JPH1119680A - Sewage treatment device - Google Patents

Sewage treatment device

Info

Publication number
JPH1119680A
JPH1119680A JP9174670A JP17467097A JPH1119680A JP H1119680 A JPH1119680 A JP H1119680A JP 9174670 A JP9174670 A JP 9174670A JP 17467097 A JP17467097 A JP 17467097A JP H1119680 A JPH1119680 A JP H1119680A
Authority
JP
Japan
Prior art keywords
head
sensor
water
aeration
tank
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.)
Granted
Application number
JP9174670A
Other languages
Japanese (ja)
Other versions
JP3825534B2 (en
Inventor
Keiichi Fujimoto
恵一 藤本
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.)
Sanyo Electric Co Ltd
Original Assignee
Sanyo Electric Co 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 Sanyo Electric Co Ltd filed Critical Sanyo Electric Co Ltd
Priority to JP17467097A priority Critical patent/JP3825534B2/en
Publication of JPH1119680A publication Critical patent/JPH1119680A/en
Application granted granted Critical
Publication of JP3825534B2 publication Critical patent/JP3825534B2/en
Anticipated expiration legal-status Critical
Expired - Fee Related legal-status Critical Current

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Classifications

    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02WCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO WASTEWATER TREATMENT OR WASTE MANAGEMENT
    • Y02W10/00Technologies for wastewater treatment
    • Y02W10/10Biological treatment of water, waste water, or sewage

Landscapes

  • Separation Using Semi-Permeable Membranes (AREA)
  • Activated Sludge Processes (AREA)

Abstract

PROBLEM TO BE SOLVED: To simplify a structure compared to a conventional method and also to regulate the size of a filtering pressure when a cake layer develops on the membrane surface of a filter membrane device. SOLUTION: Sewage to be treated is stored in a flow rate regulating tank 1 of a sewage treating device D1 . The sewage (water to be treated) is pumped up with a flow rate regulating pump 3 by specified amount to flow into an aeration tank 2. An activated sludge is previously charged in the aeration tank 2. A filter membrane device 4 is provided in the inside of the aeration tank 2 in the state that the device is immersed in the water to be treated. The filter membrane device 4 is provided with a casing 5, plural filter membrane plates 6 hung and arranged in the inside and a suction header 7 mounted on their upper end. Each of the filter membrane plates 6 is composed of a core material and a filter material stuck on the surface of the core material and an activated sludge soln. in the aeration tank 2 is solid-liquid-separated to the activated sludge and a filtrate by filtration using a head as a driving pressure.

Description

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

【0001】[0001]

【発明の属する技術分野】本発明は汚水処理装置に関
し、さらに詳しくは、生活廃水や産業廃水などの汚水を
処理するために用いられ、活性汚泥の作用によって汚水
中の有機物や窒素分を除去するとともに、濾過膜によっ
て固液分離を行い、活性汚泥を残留させる一方で濾液を
流出させるようにする汚水処理装置に関する。BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sewage treatment apparatus, and more particularly, it is used for treating sewage such as domestic wastewater or industrial wastewater, and removes organic substances and nitrogen in sewage by the action of activated sludge. In addition, the present invention relates to a sewage treatment apparatus that performs solid-liquid separation by a filtration membrane and allows the filtrate to flow out while leaving activated sludge.

【0002】[0002]

【従来の技術】この種の汚水処理装置として、従来、汚
水に曝気を施して活性汚泥処理を行わせる曝気槽と、こ
の曝気槽に設けられ槽内の活性汚泥混合液を自然水頭を
駆動圧にした濾過(重力加圧濾過)により固液分離する
濾過膜装置と、この濾過膜装置に接続されて同部材によ
る濾液である浄化水を外部へ流出させるための流出管と
を備えたものが知られている。2. Description of the Related Art Conventionally, as this type of sewage treatment apparatus, an aeration tank for aerated sewage to perform activated sludge treatment, and an activated sludge mixed solution in the aeration tank provided in the aeration tank are driven by a natural hydraulic head. A filtration membrane device for solid-liquid separation by filtration (gravitational pressure filtration), and an outflow pipe connected to the filtration membrane device to allow purified water, which is a filtrate of the same member, to flow out. Are known.

【0003】このような汚水処理装置にあっては、曝気
槽に継続的に流入してくる汚水の量は流出管から継続的
に流出していく浄化水の量とのバランスをとる目的で適
宜調整されるようになっているため、曝気槽の水位は汚
水処理装置の作動中、ほぼ一定に保たれる。In such a sewage treatment apparatus, the amount of sewage continuously flowing into the aeration tank is appropriately adjusted in order to balance the amount of purified water continuously flowing out of the outflow pipe. Because of the adjustment, the water level in the aeration tank is kept substantially constant during the operation of the sewage treatment apparatus.

【0004】[0004]

【発明が解決しようとする課題】このような汚水処理装
置によれば、時間の経過とともに濾過膜装置の膜面に活
性汚泥などの固形物が付着して固形物層(ケーキ層)が
形成されるようになる。このケーキ層が発達すると、膜
面の一部が閉塞して濾液の量が減少したり膜面の全部閉
塞が生じて濾液がほとんどなくなったりするおそれがあ
る。According to such a sewage treatment apparatus, a solid substance such as activated sludge adheres to the membrane surface of the filtration membrane apparatus with the passage of time to form a solid substance layer (cake layer). Become so. When the cake layer develops, there is a possibility that a part of the membrane surface is clogged and the amount of filtrate is reduced, or the entire membrane surface is clogged and the filtrate almost disappears.

【0005】このようなおそれを防止するためには、濾
過膜装置の膜面にかかる濾過圧力の大きさを変更するこ
とが必要である。しかしながら、重力加圧濾過による汚
水処理装置においては曝気槽の水位はほぼ一定に保たれ
るため、その自然水頭の大きさすなわち濾過圧力の大き
さはほぼ一定であり、変更することはできない。[0005] In order to prevent such a fear, it is necessary to change the magnitude of the filtration pressure applied to the membrane surface of the filtration membrane device. However, in the sewage treatment apparatus by gravity pressure filtration, the water level of the aeration tank is kept almost constant, and the size of the natural head, that is, the magnitude of the filtration pressure is almost constant and cannot be changed.

【0006】本発明は、このような実情を考慮してなさ
れたものであり、構造が簡単であるうえ、濾過膜装置の
膜面にケーキ層が発達した際に濾過圧力の大きさを調整
することのできる汚水処理装置を提供することを課題と
する。The present invention has been made in view of such circumstances, has a simple structure, and adjusts the magnitude of filtration pressure when a cake layer develops on the membrane surface of a filtration membrane device. It is an object of the present invention to provide a sewage treatment apparatus that can perform the treatment.

【0007】[0007]

【課題を解決するための手段】本発明によれば、汚水に
活性汚泥処理を施す際に曝気を行うための曝気槽と、こ
の曝気槽の内側に設けられて槽内の活性汚泥混合液をそ
の水頭を駆動圧にした濾過により固液分離する濾過膜装
置と、この濾過膜装置に接続されて同部材による濾液で
ある浄化水を外部へ流出させるための流出管と、この流
出管に設けられて浄化水の単位時間当たりの流出量を検
知する流出量センサと、曝気槽の適正水頭範囲のうちの
少なくとも最低水頭及び最高水頭を検知するための水頭
センサと、この水頭センサに電気的に接続されて流出量
センサからの検知結果に基づき水頭を適正水頭範囲で調
整すべく制御する制御部とを備えたことを特徴とする汚
水処理装置が提供される。According to the present invention, an aeration tank for performing aeration when sewage is subjected to an activated sludge treatment, and an activated sludge mixed liquid provided inside the aeration tank in the tank are provided. A filtration membrane device that performs solid-liquid separation by filtration with the head at a driving pressure, an outflow pipe connected to the filtration membrane device to allow purified water that is filtrate by the same member to flow out, and an outflow pipe provided in the outflow pipe A runoff sensor for detecting the flow rate of purified water per unit time, a head sensor for detecting at least a minimum head and a maximum head in an appropriate head range of the aeration tank, and an electrical sensor for the head sensor. A sewage treatment apparatus, comprising: a control unit that is connected to control a head to be adjusted within an appropriate head range based on a detection result from the outflow amount sensor.

【0008】曝気槽は、例えば槽外の空気供給手段に接
続される曝気管が槽底などに配され、汚水導入管などか
ら導入された汚水(被処理水)を、槽内に入れられた活
性汚泥を用いて好気条件下で生物学的に処理する。In the aeration tank, for example, an aeration pipe connected to an air supply means outside the tank is arranged at the bottom of the tank, and sewage (water to be treated) introduced from a sewage introduction pipe or the like is put into the tank. Biological treatment under aerobic conditions using activated sludge.

【0009】濾過膜装置は、槽内の活性汚泥混合液(活
性汚泥と被処理水との混合液)を濾過により活性汚泥と
濾液(浄化水)とに固液分離する。濾過膜装置としては
例えば、上下に開口する箱状のケーシングの内部に1個
の濾過膜体を配置しまたは複数枚の濾過膜板を並列配置
したものなどが用いられる。このような濾過膜装置は曝
気槽の内側に着脱可能または固着状に設けられる。濾過
膜装置が着脱可能に設けられた場合は、その保守・点検
や清掃が容易になる。濾過膜体または濾過膜板は前記曝
気管により供給される曝気用空気に触れる位置に設けら
れるのがいっそう好ましい。曝気用空気により膜面の洗
浄を行うことができるからである。The filtration membrane device separates the activated sludge mixed liquid (mixed liquid of activated sludge and water to be treated) in the tank into solid and liquid by filtration into activated sludge and a filtrate (purified water). As the filtration membrane device, for example, a device in which one filtration membrane body is arranged inside a box-shaped casing that opens vertically or a plurality of filtration membrane plates are arranged in parallel is used. Such a filtration membrane device is detachably or fixedly provided inside the aeration tank. When the filtration membrane device is detachably provided, maintenance, inspection and cleaning thereof are facilitated. More preferably, the filtration membrane or the filtration membrane plate is provided at a position in contact with the aeration air supplied by the aeration tube. This is because the film surface can be washed with the air for aeration.

【0010】流出管は、濾過膜装置による濾液である浄
化水を外部へ流出させるためのものであり、濾過膜装置
の濾過膜体または濾過膜板などに接続される。The outflow pipe is for letting purified water, which is a filtrate from the filtration membrane device, flow out to the outside, and is connected to a filtration membrane or a filtration membrane plate of the filtration membrane device.

【0011】流出量センサは流出管の所定箇所に設けら
れる。そして、流出管を通って外部へ流出する浄化水の
単位時間当たりの流出量を常時または一定時間ごとに検
知する。The outflow sensor is provided at a predetermined position of the outflow pipe. Then, the amount of purified water flowing out to the outside through the outflow pipe per unit time is constantly or periodically detected.

【0012】曝気槽における活性汚泥混合液の水位すな
わち水頭は、流出管を通って外部へ流出する浄化水の単
位時間当たりの流出量を一定の許容範囲に維持するため
に、適正な範囲(適正水頭範囲)に決められる。この適
正水頭範囲の下限を最低水頭と称し、上限を最高水頭と
称する。The water level of the activated sludge mixture in the aeration tank, that is, the water head, is set within an appropriate range (appropriate range) in order to maintain the amount of purified water flowing out through the outflow pipe to the outside per unit time within a certain allowable range. Head range). The lower limit of this proper head range is called the lowest head, and the upper limit is called the highest head.

【0013】水頭センサは、適正水頭範囲のうちの少な
くとも最低水頭及び最高水頭を検知するためのものであ
る。すなわち、最低水頭及び最高水頭の2つを検知する
ためのもの、あるいはこれら2つに加えてこれらの中間
における所定数の水頭を検知するためのものである。水
頭センサの例は以下に述べる。[0013] The head sensor is for detecting at least the minimum head and the maximum head of the proper head range. That is, it is for detecting two of the minimum head and the maximum head, or for detecting a predetermined number of heads in between these two in addition to the two. Examples of the head sensor will be described below.

【0014】制御部は、水頭センサに電気的に接続さ
れ、流出量センサからの検知結果に基づいて水頭を適正
水頭範囲で調整すべく制御する。制御部の例は以下に述
べる。The control unit is electrically connected to the head sensor and controls the head to be adjusted within an appropriate head range based on the detection result from the outflow sensor. An example of the control unit will be described below.

【0015】本発明に係る汚水処理装置は好ましくは、
水頭センサが、曝気槽の上部に固定状に設けられて槽内
の活性汚泥混合液との接触により最低水頭及び最高水頭
をそれぞれ検知するための2つの水頭センサであり、制
御部が、流出量センサからの検知結果が下限値に満たな
いときには水頭を最低水頭位置まで下げるとともに曝気
量を増加させるべく制御するように構成される。The sewage treatment apparatus according to the present invention is preferably
A water head sensor is fixedly provided on the upper part of the aeration tank, and is a water head sensor for detecting a minimum head and a maximum head respectively by contact with the activated sludge mixture in the tank. When the detection result from the sensor is less than the lower limit, the head is controlled to lower the head to the minimum head position and increase the aeration amount.

【0016】ここで、2つの水頭センサは、曝気槽の上
部−例えば槽の側壁上部など−に高さを異にして固定状
に設けられ、槽内の活性汚泥混合液と接触することで最
低水頭及び最高水頭を検知する。また、制御部は、流出
量センサからの検知結果が下限値に満たないとき−流出
量が一定の許容範囲の下限値−に満たないときには、水
頭を最低水頭位置まで下げて濾過圧力の大きさを最低水
準まで下げるように制御する(例えば、曝気槽に設けら
れた汲出手段などに槽内の活性汚泥混合液を最低水頭位
置まで汲み出すように指示する)とともに、曝気量を増
加させて濾過膜装置の濾過膜体または濾過膜板などに最
大の曝気を行うように指示する。Here, the two head sensors are fixedly provided at different heights in the upper part of the aeration tank-for example, in the upper part of the side wall of the tank-and are at least contacted with the activated sludge mixture in the tank. Detects head and head. Further, when the detection result from the outflow rate sensor is less than the lower limit value-when the outflow rate is less than the lower limit value of a certain allowable range-, the control unit lowers the water head to the minimum head position and increases the magnitude of the filtration pressure. (For example, instructing a pumping means provided in the aeration tank to pump out the activated sludge mixture in the tank to the lowest head position), and increasing the amount of aeration to perform filtration. It is instructed to perform the maximum aeration on the filtration membrane or the filtration membrane plate of the membrane device.

【0017】このように構成された汚水処理装置によれ
ば、制御部による自動制御により、濾過膜装置の濾過膜
体または濾過膜板などの膜面にケーキ層が発達した際に
濾過圧力の大きさを最低水準まで下げてそのケーキ層が
自然に剥離するのを待ったり、同膜面に曝気を行ってそ
のケーキ層を強制的に剥離させたりすることが可能にな
る。According to the sewage treatment apparatus configured as described above, when the cake layer develops on the membrane surface of the filtration membrane or the filtration membrane plate of the filtration membrane device, the filtration pressure is increased by the automatic control by the control unit. It is possible to wait until the cake layer spontaneously peels off by lowering the thickness to the minimum level, or to forcibly peel the cake layer by aerating the film surface.

【0018】本発明に係る汚水処理装置は好ましくは、
水頭センサが、曝気槽の上部もしくは上方に上下移動可
能に設けられて槽内の活性汚泥混合液との接触により最
低水頭及び最高水頭をそれぞれ検知するための1つの水
頭センサであり、制御部が、流出量センサからの検知結
果が下限値に満たないときには水頭を最低水頭位置まで
下げるとともに曝気量を増加させるべく制御するように
構成される。The wastewater treatment apparatus according to the present invention is preferably
A water head sensor is provided so as to be vertically movable above or above the aeration tank, and is a single water head sensor for detecting a minimum head and a maximum head by contact with the activated sludge mixture in the tank, respectively. When the detection result from the outflow amount sensor is less than the lower limit value, the head is controlled to be lowered to the minimum head position and the aeration amount is increased.

【0019】ここで、1つの水頭センサは、曝気槽の上
部もしくは上方−例えば槽の上部開口縁など−に高さ調
節可能なように上下移動可能に設けられ、槽内の活性汚
泥混合液と接触することで最低水頭及び最高水頭を検知
する。制御部の機能は前記と同様である。Here, one water head sensor is vertically movable so as to be adjustable in height above or above the aeration tank (for example, at the upper opening edge of the tank), and is provided with the activated sludge mixed liquid in the tank. The minimum and maximum heads are detected by contact. The function of the control unit is the same as described above.

【0020】本発明に係る汚水処理装置は好ましくは、
水頭センサが、曝気槽の上部もしくは上方に固定状に設
けられて槽内の活性汚泥混合液の水面に投射した光もし
くは超音波の反射により最低水頭及び最高水頭をそれぞ
れ検知するための1つの水頭センサであり、制御部が、
流出量センサからの検知結果が下限値に満たないときに
は水頭を最低水頭位置まで下げるとともに曝気量を増加
させるべく制御するように構成される。The sewage treatment apparatus according to the present invention is preferably
A water head sensor is provided fixedly above or above the aeration tank, and detects one of a minimum head and a maximum head by means of reflection of light or ultrasonic waves projected on the surface of the activated sludge mixture in the tank. The sensor, and the control unit is
When the detection result from the outflow amount sensor is less than the lower limit value, the water head is controlled to be lowered to the minimum water head position and to increase the aeration amount.

【0021】ここで、1つの水頭センサは光もしくは超
音波センサであり、曝気槽の上部もしくは上方−例えば
槽の上部開口縁や槽に連通する連通管の上端など−に固
定状に設けられ、槽内の活性汚泥混合液の水面に向けて
投射した光もしくは超音波の反射により測定した距離に
基づいて最低水頭及び最高水頭をそれぞれ検知する。制
御部の機能は前記と同様である。Here, one water head sensor is a light or ultrasonic sensor, and is fixedly provided above or above the aeration tank-for example, at an upper opening edge of the tank or an upper end of a communication pipe communicating with the tank. The minimum head and the maximum head are respectively detected based on the distance measured by the reflection of light or ultrasonic waves projected onto the water surface of the activated sludge mixture in the tank. The function of the control unit is the same as described above.

【0022】[0022]

【発明の実施の形態】以下、本発明の4つの実施の形態
を図面に基づいて説明する。なお、これらによって本発
明が限定されるものではない。DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Four embodiments of the present invention will be described below with reference to the drawings. The present invention is not limited by these.

【0023】実施の形態1 図1に示すように、本発明の実施の形態1に係る汚水処
理装置D1 は、流量調整槽1と、これに隣接して設けら
れた曝気槽2とを備えてなる。流量調整槽1には、処理
すべき汚水(被処理水)が上方から流入してきて溜めら
れる。流量調整槽1の汚水は流量調整ポンプ3により一
定量ずつ汲み上げられて曝気槽2に流入する。Embodiment 1 As shown in FIG. 1, a sewage treatment apparatus D 1 according to Embodiment 1 of the present invention includes a flow rate adjusting tank 1 and an aeration tank 2 provided adjacent to the tank. It becomes. In the flow rate adjusting tank 1, sewage to be treated (water to be treated) flows from above and is stored. The sewage in the flow rate adjusting tank 1 is pumped by the flow rate adjusting pump 3 at a constant rate and flows into the aeration tank 2.

【0024】曝気槽2には活性汚泥があらかじめ入れら
れている。この活性汚泥は流入してきた被処理水と混ざ
り合って活性汚泥混合液になる。曝気槽2の内側中央に
は、被処理水に浸る状態に濾過膜装置4が設けられてい
る。Activated sludge is put in the aeration tank 2 in advance. This activated sludge mixes with the incoming treated water to form an activated sludge mixture. At the center of the inside of the aeration tank 2, a filtration membrane device 4 is provided so as to be immersed in the water to be treated.

【0025】濾過膜装置4は、上下に開口する箱状のケ
ーシング5と、このケーシング5の内部上方に並列状に
かつ着脱可能に吊り下げ配置された複数の濾過膜板6
と、これらの濾過膜板6の上端に取り付けられた吸引ヘ
ッダ7とを備えてなる。濾過膜装置4の吸引ヘッダ7は
流出管8に接続されている。The filtration membrane device 4 comprises a box-shaped casing 5 which is opened up and down, and a plurality of filtration membrane plates 6 which are detachably suspended above and parallel to the inside of the casing 5.
And a suction header 7 attached to the upper end of these filtration membrane plates 6. The suction header 7 of the filtration membrane device 4 is connected to an outflow pipe 8.

【0026】各濾過膜板6は、表面に貼られた濾材によ
り、曝気槽2の活性汚泥混合液をその水頭を駆動圧にし
た濾過により活性汚泥と濾液とに固液分離する。すなわ
ち、活性汚泥混合液はその水頭の圧力に基づいて濾材に
より濾過されてその表面に活性汚泥として付着する。一
方、濾材を通過した濾液は、吸引ヘッダ7に集まり、流
出管8を経て浄化水として曝気槽2の外部へ流出され
る。Each of the filtration membrane plates 6 separates the activated sludge mixed liquid in the aeration tank 2 into solid and liquid by filtration with the water head at a driving pressure using a filter medium attached to the surface. That is, the activated sludge mixture is filtered by the filter medium based on the pressure of the water head, and adheres to the surface as activated sludge. On the other hand, the filtrate that has passed through the filter medium collects in the suction header 7 and flows out of the aeration tank 2 as purified water via the outflow pipe 8.

【0027】濾過膜装置4のケーシング5の内側下部
(槽底寄り箇所)には曝気管9が水平に配されている。
この曝気管9は、曝気槽2の外側に配された空気供給手
段である曝気用ブロア10に接続されており、ブロア1
0の作動によりケーシング5の内部に曝気用空気を供給
する。この曝気用空気は、ケーシング5の内側にある活
性汚泥混合液に曝気を施すとともに、各濾過膜板6に触
れてその膜面の洗浄を行う。An aeration tube 9 is disposed horizontally below the inside of the casing 5 of the filtration membrane device 4 (at a location near the bottom of the tank).
The aeration pipe 9 is connected to an aeration blower 10 which is an air supply means provided outside the aeration tank 2, and is connected to the blower 1.
By the operation of 0, aeration air is supplied to the inside of the casing 5. The aeration air aerates the activated sludge mixture inside the casing 5 and cleans the membrane surface by touching each filter membrane plate 6.

【0028】流出管8は、その下流側に配された切換弁
である電磁弁11を介して流出量センサ12に接続され
ている。流出量センサ12は、流出管8を通って外部へ
流出する浄化水の単位時間当たりの流出量を常時、検知
する。電磁弁11は、流出量センサ12への浄化水の供
給とその停止とを切り替える。The outflow pipe 8 is connected to an outflow sensor 12 via an electromagnetic valve 11 which is a switching valve disposed downstream of the outflow pipe 8. The outflow amount sensor 12 constantly detects the amount of purified water flowing out through the outflow pipe 8 to the outside per unit time. The electromagnetic valve 11 switches between supplying the purified water to the outflow amount sensor 12 and stopping the supply.

【0029】曝気槽2の側壁上部には、高低2つの水頭
センサ13・14が固定状に設けられている。これらの
水頭センサ13・14は、曝気槽2内の活性汚泥混合液
と接触することで、曝気槽2の適正水頭範囲(活性汚泥
混合液の水位の適正な範囲)の下限である最低水頭Lと
上限である最高水頭Hとを検知する。At the upper part of the side wall of the aeration tank 2, two water head sensors 13 and 14 are fixedly provided. These water head sensors 13 and 14 come into contact with the activated sludge mixed liquid in the aeration tank 2, so that the minimum head L which is the lower limit of the appropriate head range of the aeration tank 2 (the appropriate range of the water level of the activated sludge mixed liquid) is obtained. And the maximum head H, which is the upper limit, is detected.

【0030】図2に示すように、曝気槽2の側壁中間部
には、水位下限センサ15が固定状に設けられている。
この水位下限センサ15は、曝気槽2内の各濾過膜板6
が正常に機能するための、活性汚泥混合液の下限水位を
検知するためのものである。As shown in FIG. 2, a water level lower limit sensor 15 is fixedly provided at an intermediate portion of the side wall of the aeration tank 2.
This water level lower limit sensor 15 is connected to each filtration membrane plate 6 in the aeration tank 2.
This is for detecting the lower limit water level of the activated sludge mixture for normal functioning.

【0031】また、図3に示すように、流出量センサ1
2及び水頭センサ13・14は、電気的に接続された制
御部であるマイコン16により制御される。Further, as shown in FIG.
2 and the head sensors 13 and 14 are controlled by a microcomputer 16 which is a control unit electrically connected.

【0032】すなわちマイコン16は、流出量センサ1
2からの検知結果が下限値に満たないとき−流出量が一
定の許容範囲の下限値に満たないとき−には、活性汚泥
混合液の水頭を最低水頭Lの位置まで下げて、各濾過膜
板6にかかる濾過圧力の大きさを最低水準まで下げるよ
うに制御する。具体的には、曝気槽2から流量調整槽1
にかけて設けられた汲出手段(図示略)により曝気槽2
の活性汚泥混合液を低位水頭センサ14のある最低水頭
Lの位置まで汲み出すように指示する。マイコン16は
同時に、曝気用ブロア10の出力をアップして曝気管9
から曝気を行い、濾過膜装置4の各濾過膜板6に曝気を
行うように指示する。That is, the microcomputer 16 controls the outflow amount sensor 1
When the detection result from step 2 is below the lower limit-when the amount of runoff is below the lower limit of a certain allowable range-the head of the activated sludge mixture is lowered to the position of the minimum head L, and each filtration membrane The magnitude of the filtration pressure applied to the plate 6 is controlled to be reduced to the minimum level. Specifically, from the aeration tank 2 to the flow control tank 1
Aeration tank 2 by a pumping means (not shown) provided to
Is instructed to pump out the activated sludge mixture to the position of the lowest head L where the lower head sensor 14 is located. The microcomputer 16 simultaneously increases the output of the aeration blower 10 and increases the output of the aeration tube 9.
, And instructs each filtration membrane plate 6 of the filtration membrane device 4 to perform aeration.

【0033】以下に、図4のフローチャートに基づい
て、この汚水処理装置D1 の動作を詳しく説明する。[0033] Hereinafter, with reference to the flowchart of FIG. 4, the operation of the sewage treatment apparatuses D 1 in detail.

【0034】汚水処理装置D1 は、曝気槽2内の活性汚
泥混合液が適正水頭範囲にあり、また曝気管9からの曝
気量が通常である状態で運転される。この運転中に浄化
水流出量監視ルーチンが開始される。まず、流出管8を
通って外部へ流出する浄化水の単位時間当たりの流出量
が流出量センサ12により検知されて、その結果がマイ
コン16に入力される。The sewage treatment apparatus D 1 is operated in a state where the activated sludge mixture in the aeration tank 2 is within an appropriate head range and the amount of aeration from the aeration pipe 9 is normal. During this operation, a purified water outflow monitoring routine is started. First, the amount of purified water flowing out through the outflow pipe 8 to the outside per unit time is detected by the outflow amount sensor 12, and the result is input to the microcomputer 16.

【0035】そして、流出量センサ12からの検知結果
が下限値に満たないとき−流出量が規定値よりも低下し
ており、一定の許容範囲の下限値に満たないとき−に
は、濾過膜板6の膜面に形成された、活性汚泥などの固
形物からなる固形物層(ケーキ層)が発達してその膜面
に一部閉塞が起こったと、マイコン16により判断され
る。When the detection result from the outflow amount sensor 12 is less than the lower limit value-when the outflow amount is lower than the specified value and is less than the lower limit value of a certain allowable range-, the filtration membrane The microcomputer 16 determines that a solid layer (cake layer) formed of a solid such as activated sludge formed on the membrane surface of the plate 6 has developed and a partial blockage has occurred on the membrane surface.

【0036】すると、マイコン16は、曝気槽2内の活
性汚泥混合液の水頭を低位水頭センサ14のある最低水
頭Lの位置まで下げて濾過圧力の大きさを最低水準まで
下げるように制御する。すなわち、曝気槽2から流量調
整槽1にかけて設けられた汲出手段(図示略)により曝
気槽2の活性汚泥混合液を流量調整槽1へ汲み出して、
活性汚泥混合液の水頭を低位水頭センサ14のある最低
水頭Lの位置まで下げるように指示する。これは、濾過
膜装置4の濾過膜板6の膜面に発達したケーキ層が濾過
圧力の低下に伴って自然に剥離するのを待つためであ
る。Then, the microcomputer 16 lowers the head of the activated sludge mixture in the aeration tank 2 to the position of the lowest head L where the lower head sensor 14 is located, and controls the magnitude of the filtration pressure to the lowest level. That is, the activated sludge mixture in the aeration tank 2 is pumped out to the flow rate adjustment tank 1 by a pumping means (not shown) provided from the aeration tank 2 to the flow rate adjustment tank 1,
It is instructed to lower the head of the activated sludge mixture to the position of the lowest head L where the low head sensor 14 is located. This is to wait for the cake layer developed on the membrane surface of the filtration membrane plate 6 of the filtration membrane device 4 to be spontaneously separated as the filtration pressure decreases.

【0037】マイコン16は同時に、曝気用ブロア10
の出力をアップして曝気管9から曝気を行い、各濾過膜
板6に曝気を行うように指示する。これは、曝気量を増
加させて各濾過膜板6に曝気を行い、その膜面の洗浄を
促進することで、膜面に発達したケーキ層を強制的に剥
離させるためである。The microcomputer 16 simultaneously operates the aeration blower 10
Is output from the aeration pipe 9 to instruct the respective filtration membrane plates 6 to perform aeration. This is for increasing the amount of aeration and aerating each filtration membrane plate 6 to promote cleaning of the membrane surface, thereby forcibly removing the cake layer developed on the membrane surface.

【0038】その後、以上のような、流出量センサ12
による浄化水の流出量の検知から、マイコン16による
低位水頭センサ14への切り替え及び各濾過膜板6への
最大量の曝気までのルーチン(通常処理ルーチン)を規
定回数、実施する。Thereafter, the outflow amount sensor 12
The routine (normal processing routine) from the detection of the outflow amount of the purified water by the microcomputer 16 to the switching to the low water head sensor 14 by the microcomputer 16 and the aeration of the maximum amount to each filtration membrane plate 6 is performed a specified number of times.

【0039】そして、浄化水の流出量が規定値に回復し
ているかどうかが判断される。ここで、回復していると
判断されれば、マイコン16は、曝気槽2内の活性汚泥
混合液の水頭を適正水頭範囲に戻すとともに曝気管9か
らの曝気量を通常のものに戻すように制御する。すなわ
ち、流量調整槽1の汚水を流量調整ポンプ3により一定
量、汲み上げて曝気槽2に流入させるとともに、曝気用
ブロア10を中間出力にして曝気管9からの曝気量を通
常のものにする。Then, it is determined whether or not the outflow amount of the purified water has recovered to the specified value. Here, if it is determined that the water has recovered, the microcomputer 16 returns the head of the activated sludge mixed liquid in the aeration tank 2 to an appropriate head range and returns the amount of aeration from the aeration pipe 9 to a normal one. Control. That is, a certain amount of the sewage in the flow control tank 1 is pumped by the flow control pump 3 to flow into the aeration tank 2, and the aeration blower 10 is set to an intermediate output to make the amount of aeration from the aeration pipe 9 normal.

【0040】以上で、浄化水流出量監視ルーチンを終了
させる。Thus, the purified water outflow monitoring routine is terminated.

【0041】一方、浄化水の流出量が規定値に回復して
いないと判断されれば、異常処理ルーチンへ移行する。
すなわち、汚水処理装置D1 の運転を停止させて、濾過
膜装置4の濾過膜板6を取り出してブラシなどにより膜
面の清掃を行い、あるいは、濾過膜板6を取り出すこと
なく流出管8から濾過膜板6の内部に向けて浄化水を流
して濾過膜板6の逆洗を行う。On the other hand, if it is determined that the amount of purified water has not recovered to the specified value, the routine proceeds to an abnormality processing routine.
That is, by stopping the operation of the sewage treatment apparatus D 1, performs a cleaning of the membrane surface by a brush is taken out filtration membrane plate 6 of the filtration membrane apparatus 4, or from the outflow pipe 8 without removing the filtration membrane plate 6 Purified water flows toward the inside of the filtration membrane plate 6 to backwash the filtration membrane plate 6.

【0042】この汚水処理装置D1 によれば、マイコン
16による自動制御により、濾過膜装置4の濾過膜板6
の膜面にケーキ層が発達した際に濾過圧力の大きさを最
低水準Lまで下げてそのケーキ層が自然に剥離するのを
待ったり、同膜面に曝気を行ってそのケーキ層を強制的
に剥離させたりすることが可能になる。According to the sewage treatment apparatus D 1 , the filtration plate 6 of the filtration membrane device 4 is automatically controlled by the microcomputer 16.
When the cake layer develops on the surface of the film, the magnitude of the filtration pressure is reduced to the minimum level L and the cake layer is allowed to spontaneously peel off, or the film surface is aerated to forcibly remove the cake layer. Or the like.

【0043】実施の形態2 図5に示すように、本発明の実施の形態2に係る汚水処
理装置D2 には、1つの水頭センサ21が設けられてい
る。この水頭センサ21は、曝気槽2の上部開口縁に取
り付けられたセンサ移動機22により支持されかつ高さ
調節可能なように上下移動可能に設けられており、曝気
槽2内の活性汚泥混合液と接触することで最低水頭L及
び最高水頭Hを検知する。As shown in Embodiment 2 Figure 5 embodiment, the sewage treatment apparatus D 2 according to the second embodiment of the present invention, one of the water head sensor 21 is provided. The water head sensor 21 is supported by a sensor moving device 22 attached to the upper opening edge of the aeration tank 2 and is provided to be vertically movable so that the height can be adjusted. , The minimum head L and the maximum head H are detected.

【0044】この汚水処理装置D2 の他の部分の構成
は、実施の形態1に係る汚水処理装置D1 におけるそれ
らと同様であるので、説明を省略する。[0044] Since the structure of the other components of the sewage treatment apparatus D 2 are the same as those in sewage treatment apparatuses D 1 according to the first embodiment, the description thereof is omitted.

【0045】また、図6に示すように、流出量センサ1
2、水頭センサ21及びセンサ移動機22は、電気的に
接続された制御部であるマイコン16により制御され
る。Further, as shown in FIG.
2. The head sensor 21 and the sensor moving device 22 are controlled by the microcomputer 16 which is a control unit electrically connected.

【0046】以下に、図7のフローチャートに基づい
て、この汚水処理装置D2 の動作を説明する。[0046] Hereinafter, with reference to the flowchart of FIG. 7, the operation of the sewage treatment apparatus D 2.

【0047】汚水処理装置D1 の場合と同様に、流出管
8を通って外部へ流出する浄化水の単位時間当たりの流
出量が流出量センサ12により検知されて、その結果が
マイコン16に入力される。そして、流出量センサ12
からの検知結果が下限値に満たないときには、濾過膜板
6の膜面に形成されたケーキ層が発達してその膜面に一
部閉塞が起こったと、マイコン16により判断される。As in the case of the sewage treatment apparatus D 1 , the amount of purified water flowing out to the outside through the outflow pipe 8 per unit time is detected by the outflow amount sensor 12, and the result is input to the microcomputer 16. Is done. And the outflow amount sensor 12
If the detection result is less than the lower limit value, the microcomputer 16 determines that the cake layer formed on the membrane surface of the filtration membrane plate 6 has developed and the membrane surface has been partially blocked.

【0048】すると、マイコン16は、水頭センサ21
をセンサ移動機22により下方へ移動させて最低水頭L
とされる位置で停止させるように指示する。次に、前記
汲出手段により曝気槽2の活性汚泥混合液を流量調整槽
1へ汲み出して、活性汚泥混合液の水頭を水頭センサ2
1が移動した最低水頭Lの位置まで下げるように指示す
る。マイコン16は同時に、曝気用ブロア10の出力を
アップして曝気管9から曝気を行い、各濾過膜板6に曝
気を行うように指示する。Then, the microcomputer 16 sets the water head sensor 21
Is moved downward by the sensor moving device 22 to reduce the minimum head L
Is instructed to stop at the position indicated. Next, the activated sludge mixed solution in the aeration tank 2 is pumped out to the flow rate adjusting tank 1 by the pumping means, and the head of the activated sludge mixed solution is detected by the water head sensor 2.
1 is instructed to lower to the position of the lowest head L where it has moved. At the same time, the microcomputer 16 increases the output of the aeration blower 10 to perform aeration from the aeration tube 9 and instructs each filtration membrane plate 6 to perform aeration.

【0049】その後、汚水処理装置D1 の場合と同様の
通常処理ルーチンを規定回数、実施する。Thereafter, a normal processing routine similar to that in the case of the sewage treatment apparatus D 1 is performed a specified number of times.

【0050】そして、浄化水の流出量が規定値に回復し
ているかどうかが判断される。ここで、回復していると
判断されれば、マイコン16は、水頭センサ21をセン
サ移動機22により上方へ移動させて適正水頭範囲の所
定位置で停止させ、曝気槽2内の活性汚泥混合液の水頭
をその所定位置に戻すとともに、曝気管9からの曝気量
を通常のものに戻すように制御する。Then, it is determined whether or not the outflow amount of the purified water has recovered to the specified value. Here, if it is determined that the water has recovered, the microcomputer 16 moves the water head sensor 21 upward by the sensor moving device 22 to stop the water head sensor 21 at a predetermined position in the appropriate water head range, and activates the activated sludge mixed liquid in the aeration tank 2. Is returned to its predetermined position, and the amount of aeration from the aeration tube 9 is controlled to return to a normal value.

【0051】以上で、浄化水流出量監視ルーチンを終了
させる。With the above, the purified water outflow amount monitoring routine is completed.

【0052】一方、浄化水の流出量が規定値に回復して
いないと判断されれば、汚水処理装置D1 の場合と同様
の異常処理ルーチンへ移行する。Meanwhile, outflow of purified water if it is determined not to have recovered to a specified value, the process proceeds to the same error processing routine in the case of the sewage treatment apparatus D 1.

【0053】この汚水処理装置D2 によれば、マイコン
16による自動制御により、濾過膜装置4の濾過膜板6
の膜面にケーキ層が発達した際に濾過圧力の大きさを最
低水準Lまで下げてそのケーキ層が自然に剥離するのを
待ったり、同膜面に最大の曝気を行ってそのケーキ層を
強制的に剥離させたりすることが可能になる。According to the sewage treatment apparatus D 2 , the filtration plate 6 of the filtration membrane device 4 is automatically controlled by the microcomputer 16.
When the cake layer develops on the membrane surface of the above, the magnitude of the filtration pressure is lowered to the minimum level L and the cake layer is allowed to spontaneously separate, or the cake layer is subjected to the maximum aeration to remove the cake layer. It becomes possible to forcibly peel off.

【0054】実施の形態3 図8に示すように、本発明の実施の形態3に係る汚水処
理装置D3 には、1つの水頭センサ31が設けられてい
る。この水頭センサ31は、光もしくは超音波センサで
あり、曝気槽2の上部開口縁に固定状に設けられ、槽内
の活性汚泥混合液の水面に向けて投射した光もしくは超
音波の反射により測定した距離に基づいて最低水頭L及
び最高水頭Hをそれぞれ検知する。[0054] As in Embodiment 3 Figure 8 embodiment, the sewage treatment apparatus D 3 according to the third embodiment of the present invention, one of the water head sensor 31 is provided. The water head sensor 31 is a light or ultrasonic sensor, which is fixedly provided at the upper opening edge of the aeration tank 2 and is measured by reflection of light or ultrasonic waves projected toward the surface of the activated sludge mixed liquid in the tank. The minimum head L and the maximum head H are respectively detected based on the distances obtained.

【0055】この汚水処理装置D3 の他の部分の構成
は、実施の形態1に係る汚水処理装置D1 におけるそれ
らと同様であるので、説明を省略する。[0055] Since the structure of the other components of the sewage treatment apparatus D 3 are the same as those in sewage treatment apparatuses D 1 according to the first embodiment, the description thereof is omitted.

【0056】また、図9に示すように、流出量センサ1
2及び水頭センサ31は、電気的に接続された制御部で
あるマイコン16により制御される。Further, as shown in FIG.
2 and the head sensor 31 are controlled by the microcomputer 16 which is a control unit electrically connected.

【0057】以下に、図10のフローチャートに基づい
て、この汚水処理装置D3 の動作を説明する。[0057] Hereinafter, with reference to the flowchart of FIG. 10, the operation of the sewage treatment apparatus D 3.

【0058】汚水処理装置D1 の場合と同様に、流出管
8を通って外部へ流出する浄化水の単位時間当たりの流
出量が流出量センサ12により検知されて、その結果が
マイコン16に入力される。そして、流出量センサ12
からの検知結果が下限値に満たないときには、濾過膜板
6の膜面に形成されたケーキ層が発達してその膜面に一
部閉塞が起こったと、マイコン16により判断される。As in the case of the sewage treatment apparatus D 1 , the amount of purified water flowing out through the outflow pipe 8 per unit time is detected by the outflow amount sensor 12, and the result is input to the microcomputer 16. Is done. And the outflow amount sensor 12
If the detection result is less than the lower limit value, the microcomputer 16 determines that the cake layer formed on the membrane surface of the filtration membrane plate 6 has developed and the membrane surface has been partially blocked.

【0059】すると、水頭センサ31が曝気槽2におけ
る活性汚泥混合液の水面までの距離を測定する。そし
て、測定した距離が水頭センサ31から最低水頭Lまで
の距離よりも短いときは、マイコン16が活性汚泥混合
液の水頭を最低水頭Lの位置まで下げるように指示す
る。マイコン16は同時に、曝気用ブロア10の出力を
アップして曝気管9から曝気を行い、各濾過膜板6に曝
気を行うように指示する。Then, the water head sensor 31 measures the distance of the activated sludge mixed liquid in the aeration tank 2 to the water surface. When the measured distance is shorter than the distance from the water head sensor 31 to the minimum head L, the microcomputer 16 instructs to lower the head of the activated sludge mixture to the minimum head L position. At the same time, the microcomputer 16 increases the output of the aeration blower 10 to perform aeration from the aeration tube 9 and instructs each filtration membrane plate 6 to perform aeration.

【0060】その後、汚水処理装置D1 の場合と同様の
通常処理ルーチンを規定回数、実施する。Thereafter, a normal processing routine similar to that in the case of the sewage treatment apparatus D 1 is performed a specified number of times.

【0061】そして、浄化水の流出量が規定値に回復し
ているかどうかが判断される。ここで、回復していると
判断されれば、マイコン16は、水頭センサ31により
活性汚泥混合液の水面までの距離を測定しながら、活性
汚泥混合液の水頭を適正水頭範囲の所定位置に戻すとと
もに、曝気管9からの曝気量を通常のものに戻すように
制御する。Then, it is determined whether or not the outflow amount of the purified water has recovered to the specified value. Here, if it is determined that the water has recovered, the microcomputer 16 returns the head of the activated sludge mixture to a predetermined position in the appropriate head range while measuring the distance to the water surface of the activated sludge mixture by the water head sensor 31. At the same time, control is performed so that the amount of aeration from the aeration tube 9 is returned to a normal amount.

【0062】以上で、浄化水流出量監視ルーチンを終了
させる。Thus, the purified water outflow amount monitoring routine is completed.

【0063】一方、浄化水の流出量が規定値に回復して
いないと判断されれば、汚水処理装置D1 の場合と同様
の異常処理ルーチンへ移行する。[0063] On the other hand, outflow of purified water if it is determined not to have recovered to a specified value, the process proceeds to the same error processing routine in the case of the sewage treatment apparatus D 1.

【0064】この汚水処理装置D3 によれば、マイコン
16による自動制御により、濾過膜装置4の濾過膜板6
の膜面にケーキ層が発達した際に濾過圧力の大きさを最
低水準Lまで下げてそのケーキ層が自然に剥離するのを
待ったり、同膜面に最大の曝気を行ってそのケーキ層を
強制的に剥離させたりすることが可能になる。According to the sewage treatment apparatus D 3 , the filtration membrane plate 6 of the filtration membrane device 4 is automatically controlled by the microcomputer 16.
When the cake layer develops on the membrane surface of the above, the magnitude of the filtration pressure is lowered to the minimum level L and the cake layer is allowed to spontaneously separate, or the cake layer is subjected to the maximum aeration to remove the cake layer. It becomes possible to forcibly peel off.

【0065】実施の形態4 図11に示すように、本発明の実施の形態4に係る汚水
処理装置D4 は、汚水処理装置D3 とは異なっている。Fourth Embodiment As shown in FIG. 11, a sewage treatment apparatus D 4 according to a fourth embodiment of the present invention is different from a sewage treatment apparatus D 3 .

【0066】すなわち、この曝気槽42は、本体部42
aと、本体部42aの脇に連通状に設けられた連通管部
42bとからなる。そして、連通管部42bの上部開口
縁に前記と同じ水頭センサ31が固定状に設けられてい
る。That is, the aeration tank 42 is
a and a communication pipe portion 42b provided in a communication shape beside the main body portion 42a. The same water head sensor 31 as described above is fixedly provided at the upper opening edge of the communication pipe portion 42b.

【0067】この汚水処理装置D4 における他の部分の
構成、マイコン16の機能、汚水処理装置D4 の動作及
び利点は、実施の形態3に係る汚水処理装置D3 におけ
るそれらと同様であるので、説明を省略する。[0067] The configuration of the other portions in the sewage treatment apparatus D 4, functions of the microcontroller 16, the operation and advantages of the sewage treatment apparatus D 4 is the same as those in sewage treatment apparatus D 3 according to the third embodiment The description is omitted.

【0068】[0068]

【発明の効果】請求項1記載の発明によれば、曝気槽
と、この曝気槽の内側に設けられた濾過膜装置と、この
濾過膜装置に接続されて同部材による濾液である浄化水
を外部へ流出させるための流出管と、この流出管に設け
られて浄化水の単位時間当たりの流出量を検知する流出
量センサと、曝気槽の適正水頭範囲のうちの少なくとも
最低水頭及び最高水頭を検知するための水頭センサと、
この水頭センサに電気的に接続されて流出量センサから
の検知結果に基づき水頭を適正水頭範囲で調整すべく制
御する制御部とを備えているので、構造が簡単であるう
え、制御部による自動制御により、濾過膜装置の膜面に
形成されたケーキ層が発達した際に濾過圧力の大きさを
最低水準まで下げてそのケーキ層が自然に剥離するのを
待つことが可能になる。According to the first aspect of the present invention, an aeration tank, a filtration membrane device provided inside the aeration tank, and purified water, which is connected to the filtration membrane device and is a filtrate by the same member, is purified. An outflow pipe for discharging to the outside, an outflow sensor provided in the outflow pipe to detect an outflow amount of purified water per unit time, and at least a minimum head and a maximum head in an appropriate head range of the aeration tank. A head sensor for detecting,
A control unit electrically connected to the water head sensor and controlling the water head within an appropriate head range based on the detection result from the outflow amount sensor. By the control, when the cake layer formed on the membrane surface of the filtration membrane device has developed, the magnitude of the filtration pressure can be reduced to the minimum level, and the cake layer can wait for spontaneous peeling.

【0069】請求項2記載の発明によれば、水頭センサ
は、曝気槽の上部に固定状に設けられて槽内の活性汚泥
混合液との接触により最低水頭及び最高水頭をそれぞれ
検知するための2つの水頭センサであり、制御部は、流
出量センサからの検知結果が下限値に満たないときには
水頭を最低水頭位置まで下げるとともに曝気量を増加さ
せるべく制御するので、請求項1の発明における前記効
果に加えて、濾過膜装置の膜面に曝気を行ってそのケー
キ層を強制的に剥離させることが可能になる。According to the second aspect of the present invention, the water head sensor is fixedly provided on the upper part of the aeration tank and detects the minimum head and the maximum head by contact with the activated sludge mixture in the tank. When the detection result from the outflow amount sensor is less than the lower limit value, the control unit performs control to lower the water head to the minimum head position and increase the aeration amount. In addition to the effect, it is possible to forcibly peel off the cake layer by aerating the membrane surface of the filtration membrane device.

【0070】請求項3記載の発明によれば、水頭センサ
は、曝気槽の上部もしくは上方に上下移動可能に設けら
れて槽内の活性汚泥混合液との接触により最低水頭及び
最高水頭をそれぞれ検知するための1つの水頭センサで
あり、制御部は、流出量センサからの検知結果が下限値
に満たないときには水頭を最低水頭位置まで下げるとと
もに曝気量を増加させるべく制御するので、請求項1の
発明における前記効果に加えて、濾過膜装置の膜面に曝
気を行ってそのケーキ層を強制的に剥離させることが可
能になる。According to the third aspect of the present invention, the water head sensor is provided so as to be vertically movable above or above the aeration tank, and detects the minimum head and the maximum head by contact with the activated sludge mixture in the tank. The control unit controls the water head to be lowered to the minimum water head position and to increase the aeration amount when the detection result from the outflow amount sensor is less than the lower limit value. In addition to the above-described effects of the present invention, it is possible to forcibly peel off the cake layer by aerating the membrane surface of the filtration membrane device.

【0071】請求項4の発明によれば、水頭センサは、
曝気槽の上部もしくは上方に固定状に設けられて槽内の
活性汚泥混合液の水面に投射した光もしくは超音波の反
射により最低水頭及び最高水頭をそれぞれ検知するため
の1つの水頭センサであり、制御部は、流出量センサか
らの検知結果が下限値に満たないときには水頭を最低水
頭位置まで下げるとともに曝気量を増加させるべく制御
するので、請求項1の発明における前記効果に加えて、
濾過膜装置の膜面に曝気を行ってそのケーキ層を強制的
に剥離させることが可能になる。According to the fourth aspect of the present invention, the water head sensor
One head sensor for detecting the lowest head and the highest head respectively by reflection of light or ultrasonic waves provided on the water surface of the activated sludge mixture in the tank fixedly above or above the aeration tank, When the detection result from the outflow rate sensor is less than the lower limit value, the control unit performs control to lower the water head to the lowest water head position and increase the aeration amount. In addition to the effect in the invention of claim 1,
It is possible to forcibly peel off the cake layer by aerating the membrane surface of the filtration membrane device.

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

【図1】本発明の実施の態様1に係る汚水処理装置の垂
直断面図である。FIG. 1 is a vertical sectional view of a sewage treatment apparatus according to Embodiment 1 of the present invention.

【図2】図1の汚水処理装置の一部を示す垂直断面図で
ある。FIG. 2 is a vertical sectional view showing a part of the sewage treatment apparatus of FIG.

【図3】図1の汚水処理装置の一部を示すブロック図で
ある。FIG. 3 is a block diagram showing a part of the sewage treatment apparatus of FIG. 1;

【図4】図1の汚水処理装置の動作を説明するフローチ
ャートである。FIG. 4 is a flowchart illustrating an operation of the sewage treatment apparatus of FIG. 1;

【図5】本発明の実施の態様2に係る汚水処理装置の一
部を示す垂直断面図である。FIG. 5 is a vertical sectional view showing a part of a sewage treatment apparatus according to Embodiment 2 of the present invention.

【図6】図5の汚水処理装置の一部を示すブロック図で
ある。FIG. 6 is a block diagram showing a part of the sewage treatment apparatus of FIG.

【図7】図5の汚水処理装置の動作を説明するフローチ
ャートである。FIG. 7 is a flowchart illustrating an operation of the sewage treatment apparatus of FIG. 5;

【図8】本発明の実施の態様3に係る汚水処理装置の一
部を示す垂直断面図である。FIG. 8 is a vertical sectional view showing a part of a sewage treatment apparatus according to Embodiment 3 of the present invention.

【図9】図8の汚水処理装置の一部を示すブロック図で
ある。FIG. 9 is a block diagram showing a part of the sewage treatment apparatus of FIG.

【図10】図8の汚水処理装置の動作を説明するフロー
チャートである。FIG. 10 is a flowchart illustrating an operation of the sewage treatment apparatus of FIG. 8;

【図11】本発明の実施の態様4に係る汚水処理装置の
一部を示す垂直断面図である。FIG. 11 is a vertical sectional view showing a part of a sewage treatment apparatus according to Embodiment 4 of the present invention.

【符号の説明】[Explanation of symbols]

2 曝気槽 4 濾過膜装置 5 ケーシング 6 濾過膜板 8 流出管 9 曝気管 10 曝気用ブロア 12 流出量センサ 13 高位水頭センサ 14 低位水頭センサ 16 マイコン 17 電流センサ 21 水頭センサ 22 センサ移動機 31 水頭センサ 42 曝気槽 Reference Signs List 2 aeration tank 4 filtration membrane device 5 casing 6 filtration membrane plate 8 outflow pipe 9 aeration pipe 10 aeration blower 12 outflow rate sensor 13 high water head sensor 14 low water head sensor 16 microcomputer 17 current sensor 21 water head sensor 22 sensor moving machine 31 water head sensor 42 Aeration tank

Claims (4)

【特許請求の範囲】[Claims] 【請求項1】 汚水に活性汚泥処理を施す際に曝気を行
うための曝気槽と、この曝気槽の内側に設けられて槽内
の活性汚泥混合液をその水頭を駆動圧にした濾過により
固液分離する濾過膜装置と、この濾過膜装置に接続され
て同部材による濾液である浄化水を外部へ流出させるた
めの流出管と、この流出管に設けられて浄化水の単位時
間当たりの流出量を検知する流出量センサと、曝気槽の
適正水頭範囲のうちの少なくとも最低水頭及び最高水頭
を検知するための水頭センサと、この水頭センサに電気
的に接続されて流出量センサからの検知結果に基づき水
頭を適正水頭範囲で調整すべく制御する制御部とを備え
たことを特徴とする汚水処理装置。1. An aeration tank for performing aeration when sewage is subjected to activated sludge treatment, and an activated sludge mixed liquid provided inside the aeration tank and filtered in the tank with its head at a driving pressure. A filtration membrane device for separating the liquid, an outflow pipe connected to the filtration membrane apparatus for allowing purified water, which is a filtrate by the same member, to flow out, and an outflow per unit time provided in the outflow pipe for the purified water A runoff sensor for detecting the amount of water, a head sensor for detecting at least the lowest head and the highest head of the appropriate head range of the aeration tank, and a detection result from the runoff sensor electrically connected to the head sensor A sewage treatment apparatus comprising: a control unit that controls a water head to be adjusted within an appropriate water head range based on the control. 【請求項2】 水頭センサは、曝気槽の上部に固定状に
設けられて槽内の活性汚泥混合液との接触により最低水
頭及び最高水頭をそれぞれ検知するための2つの水頭セ
ンサであり、制御部は、流出量センサからの検知結果が
下限値に満たないときには水頭を最低水頭位置まで下げ
るとともに曝気量を増加させるべく制御する請求項1記
載の汚水処理装置。2. A water head sensor, which is fixedly provided at an upper portion of an aeration tank and detects two heads, a minimum head and a maximum head, respectively, by contact with an activated sludge mixture in the tank. 2. The sewage treatment apparatus according to claim 1, wherein the control unit controls the water head to be lowered to the minimum water head position and increases the aeration amount when the detection result from the outflow amount sensor is less than the lower limit value. 【請求項3】 水頭センサは、曝気槽の上部もしくは上
方に上下移動可能に設けられて槽内の活性汚泥混合液と
の接触により最低水頭及び最高水頭をそれぞれ検知する
ための1つの水頭センサであり、制御部は、流出量セン
サからの検知結果が下限値に満たないときには水頭を最
低水頭位置まで下げるとともに曝気量を増加させるべく
制御する請求項1記載の汚水処理装置。3. A water head sensor is a single water head sensor that is vertically movable above or above an aeration tank and detects a minimum head and a maximum head by contact with an activated sludge mixture in the tank. 2. The sewage treatment apparatus according to claim 1, wherein the control unit performs control to lower the water head to the minimum water head position and increase the aeration amount when the detection result from the outflow amount sensor is less than the lower limit value. 【請求項4】 水頭センサは、曝気槽の上部もしくは上
方に固定状に設けられて槽内の活性汚泥混合液の水面に
投射した光もしくは超音波の反射により最低水頭及び最
高水頭をそれぞれ検知するための1つの水頭センサであ
り、制御部は、流出量センサからの検知結果が下限値に
満たないときには水頭を最低水頭位置まで下げるととも
に曝気量を増加させるべく制御する請求項1記載の汚水
処理装置。4. A water head sensor is provided fixedly above or above the aeration tank, and detects a minimum head and a maximum water head by reflection of light or ultrasonic waves projected on the water surface of the activated sludge mixture in the tank. The sewage treatment according to claim 1, wherein the control unit controls the head to be lowered to the minimum head position and to increase the aeration amount when the detection result from the outflow amount sensor is less than the lower limit value. apparatus.
JP17467097A 1997-06-30 1997-06-30 Sewage treatment equipment Expired - Fee Related JP3825534B2 (en)

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Application Number Priority Date Filing Date Title
JP17467097A JP3825534B2 (en) 1997-06-30 1997-06-30 Sewage treatment equipment

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP17467097A JP3825534B2 (en) 1997-06-30 1997-06-30 Sewage treatment equipment

Publications (2)

Publication Number Publication Date
JPH1119680A true JPH1119680A (en) 1999-01-26
JP3825534B2 JP3825534B2 (en) 2006-09-27

Family

ID=15982650

Family Applications (1)

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Country Link
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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN101786718A (en) * 2010-02-11 2010-07-28 杭州王清熙水处理设备工程有限公司 Underground percolating water treatment plant and water treatment method applying same
GB2493033A (en) * 2011-09-12 2013-01-23 Pritchard Ip Ltd Water container
EP3189885A1 (en) * 2005-07-12 2017-07-12 Zenon Technology Partnership Process control for an immersed membrane system

Families Citing this family (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN101973673A (en) * 2010-10-18 2011-02-16 北京坎普尔环保技术有限公司 Sewage treatment device with aerobic and anoxia reaction regions and film solid-liquid separation region

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP3189885A1 (en) * 2005-07-12 2017-07-12 Zenon Technology Partnership Process control for an immersed membrane system
CN101786718A (en) * 2010-02-11 2010-07-28 杭州王清熙水处理设备工程有限公司 Underground percolating water treatment plant and water treatment method applying same
GB2493033A (en) * 2011-09-12 2013-01-23 Pritchard Ip Ltd Water container
GB2493033B (en) * 2011-09-12 2013-06-19 Pritchard Ip Ltd A water container
AU2012307112B2 (en) * 2011-09-12 2017-05-25 Lifesaver Ip Limited A water container

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