of the other water supply if one fails, as described above. The plurality of water supply pumps are operated alternately with respect to the operation, so that both water supply pumps are always kept in operation, so that rust and deterioration are reduced.

【0006】[0006]

【発明が解決しようとする課題】しかしながら、上記し
た給水装置は、いくら近接した位置に立設した建物であ
っても建物毎に各々一対の給水ポンプを設置しているた
めに、建物数に2倍した数の給水ポンプを用意する必要
があり、施工、配管、配線はもちろん、日常のメンテナ
ンス作業も非常に面倒なものとなっていた。
However, the above-mentioned water supply apparatus has two pairs of water supply pumps for each building, no matter how close the building stands, so that the number of buildings is two. It was necessary to prepare double the number of water supply pumps, and daily maintenance work as well as construction, plumbing, and wiring was very troublesome.

【0007】この発明の目的は、少ない数の給水ポンプ
で各建物への水供給を安定して行うことができる給水装
置を提供することである。
An object of the present invention is to provide a water supply device capable of stably supplying water to each building with a small number of water supply pumps.

【0008】[0008]

【課題を解決するための手段】請求項1記載の給水装置
は、複数の建物内に水を供給する給水装置において、建
物毎に、各建物からの給水要求信号に応答して動作し建
物内に水を供給する給水ポンプを各々設置し、建物毎の
給水ポンプとは別に補助給水ポンプを設け、この補助給
水ポンプの出力部を各々バルブを介して建物毎の給水ポ
ンプの出力部に連結し、補助給水ポンプと任意に選択さ
れた一つの建物に対応した給水ポンプと対にして選択さ
れた一つの建物からの給水要求信号に応答して交互に動
作させるポンプ制御手段を設けたことを特徴とする。
According to a first aspect of the present invention, there is provided a water supply apparatus for supplying water to a plurality of buildings, wherein the water supply apparatus operates for each building in response to a water supply request signal from each building. A water supply pump for supplying water to each building is installed, and an auxiliary water supply pump is provided separately from the water supply pump for each building, and the output part of this auxiliary water supply pump is connected to the output part of the water supply pump for each building via a valve. Pump control means which alternately operates in response to a water supply request signal from a selected one building in combination with an auxiliary water pump and a water pump corresponding to one arbitrarily selected building. And

【0009】請求項2記載の給水装置は、請求項1記載
の給水装置において、各バルブを電気信号に応答して開
閉する電動バルブとするとともに、この電動バルブを開
閉駆動するバルブ制御手段を設け、常時はバルブ制御手
段より選定された一つの建物に対応した給水ポンプの出
力部に対して補助給水ポンプの出力部を連通させるよう
に一つの電動バルブを開くとともに残りの電動バルブを
閉じる信号を出力し、ポンプ制御手段により補助給水ポ
ンプと選択された一つの建物に対応した給水ポンプとを
対にして選択された建物からの給水要求信号に応答して
交互に動作させるようにし、各建物からの渇水信号の入
力に応答してバルブ制御手段より渇水信号を出力した建
物に対応した一つの電動バルブを開き残りの建物に対応
した残りの電動バルブを閉じる信号を出力し、補助給水
ポンプを渇水信号を出力した建物からの給水要求信号に
応答して単独動作させるようにしている。
A water supply device according to a second aspect of the present invention is the water supply device according to the first aspect, wherein each valve is an electric valve that opens and closes in response to an electric signal, and valve control means that opens and closes the electric valve is provided. A signal that opens one electric valve and closes the remaining electric valves so that the output part of the auxiliary water supply pump communicates with the output part of the water supply pump corresponding to one building selected by the valve control means at all times. Output, the pump control means to alternately operate the auxiliary water supply pump and the water supply pump corresponding to the selected one building in response to a water supply request signal from the selected building in pairs, and from each building. One electric valve corresponding to the building that has output the drought signal from the valve control means in response to the input of the drought signal of the other is opened, and the remaining electric valve corresponding to the remaining building is opened. Outputs close the blanking signal, and so as to operate independently in response to auxiliary feedwater pump to the water supply request signal from the building which outputs the drought signal.

【0010】請求項3記載の給水装置は、複数の建物内
に水を供給する給水装置において、建物毎に、各建物内
からの給水要求信号に応答して動作し建物内に水を供給
する給水ポンプを各々設置し、給水ポンプの当該建物内
に水を供給する出力部に主バルブを設け、主バルブの給
水ポンプ側で給水ポンプの出力部を連結バルブを介して
他の給水ポンプの出力部に結合している。
According to a third aspect of the present invention, in the water supply apparatus for supplying water to a plurality of buildings, the water supply apparatus operates for each building in response to a water supply request signal from each building to supply water to the buildings. A water supply pump is installed, and a main valve is provided at an output part of the water supply pump that supplies water into the building, and an output part of the water supply pump is connected to an output part of another water supply pump through a connection valve on a water supply pump side of the main valve. Is connected to the department.

【0011】請求項4記載の給水装置は、請求項3記載
の給水装置において、主バルブおよび連結バルブを電気
信号に応答して開閉する電動バルブとし、主バルブおよ
び連結バルブを開閉駆動するバルブ制御手段を設け、常
時はバルブ制御手段より主バルブを開いて連結バルブを
閉じる信号を出力し、各建物からの給水要求信号に応答
して各建物に対応した給水ポンプを動作させ、建物内の
渇水信号の入力に応答して連結バルブを開いて被連結側
の給水ポンプの出力部に設けた主バルブを閉じる信号を
出力し、渇水信号を出力した建物からの給水要求信号に
応答して被連結側の給水ポンプを動作させるようにして
いる。
According to a fourth aspect of the present invention, there is provided the water supply apparatus according to the third aspect, wherein the main valve and the connection valve are electrically operated valves that open and close in response to an electric signal, and the main valve and the connection valve are opened and closed. Means, the valve control means normally outputs a signal that opens the main valve and closes the connection valve, operates the water supply pump corresponding to each building in response to a water supply request signal from each building, In response to the input of the signal, the connection valve is opened and the signal to close the main valve provided at the output of the feedwater pump on the connection side is output, and the connection is made in response to the water supply request signal from the building that output the drought signal. Side water pump is operated.

【0012】請求項5記載の給水装置は、請求項4記載
の給水装置において、渇水信号を出力した建物からの給
水要求信号の消滅に応答して、バルブ制御手段より被連
結側の給水ポンプの出力部に設けた主バルブを開いて連
結バルブを閉じる信号を出力し、被連結側の建物からの
給水要求信号に応答して被連結側の給水ポンプを動作さ
せるようにしている。
According to a fifth aspect of the present invention, in the water supply apparatus according to the fourth aspect, in response to the disappearance of the water supply request signal from the building that has output the drought signal, the valve control means controls the water supply pump on the connected side. The main valve provided in the output section is opened and a signal for closing the connection valve is output, and the water supply pump on the connection side is operated in response to a water supply request signal from the building on the connection side.

【0013】請求項6記載の給水装置は、請求項4記載
の給水装置において、渇水信号の発生に応答して異常モ
ードを保持する保持手段を設け、保持手段が異常モード
を保持している期間中において、バルブ制御手段より被
連結側の給水ポンプの出力部に設けた主バルブを開いて
連結バルブを閉じる信号を出力し被連結側の建物からの
給水要求信号に応答して被連結側の給水ポンプを動作さ
せる第1の動作と、バルブ制御手段より被連結側の給水
ポンプの出力部に設けた主バルブを閉じて連結バルブを
開く信号を出力し渇水信号を出力した建物からの給水要
求信号に応答して被連結側の給水ポンプを動作させる第
2の動作とを選択的に行わせるようにしている。
According to a sixth aspect of the present invention, in the water supply apparatus of the fourth aspect, a holding means for holding an abnormal mode in response to the occurrence of a drought signal is provided, and a period in which the holding means holds the abnormal mode. During the connection, the main valve provided at the output part of the water supply pump on the connected side is opened by the valve control means, a signal for closing the connection valve is output, and in response to a water supply request signal from the building on the connected side, the A first operation for operating a water supply pump, and a water supply request from a building which outputs a signal to open a connection valve and outputs a drought signal by closing a main valve provided at an output portion of a water supply pump on a connected side by a valve control means. The second operation of operating the water supply pump on the connected side in response to the signal is selectively performed.

【0014】請求項7記載の給水装置は、請求項4記載
の給水装置において、渇水信号の発生に応答して異常モ
ードを保持する保持手段を設け、保持手段が異常モード
を保持している期間中において、バルブ制御手段より被
連結側の給水ポンプの出力部に設けた主バルブを開いて
連結バルブを閉じる信号を出力し被連結側の建物からの
給水要求信号に応答して被連結側の給水ポンプを動作さ
せる第1の動作と、バルブ制御手段より被連結側の給水
ポンプの出力部に設けた主バルブを閉じて連結バルブを
開く信号を出力し渇水信号を出力した建物からの給水要
求信号に応答して被連結側の給水ポンプを動作させる第
2の動作とを選択的に行わせるようにし、かつ第1の動
作の実行中に渇水信号を出力した建物からの給水要求信
号が発生したときには第2の動作を優先して実行させて
第2の動作の終了後に第1の動作を再開させるととも
に、第2の動作の実行中に被連結側の建物からの給水要
求信号が発生したときには第1の動作を優先して実行さ
せて第1の動作の終了後に第2の動作を再開させるよう
にしている。
According to a seventh aspect of the present invention, there is provided the water supply apparatus according to the fourth aspect, further comprising: holding means for holding the abnormal mode in response to the occurrence of the drought signal, wherein the holding means holds the abnormal mode. During the connection, the main valve provided at the output part of the water supply pump on the connected side is opened by the valve control means, a signal for closing the connection valve is output, and in response to a water supply request signal from the building on the connected side, the A first operation for operating a water supply pump, and a water supply request from a building which outputs a signal to open a connection valve and outputs a drought signal by closing a main valve provided at an output portion of a water supply pump on a connected side by a valve control means. A second operation for operating the connected-side water supply pump in response to the signal is selectively performed, and a water supply request signal from a building that outputs a drought signal during execution of the first operation is generated. When When the water supply request signal from the connected building is generated during the execution of the second operation while the second operation is executed with priority and the first operation is restarted after the completion of the second operation. The first operation is executed with priority and the second operation is restarted after the first operation is completed.

【0015】請求項8記載の給水装置は、複数の建物内
に水を供給する給水装置において、各建物への水分配部
に各々電気信号に応答して開閉する電動バルブを設ける
とともに、各建物からの給水要求信号に応答して各電動
バルブの開閉制御を行う信号を出力するバルブ制御手段
を設け、水分配部に水を汲み上げる動作をサイクリック
に行う複数台の給水ポンプを設け、給水要求信号に応答
して複数台の給水ポンプを順次サイクリックに動作制御
する給水装置であって、バルブ制御手段を、複数の建物
からの給水要求信号が重なって発生している期間には、
複数の電動バルブを所定時間ずつ順次サイクリックに開
くように複数の電動バルブを開閉動作させるように構成
たことを特徴とする。
In a water supply apparatus for supplying water to a plurality of buildings, an electric valve that opens and closes in response to an electric signal is provided in a water distribution section to each of the buildings. Each electric motor responds to the water supply request signal from
Valve control means for outputting a signal for controlling the opening and closing of the valve
The provided a plurality of feed water pump to perform an operation to pump water to the water distribution unit cyclically <br/> provided, operating controls to sequentially cyclically a plurality of the water supply pump in response to a water supply request signal Water The apparatus, wherein the valve control means comprises a plurality of buildings.
During the period when the water supply request signal from
Multiple electric valves are opened cyclically in sequence for a predetermined time.
To open and close multiple electric valves
Characterized in that it was.

【0016】[0016]

【0017】請求項9記載の給水装置は、バルブ制御手
段を、渇水信号が入力された時に、渇水信号を出力した
建物内へ水を供給する電動バルブを優先的に開くように
構成している。
According to a ninth aspect of the present invention, when the drought signal is input, the valve control means is configured to preferentially open the electric valve for supplying water to the building that has output the drought signal. .

【0018】[0018]

【作用】請求項1記載の構成によれば、常時は、補助給
水ポンプの出力部が任意に選択された一つの建物に対応
した給水ポンプの出力部にのみ連通するように一つのバ
ルブを開き残りのバルブを閉じる。このときに、補助給
水ポンプと選択された一つの建物に対応した給水ポンプ
とを対にして選択された建物からの給水要求信号に応答
して交互に動作させる。残りの建物に対応した給水ポン
プは、その建物からの給水要求信号に応答して単独動作
させる。
According to the structure of the first aspect, one valve is normally opened so that the output of the auxiliary water supply pump communicates only with the output of the water supply pump corresponding to one arbitrarily selected building. Close the remaining valves. At this time, the auxiliary water supply pump and the water supply pump corresponding to the selected one building are paired and alternately operated in response to a water supply request signal from the selected building. The water supply pumps corresponding to the remaining buildings are independently operated in response to a water supply request signal from the building.

【0019】また、建物毎の給水ポンプの何れか1台が
故障や異常等を生じて給水できなくなった時には、渇水
信号を出力した建物に対応した一つのバルブを開き残り
の建物に対応した残りのバルブを閉じる。補助給水ポン
プは、渇水信号を出力した建物からの給水要求信号に応
答して単独動作させる。残りの建物に対応した給水ポン
プは、その建物からの給水要求信号に応答して単独動作
させる。
When one of the water supply pumps for each building fails or becomes abnormal due to a failure or abnormality, one valve corresponding to the building that outputs the drought signal is opened, and the remaining valve corresponding to the remaining building is opened. Close the valve. The auxiliary water pump operates alone in response to a water supply request signal from the building that has output the drought signal. The water supply pumps corresponding to the remaining buildings are independently operated in response to a water supply request signal from the building.

【0020】請求項2記載の構成によれば、常時は選定
された一つの建物に対応した給水ポンプの出力部に対し
て補助給水ポンプの出力部を連通させるように一つの電
動バルブが自動的に開くとともに残りの電動バルブが自
動的に閉じる。このときに、補助給水ポンプと選択され
た一つの建物に対応した給水ポンプとを対にして選択さ
れた建物からの給水要求信号に応答して交互に動作させ
る。残りの建物に対応した給水ポンプは、その建物から
の給水要求信号に応答して単独動作させる。
According to the second aspect of the present invention, one electric valve is automatically operated so that the output of the auxiliary water supply pump communicates with the output of the water supply pump corresponding to the selected one building at all times. And the remaining electric valves close automatically. At this time, the auxiliary water supply pump and the water supply pump corresponding to the selected one building are paired and alternately operated in response to a water supply request signal from the selected building. The water supply pumps corresponding to the remaining buildings are independently operated in response to a water supply request signal from the building.

【0021】また、各建物からの渇水信号の入力に応答
して渇水信号を出力した建物に対応した一つの電動バル
ブが自動的に開き残りの建物に対応した残りの電動バル
ブが自動的に閉じる。このときに、補助給水ポンプを渇
水信号を出力した建物からの給水要求信号に応答して単
独動作させる。残りの建物に対応した給水ポンプは、そ
の建物からの給水要求信号に応答して単独動作させる。
In addition, in response to the input of the drought signal from each building, one electric valve corresponding to the building that has output the drought signal is automatically opened, and the other electric valves corresponding to the remaining buildings are automatically closed. . At this time, the auxiliary water pump is operated alone in response to the water supply request signal from the building that has output the drought signal. The water supply pumps corresponding to the remaining buildings are independently operated in response to a water supply request signal from the building.

【0022】請求項3記載の構成によれば、常時は主バ
ルブを開き、連結バルブを閉じる。このときに、各建物
からの給水要求信号に応答して各建物に対応した給水ポ
ンプを動作させる。また、建物毎の給水ポンプの何れか
1台が故障や異常等を生じて給水できなくなった時に
は、渇水信号を出力した建物に対応した給水ポンプの出
力部に結合した連結バルブを開き、被連結側の給水ポン
プの主バルブを閉じる。このときに、渇水信号を出力し
た建物からの給水要求信号に応答して被連結側の給水ポ
ンプを動作させる。
According to the third aspect of the present invention, the main valve is normally opened and the connection valve is closed. At this time, a water supply pump corresponding to each building is operated in response to a water supply request signal from each building. Also, when one of the water supply pumps for each building fails or becomes abnormal due to a failure or abnormality, the connection valve connected to the output part of the water supply pump corresponding to the building that output the drought signal is opened and connected. Close the main valve of the side water pump. At this time, the connected water supply pump is operated in response to the water supply request signal from the building that has output the drought signal.

【0023】請求項4記載の構成によれば、常時は主バ
ルブが自動的に開き、連結バルブが自動的に閉じる。こ
のときに、各建物からの給水要求信号に応答して各建物
に対応した給水ポンプを動作させる。また、各建物から
の渇水信号の入力に応答して渇水信号を出力した建物に
対応した給水ポンプの出力部に結合した連結バルブが自
動的に開き、被連結側の給水ポンプの主バルブが自動的
に閉じる。このときに、渇水信号を出力した建物からの
給水要求信号に応答して被連結側の給水ポンプを動作さ
せる。
According to the configuration of the fourth aspect, the main valve is automatically opened and the connection valve is automatically closed at all times. At this time, a water supply pump corresponding to each building is operated in response to a water supply request signal from each building. In addition, in response to the input of the drought signal from each building, the connection valve connected to the output of the water supply pump corresponding to the building that outputs the drought signal automatically opens, and the main valve of the water supply pump on the connected side is automatically turned on. Close. At this time, the connected water supply pump is operated in response to the water supply request signal from the building that has output the drought signal.

【0024】請求項5記載の構成によれば、渇水信号を
出力した建物からの給水要求信号が消滅すると、被連結
側の給水ポンプの出力部に設けた主バルブが自動的に開
き、連結バルブが自動的に閉じる。このときに、被連結
側の建物からの給水要求信号に応答して被連結側の給水
ポンプを動作させる。この結果、被連結側の建物への給
水が支障なく行われる。
According to the fifth aspect of the present invention, when the water supply request signal from the building that outputs the drought signal disappears, the main valve provided at the output part of the water supply pump on the connected side automatically opens, and the connection valve is opened. Automatically closes. At this time, the water supply pump on the connected side is operated in response to a water supply request signal from the building on the connected side. As a result, water supply to the connected building is performed without any trouble.

【0025】請求項6記載の構成によれば、異常モード
が保持されている期間中は、バルブ制御手段より被連結
側の給水ポンプの出力部に設けた主バルブを開いて連結
バルブを閉じる信号を出力し被連結側の建物からの給水
要求信号に応答して被連結側の給水ポンプを動作させる
第1の動作と、バルブ制御手段より被連結側の給水ポン
プの出力部に設けた主バルブを閉じて連結バルブを開く
信号を出力し渇水信号を出力した建物からの給水要求信
号に応答して被連結側の給水ポンプを動作させる第2の
動作とが選択的に行われることになり、渇水信号を出力
した建物への給水と被連結側の建物への給水が対等な関
係で行われることになる。
According to the sixth aspect of the present invention, while the abnormal mode is maintained, the valve control means opens the main valve provided at the output of the feed water pump on the connected side and closes the connected valve. And a first operation for operating the water supply pump on the connected side in response to a water supply request signal from the building on the connected side, and a main valve provided at an output portion of the water supply pump on the connected side by valve control means. And the second operation of operating the connected-side water supply pump in response to the water supply request signal from the building that outputs the signal that opens the connection valve and outputs the drought signal, and that is selectively performed, Water supply to the building that has output the drought signal and water supply to the connected building are performed on an equal relationship.

【0026】請求項7記載の構成によれば、異常モード
を保持されている期間中は、バルブ制御手段より被連結
側の給水ポンプの出力部に設けた主バルブを開いて連結
バルブを閉じる信号を出力し被連結側の建物からの給水
要求信号に応答して被連結側の給水ポンプを動作させる
第1の動作と、バルブ制御手段より被連結側の給水ポン
プの出力部に設けた主バルブを閉じて連結バルブを開く
信号を出力し渇水信号を出力した建物からの給水要求信
号に応答して被連結側の給水ポンプを動作させる第2の
動作とが選択的に行われることになる。また、第1の動
作の実行中に渇水信号を出力した建物からの給水要求信
号が発生したときには第2の動作が優先して実行され、
第2の動作の終了後に第1の動作が再開し、第2の動作
の実行中に被連結側の建物からの給水要求信号が発生し
たときには第1の動作が優先して実行され、第1の動作
の終了後に第2の動作が再開する。この結果、渇水信号
を出力した建物への給水中に被連結側の建物が渇水状態
となったり、被連結側の建物への給水中に渇水信号を出
力した建物が渇水状態となるおそれを少なくできる。
According to the seventh aspect of the present invention, during the period in which the abnormal mode is maintained, the valve control means opens the main valve provided at the output part of the feedwater pump on the connected side and closes the connected valve. And a first operation for operating the water supply pump on the connected side in response to a water supply request signal from the building on the connected side, and a main valve provided at an output portion of the water supply pump on the connected side by valve control means. The second operation of operating the water supply pump on the connected side in response to the water supply request signal from the building that has output the signal to open the connection valve and output the drought signal to close the connection valve is selectively performed. Further, when a water supply request signal from a building that has output a drought signal during execution of the first operation is generated, the second operation is executed with priority,
After completion of the second operation, the first operation is resumed. When a water supply request signal from the connected building is generated during execution of the second operation, the first operation is executed with priority, and the first operation is executed. After the end of the operation, the second operation is restarted. As a result, it is less likely that the connected building will be in a drought state during the water supply to the building that has output the drought signal, and that the building that has output the drought signal during the water supply to the connected building will be in a drought state. it can.

【0027】請求項8記載の構成によれば、給水要求信
号に応答して複数台の給水ポンプが順次サイクリックに
動作して給水を行うことになる。また、各建物からの給
水要求信号に応答して、給水要求信号を発生した建物へ
給水を行うための電動バルブが自動的に開くことにな
る。さらに、複数の建物からの給水要求信号が重なって
発生している期間には、複数の電動バルブを所定時間ず
つ順次サイクリックに開くように複数のバルブが開閉動
作するので、複数の建物の何れか一つへ給水中に他の
何れかの建物が渇水状態となるおそれを少なくできる。
また、複数の建物からの給水要求信号が重なって発生す
る場合でも、一つの建物について給水可能な能力を持つ
だけの小容量の給水ポンプを用いて複数の建物への給水
を行うことができ、したがって低い設備コストで複数の
建物からの同時の給水要求に応えることができる。
[0027] According to the configuration of claim 8, it would supply the water operates to sequentially cyclically the plurality of the water supply pump in response to a water supply request signal. In addition, in response to the water supply request signal from each building , the electric valve for supplying water to the building that has generated the water supply request signal automatically opens. Further, during a period in which water supply request signals from a plurality of buildings overlap, a plurality of valves are opened and closed so as to sequentially open a plurality of electric valves sequentially for a predetermined period of time. It is possible to reduce the risk that any of the other buildings will be in a drought state during the water supply to one of the buildings.
Water supply request signals from multiple buildings may overlap.
Have the capacity to supply water for one building
Water supply to multiple buildings using only a small capacity water supply pump
Can therefore be performed at a lower equipment cost
It can respond to simultaneous water supply requests from buildings.

【0028】請求項9記載の構成によれば、渇水信号が
入力された時に、渇水信号を出力した建物内へ水を供給
する電動バルブが優先的に開くので、渇水信号を発生し
た建物の渇水を防止できる。
According to the configuration of the ninth aspect , when the drought signal is input, the electric valve that supplies water into the building that has output the drought signal opens preferentially, so that the drought of the building that has generated the drought signal is output. Can be prevented.

【0029】[0029]

【実施例】【Example】

〔第1の実施例〕この発明の第1の実施例を図1ないし
図5に基づいて説明する。この給水装置は、図1および
図2に示すように、複数、例えば3戸の建物1〜3内に
水を供給するものであり、建物1〜3毎に、各建物1〜
3からの給水要求信号に応答して動作し建物1〜3内に
水を供給する給水ポンプ4〜6を各々設置し、建物1〜
3毎の給水ポンプ4〜6とは別に補助給水ポンプ7を設
け、この補助給水ポンプ7の出力部を各々手動のバルブ
8〜10を介して建物1〜3毎の給水ポンプ4〜6の出
力部に連結し、補助給水ポンプ7と任意に選択された一
つの建物に対応した給水ポンプ例えば4と対にして選択
された一つの建物1からの給水要求信号に応答して交互
に動作させるポンプ制御手段(図示せず)を設けてい
る。このポンプ制御手段は、図2の制御盤20内に設け
られている。
[First Embodiment] A first embodiment of the present invention will be described with reference to FIGS. As shown in FIG. 1 and FIG. 2, this water supply device supplies water to a plurality of, for example, three buildings 1 to 3.
The water supply pumps 4 to 6 which operate in response to the water supply request signal from 3 and supply water into the buildings 1 to 3 are respectively installed, and
An auxiliary water supply pump 7 is provided separately from the water supply pumps 4 to 6 for each of the three buildings. And a pump which is alternately operated in response to a water supply request signal from one selected building 1 in combination with an auxiliary water supply pump 7 and a water supply pump corresponding to one arbitrarily selected building, for example. Control means (not shown) is provided. This pump control means is provided in the control panel 20 of FIG.

【0030】給水ポンプ4〜6および補助給水ポンプ7
は、市水道11から水の供給を受ける各建物1〜3につ
いて共通の受水槽12に蓄えられた水を、主配管13〜
15および補助配管19を通して各建物1〜3の屋上等
に個別に設けられた高架水槽16〜18へ供給するもの
である。受水槽12および高架水槽16〜18は、それ
ぞれ水位検出用電極装置21〜24が設けられている。
受水槽12の水位検出用電極装置21は、1本の共通電
極(一番長い電極)と3本の水位検出電極との合わせて
4本の電極からなり、渇水レベル、減水レベル、満水レ
ベルを検出し、その水位検出信号を制御盤20へ供給す
るようになっており、制御盤20により受水槽12の水
位を減水レベルおよび満水レベルの間に制御するととも
に、水位が渇水レベルまで下がったときに警報を発した
り、あるいは給水ポンプ4〜6および補助給水ポンプ7
の動作を強制的に停止させる等して、給水ポンプ4〜6
および補助給水ポンプ7の空運転を防止するようにして
いる。
Water supply pumps 4 to 6 and auxiliary water supply pump 7
The water stored in the common water receiving tank 12 for each of the buildings 1 to 3 supplied with water from the city water supply 11 is supplied to the main piping 13 to
The water is supplied to elevated water tanks 16 to 18 individually provided on the roof of each of the buildings 1 to 3 through the auxiliary pipes 15 and 15. The water receiving tank 12 and the elevated water tanks 16 to 18 are provided with water level detecting electrode devices 21 to 24, respectively.
The water level detecting electrode device 21 of the water receiving tank 12 includes four electrodes including one common electrode (the longest electrode) and three water level detecting electrodes, and controls the drought level, the reduced water level, and the full water level. The control panel 20 controls the water level of the water receiving tank 12 between the reduced water level and the full water level, and when the water level falls to the drought level. Alarm, or water supply pumps 4 to 6 and auxiliary water supply pump 7
Operation of the water supply pumps 4-6
In addition, the idle operation of the auxiliary water pump 7 is prevented.

【0031】また、高架水槽16〜18の水位検出用電
極装置22〜24は、それぞれ1本の共通電極(一番長
い電極)と4本の水位検出電極との合わせて本の電極
からなり、渇水レベル、減水レベル、満水レベル、異常
増水レベルを検出し、その水位検出信号を制御盤20へ
供給するようになっており、制御盤20により、高架水
槽16〜18の水位を減水レベルおよび満水レベルの間
に制御するとともに、水位が渇水レベルまで下がったと
き、および異常増水レベルを超えたときに警報を発した
り、あるいは、渇水レベルより下がったときに、後述す
るように、補助給水ポンプ7を使用して、水位が渇水レ
ベルより下がった高架水槽、例えば18へ水を供給する
等の動作を行う。
The water level detecting electrode devices 22 to 24 of the elevated water tanks 16 to 18 are each composed of five electrodes including one common electrode (longest electrode) and four water level detecting electrodes. , A drought level, a low water level, a full water level, and an abnormally high water level, and supplies a water level detection signal to the control panel 20. The control panel 20 reduces the water level of the elevated water tanks 16 to 18 to the low water level and the low water level. While controlling during the full water level, when the water level falls to the drought level and raises an alarm when the water level exceeds the abnormally high water level, or when the water level falls below the drought level, the auxiliary water supply pump will be described later. 7 is used to perform operations such as supplying water to an elevated water tank, for example, 18 whose water level has fallen below the drought level.

【0032】この給水装置では、常時は、補助給水ポン
プ7の出力部が任意に選択された一つの建物1に対応し
た給水ポンプ4の出力部にのみ連通するように一つのバ
ルブ8を開き残りのバルブ9,10を閉じる。このとき
に、補助給水ポンプ7と選択された一つの建物1に対応
した給水ポンプ4とを対にして選択された建物1からの
給水要求信号に応答して交互に動作させる。つまり、建
物1からの給水要求信号が発生する毎に、給水ポンプ4
と補助給水ポンプ7とを交互に運転して、受水槽12か
ら主配管13を通して高架水槽16へ水を供給する。残
りの建物2,3に対応した給水ポンプ5,6は、その建
物2,3からの給水要求信号に応答して単独動作させ、
受水槽12からそれぞれ主配管14,15を通して高架
水槽17,18へ水を供給する。給水要求信号は、従来
例でも述べたように、高架水槽16〜18内の水位が減
水レベルを下回ったときに立ち上がり、満水レベルを超
えたときに立ち下がることになる。つまり、高架水槽1
6〜18内の水位が減水レベルを下回ったあと、つぎに
満水レベルを超えるまでの期間給水要求信号が発生する
ことになる。したがって、高架水槽16〜18の水位
は、減水レベルから満水レベルまでの範囲に保たれる。
In this water supply apparatus, one valve 8 is normally opened so that the output part of the auxiliary water supply pump 7 communicates only with the output part of the water supply pump 4 corresponding to one arbitrarily selected building 1. Valves 9 and 10 are closed. At this time, the auxiliary water supply pump 7 and the water supply pump 4 corresponding to the selected one building 1 are paired and alternately operated in response to a water supply request signal from the selected building 1. That is, every time a water supply request signal from the building 1 is generated, the water supply pump 4
The auxiliary water supply pump 7 and the auxiliary water supply pump 7 are alternately operated to supply water from the water receiving tank 12 to the elevated water tank 16 through the main pipe 13. The water supply pumps 5 and 6 corresponding to the remaining buildings 2 and 3 are operated independently in response to a water supply request signal from the buildings 2 and 3,
Water is supplied from the water receiving tank 12 to the elevated water tanks 17 and 18 through the main pipes 14 and 15, respectively. As described in the conventional example, the water supply request signal rises when the water level in the elevated water tanks 16 to 18 falls below the reduced water level, and falls when the water level exceeds the full water level. That is, the elevated water tank 1
After the water level in 6 to 18 falls below the water reduction level, a water supply request signal is generated for a period until the water level exceeds the full water level. Therefore, the water level of the elevated water tanks 16 to 18 is maintained in a range from the reduced water level to the full water level.

【0033】また、建物1〜3毎の給水ポンプ4〜6の
何れか1台が故障や異常等を生じて給水できなくなって
水位が渇水レベルまで下がった時には、渇水信号を出力
した建物例えば3に対応した一つのバルブ10を開き残
りの建物1,2に対応した残りのバルブ8,9を閉じ
る。補助給水ポンプ7は、渇水信号を出力した建物3か
らの給水要求信号に応答して単独動作させ、建物3の高
架水槽18へは補助給水ポンプ7により受水槽12から
補助配管19および主配管15を通して水を供給し、高
架水槽18の水位を減水レベルから満水レベルまでの範
囲に保つ。残りの建物1,2に対応した給水ポンプ4,
5は、その建物1,2からの給水要求信号に応答して単
独動作させ、建物1,2の高架水槽16,17へは給水
ポンプ4,5により受水槽12から主配管13,14を
それぞれ通して水を供給し、高架水槽16,17の水位
を減水レベルから満水レベルまでの範囲に保つ。
When one of the water supply pumps 4 to 6 for each of the buildings 1 to 3 fails or fails to supply water due to a failure or abnormality, and the water level falls to a drought level, the building that has output a drought signal, for example, 3 Is opened and the remaining valves 8, 9 corresponding to the remaining buildings 1, 2 are closed. The auxiliary water supply pump 7 is operated independently in response to a water supply request signal from the building 3 that has output the drought signal. The auxiliary water supply pump 7 supplies the elevated water tank 18 of the building 3 from the water receiving tank 12 to the auxiliary pipe 19 and the main pipe 15. To maintain the water level in the elevated water tank 18 in a range from a reduced water level to a full water level. Water pumps 4, corresponding to the remaining buildings 1, 2
5 is operated independently in response to a water supply request signal from the buildings 1 and 2, and the main pipes 13 and 14 are respectively connected to the elevated water tanks 16 and 17 of the buildings 1 and 2 from the water receiving tank 12 by the water supply pumps 4 and 5. The water level is supplied to the elevated water tanks 16 and 17 to keep the water level in a range from a reduced water level to a full water level.

【0034】図3に、図1および図2に示した給水装置
の制御盤20の一例のブロック図を示す。図3におい
て、31〜34は、水位検出用電極装置21〜24を接
続した水位検出手段、35〜37は高架水槽16〜18
の渇水、異常増水等の異常を個別に表示する異常表示手
段、38は高架水槽16〜18の渇水、異常増水等の異
常発生時に警報音を発する共通の警報手段である。39
は故障した給水ポンプを設定する故障対応スイッチ群で
あり、40は水位検出手段32〜34,故障対応スイッ
チ群39の出力信号を信号処理する信号処理手段であ
る。41〜44は信号処理手段40の出力信号に基づい
て給水ポンプ4〜6および補助給水ポンプ7を駆動する
ポンプ駆動手段である。
FIG. 3 is a block diagram showing an example of the control panel 20 of the water supply apparatus shown in FIGS. In FIG. 3, 31 to 34 are water level detecting means connected to the water level detecting electrode devices 21 to 24, and 35 to 37 are elevated water tanks 16 to 18.
Abnormality display means 38 for individually displaying abnormalities such as drought, abnormally high water, and the like, and 38 is a common alarm means for issuing an alarm sound when abnormalities such as drought, abnormally high water, etc. of the elevated water tanks 16 to 18 occur. 39
Reference numeral denotes a failure handling switch group for setting a failed water supply pump, and reference numeral 40 denotes signal processing means for processing the output signals of the water level detection means 32 to 34 and the failure handling switch group 39. Reference numerals 41 to 44 denote pump driving means for driving the water supply pumps 4 to 6 and the auxiliary water supply pump 7 based on the output signal of the signal processing means 40.

【0035】図4に、図3における故障対応スイッチ群
39および信号処理手段40の一例の回路図を示す。こ
の回路では、常時は給水ポンプ4と補助給水ポンプ7と
を交互運転し、給水ポンプ5,6を単独運転する構成と
なっている。故障対応スイッチ群39の設定により故障
した1台の給水ポンプ例えば6のみ運転を停止するとと
もに、補助給水ポンプ7を給水ポンプ6に代えて作動さ
せることができるような回路構成となっている。
FIG. 4 is a circuit diagram showing an example of the failure handling switch group 39 and the signal processing means 40 in FIG. In this circuit, the water supply pump 4 and the auxiliary water supply pump 7 are alternately operated at all times, and the water supply pumps 5 and 6 are independently operated. The circuit configuration is such that the operation of only one water supply pump, for example, 6 which has failed due to the setting of the failure handling switch group 39 is stopped, and the auxiliary water supply pump 7 can be operated in place of the water supply pump 6.

【0036】図4において、S1 はそれぞれ高架水槽1
6への給水を要求する給水要求信号が立ち上がった状態
でオンとなり、給水要求信号が立ち下がった状態でオフ
となるスイッチである。同様に、S2 は高架水槽17へ
の給水要求信号に対応し、S 3 は高架水槽18への給水
要求信号に対応するスイッチである。S4 〜S7 は各々
給水ポンプ4〜6および補助給水ポンプ7のうちの故障
した1台のみを設定する故障対応スイッチであり、これ
らは何れか1個のみオンにできる多連プッシュスイッチ
構成で、故障対応スイッチS4 〜S7 で図3の故障対応
スイッチ群39を構成している。
In FIG. 4, S1Is an elevated water tank 1
Water supply request signal for requesting water supply to 6 has risen
To turn on, and to turn off when the water supply request signal falls
Switch. Similarly, STwoGoes to elevated water tank 17
Corresponding to the water supply request signal of ThreeIs the water supply to the elevated water tank 18
A switch corresponding to the request signal. SFour~ S7Are each
Failure of water supply pumps 4 to 6 and auxiliary water supply pump 7
This is a failure response switch that sets only one switch.
Are multiple push switches that can be turned on only one of them
With the configuration, the failure handling switch SFour~ S7For the failure of Fig. 3
The switch group 39 is constituted.

【0037】高架水槽16から渇水信号が出力されたと
きは、給水ポンプ4および補助給水ポンプ7の何れかが
故障と考えられるので、故障した方を識別し、給水ポン
プ4および補助給水ポンプ7のうちの故障した方に対応
する故障対応スイッチS4 またはS7 の何れかをオンに
手動設定する。高架水槽17から渇水信号が出力された
ときは、給水ポンプ5が故障と考えられるので、給水ポ
ンプ5に対応する故障対応スイッチS5 をオンに手動設
定する。同様に、高架水槽18から渇水信号が出力され
たときは、給水ポンプ6が故障と考えられるので、給水
ポンプ6に対応する故障対応スイッチS6 をオンに手動
設定する。
When the drought signal is output from the elevated water tank 16, it is considered that either the water supply pump 4 or the auxiliary water supply pump 7 is out of order. out of the failed whichever of failure countermeasure switch S 4 or S 7 corresponding to the manually set to oN. When drought signal from the elevated water tank 17 is output, since the feed water pump 5 is considered a failure, manually set to ON failure countermeasure switch S 5 corresponding to the feed water pump 5. Similarly, when the drought signal from elevated tank 18 is output, since the feed water pump 6 is considered a failure, manually set the failure corresponding switch S 6 corresponding to the feed water pump 6 on.

【0038】FFは、高架水槽16への給水要求信号
(スイッチS1 のオン)が立ち上がる毎に給水ポンプ4
と補助給水ポンプ7とを交互に動作させるためのフリッ
プフロップである。X1 〜X4 はそれぞれ給水ポンプ4
〜6および補助給水ポンプ7を駆動するリレーである。
NA1 〜NA4 は故障対応スイッチS4 〜S7 がオフの
ときに開くNANDゲートである。AN1 〜AN6 はそ
れぞれANDゲート、OR1 〜OR 3 はそれぞれORゲ
ート、IN1 〜IN3 はそれぞれ反転回路、D1 〜D4
はそれぞれダイオードである。
FF is a water supply request signal to the elevated water tank 16.
(Switch S1Water pump 4 each time
And the auxiliary water supply pump 7 to operate alternately.
It is a flop. X1~ XFourIs a water supply pump 4
6 and a relay for driving the auxiliary water supply pump 7.
NA1~ NAFourIs the failure response switch SFour~ S7Is off
A NAND gate that sometimes opens. AN1~ AN6Haso
AND gate, OR respectively1~ OR ThreeAre OR
, IN1~ INThreeIs an inverting circuit, D1~ DFour
Are diodes.

【0039】図4の回路の動作について簡単に説明す
る。給水ポンプ4〜6および補助給水ポンプ7が全て正
常であるときは、故障対応スイッチS4 〜S7 を全てオ
フにしておく。この状態では、NANDゲートNA 1
NA4 は全て開いている。また、ANDゲートAN1
AN4 〜AN6 は全て閉じている。この結果、スイッチ
1 がオンとなる毎に、フリップフロップFFで何れか
一方が選択されるリレーX1 およびX4 の何れか一方が
動作して、給水ポンプ4および補助給水ポンプ7が交互
に運転され、高架水槽16に給水される。また、スイッ
チS2 がオンとなる毎にリレーX2 が動作して給水ポン
プ5が運転され、スイッチS3 がオンとなる毎にリレー
3 が動作して給水ポンプ6が運転され、高架水槽1
7,18にそれぞれ給水される。
The operation of the circuit shown in FIG. 4 will be briefly described.
You. Water supply pumps 4 to 6 and auxiliary water supply pump 7 are all correct.
When it is normal, the failure handling switch SFour~ S7All
Keep it. In this state, the NAND gate NA 1~
NAFourAre all open. Also, an AND gate AN1,
ANFour~ AN6Are all closed. As a result, the switch
S1Is turned on by flip-flop FF
Relay X with one selected1And XFourOne of
Operate, water supply pump 4 and auxiliary water supply pump 7 alternate
And water is supplied to the elevated water tank 16. Also, switch
Chi STwoRelay X each time is turned onTwoWorking water pon
Is operated and the switch SThreeRelay is turned on every time
XThreeOperates to operate the water supply pump 6 and the elevated water tank 1
Water is supplied to 7, 18 respectively.

【0040】給水ポンプ4が故障したときには、故障対
応スイッチS4 のみオンにし、残りをオフにする。この
状態では、NANDゲートNA1 が閉じ、またANDゲ
ートAN4 が開く。この結果、スイッチS1 がオンとな
る毎に、リレーX4 が動作して、補助給水ポンプ7が単
独運転され、高架水槽16に給水される。また、スイッ
チS2 がオンとなる毎にリレーX2 が動作して給水ポン
プ5が運転され、スイッチS3 がオンとなる毎にリレー
3 が動作して給水ポンプ6が運転され、高架水槽1
7,18にそれぞれ給水される。
[0040] When the water supply pump 4 has failed, to turn on only the failure corresponding switch S 4, to turn off the rest. In this state, NAND gate NA 1 is closed, also opens AND gate AN 4. As a result, each time the switch S 1 is turned on, the relay X 4 is operated, the auxiliary water supply pump 7 is operated independently, and water is supplied to the elevated water tank 16. Also, each time the switch S 2 is turned on, the relay X 2 is operated to operate the water supply pump 5, and each time the switch S 3 is turned on, the relay X 3 is operated to operate the water supply pump 6. 1
Water is supplied to 7, 18 respectively.

【0041】給水ポンプ5が故障したときには、故障対
応スイッチS5 のみオンにし、残りをオフにする。この
状態では、NANDゲートNA2 が閉じ、またANDゲ
ートAN1 ,AN5 が開く。この結果、スイッチS1
オンとなる毎に、リレーX1が動作して、給水ポンプ4
が単独運転され、高架水槽16に給水される。また、ス
イッチS2 がオンとなる毎にリレーX4 が動作して補助
給水ポンプ7が運転され、スイッチS3 がオンとなる毎
にリレーX3 が動作して給水ポンプ6が運転され、高架
水槽17,18にそれぞれ給水される。
[0041] When the water supply pump 5 has failed, to turn on only the failure corresponding switch S 5, to turn off the rest. In this state, closing the NAND gate NA 2 is also opened AND gate AN 1, AN 5. As a result, each time the switch S 1 is turned on, the relay X 1 operates and the water supply pump 4
Is operated independently, and water is supplied to the elevated water tank 16. The auxiliary feedwater pump 7 relay X 4 each time the switch S 2 is turned on is operated is operated, the water supply pump 6 is operated relay X 3 each time the switch S 3 is turned on is operated, the elevated Water is supplied to the water tanks 17 and 18, respectively.

【0042】給水ポンプ6が故障したときには、故障対
応スイッチS6 のみオンにし、残りをオフにする。この
状態では、NANDゲートNA3 が閉じ、またANDゲ
ートAN1 ,AN6 が開く。この結果、スイッチS1
オンとなる毎に、リレーX1が動作して、給水ポンプ4
が単独運転され、高架水槽16に給水される。また、ス
イッチS2 がオンとなる毎にリレーX2 が動作して給水
ポンプ5が運転され、スイッチS3 がオンとなる毎にリ
レーX4 が動作して補助給水ポンプ7が運転され、高架
水槽17,18にそれぞれ給水される。
[0042] When the water supply pump 6 has failed, to turn on only the failure corresponding switch S 6, to turn off the rest. In this state, it closed NAND gate NA 3, also the AND gate AN 1, AN 6 is opened. As a result, each time the switch S 1 is turned on, the relay X 1 operates and the water supply pump 4
Is operated independently, and water is supplied to the elevated water tank 16. Also, the water supply pump 5 is operated by operating the relay X 2 is each time the switch S 2 is turned on, the auxiliary feedwater pumps 7 relay X 4 each time the switch S 3 is turned on is operated is operated, elevated Water is supplied to the water tanks 17 and 18, respectively.

【0043】補助給水ポンプ7が故障したときには、故
障対応スイッチS7 のみオンにし、残りをオフにする。
この状態では、NANDゲートNA4 が閉じ、またAN
DゲートAN1 が開く。この結果、スイッチS1 がオン
となる毎に、リレーX1 が動作して、給水ポンプ4が単
独運転され、高架水槽16に給水される。また、スイッ
チS2 がオンとなる毎にリレーX2 が動作して給水ポン
プ5が運転され、スイッチS3 がオンとなる毎にリレー
3 が動作して給水ポンプ6が運転され、高架水槽1
7,18にそれぞれ給水される。
[0043] When the auxiliary feedwater pump 7 has failed, the ON failure corresponding switches S 7 only to turn off the rest.
In this state, NAND gate NA 4 is closed and
D gate AN 1 is open. As a result, every time the switch S 1 is turned on, the relay X 1 is operated, the water supply pump 4 is operated independently, and the water is supplied to the elevated water tank 16. Also, each time the switch S 2 is turned on, the relay X 2 is operated to operate the water supply pump 5, and each time the switch S 3 is turned on, the relay X 3 is operated to operate the water supply pump 6. 1
Water is supplied to 7, 18 respectively.

【0044】図5に図4の各部のタイムチャートを示
す。同図(a)は高架水槽16の水位を示し、同図
(b)はスイッチS1 のオンオフ状態、つまり高架水槽
16への給水要求信号のレベルを示している。同図
(c)高架水槽17の水位を示し、同図(d)はスイッ
チS2 のオンオフ状態、つまり高架水槽17への給水要
求信号のレベルを示している。同図(e),(f)は故
障対応スイッチS4 ,S5 のオンオフ状態を示し、ハイ
レベルが故障対応スイッチS4 ,S5 がオフの状態で、
ローレベルが故障対応スイッチS4 ,S5 がオンの状態
である。同図(g),(h)はフリップフロップFFの
出力Qおよび反転出力/Qを示し、同図(i),(j)
はANDゲートAN2 ,AN3 の出力を示し、同図
(k)はORゲートOR 3 の出力を示し、同図(l)は
ANDゲートAN1 の出力を示し、同図(m)はORゲ
ートOR1 の出力を示し、同図(n),(o)はAND
ゲートAN4 ,AN5 の出力を示し、同図(p)はOR
ゲートOR2 の出力を示し、同図(q),(r),
(s)は、NANDゲートNA1 ,NA2 ,NA4 の出
力を示している。
FIG. 5 shows a time chart of each part in FIG.
You. FIG. 3A shows the water level of the elevated water tank 16.
(B) Switch S1ON / OFF state, that is, elevated water tank
16 shows the level of a water supply request signal to the water supply request signal 16. Same figure
(C) The water level of the elevated water tank 17 is shown, and FIG.
Chi STwoON / OFF state, that is, water supply to the elevated water tank 17 is required.
It shows the level of the request signal. Figures (e) and (f) show the late
Obstacle switch SFour, SFiveIndicates the on / off state of the
Level is failure switch SFour, SFiveIs off,
Low-level failure SFour, SFiveIs on
It is. (G) and (h) of FIG.
(I) and (j) in FIG.
Is the AND gate ANTwo, ANThreeThe output of
(K) OR gate OR ThreeFIG. 1 (l) shows the output of
AND gate AN1(M) shows the output of the OR gate.
Auto OR1(N) and (o) of FIG.
Gate ANFour, ANFiveThe output (p) of FIG.
Gate ORTwo(Q), (r),
(S) shows the NAND gate NA1, NATwo, NAFourOut of
Showing power.

【0045】図5の前半部は、高架水槽16へ給水ポン
プ4および補助給水ポンプ7を使用して給水し、高架水
槽17へ給水ポンプ5を使用して給水している途中で、
給水ポンプ4が故障して、補助給水ポンプ7単独で高架
水槽16へ給水するように切り替えたときのタイムチャ
ートを示している。図5の後半部は、高架水槽16へ給
水ポンプ4および補助給水ポンプ7を使用して給水し、
高架水槽17へ給水ポンプ5を使用して給水している途
中で給水ポンプ5が故障して補助給水ポンプ7で高架水
槽17へ給水するように切り替えたときにタイムチャー
トを示している。
In the first half of FIG. 5, water is supplied to the elevated water tank 16 using the water supply pump 4 and the auxiliary water supply pump 7, and water is supplied to the elevated water tank 17 using the water supply pump 5.
The time chart when the water supply pump 4 breaks down and the auxiliary water supply pump 7 is switched to supply water to the elevated water tank 16 by itself is shown. 5 supplies water to the elevated water tank 16 using the water supply pump 4 and the auxiliary water supply pump 7,
A time chart is shown when the water supply pump 5 breaks down while supplying water to the elevated water tank 17 using the water supply pump 5 and the auxiliary water supply pump 7 switches to supply water to the elevated water tank 17.

【0046】この実施例の給水装置によれば、各建物1
〜3について1台ずつの給水ポンプ4〜6を設ける他
に、全建物1〜3について1台の補助給水ポンプ7を設
けるとともに、補助給水ポンプ7の出力部と各建物1〜
3毎の給水ポンプ4〜6の出力部とを結合するバルブ8
〜10を設けるだけで、つまり少ない給水ポンプ台数で
各建物1〜3への水の供給を安定して行うことができ
る。また、常時は補助給水ポンプ7と1台の給水ポンプ
4とを対にして交互運転を行うので、各建物1〜3毎の
給水ポンプ4〜6だけでなく、補助給水ポンプ7も常に
動作状態に保つことができ、錆や劣化で異常時に補助給
水ポンプ7が動作不良を起こすおそれを少なくすること
ができる。
According to the water supply system of this embodiment, each building 1
In addition to providing one water supply pump 4 to 6 for each of ~ 3, one auxiliary water supply pump 7 is provided for all buildings 1 to 3, and the output section of the auxiliary water supply pump 7 and each building 1 to
A valve 8 for connecting the output of each of the three feed pumps 4 to 6
By simply providing 10 to 10, that is, it is possible to stably supply water to each of the buildings 1 to 3 with a small number of water supply pumps. In addition, since the auxiliary water supply pump 7 and one water supply pump 4 are always operated alternately as a pair, not only the water supply pumps 4 to 6 in each of the buildings 1 to 3 but also the auxiliary water supply pump 7 is always in the operating state. The auxiliary water supply pump 7 can be less likely to malfunction when it is abnormal due to rust or deterioration.

【0047】〔第2の実施例〕 この発明の第2の実施例を図6ないし図8に基づいて説
明する。この給水装置は、図6に示すように、図1の手
動のバルブ8〜10に代えて、電気信号に応答して開閉
する電動バルブ8A,9A,10Aを使用するととも
に、この電動バルブ8A,9A,10Aを開閉駆動する
バルブ制御手段(図示せず)を設け、常時はバルブ制御
手段より選定された一つの建物例えば1に対応した給水
ポンプ4の出力部に対して補助給水ポンプ7の出力部を
連通させるように一つの電動バルブ8Aを開くとともに
残りの電動バルブ9A,10Aを閉じる信号を出力し、
ポンプ制御手段(図示せず)により補助給水ポンプ7と
選択された一つの建物1に対応した給水ポンプ4とを対
にして選択された建物1からの給水要求信号に応答して
交互に動作させるようにし、各建物1〜3からの渇水信
号の入力に応答してバルブ制御手段より渇水信号を出力
した建物例えば3に対応した一つの電動バルブ10Aを
開き残りの建物1,2に対応した残りの電動バルブ8
A,9Aを閉じる信号を出力し、補助給水ポンプ7を渇
水信号を出力した建物3からの給水要求信号に応答して
単独動作させるようにしている。このバルブ制御手段
は、図2の制御盤20A内に設けられている。
[0047] Second Embodiment] will be described based the second embodiment of the present invention in FIGS. 6-8. As shown in FIG. 6, this water supply device uses electric valves 8A, 9A, and 10A that open and close in response to electric signals instead of the manual valves 8 to 10 in FIG. Valve control means (not shown) for opening and closing 9A and 10A is provided, and the output of the auxiliary water supply pump 7 is normally provided to the output section of the water supply pump 4 corresponding to one building, for example, 1 selected by the valve control means. A signal is output to open one electric valve 8A and to close the remaining electric valves 9A and 10A so as to communicate the parts,
The auxiliary water supply pump 7 and the water supply pump 4 corresponding to the selected one building 1 are paired by pump control means (not shown) and alternately operated in response to a water supply request signal from the selected building 1. In this way, one electric valve 10A corresponding to the building, for example, 3 which outputs the drought signal from the valve control means in response to the input of the drought signal from each of the buildings 1 to 3 is opened, and the rest corresponding to the remaining buildings 1, 2 is opened. Electric valve 8
A signal for closing A and 9A is output, and the auxiliary water supply pump 7 is operated independently in response to a water supply request signal from the building 3 that has output the drought signal. This valve control means is provided in the control panel 20A of FIG.

【0048】この給水装置では、常時は選定された一つ
の建物1に対応した給水ポンプ4の出力部に対して補助
給水ポンプ7の出力部を連通させるように一つの電動バ
ルブ8Aが自動的に開くとともに残りの電動バルブ9
A,10Aが自動的に閉じる。このときに、補助給水ポ
ンプ7と選択された一つの建物1に対応した給水ポンプ
4とを対にして選択された建物1からの給水要求信号に
応答して交互に動作させる。残りの建物2,3に対応し
た給水ポンプ5,6は、その建物2,3からの給水要求
信号に応答して単独動作させる。
In this water supply apparatus, one electric valve 8A is automatically operated so that the output of the auxiliary water supply pump 7 is always connected to the output of the water supply pump 4 corresponding to one selected building 1. Open and remaining electric valve 9
A, 10A closes automatically. At this time, the auxiliary water supply pump 7 and the water supply pump 4 corresponding to the selected one building 1 are paired and alternately operated in response to a water supply request signal from the selected building 1. The water supply pumps 5 and 6 corresponding to the remaining buildings 2 and 3 are independently operated in response to a water supply request signal from the buildings 2 and 3.

【0049】また、各建物1〜3からの渇水信号の入力
に応答して渇水信号を出力した建物3に対応した一つの
電動バルブ10Aが自動的に開き残りの建物1,2に対
応した残りの電動バルブ8A,9Aが自動的に閉じる。
このときに、補助給水ポンプ7を渇水信号を出力した建
物3からの給水要求信号に応答して単独動作させる。残
りの建物1,2に対応した給水ポンプ4,5は、その建
物1,2からの給水要求信号に応答して単独動作させ
る。図8に、図6および図7に示した給水装置の制御盤
20Aの一例のブロック図を示す。図8において、31
〜34は、水位検出用電極装置21〜24を接続した水
位検出手段、35〜37は高架水槽16〜18の渇水、
異常増水等の異常を個別に表示する異常表示手段、38
は高架水槽16〜18の渇水、異常増水等の異常発生時
に警報音を発する共通の警報手段である。45〜47は
異常表示手段35〜37の出力に基づいて電動バルブ8
A〜10Aの開閉を制御するバルブ制御手段である。4
8は、異常表示手段35〜37および信号処理手段40
の出力に基づいて故障の状態を判別する故障判別手段、
49は異常表示手段35〜37の出力および故障判別手
段48の出力に基づいて、図4の故障対応スイッチS4
〜S7 のオンオフ切替動作と等価な動作を行う故障信号
処理手段であり、図3の故障対応スイッチ群39に代わ
るものである。40は水位検出手段32〜34,故障信
号処理手段49の出力信号を信号処理する信号処理手段
である。41〜44は信号処理手段40の出力信号に基
づいて給水ポンプ4〜6および補助給水ポンプ7を駆動
するポンプ駆動手段である。信号処理手段40の構成に
ついては第1の実施例と同様である。
Further, one electric valve 10A corresponding to the building 3 which has output the drought signal in response to the input of the drought signal from each of the buildings 1 to 3 is automatically opened, and the remaining valve corresponding to the remaining buildings 1 and 2 is automatically opened. Are automatically closed.
At this time, the auxiliary water pump 7 is independently operated in response to the water supply request signal from the building 3 that has output the drought signal. The water supply pumps 4 and 5 corresponding to the remaining buildings 1 and 2 are independently operated in response to the water supply request signals from the buildings 1 and 2. FIG. 8 is a block diagram illustrating an example of the control panel 20A of the water supply device illustrated in FIGS. 6 and 7. In FIG. 8, 31
34 is a water level detecting means connected to the water level detecting electrode devices 21 to 24, 35 to 37 are droughts of the elevated water tanks 16 to 18,
Abnormality display means for individually displaying abnormalities such as abnormally high water, 38
Is a common alarm unit that emits an alarm sound when an abnormality such as a drought of the elevated water tanks 16 to 18 or an abnormal increase in water occurs. 45 to 47 are motorized valves 8 based on the outputs of the abnormality display means 35 to 37.
Valve control means for controlling the opening and closing of A to 10A. 4
8 is an abnormality display means 35 to 37 and a signal processing means 40
Failure determination means for determining a failure state based on the output of
49 is a failure handling switch S 4 of FIG. 4 based on the outputs of the abnormality display means 35 to 37 and the output of the failure determination means 48.
A fault signal processing means for performing an on-off switching operation equivalent to the operation of the to S 7, in place of any failure countermeasure switch group 39 in FIG. 3. Numeral 40 is a signal processing means for processing the output signals of the water level detecting means 32 to 34 and the failure signal processing means 49. Reference numerals 41 to 44 denote pump driving means for driving the water supply pumps 4 to 6 and the auxiliary water supply pump 7 based on the output signal of the signal processing means 40. The configuration of the signal processing means 40 is the same as in the first embodiment.

【0050】この実施例において、各建物1〜3からの
渇水信号の入力に応答して電動バルブ8A,9A,10
Aを自動的に開閉させるようにした点以外は第1の実施
例と同様である。この実施例の給水装置によれば、各建
物1〜3からの渇水信号の入力に応答して渇水信号を出
力した建物3に対応した一つの電動バルブ10Aが自動
的に開き残りの建物1,2に対応した残りの電動バルブ
8A,9Aが自動的に閉じるので、異常時に自動的に異
常状態を解消することができ、補修員による対策を緊急
性を解消することができる。
In this embodiment, the electric valves 8A, 9A, 10 are operated in response to the input of the drought signal from each of the buildings 1 to 3.
A is similar to the first embodiment except that A is automatically opened and closed. According to the water supply device of this embodiment, one electric valve 10A corresponding to the building 3 that has output the drought signal in response to the input of the drought signal from each of the buildings 1 to 3 is automatically opened, and the remaining buildings 1 and 2 are opened. Since the remaining electric valves 8A and 9A corresponding to 2 automatically close, an abnormal state can be automatically eliminated in the event of an abnormality, and urgency can be taken by the repair staff.

【0051】〔第3の実施例〕この発明の第3の実施例
を図9ないし図11に基づいて説明する。この給水装置
は、図9および図10に示すように、複数の建物51,
52内に水を供給するもので、建物51,52毎に、各
建物51,52内からの給水要求信号に応答して動作し
建物51,52内に水を供給する給水ポンプ53,54
を各々設置し、給水ポンプ53,54の当該建物51,
52内に水を供給する出力部に手動の主バルブ55,5
6を設け、主バルブ55,56の給水ポンプ53,54
側で給水ポンプ53,54の出力部を手動の連結バルブ
57を介して相互に結合している。
[Third Embodiment] A third embodiment of the present invention will be described with reference to FIGS. As shown in FIGS. 9 and 10, the water supply device includes a plurality of buildings 51,
The water supply pumps 53 and 54 operate in response to water supply request signals from the buildings 51 and 52 and supply water to the buildings 51 and 52.
Are installed, and the buildings 51,
Manual main valves 55, 5
6 and the feed pumps 53, 54 of the main valves 55, 56
On the side, the outputs of the feed pumps 53, 54 are connected to one another via a manual connection valve 57.

【0052】給水ポンプ53,54は、市水道58から
水の供給を受ける各建物51,52について共通の受水
槽59に蓄えられた水を、主配管60,61を通して各
建物51,52の屋上等に個別に設けられた高架水槽6
2,63へ供給するものである。受水槽59および高架
水槽62,63は、それぞれ水位検出用電極装置65〜
67が設けられている。受水槽59の水位検出用電極装
置65は、1本の共通電極(一番長い電極)と3本の水
位検出電極との合わせて4本の電極からなり、渇水レベ
ル、減水レベル、満水レベルを検出し、その水位検出信
号を制御盤64へ供給するようになっており、制御盤6
4により受水槽59の水位を減水レベルおよび満水レベ
ルの間に制御するとともに、水位が渇水レベルまで下が
ったときに警報を発したり、あるいは給水ポンプ53,
54の動作を強制的に停止させる等して、給水ポンプ5
3,54の空運転を防止するようにしている。
The water supply pumps 53 and 54 supply the water stored in the common water receiving tank 59 for each of the buildings 51 and 52 receiving the water supply from the city water supply 58 to the roof of each of the buildings 51 and 52 through the main pipes 60 and 61. Elevated water tank 6 provided separately for example
2 and 63. The water receiving tank 59 and the elevated water tanks 62 and 63 are respectively provided with water level detecting electrode devices 65 to 65.
67 are provided. The water level detection electrode device 65 of the water receiving tank 59 is composed of four electrodes including one common electrode (longest electrode) and three water level detection electrodes, and controls the drought level, the water reduction level, and the full water level. The control panel 64 detects the water level and supplies the water level detection signal to the control panel 64.
4 controls the water level of the water receiving tank 59 between the reduced water level and the full water level, and issues an alarm when the water level falls to the drought level, or the water supply pump 53,
54, for example, by forcibly stopping the operation of the water supply pump 5.
3, 54 are prevented from running idle.

【0053】また、高架水槽62,63の水位検出用電
極装置66,67は、それぞれ1本の共通電極(一番長
い電極)と4本の水位検出電極との合わせて本の電極
からなり、渇水レベル、減水レベル、満水レベル、異常
増水レベルを検出し、その水位検出信号を制御盤64へ
供給するようになっており、制御盤64により、高架水
槽62,63の水位を減水レベルおよび満水レベルの間
に制御するとともに、水位が渇水レベルまで下がったと
き、および異常増水レベルを超えたときに警報を発した
り、あるいは、渇水レベルより下がったときに、後述す
るように、給水ポンプ53,54の一方を両高架水槽6
2,63への給水に両用して、水位が渇水レベルより下
がった高架水槽、例えば62へ水を供給する等の動作を
行う。
The water level detecting electrode devices 66 and 67 of the elevated water tanks 62 and 63 are each composed of five electrodes including one common electrode (longest electrode) and four water level detecting electrodes. , A drought level, a low water level, a full water level, and an abnormally high water level are detected, and a water level detection signal is supplied to a control panel 64. Control is performed during the full water level, and when the water level falls to the drought level and when the water level exceeds the abnormally high water level, an alarm is issued, or when the water level falls below the drought level, as described later, the water supply pump 53 is used. , 54 to both elevated water tanks 6
An operation of supplying water to an elevated water tank whose water level has fallen below the drought level, for example, 62, is used for both water supply to the tanks 2 and 63.

【0054】この給水装置では、常時は主バルブ55,
56を開き、連結バルブ57を閉じる。このときに、各
建物51,52からの給水要求信号に応答して各建物5
1,52に対応した給水ポンプ53,54を動作させ、
主配管60,61を通して高架水槽62,63へ水を供
給する。給水要求信号は、従来例でも述べたように、高
架水槽62,63内の水位が減水レベルを下回ったとき
に立ち上がり、満水レベルを超えたときに立ち下がるこ
とになる。つまり、高架水槽62,63内の水位が減水
レベルを下回ったあと、つぎに満水レベルを超えるまで
の期間給水要求信号が発生することになる。したがっ
て、高架水槽62,63の水位は、減水レベルから満水
レベルまでの範囲に保たれる。
In this water supply device, the main valve 55,
56 is opened and the connection valve 57 is closed. At this time, in response to the water supply request signal from each of the buildings 51 and 52, each of the buildings 5
Operate the water supply pumps 53 and 54 corresponding to
Water is supplied to the elevated water tanks 62 and 63 through the main pipes 60 and 61. As described in the conventional example, the water supply request signal rises when the water level in the elevated water tanks 62 and 63 falls below the reduced water level, and falls when the water level exceeds the full water level. That is, after the water levels in the elevated water tanks 62 and 63 fall below the water reduction level, a water supply request signal is generated for a period until the water level next exceeds the full water level. Therefore, the water levels of the elevated water tanks 62 and 63 are maintained in the range from the reduced water level to the full water level.

【0055】また、建物51,52毎の給水ポンプの何
れか1台が故障や異常等を生じて給水できなくなった時
には、渇水信号を出力した建物51に対応した給水ポン
プ53の出力部に結合した連結バルブ57を開き、被連
結側の給水ポンプ54の主バルブ56を閉じる。このと
きに、渇水信号を出力した建物51からの給水要求信号
に応答して被連結側の給水ポンプ54を動作させ、主配
管60を通して高架水槽62へ水を供給する。なお、給
水ポンプ54が動作して高架水槽63への給水を行われ
ているときは、高架水槽63への給水の終了を待って、
給水ポンプ54を再度動作させて高架水槽62への給水
を行う。また、高架水槽62への給水が完了したとき
は、連結バルブ57を閉じ、主バルブ56を開いて、高
架水槽63への給水が可能なようにする。
When any one of the water supply pumps of the buildings 51 and 52 fails to supply water due to a failure or abnormality, the water supply pump is connected to the output section of the water supply pump 53 corresponding to the building 51 which has output the drought signal. The connected valve 57 is opened, and the main valve 56 of the water supply pump 54 on the connected side is closed. At this time, the connected water supply pump 54 is operated in response to a water supply request signal from the building 51 that has output the drought signal, and water is supplied to the elevated water tank 62 through the main pipe 60. Note that when the water supply pump 54 is operating to supply water to the elevated water tank 63, the system waits for the supply of water to the elevated water tank 63 to be completed.
The water supply pump 54 is operated again to supply water to the elevated water tank 62. When the water supply to the elevated water tank 62 is completed, the connection valve 57 is closed and the main valve 56 is opened to supply water to the elevated water tank 63.

【0056】図11に、図9および図10に示した給水
装置の制御盤64の一例のブロック図を示す。図11に
おいて、71〜73は、水位検出用電極装置65〜67
を接続した水位検出手段、74,75は高架水槽62,
63の渇水、異常増水等の異常を個別に表示する異常表
示手段、76は高架水槽62,63の渇水、異常増水等
の異常発生時に警報音を発する共通の警報手段である。
77,78は故障した給水ポンプ53または54に応じ
て切り替え動作を行う故障対応スイッチである。79,
80は水位検出手段72,73の出力に応じて給水ポン
プ53,54を駆動するポンプ駆動手段である。
FIG. 11 is a block diagram showing an example of the control panel 64 of the water supply device shown in FIGS. 9 and 10. 11, reference numerals 71 to 73 denote water level detection electrode devices 65 to 67.
, Water level detecting means 74, 75 are elevated water tanks 62,
Abnormality display means for individually displaying abnormalities such as drought and abnormally high water in 63, and common alarm means for issuing an alarm sound when abnormalities such as drought and abnormally high water in the elevated water tanks 62 and 63 occur.
77, 78 are failure handling switches that perform a switching operation according to the failed water supply pump 53 or 54. 79,
Reference numeral 80 denotes a pump driving unit that drives the water supply pumps 53 and 54 according to the outputs of the water level detection units 72 and 73.

【0057】この実施例の給水装置は、建物数と同数の
給水ポンプ53,54を設けるだけで、つまり少ない給
水ポンプ台数で各建物51,52への水の供給を安定し
て行うことができる。なお、上記実施例では、建物が2
戸で、給水ポンプが2台である実施例を示したが、建物
が3戸以上で、給水ポンプも3台以上(建物と同数)で
ある系統において、前記実施例と同様に各給水ポンプの
出力部に主バルブを設けるとともに、各給水ポンプの出
力部を相互に結合する連結バルブを設けることで、上記
と同様の効果を達成できる。
The water supply apparatus of this embodiment can stably supply water to each of the buildings 51 and 52 only by providing the same number of water supply pumps 53 and 54 as the number of buildings, that is, with a small number of water supply pumps. . In the above embodiment, the building is 2
Although the embodiment in which the number of water supply pumps is two in the door is shown, in a system in which the number of buildings is three or more and the number of water supply pumps is three or more (the same number as the buildings), each water supply pump is provided in the same manner as in the above embodiment. The same effect as described above can be achieved by providing a main valve at the output section and providing a connection valve that mutually connects the output sections of the water supply pumps.

【0058】〔第4の実施例〕この発明の第4の実施例
を図12および図13に基づいて説明する。この給水装
置は、図12に示すように、図9および図10の手動の
主バルブ55,56および連結バルブ57に代えて、電
気信号に応答して開閉する電動主バルブ55A,56A
および電動連結バルブ57Aを用い、電動主バルブ55
A,56Aおよび電動補助バルブ57Aを開閉駆動する
バルブ制御手段(図示せず)を設けている。
[Fourth Embodiment] A fourth embodiment of the present invention will be described with reference to FIGS. This water supply device, as shown in FIG. 12, replaces the manual main valves 55 and 56 and the connection valve 57 of FIGS. 9 and 10 with electric main valves 55A and 56A that open and close in response to electric signals.
And the electric main valve 55 using the electric connection valve 57A.
A, 56A and valve control means (not shown) for opening and closing the electric auxiliary valve 57A are provided.

【0059】そして、常時はバルブ制御手段より電動主
バルブ55A,56Aを開いて電動連結バルブ57Aを
閉じる信号を出力し、各建物51,52からの給水要求
信号に応答して各建物51,52に対応した給水ポンプ
53,54を動作させ、建物51,52内の渇水信号の
入力に応答して電動連結バルブ57Aを開いて被連結側
の給水ポンプ54の出力部に設けた電動主バルブ56A
を閉じる信号を出力し、渇水信号を出力した建物51か
らの給水要求信号に応答して被連結側の給水ポンプ54
を動作させるようにしている。
Normally, the valve control means outputs a signal for opening the electric main valves 55A and 56A and closing the electric connection valve 57A, and responds to a water supply request signal from each of the buildings 51 and 52 so as to respond to the water supply request signal. In response to the input of a drought signal in the buildings 51, 52, the electric connection valve 57A is opened in response to the input of the drought signal in the buildings 51, 52, and the electric main valve 56A provided at the output portion of the water supply pump 54 on the connected side.
In response to the water supply request signal from the building 51 that has output the drought signal, the water pump 54 on the connected side.
To make it work.

【0060】また、渇水信号を出力した建物51からの
給水要求信号の消滅に応答して、バルブ制御手段より被
連結側の給水ポンプ54の出力部に設けた電動主バルブ
56Aを開いて電動連結バルブ57Aを閉じる信号を出
力し、被連結側の建物54からの給水要求信号に応答し
て被連結側の給水ポンプ54を動作させるようにしてい
る。バルブ制御手段は、図12の制御盤64A内に設け
られている。
Further, in response to the disappearance of the water supply request signal from the building 51 which has output the drought signal, the valve control means opens the electric main valve 56A provided at the output part of the water supply pump 54 on the connected side to open the electric connection. A signal for closing the valve 57A is output, and the water supply pump 54 on the connected side is operated in response to a water supply request signal from the building 54 on the connected side. The valve control means is provided in the control panel 64A of FIG.

【0061】この給水装置では、常時は電動主バルブ5
5A,56Aが自動的に開き、電動連結バルブ57Aが
自動的に閉じる。このときに、各建物51,52からの
給水要求信号に応答して各建物51,52に対応した給
水ポンプ53,54を動作させる。また、各建物51,
52からの渇水信号の入力に応答して渇水信号を出力し
た建物51に対応した給水ポンプ53の出力部に結合し
た電動連結バルブ57Aが自動的に開き、被連結側の給
水ポンプ54の電動主バルブ56Aが自動的に閉じる。
このときに、渇水信号を出力した建物51からの給水要
求信号に応答して被連結側の給水ポンプ54を動作させ
る。
In this water supply device, the electric main valve 5
5A and 56A are automatically opened, and the electric connection valve 57A is automatically closed. At this time, the water supply pumps 53, 54 corresponding to the buildings 51, 52 are operated in response to the water supply request signals from the buildings 51, 52. In addition, each building 51,
The electric connection valve 57A connected to the output of the water supply pump 53 corresponding to the building 51 that has output the water shortage signal in response to the input of the water shortage signal from 52 automatically opens, and the electric motor of the water supply pump 54 on the connected side is automatically opened. Valve 56A automatically closes.
At this time, the connected water supply pump 54 is operated in response to a water supply request signal from the building 51 that has output the drought signal.

【0062】そして、渇水信号を出力した建物51から
の給水要求信号が消滅すると、被連結側の給水ポンプ5
4の出力部に設けた電動主バルブ56Aが自動的に開
き、電動連結バルブ57Aが自動的に閉じる。このとき
に、被連結側の建物52からの給水要求信号に応答して
被連結側の給水ポンプ54を動作させる。この結果、被
連結側の建物52への給水が支障なく行われる。
Then, when the water supply request signal from the building 51 which has output the drought signal disappears, the water supply pump 5
The motor-operated main valve 56A provided at the output unit 4 automatically opens, and the motor-operated connection valve 57A automatically closes. At this time, the water supply pump 54 on the connected side is operated in response to a water supply request signal from the building 52 on the connected side. As a result, water is supplied to the connected building 52 without any trouble.

【0063】図13に、図12に示した給水装置の制御
盤64Aの一例のブロック図を示す。図13において、
71〜73は、水位検出用電極装置65〜67を接続し
た水位検出手段、74,75は高架水槽62,63の渇
水、異常増水等の異常を個別に表示する異常表示手段、
76は高架水槽62,63の渇水、異常増水等の異常発
生時に警報音を発する共通の警報手段である。81は信
号判別手段・バルブ制御手段であり、異常表示手段7
4,75の出力および水位検出手段72,73の出力に
より故障状態を判別するとともに、電動主バルブ55
A,56Aおよび電動連結バルブ57Aを制御する。8
2は信号処理手段であり、信号判別手段・バルブ制御手
段81の出力に従ってポンプ駆動手段79,80を制御
するもので、図11の故障対応スイッチ77,78に代
わるものである。79,80は水位検出手段72,73
の出力に応じて給水ポンプ53,54を駆動するポンプ
駆動手段である。
FIG. 13 is a block diagram showing an example of the control panel 64A of the water supply apparatus shown in FIG. In FIG.
71 to 73 are water level detecting means connected to the water level detecting electrode devices 65 to 67; 74 and 75 are abnormal display means for individually displaying abnormalities such as drought of the elevated water tanks 62 and 63 and abnormally high water;
Reference numeral 76 denotes a common alarm unit that emits an alarm sound when an abnormality such as a drought of the elevated water tanks 62 and 63 or an abnormal increase in the water level occurs. 81 is a signal determining means, the valve control means, the abnormality display means 7
4 and 75 and the output of the water level detecting means 72 and 73, the failure state is determined, and the electric main valve 55 is determined.
A, 56A and the electric connection valve 57A are controlled. 8
Numeral 2 denotes a signal processing unit which controls the pump driving units 79 and 80 in accordance with the output of the signal discriminating unit / valve control unit 81, and replaces the failure handling switches 77 and 78 in FIG. 79 and 80 are water level detecting means 72 and 73
Is a pump driving means for driving the water supply pumps 53 and 54 in accordance with the output of.

【0064】この実施例において、各建物51,52か
らの渇水信号の入力に応答して電動主バルブ55A,5
6Bおよび電動連結バルブ57Aを自動的に開閉させる
ようにした点以外は第3の実施例と同様である。ここ
で、上記第4の実施例における給水ポンプ53,54お
よび電動主バルブ55A,56A,電動連結バルブ57
Aの動作を図14のフローチャートを参照しながら説明
する。以下の説明では、便宜上、給水ポンプ53の系統
を1系と呼び、給水ポンプ54の系統を2系と呼び、給
水ポンプ53をポンプと、給水ポンプ54をポンプ
と、電動主バルブ55Aをバルブと、電動主バルブ5
6Aをバルブと、電動連結バルブ57Aをバルブ
と、それぞれ記すことにする。
In this embodiment, in response to the input of a drought signal from each of the buildings 51 and 52, the electric main valves 55A and 55
6B and the third embodiment except that the electric connection valve 57A is automatically opened and closed. Here, the water supply pumps 53 and 54, the electric main valves 55A and 56A, and the electric connection valve 57 in the fourth embodiment are used.
The operation of A will be described with reference to the flowchart of FIG. In the following description, for convenience, the system of the water supply pump 53 is referred to as system 1, the system of the water supply pump 54 is referred to as system 2, the water supply pump 53 is a pump, the water supply pump 54 is a pump, and the electric main valve 55A is a valve. , Electric main valve 5
6A is referred to as a valve, and the electric connection valve 57A is referred to as a valve.

【0065】まず、1系が異常かどうかを渇水信号の有
無で判定し、1系が異常でなければ、2系が異常かどう
かを同じく渇水信号の有無で判定する。2系が異常でな
ければ、1系に給水要求信号が発生しているかどうかを
判定し、給水要求信号が発生しておれば、ポンプをO
N(運転)にし、給水要求信号が消滅しておれば、ポン
プをOFF(運転停止)にする。つぎに、2系に給水
要求信号が発生しているかどうかを判定し、給水要求信
号が発生しておれば、ポンプをON(運転)にし、給
水要求信号が消滅しておれば、ポンプをOFF(運転
停止)にし、最初に戻る。
First, whether or not the system 1 is abnormal is determined by the presence or absence of a drought signal. If the system 1 is not abnormal, it is determined whether or not the system 2 is abnormal by the presence or absence of a drought signal. If the system 2 is not abnormal, it is determined whether a water supply request signal is generated in the system 1 and if the water supply request signal is generated, the pump is turned off.
N (operation), and if the water supply request signal has disappeared, the pump is turned off (operation stopped). Next, it is determined whether or not a water supply request signal is generated in the second system. If the water supply request signal is generated, the pump is turned on (operating). If the water supply request signal is extinguished, the pump is turned off. (Stop operation) and return to the beginning.

【0066】1系が異常であれば、ポンプがONにな
っているかどうかを判定し、ONになっておれば、1系
に給水要求信号が発生しているかどうかの判定ステップ
へ移行する。また、ポンプがONになっていなけれ
ば、バルブを閉とし、バルブを開とした後、ポンプ
をONにし、1系に給水要求信号が発生しているかど
うかを判定し、1系の給水要求信号が消滅するまでその
ステップを繰り返す。1系の給水要求信号が消滅する
と、バルブを開とし、バルブを閉とし、ポンプを
OFFにして最初に戻る。
If the first system is abnormal, it is determined whether or not the pump is ON. If the first system is ON, the process proceeds to a determination step as to whether or not a water supply request signal is generated in the first system. If the pump has not been turned on, the valve is closed, the valve is opened, the pump is turned on, and it is determined whether or not a water supply request signal is generated in the first system. Repeat that step until disappears. When the water supply request signal of the first system disappears, the valve is opened, the valve is closed, the pump is turned off, and the process returns to the beginning.

【0067】また、2系が異常であれば、ポンプがO
Nになっているかどうかを判定し、ONになっておれ
ば、1系に給水要求信号が発生しているかどうかの判定
ステップへ移行する。また、ポンプがONになってい
なければ、バルブを閉とし、バルブを開とした後、
ポンプをONにし、2系に給水要求信号が発生してい
るかどうかを判定し、2系の給水要求信号が消滅するま
でそのステップを繰り返す。2系の給水要求信号が消滅
すると、バルブを開とし、バルブを閉とし、ポンプ
をOFFにして最初に戻る。
If the system 2 is abnormal, the pump
It is determined whether it is N or not, and if it is ON, the process proceeds to a determination step of whether a water supply request signal is generated in the first system. If the pump is not ON, close the valve and open the valve,
The pump is turned on, it is determined whether or not a water supply request signal is generated in the second system, and the steps are repeated until the water supply request signal in the second system disappears. When the water supply request signal of the second system disappears, the valve is opened, the valve is closed, the pump is turned off, and the process returns to the beginning.

【0068】なお、上記の動作の条件として、異常とな
った系にも減水信号が出力されていることが必要であ
る。以上の動作により、1系および2系の両方が正常な
ときは、ポンプおよびポンプがそれぞれ動作して給
水要求信号に従って動作し、各々1系および2系の高架
水槽へ給水する。
As a condition of the above operation, it is necessary that the water reduction signal is also output to the abnormal system. According to the above operation, when both the first system and the second system are normal, the pump and the pump operate to operate according to the water supply request signal, and supply water to the first and second system elevated water tanks.

【0069】また、例えば1系が異常となったときは、
ポンプが止まるので、ポンプにより1系の高架水槽
へ給水する。ポンプが2系の高架水槽への給水を行っ
ている期間はポンプによる1系の高架水槽への給水は
行わず、ポンプによる2系の高架水槽への給水が終了
した後でポンプによる1系の高架水槽への給水を行
う。そして、ポンプによる1系の高架水槽への給水が
終了すると、ポンプにより2系の高架水槽への給水が
行えるように復帰させる。
For example, when the system 1 becomes abnormal,
Since the pump stops, water is supplied to the elevated water tank of the first system by the pump. While the pump is supplying water to the 2nd elevated water tank, the pump does not supply water to the 1st elevated water tank, and after the water supply to the 2nd elevated water tank is completed by the pump, the 1st Supply water to the elevated water tank. Then, when the water supply to the first system elevated water tank by the pump is completed, the pump is returned to be able to supply water to the second system elevated water tank.

【0070】2系が異常となった時も、ポンプが止ま
るので、ポンプにより2系の高架水槽へ給水する。ポ
ンプが1系の高架水槽への給水を行っている期間はポ
ンプによる2系の高架水槽への給水は行わず、ポンプ
による1系の高架水槽への給水が終了した後でポンプ
による2系の高架水槽への給水を行う。そして、ポン
プによる2系の高架水槽への給水が終了すると、ポン
プにより1系の高架水槽への給水が行えるように復帰
させる。
When the system 2 becomes abnormal, the pump stops, and the pump supplies water to the system 2 elevated water tank. During the period when the pump is supplying water to the 1st elevated water tank, water is not supplied to the 2nd elevated water tank by the pump, and after the water supply to the 1st elevated water tank by the pump is completed, Supply water to the elevated water tank. Then, when the water supply to the second system elevated water tank by the pump is completed, the pump is returned so that the pump can supply water to the first system elevated water tank.

【0071】このような動作により、1系および2系の
片方が異常となったときは、正常側の系の高架水槽は、
減水レベルと満水レベルの間で水位が制御され、異常側
の系の高架水槽は、渇水レベルと満水レベルの間で水位
が制御されることになり、異常側の系の高架水槽の水位
の変動幅は正常側の系に比べて大きい状態となる。この
実施例の給水装置によれば、各建物51,52からの渇
水信号の入力に応答して渇水信号を出力した建物51に
対応した給水ポンプ53の出力部に結合した電動連結バ
ルブ57Aが自動的に開き、被連結側の給水ポンプ54
の電動主バルブ56Aが自動的に閉じるので、異常時に
自動的に異常状態を解消することができ、補修員による
対策を緊急性を解消することができる。
When one of the systems 1 and 2 becomes abnormal due to such an operation, the elevated water tank of the normal system is
The water level is controlled between the reduced water level and the full water level, and the elevation of the elevated water tank in the abnormal system is controlled between the drought level and the full water level. The width is larger than that of the normal system. According to the water supply apparatus of this embodiment, the motor-operated connection valve 57A coupled to the output of the water supply pump 53 corresponding to the building 51 that has output the drought signal in response to the input of the drought signal from each of the buildings 51 and 52 automatically operates. The feed water pump 54 on the connected side
Since the electric main valve 56A is automatically closed, the abnormal state can be automatically eliminated in the event of an abnormality, and the urgency of the measures taken by the repair staff can be eliminated.

【0072】また、渇水信号を出力した建物51からの
給水要求信号が消滅すると、被連結側の給水ポンプ54
の出力部に設けた電動主バルブ56Aが自動的に開き、
電動連結バルブ57Aが自動的に閉じ、被連結側の建物
52からの給水要求信号に応答して被連結側の給水ポン
プ54を動作させるので、渇水信号を出力した建物51
への給水を行うだけでなく、被連結側の建物52への給
水も行えるので、補修を長時間にわたって行わずに放置
していても、安定した水の供給が可能となる。
When the water supply request signal from the building 51 that has output the drought signal is extinguished, the water pump 54 on the connected side is turned off.
The motor-operated main valve 56A provided at the output section automatically opens,
The electric connection valve 57A is automatically closed, and the water supply pump 54 on the connected side is operated in response to a water supply request signal from the building 52 on the connected side.
In addition to supplying water to the building, it is also possible to supply water to the building 52 on the connected side, so that stable water can be supplied even if repair is not performed for a long time.

【0073】〔第5の実施例〕この発明の第5の実施例
を図12および図15に基づいて説明する。この給水装
置は、渇水信号の発生に応答して異常モードを保持する
保持手段(図示せず)を設け、保持手段が異常モードを
保持している期間中において、バルブ制御手段より被連
結側の給水ポンプ54の出力部に設けた主バルブ56A
を開いて連結バルブ57Aを閉じる信号を出力し被連結
側の建物52からの給水要求信号に応答して被連結側の
給水ポンプ54を動作させる第1の動作と、バルブ制御
手段より被連結側の給水ポンプ54の出力部に設けた主
バルブ56Aを閉じて連結バルブ57Aを開く信号を出
力し渇水信号を出力した建物51からの給水要求信号に
応答して被連結側の給水ポンプ54を動作させる第2の
動作とを選択的に行わせるようにしている。
[Fifth Embodiment] A fifth embodiment of the present invention will be described with reference to FIGS. This water supply device is provided with a holding means (not shown) for holding the abnormal mode in response to the occurrence of the drought signal, and during the period in which the holding means holds the abnormal mode, the valve control means is connected to the connected side by the valve control means. Main valve 56A provided at the output of water supply pump 54
A first operation of opening the connection valve 57A to output a signal to close the connection valve 57A and operating the water supply pump 54 on the connection side in response to a water supply request signal from the building 52 on the connection side; The water supply pump 54 on the connected side operates in response to a water supply request signal from the building 51 that outputs a signal to close the main valve 56A provided at the output portion of the water supply pump 54 and opens the connection valve 57A and outputs a drought signal. The second operation to be performed is selectively performed.

【0074】上記のような構成および動作は、図12の
制御盤64Aにより実現される。このように構成する
と、異常モードが保持されている期間中は、第1の動作
と第2の動作とが選択的に行われることになり、渇水信
号を出力した建物への給水と被連結側の建物への給水が
対等な関係で行われることになる。上記以外の動作は第
4の実施例と同様である。
The above configuration and operation are realized by the control panel 64A of FIG. With this configuration, during the period in which the abnormal mode is maintained, the first operation and the second operation are selectively performed, and the water supply to the building that outputs the drought signal and the connection to the connected side are performed. Will be provided on an equal basis. Operations other than those described above are the same as in the fourth embodiment.

【0075】ここで、上記第5の実施例における給水ポ
ンプ53,54および電動主バルブ55A,56A,電
動連結バルブ57Aの動作を図15のフローチャートを
参照しながら説明する。まず、リセット操作が行われた
かどうかを判定する。なお、リセット操作は、故障した
ポンプ等を修理して系統が正常な状態に戻した後、リセ
ットボタンを手動操作することにより行う。
The operation of the water supply pumps 53 and 54, the electric main valves 55A and 56A, and the electric connection valve 57A in the fifth embodiment will now be described with reference to the flowchart of FIG. First, it is determined whether a reset operation has been performed. The reset operation is performed by manually operating a reset button after repairing a failed pump or the like and returning the system to a normal state.

【0076】リセット操作が行われていなければ、1系
が異常かどうかを判定し、リセット操作が行われておれ
ば、バルブ,を開とし、バルブを閉とし、1系お
よび2系の異常保持を解除した後、1系が異常かどうか
を判定する。1系が異常でなければ、2系が異常かどう
かを判定する。2系が異常でなければ、1系に給水要求
信号が発生しているかどうかを判定し、給水要求信号が
発生しておれば、ポンプをON(運転)にし、給水要
求信号が消滅しておれば、ポンプをOFF(運転停
止)にする。つぎに、2系に給水要求信号が発生してい
るかどうかを判定し、給水要求信号が発生しておれば、
ポンプをON(運転)にし、給水要求信号が消滅して
おれば、ポンプをOFF(運転停止)にし、最初に戻
る。
If the reset operation has not been performed, it is determined whether or not the system 1 is abnormal. If the reset operation has been performed, the valve is opened, the valve is closed, and the abnormality of the system 1 and the system 2 is maintained. Is canceled, it is determined whether the system 1 is abnormal. If the first system is not abnormal, it is determined whether the second system is abnormal. If the system 2 is not abnormal, it is determined whether or not a water supply request signal is generated in the system 1. If the water supply request signal is generated, the pump is turned on (operated), and the water supply request signal has disappeared. If so, the pump is turned off (stop operation). Next, it is determined whether or not a water supply request signal is generated in the second system.
When the pump is turned on (operation) and the water supply request signal has disappeared, the pump is turned off (operation stopped) and the process returns to the beginning.

【0077】1系が異常であれば、ポンプがONにな
っているかどうかを判定し、ONになっておれば、1系
に給水要求信号が発生しているかどうかの判定ステップ
へ移行する。また、ポンプがONになっていなけれ
ば、1系の異常保持を行い、1系に給水要求信号が発生
しているかどうかを判定し、給水要求信号が発生してい
る場合は、バルブを閉とし、バルブを開とした後、
ポンプをONにし、1系の給水要求信号の判定ステッ
プに戻り、1系の給水要求信号が消滅するまでその状態
を繰り返す。
If the first system is abnormal, it is determined whether or not the pump is ON. If the first system is ON, the process proceeds to a determination step as to whether or not a water supply request signal is generated in the first system. If the pump is not turned on, the system 1 is maintained abnormally, and it is determined whether or not a water supply request signal is generated in the system 1. If the water supply request signal is generated, the valve is closed. , After opening the valve,
The pump is turned on, and the process returns to the determination step of the water supply request signal of the first system, and the state is repeated until the water supply request signal of the first system disappears.

【0078】1系の給水要求信号が消滅すると、ポンプ
をOFFにする。つぎに、2系に給水要求信号が発生
しているかどうかを判定し、2系の給水要求信号が発生
している場合は、バルブを開とし、バルブを閉と
し、ポンプをONにし、2系の給水要求信号の判定ス
テップに戻り、2系の給水要求信号が消滅するまでその
状態を繰り返す。2系の給水要求信号が消滅すると、ポ
ンプをOFFにして最初に戻る。
When the water supply request signal of the first system disappears, the pump is turned off. Next, it is determined whether or not a water supply request signal is generated in the second system. If the second water supply request signal is generated, the valve is opened, the valve is closed, the pump is turned on, and the Returning to the step of determining the water supply request signal, the state is repeated until the water supply request signal of the second system disappears. When the water supply request signal of the second system disappears, the pump is turned off and the process returns to the beginning.

【0079】2系が異常であれば、ポンプがONにな
っているかどうかを判定し、ONになっておれば、1系
に給水要求信号が発生しているかどうかの判定ステップ
へ移行する。また、ポンプがONになっていなけれ
ば、2系の異常保持を行い、2系に給水要求信号が発生
しているかどうかを判定し、給水要求信号が発生してい
る場合は、バルブを閉とし、バルブを開とした後、
ポンプをONにし、2系の給水要求信号の判定ステッ
プに戻り、2系の給水要求信号が消滅するまでその状態
を繰り返す。
If the second system is abnormal, it is determined whether or not the pump is ON. If the second system is ON, the process proceeds to a determination step as to whether or not a water supply request signal is generated in the first system. If the pump is not ON, the abnormality of the system 2 is maintained, and it is determined whether or not a water supply request signal is generated in the system 2. If the water supply request signal is generated, the valve is closed. , After opening the valve,
The pump is turned on, the process returns to the determination step of the water supply request signal of the second system, and the state is repeated until the water supply request signal of the second system disappears.

【0080】2系の給水要求信号が消滅すると、ポンプ
をOFFにする。つぎに、1系に給水要求信号が発生
しているかどうかを判定し、1系の給水要求信号が発生
している場合は、バルブを開とし、バルブを閉と
し、ポンプをONにし、1系の給水要求信号の判定ス
テップに戻り、1系の給水要求信号が消滅するまでその
状態を繰り返す。1系の給水要求信号が消滅すると、ポ
ンプをOFFにして最初に戻る。
When the water supply request signal of the second system disappears, the pump is turned off. Next, it is determined whether or not a water supply request signal is generated in the first system. If a water supply request signal is generated in the first system, the valve is opened, the valve is closed, the pump is turned on, and the Returning to the step of determining the water supply request signal, the state is repeated until the water supply request signal of the first system disappears. When the water supply request signal of the first system disappears, the pump is turned off and the process returns to the beginning.

【0081】なお、上記の動作の条件として、異常とな
った系にも減水信号が出力されていることが必要であ
る。以上の動作により、1系および2系の両方が正常な
ときは、ポンプおよびポンプがそれぞれ動作して給
水要求信号に従って動作し、各々1系および2系の高架
水槽へ給水する。
As a condition of the above-mentioned operation, it is necessary that the water reduction signal is also output to the abnormal system. According to the above operation, when both the first system and the second system are normal, the pump and the pump operate to operate according to the water supply request signal, and supply water to the first and second system elevated water tanks.

【0082】また、例えば1系が異常となったときは、
ポンプが止まるので、ポンプにより1系の高架水槽
へ給水する。ポンプが2系の高架水槽への給水を行っ
ている期間はポンプによる1系の高架水槽への給水は
行わず、ポンプによる2系の高架水槽への給水が終了
した後でポンプによる1系の高架水槽への給水を行
う。そして、ポンプによる1系の高架水槽への給水が
終了すると、ポンプによる1系および2系の高架水槽
への給水が同じ条件で行われることになる。
Further, for example, when the system 1 becomes abnormal,
Since the pump stops, water is supplied to the elevated water tank of the first system by the pump. While the pump is supplying water to the 2nd elevated water tank, the pump does not supply water to the 1st elevated water tank, and after the water supply to the 2nd elevated water tank is completed by the pump, the 1st Supply water to the elevated water tank. When the water supply to the first system elevated water tank by the pump is completed, the water supply to the first system and second system elevated water tank by the pump is performed under the same conditions.

【0083】2系が異常となった時も、ポンプが止ま
るので、ポンプにより2系の高架水槽へ給水する。ポ
ンプが1系の高架水槽への給水を行っている期間はポ
ンプによる2系の高架水槽への給水は行わず、ポンプ
による1系の高架水槽への給水が終了した後でポンプ
による2系の高架水槽への給水を行う。そして、ポン
プによる2系の高架水槽への給水が終了すると、ポン
プにより1系および2系の高架水槽への給水が同じ条
件で行われることになる。
When the system 2 becomes abnormal, the pump stops, so that the pump supplies water to the system 2 elevated water tank. During the period when the pump is supplying water to the 1st elevated water tank, water is not supplied to the 2nd elevated water tank by the pump, and after the water supply to the 1st elevated water tank by the pump is completed, Supply water to the elevated water tank. When the water supply to the second system elevated water tank by the pump is completed, the pump supplies water to the first system and the second system elevated water tank under the same conditions.

【0084】このような動作により、1系および2系の
片方が異常となったときは、正常側および異常側の系の
高架水槽は、ともに減水レベルと満水レベルの間で水位
が制御されることになり、異常側の系の高架水槽の水位
の変動幅は正常側の系と同じになる。この実施例の給水
装置によれば、渇水信号を出力した建物51への給水と
被連結側の建物52への給水が対等な関係で行われるこ
とになり、渇水信号を出力した建物51への給水も被連
結側の建物52への給水と同じ条件で行われることにな
り、渇水信号を出力した建物51についても、つぎに渇
水状態となる前に、つまり減水状態となった時点から給
水を行うことが可能となり、一層安定した水の供給が可
能となる。
When one of the systems 1 and 2 becomes abnormal due to such an operation, the elevated water tanks of the normal side and the abnormal side are both controlled between the reduced water level and the full water level. That is, the fluctuation range of the water level of the elevated water tank in the abnormal system is the same as that in the normal system. According to the water supply device of this embodiment, the water supply to the building 51 that outputs the drought signal and the water supply to the building 52 on the connected side are performed in an equal relationship, and the water supply to the building 51 that outputs the drought signal is performed. The water supply is also performed under the same conditions as the water supply to the connected building 52, and the building 51 that has output the drought signal is also supplied with water before the next drought state, that is, from the time of the reduced water state. And water can be supplied more stably.

【0085】〔第6の実施例〕この発明の第6の実施例
を図16および図17に基づいて説明する。この給水装
置は、図15のフローチャートに代えて図16および図
17のフローチャートで、給水ポンプ53,54および
電動主バルブ55A,56A,電動連結バルブ57Aを
制御することにより、第5の実施例の構成に加え、第1
の動作の実行中に渇水信号を出力した建物からの給水要
求信号が発生したときには第2の動作を優先して実行さ
せて第2の動作の終了後に第1の動作を再開させるとと
もに、第2の動作の実行中に被連結側の建物からの給水
要求信号が発生したときには第1の動作を優先して実行
させて第1の動作の終了後に第2の動作を再開させるよ
うにしている。
[Sixth Embodiment] A sixth embodiment of the present invention will be described with reference to FIGS. This water supply apparatus controls the water supply pumps 53 and 54, the electric main valves 55A and 56A, and the electric connection valve 57A in the flowcharts of FIGS. 16 and 17 instead of the flowchart of FIG. In addition to the configuration, the first
When a water supply request signal from the building that has output the drought signal occurs during the execution of the operation, the second operation is preferentially executed, and after the second operation is completed, the first operation is restarted. When a water supply request signal is generated from the connected building during the execution of the operation (1), the first operation is preferentially executed, and the second operation is restarted after the end of the first operation.

【0086】この給水装置では、渇水信号を出力した建
物への給水中に被連結側の建物が渇水状態となったり、
被連結側の建物への給水中に渇水信号を出力した建物が
渇水状態となるおそれを少なくできる。ここで、上記第
6の実施例における給水ポンプ53,54および電動主
バルブ55A,56A,電動連結バルブ57Aの動作を
図1および図17のフローチャートを参照しながら説
明する。
[0086] In this water supply device, during the water supply to the building that has output the drought signal, the connected building becomes drought,
It is possible to reduce the possibility that a building that has output a drought signal while supplying water to the connected building will be in a drought state. Here, the operation of the water supply pumps 53 and 54, the electric main valves 55A and 56A, and the electric connection valve 57A in the sixth embodiment will be described with reference to the flowcharts of FIGS.

【0087】まず、リセット操作が行われたかどうかを
判定する。なお、リセット操作は、故障したポンプ等を
修理して系統が正常な状態に戻した後、リセットボタン
を手動操作することにより行う。リセット操作が行われ
ていなければ、1系が異常かどうかを判定し、リセット
操作が行われておれば、バルブ,を開とし、バルブ
を閉とし、1系および2系の異常保持を解除した後、
1系が異常かどうかを判定する。1系が異常でなけれ
ば、2系が異常かどうかを判定する。2系が異常でなけ
れば、1系に給水要求信号が発生しているかどうかを判
定し、給水要求信号が発生しておれば、ポンプをON
(運転)にし、給水要求信号が消滅しておれば、ポンプ
をOFF(運転停止)にする。つぎに、2系の給水要
求信号が発生しておれば、ポンプをON(運転)に
し、2系の給水要求信号が消滅しておれば、ポンプを
OFF(運転停止)にし、最初に戻る。
First, it is determined whether or not a reset operation has been performed. The reset operation is performed by manually operating a reset button after repairing a failed pump or the like and returning the system to a normal state. If the reset operation has not been performed, it is determined whether or not the system 1 is abnormal. If the reset operation has been performed, the valve is opened, the valve is closed, and the abnormality holding of the system 1 and the system 2 is released. rear,
It is determined whether the system 1 is abnormal. If the first system is not abnormal, it is determined whether the second system is abnormal. If the second system is not abnormal, it is determined whether the first system has a water supply request signal. If the second system has a water supply request signal, the pump is turned on.
(Operation), and if the water supply request signal has disappeared, the pump is turned off (operation stopped). Next, if the water supply request signal of the second system has been generated, the pump is turned on (operation). If the water supply request signal of the second system has disappeared, the pump is turned off (operation stopped), and the process returns to the beginning.

【0088】まず、1系が異常であれば、ポンプがO
Nになっているかどうかを判定し、ONになっておれ
ば、1系に給水要求信号が発生しているかどうかの判定
ステップへ移行する。また、ポンプがONになってい
なければ、1系の異常保持を行い、1系に給水要求信号
が発生しているかどうかを判定し、1系の給水要求信号
が発生している場合は、バルブを閉とし、バルブを
開とした後、ポンプをONにし、さらに2系に給水要
求信号が発生しているかどうかを判定し、2系の給水要
求信号が発生していなければ、1系の給水要求信号の発
生の判断ステップに戻り、1系の給水要求信号が消滅す
るまでその状態を繰り返す。
First, if the system 1 is abnormal, the pump
It is determined whether it is N or not, and if it is ON, the process proceeds to a determination step of whether a water supply request signal is generated in the first system. If the pump is not turned on, the system 1 is held abnormally, and it is determined whether or not a water supply request signal is generated in the system 1. Is closed, the valve is opened, the pump is turned on, and it is determined whether or not the water supply request signal is generated in the second system. If the water supply request signal is not generated in the second system, the water supply of the first system is performed. Returning to the determination step of the generation of the request signal, the state is repeated until the water supply request signal of the first system disappears.

【0089】一方、2系の給水要求信号が発生している
と、1系の給水要求信号の発生の判断ステップには戻ら
ずに、ポンプをOFFにし、バルブを開とし、バル
ブを閉とし、ポンプをONにし、さらに2系に給水
要求信号が発生しているかどうかを判定し、2系の給水
要求信号が発生しておれば、2系の給水要求信号の発生
の判断ステップに戻り、2系の給水要求信号が消滅する
までその状態を繰り返す。2系の給水要求信号が消滅す
ると、ポンプをOFFにし、1系の給水要求信号の発
生の判断ステップに戻り、1系の給水要求信号が消滅す
るまでその状態を繰り返す。
On the other hand, if the water supply request signal of the second system is generated, the pump is turned off, the valve is opened, and the valve is closed without returning to the determination step of the generation of the water supply request signal of the first system. The pump is turned on, and it is determined whether a water supply request signal has been generated in the second system. If the second water supply request signal has been generated, the process returns to the determination step of the second water supply request signal and returns to step 2. The state is repeated until the water supply request signal of the system disappears. When the water supply request signal of the second system disappears, the pump is turned off, the process returns to the determination step of the generation of the water supply request signal of the first system, and the state is repeated until the water supply request signal of the first system disappears.

【0090】1系の給水要求信号が消滅すると、ポンプ
をOFFにし、2系に給水要求信号が発生しているか
どうかを判定し、2系の給水要求信号が発生している場
合は、バルブを開とし、バルブを閉とした後、ポン
プをONにし、さらに1系に給水要求信号が発生して
いるかどうかを判定し、1系の給水要求信号が発生して
いなければ、2系の給水要求信号の発生の判断ステップ
に戻り、2系の給水要求信号が消滅するまでその状態を
繰り返す。
When the water supply request signal of the first system disappears, the pump is turned off, and it is determined whether the water supply request signal of the second system is generated. If the water supply request signal of the second system is generated, the valve is turned on. After opening and closing the valve, the pump is turned on. Further, it is determined whether or not a water supply request signal is generated in the first system. Returning to the signal generation determination step, the state is repeated until the water supply request signal for the second system disappears.

【0091】一方、1系の給水要求信号が発生している
と、2系の給水要求信号の発生の判断ステップには戻ら
ずに、ポンプをOFFにし、バルブを閉とし、バル
ブを開とし、ポンプをONにし、さらに1系に給水
要求信号が発生しているかどうかを判定し、1系の給水
要求信号が発生しておれば、1系の給水要求信号の発生
の判断ステップに戻り、1系の給水要求信号が消滅する
までその状態を繰り返す。1系の給水要求信号が消滅す
ると、ポンプをOFFにし、2系の給水要求信号の発
生の判断ステップに戻り、2系の給水要求信号が消滅す
るまでその状態を繰り返す。2系の給水要求信号が消滅
すると、ポンプをOFFにし、最初に戻る。
On the other hand, if the system 1 water supply request signal is generated, the pump is turned off, the valve is closed, and the valve is opened without returning to the step of determining the generation of the system 2 water supply request signal. The pump is turned on, and it is determined whether a water supply request signal is generated in the first system. If the first water supply request signal is generated, the process returns to the determination step of the first water supply request signal, and The state is repeated until the water supply request signal of the system disappears. When the water supply request signal of the first system disappears, the pump is turned off, and the process returns to the determination step of the generation of the water supply request signal of the second system, and the state is repeated until the water supply request signal of the second system disappears. When the water supply request signal for the second system disappears, the pump is turned off and the process returns to the beginning.

【0092】つぎに、2系が異常であれば、ポンプが
ONになっているかどうかを判定し、ONになっておれ
ば、1系に給水要求信号が発生しているかどうかの判定
ステップへ移行する。また、ポンプがONになってい
なければ、2系の異常保持を行い、2系に給水要求信号
が発生しているかどうかを判定し、2系の給水要求信号
が発生している場合は、バルブを閉とし、バルブを
開とした後、ポンプをONにし、さらに1系に給水要
求信号が発生しているかどうかを判定し、1系の給水要
求信号が発生していなければ、2系の給水要求信号の発
生の判断ステップに戻り、2系の給水要求信号が消滅す
るまでその状態を繰り返す。
Next, if the second system is abnormal, it is determined whether or not the pump is ON. If the second system is ON, the flow proceeds to a determination step for determining whether or not a water supply request signal is generated in the first system. I do. If the pump is not ON, the abnormality of the second system is held, and it is determined whether or not the water supply request signal is generated in the second system. Is closed, the valve is opened, the pump is turned on, and it is determined whether a water supply request signal is generated in the first system. If the water supply request signal in the first system is not generated, the water supply in the second system is performed. Returning to the determination step of the generation of the request signal, the state is repeated until the water supply request signal of the second system disappears.

【0093】一方、1系の給水要求信号が発生している
と、2系の給水要求信号の発生の判断ステップには戻ら
ずに、ポンプをOFFにし、バルブを開とし、バル
ブを閉とし、ポンプをONにし、さらに1系に給水
要求信号が発生しているかどうかを判定し、1系の給水
要求信号が発生しておれば、1系の給水要求信号の発生
の判断ステップに戻り、1系の給水要求信号が消滅する
までその状態を繰り返す。1系の給水要求信号が消滅す
ると、ポンプをOFFにし、2系の給水要求信号の発
生の判断ステップに戻り、2系の給水要求信号が消滅す
るまでその状態を繰り返す。
On the other hand, if the first system water supply request signal is generated, the pump is turned off, the valve is opened, and the valve is closed without returning to the step of determining the generation of the second system water supply request signal. The pump is turned on, and it is determined whether a water supply request signal is generated in the first system. If the first water supply request signal is generated, the process returns to the determination step of the first water supply request signal, and The state is repeated until the water supply request signal of the system disappears. When the water supply request signal of the first system disappears, the pump is turned off, and the process returns to the determination step of the generation of the water supply request signal of the second system, and the state is repeated until the water supply request signal of the second system disappears.

【0094】2系の給水要求信号が消滅すると、ポンプ
をOFFにし、1系に給水要求信号が発生しているか
どうかを判定し、1系の給水要求信号が発生している場
合は、バルブを開とし、バルブを閉とした後、ポン
プをONにし、さらに2系に給水要求信号が発生して
いるかどうかを判定し、2系の給水要求信号が発生して
いなければ、1系の給水要求信号の発生の判断ステップ
に戻り、1系の給水要求信号が消滅するまでその状態を
繰り返す。
When the water supply request signal of the second system disappears, the pump is turned off, and it is determined whether the water supply request signal of the first system is generated. If the water supply request signal of the first system is generated, the valve is turned on. After the valve is closed and the valve is closed, the pump is turned on, and it is determined whether or not a water supply request signal is generated in the second system. Returning to the signal generation determination step, the state is repeated until the water supply request signal of the first system disappears.

【0095】一方、2系の給水要求信号が発生している
と、1系の給水要求信号の発生の判断ステップには戻ら
ずに、ポンプをOFFにし、バルブを閉とし、バル
ブを開とし、ポンプをONにし、さらに2系に給水
要求信号が発生しているかどうかを判定し、2系の給水
要求信号が発生しておれば、2系の給水要求信号の発生
の判断ステップに戻り、2系の給水要求信号が消滅する
までその状態を繰り返す。2系の給水要求信号が消滅す
ると、ポンプをOFFにし、1系の給水要求信号の発
生の判断ステップに戻り、1系の給水要求信号が消滅す
るまでその状態を繰り返す。
On the other hand, when the water supply request signal of the second system is generated, the pump is turned off, the valve is closed, and the valve is opened without returning to the step of determining the generation of the water supply request signal of the first system. The pump is turned on, and it is determined whether a water supply request signal has been generated in the second system. If the second water supply request signal has been generated, the process returns to the determination step of the second water supply request signal and returns to step 2. The state is repeated until the water supply request signal of the system disappears. When the water supply request signal of the second system disappears, the pump is turned off, the process returns to the determination step of the generation of the water supply request signal of the first system, and the state is repeated until the water supply request signal of the first system disappears.

【0096】1系の給水要求信号が消滅すると、ポンプ
をOFFにし、最初に戻る。なお、上記の動作の条件
として、異常となった系にも減水信号が出力されている
ことが必要である。以上の動作により、1系および2系
の両方が正常なときは、ポンプおよびポンプがそれ
ぞれ動作して給水要求信号に従って動作し、各々1系お
よび2系の高架水槽へ給水する。
When the water supply request signal of the first system disappears, the pump is turned off and the process returns to the beginning. As a condition for the above operation, it is necessary that the water reduction signal is also output to the abnormal system. According to the above operation, when both the first system and the second system are normal, the pump and the pump operate to operate according to the water supply request signal, and supply water to the first and second system elevated water tanks.

【0097】また、例えば1系が異常となったときは、
ポンプが止まるので、ポンプにより1系の高架水槽
へ給水する。ポンプが2系の高架水槽への給水を行っ
ている期間はポンプによる1系の高架水槽への給水は
行わず、ポンプによる2系の高架水槽への給水が終了
した後でポンプによる1系の高架水槽への給水を行
う。そして、ポンプによる1系の高架水槽への給水が
終了すると、ポンプによる1系および2系の高架水槽
への給水が同じ条件で行われることになる。この際、1
系への給水中に2系から給水要求があったときは、1系
への給水を中断して2系への給水を行い、2系の給水の
終了後1系の給水を再開し、同様に2系への給水中に1
系から給水要求があったときは、2系への給水を中断し
て1系への給水を行い、1系の給水の終了後2系の給水
を再開する。
For example, when the system 1 becomes abnormal,
Since the pump stops, water is supplied to the elevated water tank of the first system by the pump. While the pump is supplying water to the 2nd elevated water tank, the pump does not supply water to the 1st elevated water tank, and after the water supply to the 2nd elevated water tank is completed by the pump, the 1st Supply water to the elevated water tank. When the water supply to the first system elevated water tank by the pump is completed, the water supply to the first system and second system elevated water tank by the pump is performed under the same conditions. At this time, 1
When there is a water supply request from the second system during the water supply to the system, the water supply to the first system is interrupted and the water supply to the second system is resumed. 1 to the water supply to system 2
When there is a water supply request from the system, the water supply to the second system is interrupted to supply water to the first system, and after the completion of the first system water supply, the second system water supply is resumed.

【0098】2系が異常となった時も、ポンプが止ま
るので、ポンプにより2系の高架水槽へ給水する。ポ
ンプが1系の高架水槽への給水を行っている期間はポ
ンプによる2系の高架水槽への給水は行わず、ポンプ
による1系の高架水槽への給水が終了した後でポンプ
による2系の高架水槽への給水を行う。そして、ポン
プによる2系の高架水槽への給水が終了すると、ポン
プにより1系および2系の高架水槽への給水が同じ条
件で行われることになる。この際も同様に、1系への給
水中に2系から給水要求があったときは、1系への給水
を中断して2系への給水を行い、2系の給水の終了後1
系の給水を再開し、同様に2系への給水中に1系から給
水要求があったときは、2系への給水を中断して1系へ
の給水を行い、1系の給水の終了後2系の給水を再開す
る。
When the system 2 becomes abnormal, the pump stops, and the pump supplies water to the system 2 elevated water tank. During the period when the pump is supplying water to the 1st elevated water tank, water is not supplied to the 2nd elevated water tank by the pump, and after the water supply to the 1st elevated water tank by the pump is completed, Supply water to the elevated water tank. When the water supply to the second system elevated water tank by the pump is completed, the pump supplies water to the first system and the second system elevated water tank under the same conditions. In this case, similarly, when there is a water supply request from the second system during the water supply to the first system, the water supply to the first system is interrupted and the water is supplied to the second system.
When the water supply to the system is restarted and the water supply is requested from the system 1 during the water supply to the system 2 as well, the water supply to the system 2 is interrupted and the water supply to the system 1 is performed, and the water supply to the system 1 is completed. After that, the water supply of the second system is restarted.

【0099】このような動作により、1系および2系の
片方が異常となったときは、正常側および異常側の系の
高架水槽は、ともに減水レベルと満水レベルの間で水位
が制御されることになり、異常側の系の高架水槽の水位
の変動幅は正常側の系と同じになる。この実施例の給水
装置によれば、第1の動作の実行中に渇水信号を出力し
た建物51からの給水要求信号が発生したときには第2
の動作が優先して実行され、第2の動作の終了後に第1
の動作が再開し、第2の動作の実行中に被連結側の建物
52からの給水要求信号が発生したときには第1の動作
が優先して実行され、第1の動作の終了後に第2の動作
が再開するので、渇水信号を出力した建物51への給水
中に被連結側の建物52が渇水状態となったり、被連結
側の建物52への給水中に渇水信号を出力した建物51
が渇水状態となるおそれを少なくでき、さらに一層安定
した水の供給が可能となる。
When one of the systems 1 and 2 becomes abnormal by such an operation, the elevated water tanks of the normal side and the abnormal side both have their water levels controlled between the reduced water level and the full water level. That is, the fluctuation range of the water level of the elevated water tank in the abnormal system is the same as that in the normal system. According to the water supply device of this embodiment, when the water supply request signal from the building 51 that outputs the drought signal during the execution of the first operation is generated, the second operation is performed.
Is performed with priority, and after the second operation is completed, the first operation is performed.
When the water supply request signal from the connected building 52 is generated during the execution of the second operation, the first operation is preferentially executed, and the second operation is performed after the first operation is completed. Since the operation is resumed, the connected building 52 becomes drought during the water supply to the building 51 that has output the drought signal, or the building 51 that has output the drought signal during the water supply to the connected building 52.
Can be less likely to be in a drought state, and the water can be supplied more stably.

【0100】なお、上記第6の実施例の構成において
は、後で給水要求信号が発生した方への給水を優先させ
る構成としたが、複数の建物からの給水要求信号が重な
って発生している期間には、両建物51,52へ所定時
間ずつ、例えば1分ないし10分ずつ交互に給水するよ
うにしてもよい。このように構成すると、複数の建物か
らの給水要求信号が重なって発生している期間において
複数の建物の何れか一つへ給水中に他の何れかの建物
が渇水状態となるおそれを一層少なくできる。当然、片
方が満水状態になれば、当然残りの方へのみ給水するの
はいうまでもないことである。
In the configuration of the sixth embodiment, the priority is given to the water supply to the one where the water supply request signal is generated later. However, when the water supply request signals from a plurality of buildings overlap, the water supply request signal is generated. During this period, water may be alternately supplied to both buildings 51 and 52 for a predetermined time, for example, 1 minute to 10 minutes. With such a configuration, during a period in which the water supply request signals from the plurality of buildings overlap, the risk that one of the plurality of buildings becomes drought during the water supply to one of the plurality of buildings is further increased. Can be reduced. Of course, when one of them is full, it goes without saying that water is supplied only to the other.

【0101】〔参考例つぎの実施例の説明の参考となる給水装置 を図18およ
び図19に基づいて説明する。この給水装置は、図18
および図19に示すように、複数の建物(参考例では2
戸であるが、3戸以上でもよい)51,52内に水を供
給するもので、各建物51,52への水分配部57Bの
分岐側に各々バルブ55,56を設けるとともにこの水
分配部57Bに水を汲み上げる動作を交互に行う複数台
(建物数と同数またはそれより少ない台数)の給水ポン
プ53,54を設け、バルブ55,56を開いた建物5
1,52からの給水要求信号に応答して複数台の給水ポ
ンプ53,54を交互に(3台以上の場合はサイクリッ
クに)動作制御したことを特徴とする。
[ Reference Example ] A water supply device serving as a reference for the description of the next embodiment will be described with reference to FIGS. This water supply device is shown in FIG.
And as shown in FIG. 19, a plurality of buildings (in Reference Example 2
It supplies water to the inside of 51 and 52. Valves 55 and 56 are provided on the branch side of the water distribution unit 57B to each of the buildings 51 and 52, and the water distribution unit is provided. A building 5 in which a plurality of water pumps 53, 54 (the same number or less than the number of buildings) for alternately pumping water is provided in 57B, and valves 55, 56 are opened.
A plurality of water supply pumps 53 and 54 are alternately operated (cyclically when three or more water supply pumps are used) in response to a water supply request signal from the first and second water supply request signals.

【0102】この給水装置では、バルブ55または56
を開いた建物51または52からの給水要求信号に応答
して複数台の給水ポンプ53,54が交互に動作して給
水を行うことになる。なお、この場合、給水要求信号が
発生する毎に、対応するバルブ55または56を選択的
に開けることが必要である。上記以外の点は、第3の実
施例と同様であるので、説明を省略する。
In this water supply device, the valve 55 or 56
In response to the water supply request signal from the building 51 or 52 having opened the water supply pumps 53 and 54, the water supply pumps 53 and 54 operate alternately to supply water. In this case, it is necessary to selectively open the corresponding valve 55 or 56 every time the water supply request signal is generated. The other points are the same as in the third embodiment, and the description is omitted.

【0103】この参考例の給水装置によれば、バルブ5
5または56を開いた建物51または52からの給水要
求信号に応答して複数台の給水ポンプ53,54が交互
に動作して給水を行うことができ、例えば1台の給水ポ
ンプ53が故障したときには残りの給水ポンプ54で複
数の建物51,52への給水を継続でき、少ない給水ポ
ンプ台数で複数の建物への水の供給を安定して行うこと
ができる。
According to the water supply device of this reference example , the valve 5
In response to a water supply request signal from a building 51 or 52 with 5 or 56 opened, a plurality of water supply pumps 53 and 54 can be operated alternately to supply water, for example, one water supply pump 53 fails. Sometimes, the remaining water supply pump 54 can continue to supply water to the plurality of buildings 51 and 52, and the supply of water to the plurality of buildings can be stably performed with a small number of water supply pumps.

【0104】〔第の実施例〕 この発明の第の実施例を図20に基づいて説明する。
この給水装置は、図20に示すように、バルブ55,5
6に代えて電気信号に応答して開閉する電動バルブ55
A,56Aを用い、各建物51,52からの給水要求信
号に応答して各電動バルブ55A,56Aの開閉制御を
行う信号を出力するバルブ制御手段(図示せず)を設け
ている。
[ Seventh Embodiment] A seventh embodiment of the present invention will be described with reference to FIG.
As shown in FIG. 20, the water supply device includes valves 55, 5
6, an electric valve 55 that opens and closes in response to an electric signal
A and 56A are provided with valve control means (not shown) for outputting a signal for controlling the opening and closing of each of the electric valves 55A and 56A in response to a water supply request signal from each of the buildings 51 and 52.

【0105】この給水装置では、各建物51,52から
の給水要求信号に応答して、給水要求信号を発生した建
物51,52へ給水を行うためのバルブが自動的に開く
ことになる。その他は、図18および図19に示した給
水装置と同様である。この実施例の給水装置によれば、
各建物からの給水要求信号に応答して、給水要求信号を
発生した建物へ給水を行うためのバルブが自動的に開く
ので、異常時に自動的に異常状態を解消することがで
き、補修員による対策を緊急性を解消することができ
る。
In this water supply apparatus, in response to a water supply request signal from each of the buildings 51 and 52, a valve for supplying water to the buildings 51 and 52 that have generated the water supply request signal is automatically opened. Others are the same as the water supply device shown in FIG. 18 and FIG. According to the water supply device of this embodiment,
In response to the water supply request signal from each building, the valve for supplying water to the building that generated the water supply request signal automatically opens, so that abnormal conditions can be automatically canceled when abnormal, Measures can eliminate urgency.

【0106】特に、上記第の実施例の構成において
、バルブ制御手段を、複数の建物からの給水要求信号
が重なって発生している期間には、複数のバルブを所定
時間ずつ、例えば1分ないし10分ずつ順次サイクリッ
クに開くように複数のバルブを開閉動作させるように構
している。このように構成すると、複数の建物からの
給水要求信号が重なって発生している期間には、複数の
バルブを所定時間ずつ順次サイクリックに開くように複
数のバルブが開閉動作するので、複数の建物の何れか一
つへ給水中に他の何れかの建物が渇水状態となるおそ
れを少なくできる。また、複数の建物からの給水要求信
号が重なって発生する場合でも、一つの建物について給
水可能な能力を持つだけの小容量の給水ポンプを用いて
複数の建物への給水を行うことができ、したがって低い
設備コストで複数の建物からの同時の給水要求に応える
ことができる。
In particular , in the configuration of the seventh embodiment,
A plurality of valves are controlled so as to cyclically open a plurality of valves at predetermined time intervals, for example, every 1 to 10 minutes, during a period in which water supply request signals from a plurality of buildings overlap. It is configured so as to open and close operation of the valve. With such a configuration, during a period in which water supply request signals from a plurality of buildings overlap, a plurality of valves are opened and closed so as to sequentially open a plurality of valves sequentially for a predetermined time. any buildings in the feedwater of the other to any one of the building can be reduced the risk of the drought state. Water supply requests from multiple buildings
Even if overlapping numbers occur, supply for one building
Using a small-capacity water supply pump that has only water-capable capacity
Water can be supplied to multiple buildings and therefore low
Meet simultaneous water demands from multiple buildings at equipment cost
be able to.

【0107】また、バルブ制御手段を、渇水信号が入力
された時に、渇水信号を出力した建物内へ水を供給する
バルブを優先的に開くように構成してもよい。このよう
に構成すると、渇水信号が入力された時に、渇水信号を
出力した建物内へ水を供給するバルブが優先的に開くの
で、渇水信号を発生した建物の渇水を防止できる。
Further, the valve control means may be configured such that, when a drought signal is input, a valve for supplying water to the building that has output the drought signal is preferentially opened. With this configuration, when the drought signal is input, the valve that supplies water into the building that has output the drought signal opens preferentially, so that the building that has generated the drought signal can be prevented from being drought.

【0108】[0108]

【発明の効果】請求項1記載の給水装置によれば、各建
物について1台ずつの給水ポンプを設ける他に、全建物
について1台の補助給水ポンプを設けるとともに、補助
給水ポンプの出力部と各建物毎の給水ポンプの出力部と
を結合するバルブを設けるだけで、つまり少ない給水ポ
ンプ台数で各建物への水供給を安定して行うことができ
る。また、常時は補助給水ポンプと1台の給水ポンプと
を対にして交互運転を行うので、各建物毎の給水ポンプ
だけでなく、補助給水ポンプも常に動作状態に保つこと
ができ、錆や劣化で異常時に補助給水ポンプが動作不良
を起こすおそれを少なくすることができる。
According to the water supply apparatus of the first aspect, in addition to providing one water supply pump for each building, one auxiliary water supply pump is provided for all buildings, and the output section of the auxiliary water supply pump is provided. The water supply to each building can be stably performed with a small number of water supply pumps only by providing a valve that connects the output section of the water supply pump for each building. In addition, the auxiliary water supply pump and one water supply pump are always operated alternately, so that not only the water supply pump for each building but also the auxiliary water supply pump can always be kept in operation, resulting in rust and deterioration. Thus, the possibility that the auxiliary water supply pump malfunctions in the event of an abnormality can be reduced.

【0109】請求項2記載の給水装置によれば、各建物
からの渇水信号の入力に応答して渇水信号を出力した建
物に対応した一つの電動バルブが自動的に開き残りの建
物に対応した残りの電動バルブが自動的に閉じるので、
異常時に自動的に異常状態を解消することができ、補修
員による対策を緊急性を解消することができる。請求項
3記載の給水装置によれば、建物数と同数の給水ポンプ
を設けるだけで、つまり少ない給水ポンプ台数で各建物
への水供給を安定して行うことができる。
According to the water supply device of the present invention, one electric valve corresponding to the building that has output the drought signal in response to the input of the drought signal from each building is automatically opened to correspond to the remaining buildings. The remaining motorized valves close automatically,
In the event of an abnormality, the abnormal state can be automatically eliminated, and the urgency of the measures taken by the repair staff can be eliminated. According to the water supply device of the third aspect, it is possible to stably supply water to each building with only a small number of water supply pumps by providing the same number of water supply pumps as the number of buildings.

【0110】請求項4記載の給水装置によれば、各建物
からの渇水信号の入力に応答して渇水信号を出力した建
物に対応した給水ポンプの出力部に結合した連結バルブ
が自動的に開き、被連結側の給水ポンプの主バルブが自
動的に閉じるので、異常時に自動的に異常状態を解消す
ることができ、補修員による対策を緊急性を解消するこ
とができる。
According to the fourth aspect of the present invention, the connecting valve connected to the output of the water supply pump corresponding to the building that has output the drought signal in response to the input of the drought signal from each building automatically opens. Since the main valve of the feed water pump on the connected side is automatically closed, the abnormal state can be automatically eliminated in the event of an abnormality, and the urgency of the measures taken by the repair staff can be eliminated.

【0111】請求項5記載の給水装置によれば、渇水信
号を出力した建物からの給水要求信号が消滅すると、被
連結側の給水ポンプの出力部に設けた主バルブが自動的
に開き、連結バルブが自動的に閉じ、被連結側の建物か
らの給水要求信号に応答して被連結側の給水ポンプを動
作させるので、渇水信号を出力した建物への給水を行う
だけでなく、被連結側の建物への給水も行え、補修を長
時間にわたって行わずに放置していても、安定した水の
供給が可能となる。
According to the water supply device of the fifth aspect, when the water supply request signal from the building that has output the drought signal disappears, the main valve provided at the output of the water supply pump on the connected side is automatically opened to connect the water supply pump. The valve automatically closes, and the water supply pump on the connected side operates in response to the water supply request signal from the building on the connected side, so not only can water be supplied to the building that output the drought signal, but also on the connected side. Water can be supplied to the building, and stable water supply is possible even if the repair is not performed for a long time.

【0112】請求項6記載の給水装置によれば、渇水信
号を出力した建物への給水と被連結側の建物への給水が
対等な関係で行われることになり、渇水信号を出力した
建物への給水も被連結側の建物への給水と同じ条件で行
われることになり、渇水信号を出力した建物について
も、つぎに渇水状態となる前に、つまり減水状態となっ
た時点から給水を行うことが可能となり、一層安定した
水の供給が可能となる。
According to the water supply apparatus of the sixth aspect, the water supply to the building that has output the drought signal and the water supply to the building on the connected side are performed in an equal relationship, and the water supply to the building that has output the drought signal is performed. Will be performed under the same conditions as the water supply to the connected building, and the building that has output the drought signal will also supply water before the next drought condition, that is, from the time of the reduced water condition. It is possible to supply water more stably.

【0113】請求項7記載の給水装置によれば、第1の
動作の実行中に渇水信号を出力した建物からの給水要求
信号が発生したときには第2の動作が優先して実行さ
れ、第2の動作の終了後に第1の動作が再開し、第2の
動作の実行中に被連結側の建物からの給水要求信号が発
生したときには第1の動作が優先して実行され、第1の
動作の終了後に第2の動作が再開するので、渇水信号を
出力した建物への給水中に被連結側の建物が渇水状態と
なったり、被連結側の建物への給水中に渇水信号を出力
した建物が渇水状態となるおそれを少なくでき、さらに
一層安定した水の供給が可能となる。請求項8記載の給
水装置によれば、給水要求信号に応答して複数台の給水
ポンプが順次サイクリックに動作して給水を行うことが
でき、例えば1台の給水ポンプが故障したときには残り
の給水ポンプで複数の建物への給水を継続でき、少ない
給水ポンプ台数で複数の建物への水の供給を安定して行
うことができる。
According to the water supply apparatus of the seventh aspect, when a water supply request signal from a building that has output a drought signal during execution of the first operation is generated, the second operation is executed with priority, and the second operation is executed. After the end of the operation, the first operation is restarted, and when a water supply request signal from the connected building is generated during the execution of the second operation, the first operation is preferentially executed, and the first operation is performed. Since the second operation is resumed after the completion of the operation, the connected building is in a drought state during the water supply to the building that has output the drought signal, or the drought signal is output during the water supply to the connected building. The risk of the building being in a drought state can be reduced, and the water can be supplied more stably. According to the water supply device according to claim 8, rest when in response to a water supply request signal can supply the water operates to sequentially cyclically is a plurality of water supply pumps, for example the one of the feedwater pumps failed The water supply pump can continue to supply water to a plurality of buildings, and the supply of water to a plurality of buildings can be stably performed with a small number of water supply pumps.

【0114】また、各建物からの給水要求信号に応答し
て、給水要求信号を発生した建物へ給水を行うための
バルブが自動的に開くので、異常時に自動的に異常状
態を解消することができ、補修員による対策を緊急性を
解消することができる。さらに、複数の建物からの給水
要求信号が重なって発生している期間には、複数の電動
バルブを所定時間ずつ順次サイクリックに開くように複
数の電動バルブが開閉動作するので、複数の建物の何れ
か一つへ給水中に他の何れかの建物が渇水状態となる
おそれを少なくできる。また、複数の建物からの給水要
求信号が重なって発生する場合でも、一つの建物につい
て給水可能な能力を持つだけの小容量の給水ポンプを用
いて複数の建物への給水を行うことができ、したがって
低い設備コストで複数の建物からの同時の給水要求に応
えることができる。
In addition, in response to a water supply request signal from each building , a power supply for supplying water to the building that has generated the water supply request signal.
Since the dynamic valve is automatically opened, an abnormal state can be automatically eliminated in the event of an abnormality, and the urgency of measures taken by the repair staff can be eliminated. Further, during a period in which water supply request signals from a plurality of buildings overlap, a plurality of electrically operated valves are opened and closed so that a plurality of electrically operated valves are sequentially and cyclically opened at predetermined time intervals. a plurality of any other building feedwater to any one of the building can be reduced the risk of the drought state. It is also necessary to supply water from multiple buildings.
Even if signal requests overlap, it may not be possible to
Use a small-capacity water supply pump with enough capacity to supply water
To supply water to multiple buildings
Simultaneous water demand from multiple buildings at low equipment cost
Can be obtained.

【0115】請求項9記載の給水装置によれば、渇水信
号が入力された時に、渇水信号を出力した建物内へ水を
供給する電動バルブが優先的に開くので、渇水信号を発
生した建物の渇水を防止できる。
According to the water supply device of the ninth aspect , when the drought signal is input, the motor-operated valve for supplying water to the building that has output the drought signal opens preferentially. Drought can be prevented.

【図面の簡単な説明】[Brief description of the drawings]

【図1】この発明の第1の実施例の給水装置の構成を示
す概略図である。
FIG. 1 is a schematic diagram showing a configuration of a water supply device according to a first embodiment of the present invention.

【図2】同じくこの発明の第1の実施例の給水装置の構
成を示す概略図である。
FIG. 2 is a schematic diagram showing a configuration of a water supply device according to the first embodiment of the present invention.

【図3】制御盤の構成を示すブロック図である。FIG. 3 is a block diagram illustrating a configuration of a control panel.

【図4】制御盤内の故障対応スイッチおよび信号処理部
の構成を示す回路図である。
FIG. 4 is a circuit diagram showing a configuration of a failure handling switch and a signal processing unit in a control panel.

【図5】図4の各部の動作を示すタイムチャートであ
る。
FIG. 5 is a time chart illustrating the operation of each unit in FIG. 4;

【図6】この発明の第2の実施例の給水装置の構成を示
す概略図である。
FIG. 6 is a schematic diagram illustrating a configuration of a water supply device according to a second embodiment of the present invention.

【図7】同じくこの発明の第2の実施例の給水装置の構
成を示す概略図である。
FIG. 7 is a schematic diagram showing a configuration of a water supply device according to a second embodiment of the present invention.

【図8】制御盤の構成を示すブロック図である。FIG. 8 is a block diagram showing a configuration of a control panel.

【図9】この発明の第3の実施例の給水装置の構成を示
す概略図である。
FIG. 9 is a schematic diagram showing a configuration of a water supply device according to a third embodiment of the present invention.

【図10】同じくこの発明の第3の実施例の給水装置の
構成を示す概略図である。
FIG. 10 is a schematic diagram showing a configuration of a water supply device according to a third embodiment of the present invention.

【図11】制御盤の構成を示すブロック図である。FIG. 11 is a block diagram showing a configuration of a control panel.

【図12】この発明の第4の実施例の給水装置の構成を
示す概略図である。
FIG. 12 is a schematic diagram showing a configuration of a water supply device according to a fourth embodiment of the present invention.

【図13】制御盤の構成を示すブロック図である。FIG. 13 is a block diagram showing a configuration of a control panel.

【図14】給水ポンプおよびバルブの制御の様子を示す
フローチャートである。
FIG. 14 is a flowchart showing a state of control of a water supply pump and a valve.

【図15】この発明の第5の実施例の給水装置における
給水ポンプおよびバルブの制御の様子を示すフローチャ
ートである。
FIG. 15 is a flowchart showing how a water supply pump and a valve are controlled in a water supply device according to a fifth embodiment of the present invention.

【図16】この発明の第6の実施例の給水装置における
給水ポンプおよびバルブの制御の様子を示すフローチャ
ートである。
FIG. 16 is a flowchart showing how a water supply pump and a valve are controlled in a water supply device according to a sixth embodiment of the present invention.

【図17】この発明の第6の実施例の給水装置における
給水ポンプおよびバルブの制御の様子を示すフローチャ
ートである。
FIG. 17 is a flowchart showing how a water supply pump and a valve are controlled in a water supply device according to a sixth embodiment of the present invention.

【図18】参考例の給水装置の構成を示す概略図であ
る。
FIG. 18 is a schematic diagram illustrating a configuration of a water supply device of a reference example .

【図19】同じく参考例の給水装置の構成を示す概略図
である。
FIG. 19 is a schematic diagram showing a configuration of a water supply device of a reference example .

【図20】この発明の第の実施例の給水装置の構成を
示す概略図である。
FIG. 20 is a schematic diagram showing a configuration of a water supply device according to a seventh embodiment of the present invention.

【符号の説明】[Explanation of symbols]

1〜3 建物 4〜6 給水ポンプ 7 補助給水ポンプ 8〜10 バルブ 12 受水槽 16〜18 高架水槽 1-3 Building 4-6 Water pump 7 Auxiliary water pump 8-10 Valve 12 Water tank 16-18 Elevated water tank

Claims (9)

(57)【特許請求の範囲】(57) [Claims] 【請求項1】 複数の建物内に水を供給する給水装置に
おいて、前記建物毎に、各建物からの給水要求信号に応
答して動作し前記建物内に水を供給する給水ポンプを各
々設置し、前記建物毎の給水ポンプとは別に補助給水ポ
ンプを設け、この補助給水ポンプの出力部を各々バルブ
を介して前記建物毎の給水ポンプの出力部に連結し、前
記補助給水ポンプと任意に選択された一つの建物に対応
した給水ポンプと対にして前記選択された一つの建物か
らの給水要求信号に応答して交互に動作させるポンプ制
御手段を設けたことを特徴とする給水装置。
1. A water supply apparatus for supplying water to a plurality of buildings, wherein a water supply pump which operates in response to a water supply request signal from each building and supplies water to the buildings is provided for each of the buildings. An auxiliary water supply pump is provided separately from the water supply pump for each building, and an output of the auxiliary water supply pump is connected to an output of the water supply pump for each building via a valve, and optionally selected as the auxiliary water supply pump. And a pump control means which alternately operates in response to a water supply request signal from the selected one building in combination with a water supply pump corresponding to the selected one building.
【請求項2】 各バルブを電気信号に応答して開閉する
電動バルブとするとともに、この電動バルブを開閉駆動
するバルブ制御手段を設け、常時は前記バルブ制御手段
より選定された一つの建物に対応した給水ポンプの出力
部に対して補助給水ポンプの出力部を連通させるように
一つの電動バルブを開くとともに残りの電動バルブを閉
じる信号を出力し、ポンプ制御手段により前記補助給水
ポンプと前記選択された一つの建物に対応した給水ポン
プとを対にして前記選択された建物からの給水要求信号
に応答して交互に動作させるようにし、各建物からの渇
水信号の入力に応答して前記バルブ制御手段より渇水信
号を出力した建物に対応した一つの電動バルブを開き残
りの建物に対応した残りの電動バルブを閉じる信号を出
力し、前記補助給水ポンプを渇水信号を出力した建物か
らの給水要求信号に応答して単独動作させるようにした
ことを特徴とする請求項1記載の給水装置。
2. An electric valve which opens and closes each valve in response to an electric signal, and a valve control means for opening and closing this electric valve is provided, which always corresponds to one building selected by said valve control means. One electric valve is opened and a signal for closing the remaining electric valves is output so that the output part of the auxiliary water supply pump communicates with the output part of the supplied water supply pump, and the auxiliary water supply pump and the selected one are output by pump control means. And a water supply pump corresponding to one of the buildings is operated alternately in response to a water supply request signal from the selected building, and the valve control is performed in response to a drought signal input from each building. Means for opening one electric valve corresponding to the building that has output the drought signal from the means and outputting a signal for closing the remaining electric valves corresponding to the remaining buildings, The water supply apparatus according to claim 1, wherein the pump is operated independently in response to a water supply request signal from a building that has output a drought signal.
【請求項3】 複数の建物内に水を供給する給水装置に
おいて、前記建物毎に、各建物内からの給水要求信号に
応答して動作し前記建物内に水を供給する給水ポンプを
各々設置し、前記給水ポンプの当該建物内に水を供給す
る出力部に主バルブを設け、前記主バルブの給水ポンプ
側で前記給水ポンプの出力部を連結バルブを介して他の
給水ポンプの出力部に結合したことを特徴とする給水装
置。
3. A water supply device for supplying water to a plurality of buildings, wherein a water supply pump for operating in response to a water supply request signal from each building and supplying water to the buildings is provided for each of the buildings. A main valve is provided at an output part of the water supply pump that supplies water into the building, and the output part of the water supply pump is connected to the output part of another water supply pump via a connection valve on the water supply pump side of the main valve. A water supply device characterized by being combined.
【請求項4】 主バルブおよび連結バルブを電気信号に
応答して開閉する電動バルブとし、前記主バルブおよび
連結バルブを開閉駆動するバルブ制御手段を設け、常時
は前記バルブ制御手段より主バルブを開いて連結バルブ
を閉じる信号を出力し、各建物からの給水要求信号に応
答して各建物に対応した給水ポンプを動作させ、建物内
の渇水信号の入力に応答して前記連結バルブを開いて被
連結側の給水ポンプの出力部に設けた主バルブを閉じる
信号を出力し、渇水信号を出力した建物からの給水要求
信号に応答して被連結側の給水ポンプを動作させるよう
にしたことを特徴とする請求項3記載の給水装置。
4. An electric valve which opens and closes a main valve and a connection valve in response to an electric signal, and valve control means for driving the main valve and the connection valve to open and close is provided, and the main valve is normally opened by the valve control means. And outputs a signal to close the connection valve, operates a water supply pump corresponding to each building in response to a water supply request signal from each building, and opens and closes the connection valve in response to the input of a drought signal in the building. A signal that closes a main valve provided at an output portion of the connection-side water supply pump is output, and the connection-side water supply pump is operated in response to a water supply request signal from a building that outputs a drought signal. The water supply device according to claim 3, wherein
【請求項5】 渇水信号を出力した建物からの給水要求
信号の消滅に応答して、バルブ制御手段より前記被連結
側の給水ポンプの出力部に設けた主バルブを開いて連結
バルブを閉じる信号を出力し、前記被連結側の建物から
の給水要求信号に応答して前記被連結側の給水ポンプを
動作させるようにしたことを特徴とする請求項4記載の
給水装置。
5. A signal in response to the disappearance of a water supply request signal from a building that has output a drought signal, a valve control means for opening a main valve provided at an output part of the water supply pump on the connected side and closing a connection valve. 5. The water supply device according to claim 4, wherein the water supply pump is output in response to a water supply request signal from the building on the connected side.
【請求項6】 渇水信号の発生に応答して異常モードを
保持する保持手段を設け、前記保持手段が異常モードを
保持している期間中において、バルブ制御手段より前記
被連結側の給水ポンプの出力部に設けた主バルブを開い
て連結バルブを閉じる信号を出力し前記被連結側の建物
からの給水要求信号に応答して前記被連結側の給水ポン
プを動作させる第1の動作と、前記バルブ制御手段より
前記被連結側の給水ポンプの出力部に設けた主バルブを
閉じて前記連結バルブを開く信号を出力し前記渇水信号
を出力した建物からの給水要求信号に応答して前記被連
結側の給水ポンプを動作させる第2の動作とを選択的に
行わせるようにしたことを特徴とする請求項4記載の給
水装置。
6. A holding means for holding an abnormal mode in response to the occurrence of a drought signal, and during a period in which the holding means holds the abnormal mode, a valve control means controls the water supply pump on the connected side. A first operation of opening a main valve provided in an output unit and outputting a signal for closing a connection valve and operating the water supply pump on the connection side in response to a water supply request signal from the building on the connection side; In response to a water supply request signal from a building that outputs a signal to open a connection valve and outputs the drought signal by closing a main valve provided at an output portion of the water supply pump on the connection side by valve control means, The water supply device according to claim 4, wherein the second operation for operating the water supply pump on the side is selectively performed.
【請求項7】 渇水信号の発生に応答して異常モードを
保持する保持手段を設け、前記保持手段が異常モードを
保持している期間中において、バルブ制御手段より前記
被連結側の給水ポンプの出力部に設けた主バルブを開い
て連結バルブを閉じる信号を出力し前記被連結側の建物
からの給水要求信号に応答して前記被連結側の給水ポン
プを動作させる第1の動作と、前記バルブ制御手段より
前記被連結側の給水ポンプの出力部に設けた主バルブを
閉じて前記連結バルブを開く信号を出力し前記渇水信号
を出力した建物からの給水要求信号に応答して前記被連
結側の給水ポンプを動作させる第2の動作とを選択的に
行わせるようにし、かつ前記第1の動作の実行中に前記
渇水信号を出力した建物からの給水要求信号が発生した
ときには前記第2の動作を優先して実行させて前記第2
の動作の終了後に前記第1の動作を再開させるととも
に、前記第2の動作の実行中に前記被連結側の建物から
の給水要求信号が発生したときには前記第1の動作を優
先して実行させて前記第1の動作の終了後に前記第2の
動作を再開させるようにしたことを特徴とする請求項4
記載の給水装置。
7. A water supply pump on the connected side provided by a valve control means during a period in which the holding means holds the abnormal mode in response to generation of a drought signal. A first operation of opening a main valve provided in an output unit and outputting a signal for closing a connection valve and operating the water supply pump on the connection side in response to a water supply request signal from the building on the connection side; In response to a water supply request signal from a building that outputs a signal to open a connection valve and outputs the drought signal by closing a main valve provided at an output portion of the water supply pump on the connection side by valve control means, And the second operation for operating the water supply pump on the side is selectively performed, and when a water supply request signal from the building that outputs the drought signal is generated during execution of the first operation, the second operation is performed. of The operation is executed with priority and the second
After the completion of the operation, the first operation is resumed, and when a water supply request signal from the connected building is generated during the execution of the second operation, the first operation is preferentially executed. 5. The method according to claim 4, wherein the second operation is restarted after the first operation is completed.
Water supply device as described.
【請求項8】 複数の建物内に水を供給する給水装置に
おいて、前記各建物への水分配部に各々電気信号に応答
して開閉する電動バルブを設けるとともに、各建物から
の給水要求信号に応答して前記各電動バルブの開閉制御
を行う信号を出力するバルブ制御手段を設け、前記水分
配部に水を汲み上げる動作をサイクリックに行う複数台
の給水ポンプを設け、前記給水要求信号に応答して前記
複数台の給水ポンプを順次サイクリックに動作制御する
給水装置であって、前記バルブ制御手段を、前記複数の
建物からの給水要求信号が重なって発生している期間に
は、複数の電動バルブを所定時間ずつ順次サイクリック
に開くように前記複数の電動バルブを開閉動作させるよ
うに構成したことを特徴とする給水装置。
8. A water supply device for supplying water to a plurality of buildings, wherein a water distribution unit to each of the buildings responds to an electric signal.
Provided with an electric valve which is opened and closed from each building
Opening and closing control of each electric valve in response to a water supply request signal of
The valve control means for outputting a signal for providing said a plurality of feedwater pump for cyclically operating to pump water to the water distribution unit is provided, the plurality of the water supply pump in response to the previous SL water supply request signal Operation is controlled cyclically
A water supply device, wherein the valve control means comprises:
During the period when the water supply request signal from the building overlaps
Is to cycle multiple electric valves sequentially for a predetermined time
Open and close the plurality of electric valves so that
A water supply device characterized in that it is configured as follows.
【請求項9】 バルブ制御手段を、渇水信号が入力され
た時に、前記渇水信号を出力した建物内へ水を供給する
電動バルブを優先的に開くように構成した請求項8記載
給水装置。
9. A drought signal is input to the valve control means.
Supply water to the building that output the drought signal
9. The electric valve according to claim 8, wherein the electric valve is opened preferentially.
Water supply apparatus.
JP11309693A 1993-05-14 1993-05-14 Water supply device Expired - Fee Related JP3260476B2 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP11309693A JP3260476B2 (en) 1993-05-14 1993-05-14 Water supply device

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP11309693A JP3260476B2 (en) 1993-05-14 1993-05-14 Water supply device

Publications (2)

Publication Number Publication Date
JPH06322799A JPH06322799A (en) 1994-11-22
JP3260476B2 true JP3260476B2 (en) 2002-02-25

Family

ID=14603382

Family Applications (1)

Application Number Title Priority Date Filing Date
JP11309693A Expired - Fee Related JP3260476B2 (en) 1993-05-14 1993-05-14 Water supply device

Country Status (1)

Country Link
JP (1) JP3260476B2 (en)

Also Published As

Publication number Publication date
JPH06322799A (en) 1994-11-22

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