JPS621426A - Electroosmotic dehydration apparatus - Google Patents

Electroosmotic dehydration apparatus

Info

Publication number
JPS621426A
JPS621426A JP60139924A JP13992485A JPS621426A JP S621426 A JPS621426 A JP S621426A JP 60139924 A JP60139924 A JP 60139924A JP 13992485 A JP13992485 A JP 13992485A JP S621426 A JPS621426 A JP S621426A
Authority
JP
Japan
Prior art keywords
filter chamber
sludge
negative pressure
electroosmotic
dehydrated
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.)
Pending
Application number
JP60139924A
Other languages
Japanese (ja)
Inventor
Masataka Yoshida
吉田 正孝
Hideyuki Oohanamori
英幸 大花森
Mikimasa Yamaguchi
山口 幹昌
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.)
Fuji Electric Co Ltd
Original Assignee
Fuji 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 Fuji Electric Co Ltd filed Critical Fuji Electric Co Ltd
Priority to JP60139924A priority Critical patent/JPS621426A/en
Publication of JPS621426A publication Critical patent/JPS621426A/en
Pending legal-status Critical Current

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  • Separation Using Semi-Permeable Membranes (AREA)
  • Treatment Of Sludge (AREA)

Abstract

PURPOSE:To prevent the generation of a gas protrusion phenomenon, by forming a filter chamber held to negative pressure to the back surface side of a filtering surface and positively sucking a filtrate or the gas generated in a substance to be subjected to dehydration treatment by negative pressure acting on the filter chamber to discharge the same out of the system. CONSTITUTION:The side of a filter chamber 11 is held to negative pressure across a filter material 4 and a cathode side electrode 5 by a vacuum pump 14 through a vacuum tank 1 and, because of this, the moisture separated from sludge 10 by electroosmotic action and flowed toward the cathode side electrode 5 is flowed out to the filter chamber 11 by negative pressure acting on the filter chamber 11 and recovered in the vacuum chamber 13. At the same time, the gas such as steam generated during the electroosmotic process is vented to the filter chamber 11 and exhausted to the outside by a vacuum pump 14.

Description

【発明の詳細な説明】[Detailed description of the invention] 【発明の属する技術分野】[Technical field to which the invention pertains]

この発明は、例えば下水処理場に生じた余剰汚泥等を被
脱水処理物として電気浸透作用により脱水処理する電気
浸透脱水装置に関する。
The present invention relates to an electroosmotic dewatering device that dehydrates excess sludge generated in a sewage treatment plant, for example, by electroosmotic action as a material to be dehydrated.

【従来技術とその問題点】[Prior art and its problems]

従来より電気浸透作用を応用して汚泥等の被脱水処理物
の脱水を行う電気浸透脱水装置が知られている。ここで
第4図に従来におけるバッチ処理方式の電気浸透脱水装
置の構成を説明す゛る。第4図において、lはシリンダ
としてなる脱水処理容器、2は咳容器内に挿入されたピ
ストン、3はピストン2の駆動部であり、前記容器lの
底部には濾布等の濾材4および有孔電極板としての¥に
極側電Bi5が、またピストン2の内面には前記陰i側
電8i5に対向する陽極側電極6がそれぞれ装備され、
かつt捲5と6との間に直流電源7が接続されている。 なお8は被脱水処理物!物の供給口、9は濾液の排出口
である。 上記構成でt極5.6間に電圧を印加した状態で供給口
8を通じて被脱水処理物としての汚泥10を脱水処理容
器l内に導入し、この状態でピストン2を駆動して加圧
することにより、汚泥10にはピストン加圧による機械
的な圧搾力に加えて対向を極5.6の間に電場が作用し
、その電気浸透作用により汚泥に含まれている水分は正
に帯電して陰極側に流動してこの電極へ放電するととも
に、濾材4および陰極側電pi5の透孔を透過して濾液
排出口9より系外に排出される。 ところで上記した電気浸透脱水装置では、汚泥10内の
水分が電気浸透作用によ陰極側電極5へ向けて流動する
際に汚泥粒子が濾過抵抗として水分の流動を妨げるため
に、このままでは高い脱水効率が得られない、またこれ
とは別にt8i間の通電に伴う発熱により汚泥の含有水
分等の一部が蒸気化して汚泥内にガス層を形成する。し
かもこのような汚泥内でのガスの発生は!極間の通電抵
抗の増加原因となって電気浸透作用の働きを低下させる
のみならず、さらに汚泥中で圧力上昇を招き、脱水処理
操作の過程で汚泥内部に自然発生的に生した隙間をガス
抜けill路として突発的に外部へガス突出することが
あるが、このような高温、高圧のガス突出現象は保安上
からも危険である。
2. Description of the Related Art Electroosmotic dewatering apparatuses have been known that apply electroosmotic action to dehydrate materials to be dehydrated, such as sludge. Here, the configuration of a conventional batch processing type electroosmotic dewatering apparatus will be explained with reference to FIG. In FIG. 4, 1 is a dehydration treatment container in the form of a cylinder, 2 is a piston inserted into the cough container, 3 is a driving part of the piston 2, and a filter material 4 such as a filter cloth is provided at the bottom of the container 1. A pole side electrode Bi5 is provided on the hole electrode plate, and an anode side electrode 6 is provided on the inner surface of the piston 2, facing the negative i side electrode 8i5.
In addition, a DC power source 7 is connected between the T-windings 5 and 6. Note that 8 is the material to be dehydrated! 9 is a filtrate outlet. With the above configuration, the sludge 10 as the material to be dehydrated is introduced into the dehydration treatment container l through the supply port 8 with a voltage applied between the t poles 5 and 6, and in this state, the piston 2 is driven to pressurize it. In addition to the mechanical squeezing force caused by pressurizing the piston, an electric field acts on the sludge 10 between the opposing poles 5 and 6, and the water contained in the sludge becomes positively charged due to the electroosmotic action. It flows to the cathode side and is discharged to this electrode, and at the same time, it passes through the filter medium 4 and the through hole of the cathode side electrode pi5 and is discharged out of the system from the filtrate discharge port 9. By the way, in the electroosmotic dewatering device described above, when the water in the sludge 10 flows toward the cathode electrode 5 due to electroosmotic action, the sludge particles act as filtration resistance and prevent the flow of water, so the dewatering efficiency is not high. Separately, due to the heat generated during t8i, part of the moisture contained in the sludge is vaporized to form a gas layer within the sludge. Moreover, gas is generated in such sludge! This not only causes an increase in the current carrying resistance between the electrodes and reduces the electroosmotic effect, but also causes a pressure increase in the sludge, and the gaps that naturally occur inside the sludge during the dewatering process are filled with gas. Gas may suddenly protrude outside as an escape route, but such a phenomenon of high-temperature, high-pressure gas protruding is dangerous from a safety standpoint.

【発明の目的】[Purpose of the invention]

この発明は上記の点にかんがみなされたものであり、前
記した従来の難点を解消して電気浸透作用により被脱水
処理物から分離した濾液を効率よく系外に排出し、同時
に被脱水処理物内部に発生した水蒸気等の発生ガスを良
好にガス抜してガス突出現象の発生を防止できるように
した電気浸透脱水装置を提供することを目的とする。
This invention has been developed in consideration of the above points, and it solves the above-mentioned conventional difficulties and efficiently discharges the filtrate separated from the material to be dehydrated by electroosmosis to the outside of the system. An object of the present invention is to provide an electroosmotic dehydration device that can effectively degas generated gases such as water vapor generated during operation and prevent the occurrence of gas protrusion phenomenon.

【発明の要点】[Key points of the invention]

上記目的を達成するために、この発明は電気浸透脱水装
置における濾過面の背面側に負圧に保持された減車を形
成し、該減車に作用する負圧により濾液および被脱水処
理物内の発生ガスを積極的に系外へ吸引排除するように
したものである。
In order to achieve the above object, the present invention forms a reducing wheel maintained at negative pressure on the back side of the filtration surface in an electroosmotic dehydration device, and the negative pressure acting on the reducing wheel causes the generation in the filtrate and the material to be dehydrated to be reduced. This system actively sucks gas out of the system.

【発明の実施例】[Embodiments of the invention]

第1図、第2図、第3図はそれぞれ異なるこの発明の実
施例を示すものである。まず第1図は先述した第4図の
バッチ処理方式に対応する実施例であり、第4図に対応
する同一部材には同じ符号が付しである。すなわちこの
発明により脱水処理容器1の底部側には濾材4.陰極側
f8i5の背後に符号11で示す減車が画成されており
、かつ該減車11が排水管12を介して濾液回収用の真
空タンク13に配管接続されている。なお14は真空タ
ンク13に接続した真空ポンプ、15は濾液排出用のド
レン弁であり、脱水処理を行う際にはドレン弁15を閉
じ、真空ポンプ14を運転して真空タンク13およびこ
れに通じる減車11内を負圧に保持している。 上記の構成によれば、濾材4および電極5を境に減車1
1側が負圧に保持されているために、電気浸透作用によ
り汚泥10から分離して陰奢j側;極5へ向けて流動す
る水分は汚泥粒子のi!!過抵抗抵抗害されることなく
減車11に働く負圧の吸引力によりX空引きされて強制
的に減車11へ流出し、ここから排水管12を経て真空
タンク13内に回収されるようになる。同時に電気浸i
3の過程で汚泥内に発生した水蒸気等の発生ガスも汚泥
内に停滞、ないし突発的に外部へガス突出することなく
減車11内の負圧作用に受けてガス抜きされるようにな
る。 なお、このガスは−H真空タンク13内に回収された後
に真空ポンプ14を通じて外部に排出される。これによ
り、第4図で述べた従来構成における問題点を解消し、
脱水効率の向上並びに保安上での安全性の改善を図るこ
とができる。 第2図は連続処理方式のベルト搬送式電気浸透脱水装置
に通用した実施例を示すものであり、電気浸透脱水機は
陽極電極を兼ねたプレスベルト16、を亥プレスベルト
16との間に汚泥通路17を隔てて対向するフィルタベ
ルト18、ベルトの駆動モータ19、汚泥供給ホッパ2
0、フィルタベルト18の背面に設置した陰極側電極5
、および前記の陰極側ブレスベルト16と陰極側電極5
との間に電圧を印加する電源7等で構成されている。な
お21は脱水処理された汚泥の脱水ケーキ、22は脱水
ケーキの回収容器を示す、かかる構成で汚泥10は供給
ホッパ2oより汚泥通路17内に連続式に供給され、プ
レスベルト16とフィルタベルト18との間で圧搾力を
受けっつつ矢印P方向へ搬送される搬送過程で1!極間
の通電により電気浸透脱水を受け、これにより汚泥内の
含有水はフィルタベルト18および陰極側電極5の透孔
を透過して分離脱水される。ここでこの発明により、陰
極側電極5の背後には減車11が設置されており、かっ
この減車11が第1図で述べたと同様に真空タンク13
に連通接続されている。したがって電気浸透脱水処理工
程に際して真空ポンプ14を運転して前記の濾室11内
を負圧に保持することにより、第1図の実施例と同様に
汚泥から分離した濾液および汚泥内の発生ガスを効果的
に吸引し系外に排除することができる。 第3図は更に別な実施例を示すものであり、第2図に対
応する同一ないし等価な部材には同じ符号が付しである
。すなわちこの実施例ではリング状の陰極側電極5が回
転ドラムの外周に設置されており、かつこの電極の外周
面にフィルタベルト18が張架されている。一方前記陰
極側電極5の内周面側には排水管12を介して真空タン
ク13と連通し合う濾室11がドラム内部に分割画成さ
れている。 かかるドラム組立体はその周面の下部域が濃度の低い汚
泥lOを収容した汚泥タンク23内に浸漬され、かつ一
方てはドラムの上部周域に対向して陽極側を極を兼ねる
プレスベルト16が配備されている。 かかる構成で真空タンク13に接続した真空ポンプ14
を運転して前記したドラム内の各濾室11を負圧に保持
した状態でドラムを矢印方向に回転駆動すれば、前記し
た汚泥タンク23内を通過するゾーンでフィルタベルト
18上に汚泥が’tN tKAされた形で吸着される。 またフィルタベルト上に@、着された汚泥はベルト搬送
され、プレスベルト16との間を通過する過程で電気浸
透作用を受けるようになる。 これにより濾液はフィルタベルト18.電極5の透孔を
透過して負圧に保持されている濾室11側に吸引濾過さ
れ、ここから排水間12を通じて真空タンク13内に回
収される。また同時に汚泥内に発生した水蒸気等の発生
ガスも汚泥からガス抜きされ、真空タンク側に吸引排除
されることは先の実施例と同様である。
1, 2, and 3 show different embodiments of the present invention. First, FIG. 1 shows an embodiment corresponding to the batch processing method shown in FIG. 4 described above, and the same members corresponding to FIG. 4 are given the same reference numerals. That is, according to the present invention, a filter medium 4 is provided on the bottom side of the dehydration treatment container 1. Behind the cathode side f8i5, a reducing wheel indicated by reference numeral 11 is defined, and the reducing wheel 11 is connected via a drain pipe 12 to a vacuum tank 13 for collecting filtrate. Note that 14 is a vacuum pump connected to the vacuum tank 13, and 15 is a drain valve for discharging filtrate. When performing dehydration processing, the drain valve 15 is closed and the vacuum pump 14 is operated to connect the vacuum tank 13 and the drain valve 15. The inside of the reduced vehicle 11 is maintained at negative pressure. According to the above configuration, the number of vehicles reduced by 1 at the border of the filter medium 4 and the electrode 5 is
Since the 1 side is maintained at negative pressure, the water that separates from the sludge 10 by electroosmosis and flows toward the negative electrode 5 is the i! of the sludge particles. ! The suction force of the negative pressure acting on the reducing wheel 11 causes the water to be emptied by the suction force of the negative pressure acting on the reducing wheel 11 without being affected by excessive resistance, and forcibly flows out to the reducing wheel 11, from where it is collected in the vacuum tank 13 via the drain pipe 12. At the same time electric immersion
The generated gases such as water vapor generated in the sludge in the step 3 are also degassed by the negative pressure action in the reducing vehicle 11 without being stagnated in the sludge or suddenly protruding to the outside. Note that this gas is recovered in the -H vacuum tank 13 and then exhausted to the outside through the vacuum pump 14. This solves the problems with the conventional configuration described in Figure 4,
It is possible to improve dewatering efficiency and safety in terms of safety. FIG. 2 shows an example of a continuous processing type belt conveyance type electroosmotic dehydrator, in which a press belt 16 that also serves as an anode electrode is placed between the press belt 16 and the sludge. A filter belt 18, a belt drive motor 19, and a sludge supply hopper 2 facing each other across a passage 17.
0, cathode side electrode 5 installed on the back side of the filter belt 18
, and the cathode side bracelet 16 and the cathode side electrode 5
It is composed of a power source 7 and the like that applies a voltage between the two. Note that 21 is a dehydrated cake of sludge that has been dehydrated, and 22 is a collection container for the dehydrated cake. With this configuration, the sludge 10 is continuously supplied from the supply hopper 2o into the sludge passage 17, and the press belt 16 and filter belt 18 1! During the conveyance process in which it is conveyed in the direction of arrow P while receiving a squeezing force between it! Electricity is passed between the electrodes to cause electroosmotic dehydration, whereby the water contained in the sludge passes through the filter belt 18 and the through holes of the cathode side electrode 5 and is separated and dehydrated. Here, according to the present invention, a reducing wheel 11 is installed behind the cathode side electrode 5, and the reducing wheel 11 in parentheses is connected to a vacuum tank 13 in the same way as described in FIG.
is connected to. Therefore, by operating the vacuum pump 14 to maintain the inside of the filter chamber 11 at a negative pressure during the electroosmotic dewatering process, the filtrate separated from the sludge and the gas generated in the sludge are removed as in the embodiment shown in FIG. It can be effectively sucked up and removed from the system. FIG. 3 shows yet another embodiment, in which the same or equivalent members corresponding to those in FIG. 2 are given the same reference numerals. That is, in this embodiment, a ring-shaped cathode side electrode 5 is installed on the outer periphery of the rotating drum, and a filter belt 18 is stretched over the outer periphery of this electrode. On the other hand, on the inner peripheral surface side of the cathode side electrode 5, a filter chamber 11 which communicates with a vacuum tank 13 via a drain pipe 12 is divided and defined inside the drum. The drum assembly has a lower circumferential area immersed in a sludge tank 23 containing low-concentration sludge 1O, and a press belt 16 facing the upper circumferential area of the drum that also serves as an anode. is in place. Vacuum pump 14 connected to vacuum tank 13 with such a configuration
If the drum is rotated in the direction of the arrow while maintaining each filter chamber 11 in the drum at a negative pressure, sludge will be deposited on the filter belt 18 in the zone passing through the sludge tank 23. Adsorbed in tN tKA form. Further, the sludge deposited on the filter belt is conveyed by the belt, and in the process of passing between it and the press belt 16, it is subjected to an electroosmotic action. This causes the filtrate to flow through the filter belt 18. The water passes through the through hole of the electrode 5 and is suction-filtered to the filtration chamber 11 which is maintained at negative pressure, and from there is collected into the vacuum tank 13 through the drainage gap 12. At the same time, generated gases such as water vapor generated in the sludge are also degassed from the sludge and suctioned away to the vacuum tank side, as in the previous embodiment.

【発明の効果】【Effect of the invention】

以上述べたようにこの発明によれば、電気浸透脱水装置
における濾過面の背面側に負圧に保持された濾室を形成
し、咳濾室を通じて濾液および被脱水処理物内の発生し
た水戸気等の発生ガスを系外に吸引排除するようにした
ことにより、電気浸透脱水作用により被脱水処理物から
分離して濾過面へ向けて流動する濾液を効率よく脱水す
ることができ、かつ同時に脱水処理中に被脱水処理物内
に発生する水蒸気等のガス抜きが行える等、脱水効率お
よび安全性の高′・電気浸透脱水装置を得ることができ
る。
As described above, according to the present invention, a filtration chamber maintained at negative pressure is formed on the back side of the filtration surface in an electroosmotic dehydration device, and mito air generated in the filtrate and the material to be dehydrated is passed through the cough filtration chamber. By sucking and discharging generated gases from the system, it is possible to efficiently dehydrate the filtrate that is separated from the material to be dehydrated and flows toward the filtration surface by electroosmotic dehydration. It is possible to obtain an electroosmotic dehydration apparatus with high dehydration efficiency and safety, such as being able to remove gases such as water vapor generated in the object to be dehydrated during treatment.

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

第1図、第2図および第3図はそれぞれこの発明の異な
る実施例の構成断面図、第4図は従来におけるバッチ処
理方式の電気浸透脱水装置の構成断面図である0図にお
いて、 4;濾材、5:陰極側電極、6:陽掻側電極、7:電源
、10:被脱水処理物としての汚泥、11:濾室、13
:濾液回収用真空タンク、14:真空ボン第1因 第3図 第40
1, 2, and 3 are cross-sectional views of different embodiments of the present invention, and FIG. 4 is a cross-sectional view of a conventional batch processing type electroosmotic dehydrator. Filter medium, 5: cathode side electrode, 6: positive side electrode, 7: power source, 10: sludge as a material to be dehydrated, 11: filter chamber, 13
: Vacuum tank for filtrate collection, 14: Vacuum bong 1st factor Figure 3 Figure 40

Claims (1)

【特許請求の範囲】 1)対向電極の間に被脱水処理物を供給し、電気浸透作
用により濾過面を透過して被脱水処理物の水分の分離脱
水を行う電気浸透脱水装置において、前記濾過面の背面
側に負圧に保持された濾室を形成し、該濾室を通じて濾
液および被脱水処理物内部の発生ガスを系外に吸引排出
するようにしたことを特徴とする電気浸透脱水装置。 2)特許請求の範囲第1項記載の電気浸透脱水装置にお
いて、濾室に通じて濾液回収用の真空タンクが接続され
ていることを特徴とする電気浸透脱水装置。
[Scope of Claims] 1) An electroosmotic dehydration apparatus in which a material to be dehydrated is supplied between opposing electrodes, and the water in the material to be dehydrated is separated and dehydrated by passing through a filtration surface by electroosmotic action. An electroosmotic dehydration apparatus characterized in that a filter chamber maintained at negative pressure is formed on the back side of the surface, and the filtrate and the gas generated inside the material to be dehydrated are suctioned and discharged outside the system through the filter chamber. . 2) The electroosmotic dehydration apparatus according to claim 1, characterized in that a vacuum tank for filtrate recovery is connected to the filtration chamber.
JP60139924A 1985-06-26 1985-06-26 Electroosmotic dehydration apparatus Pending JPS621426A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP60139924A JPS621426A (en) 1985-06-26 1985-06-26 Electroosmotic dehydration apparatus

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP60139924A JPS621426A (en) 1985-06-26 1985-06-26 Electroosmotic dehydration apparatus

Publications (1)

Publication Number Publication Date
JPS621426A true JPS621426A (en) 1987-01-07

Family

ID=15256829

Family Applications (1)

Application Number Title Priority Date Filing Date
JP60139924A Pending JPS621426A (en) 1985-06-26 1985-06-26 Electroosmotic dehydration apparatus

Country Status (1)

Country Link
JP (1) JPS621426A (en)

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JPH0552300A (en) * 1991-08-22 1993-03-02 Ngk Insulators Ltd Starting-up of dehydrated cake pump transport device
US5725961A (en) * 1995-10-06 1998-03-10 Seiko Epson Corp. Recording medium having ink-absorbent layer
WO2000006390A1 (en) 1998-07-27 2000-02-10 Seiko Epson Corporation Method of ink-jet recording with two fluids
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