JPH04305300A - Waste water treating device - Google Patents

Waste water treating device

Info

Publication number
JPH04305300A
JPH04305300A JP3069879A JP6987991A JPH04305300A JP H04305300 A JPH04305300 A JP H04305300A JP 3069879 A JP3069879 A JP 3069879A JP 6987991 A JP6987991 A JP 6987991A JP H04305300 A JPH04305300 A JP H04305300A
Authority
JP
Japan
Prior art keywords
tank
sludge
filtration
aeration
wastewater
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
JP3069879A
Other languages
Japanese (ja)
Inventor
Toshiyasu Sato
佐藤 利安
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.)
TOKUMOTO SADAMI
Original Assignee
TOKUMOTO SADAMI
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 TOKUMOTO SADAMI filed Critical TOKUMOTO SADAMI
Priority to JP3069879A priority Critical patent/JPH04305300A/en
Publication of JPH04305300A publication Critical patent/JPH04305300A/en
Pending legal-status Critical Current

Links

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

  • Aeration Devices For Treatment Of Activated Polluted Sludge (AREA)
  • Activated Sludge Processes (AREA)
  • Filtration Of Liquid (AREA)
  • Water Treatment By Sorption (AREA)
  • Separation Of Suspended Particles By Flocculating Agents (AREA)

Abstract

PURPOSE:To provide the waste water treating device which can inexpensively purify the waste water from hotels, restaurants, etc., having relatively high BOD, COD, SS, etc. CONSTITUTION:This device has a water receiving tank (1) which receives the raw water of waste water, an aeration tank (2) which can make superconvectional aeration by fine bubbles, a reaction chamber (3) which subjects sludge to flotation in an acid or alkaline soln. then to neutralization and sends this sludge to the ensuing stage, a settling sepn. chamber (4) which separates the materials contained in the sludge by utilizing the sp. gr. differences, a treated water tank (5), a sand filter column (6), and a multistage type active carbon filter column (7).

Description

【発明の詳細な説明】[Detailed description of the invention]

【0001】0001

【産業上の利用分野】本発明は,曝気槽、複数の濾過塔
を有する排水処理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 wastewater treatment system having an aeration tank and a plurality of filtration towers.

【0002】0002

【従来の技術】一般に、排水処理は、物理的処理、化学
的処理を適用すれば排水処理時間が比較的短時間にて装
置自体も小規模ですむ一面、運転経費が嵩むと言う欠点
がある。ところで排水中の汚濁物質の存在状態は懸濁物
質と溶存物質とに大別される。そして懸濁物質は水中で
、そのままの状態では分子分散あるいはイオンとなって
解離しない金属、金属酸化物、難溶性化合物、有機の高
分子物質等であるから,その物理的性質を利用して、固
液分離による処理技術が適用される。
[Prior Art] In general, in wastewater treatment, if physical treatment or chemical treatment is applied, the wastewater treatment time can be relatively short and the equipment itself can be small-scale, but it has the disadvantage of high operating costs. . By the way, the state of existence of pollutants in wastewater is roughly divided into suspended substances and dissolved substances. Suspended substances are metals, metal oxides, poorly soluble compounds, organic polymer substances, etc. that do not dissociate into molecules or ions in water, so by utilizing their physical properties, Processing technology based on solid-liquid separation is applied.

【0003】一方、溶存物質は無機の金属イオン、有機
の可溶性化合物からなる事が多く、先ず溶存物質を不溶
性物質に転換すると共に、無害の物質に変化させる必要
があり,この後に固液分離による処理技術が適用される
ことになる。
On the other hand, dissolved substances often consist of inorganic metal ions and organic soluble compounds, and it is first necessary to convert the dissolved substances into insoluble substances and also to harmless substances, and after this, solid-liquid separation is performed. Processing techniques will be applied.

【0004】0004

【発明が解決しようとする課題】これら従来の排水処理
は、設備が大規模となり使用する薬剤量も多く、運転経
費が嵩むと言う欠点の他に、排出する汚濁物質やその分
解生成した汚泥量も多くなり、これを安全に廃棄処分す
るのが困難である等の問題があり、これらの早期解決が
望まれている。
[Problems to be Solved by the Invention] These conventional wastewater treatment methods require large-scale equipment, use a large amount of chemicals, and have the disadvantage of increasing operating costs. There are many problems such as the difficulty of safely disposing of these, and an early solution to these problems is desired.

【0005】本発明は、有機の可溶性化合物や無機の金
属イオンからなる溶存物質を多く含んでいる工場排水や
、家庭排水の処理等、幅広く広範囲な排水処理に利用で
きる機能を有する処理装置、特にBOD,COD,SS
等の比較的高い食堂等からの排水の浄化に最適の処理装
置を提供することを目的としている。
[0005] The present invention provides a treatment device having a function that can be used for a wide range of wastewater treatment, such as treatment of industrial wastewater and domestic wastewater, which contain a large amount of dissolved substances consisting of organic soluble compounds and inorganic metal ions. BOD, COD, SS
The purpose of this project is to provide an optimal treatment device for purifying wastewater from relatively expensive cafeterias, etc.

【0006】[0006]

【課題を解決するための手段】上記の目的を達成するた
めに、本発明の排水処理装置は、曝気には微細直径気泡
の噴射設備を設け、また、濾過では、上流側に砂濾過塔
と、下流側に弁切り替えにより最新の濾過剤を充填した
濾過塔が最終濾過順位になるように接続した複数の濾過
塔を設けてなることを特徴とするものである。
[Means for Solving the Problems] In order to achieve the above object, the wastewater treatment device of the present invention is equipped with a fine diameter bubble injection equipment for aeration, and a sand filter tower is installed on the upstream side for filtration. The present invention is characterized in that a plurality of filtration towers are connected on the downstream side so that the filtration tower filled with the latest filtration agent becomes the final filtration order by valve switching.

【0007】[0007]

【作用】上記のように構成された排水処理装置によれば
、曝気は、曝気槽の底部より上向きに噴射される微細直
径の気泡により行われるため、極めて効率的に行われる
。また、濾過は砂濾過塔と多段式の活性炭濾過塔とによ
り行われ、該活性炭濾過塔においては新規活性炭を充填
した濾過塔が常に最終段に来るように流路が切替えられ
るため、活性炭濾過塔全体の濾過効率は常に一定に保持
される。
[Function] According to the wastewater treatment apparatus constructed as described above, aeration is carried out by air bubbles of fine diameter that are injected upward from the bottom of the aeration tank, so that it is carried out extremely efficiently. In addition, filtration is performed using a sand filtration tower and a multi-stage activated carbon filtration tower, and in the activated carbon filtration tower, the flow path is switched so that the filtration tower filled with new activated carbon is always at the last stage, so the activated carbon filtration tower The overall filtration efficiency remains constant at all times.

【0008】[0008]

【実施例】図1は本発明の一実施例を示す排水処理装置
の概略図である。図中、1は食堂等から排出される汚水
の受水槽,2は曝気槽、3は酸またはアルカリ性液中で
汚泥を浮沈分離せしめた後中和して次行程に送る反応槽
、4は汚水中に含まれる物質の比重差を利用して分離す
る沈降分離槽、5は処理水槽、6は砂濾過塔、7は多段
式活性炭濾過塔、8は汚泥タンク、9は各機器間を接続
する配管である。
DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is a schematic diagram of a wastewater treatment apparatus showing an embodiment of the present invention. In the figure, 1 is a receiving tank for sewage discharged from cafeterias, etc., 2 is an aeration tank, 3 is a reaction tank in which sludge is floated and separated in acid or alkaline liquid, neutralized, and sent to the next process, and 4 is sewage water. 5 is a treated water tank, 6 is a sand filtration tower, 7 is a multistage activated carbon filtration tower, 8 is a sludge tank, and 9 is a connection between each device. It's plumbing.

【0009】先ず、図面に基づいて排水処理の行程を説
明する。食堂等から流出され受水槽1に貯蔵された汚水
は、ポンプPにより曝気槽2に流入される。曝気はコン
プレッサー21により加圧された空気が気体噴出孔22
から微細気泡(例えば直径が0.1〜0.2ミクロン)
になって槽内汚水中に噴出されるような構造を有する所
謂湿式高圧酸化法のものであればよいが,この噴射は図
に示す如く、受水槽2の底面側から上向噴射される方式
のものが好ましく、これにより落下方向に流動する汚水
に対向して逆に勢い良く空気が上向噴射され、「超対流
曝気」と称する対向方式であるため、気液接触が多くな
り空気による酸化作用が著しく促進されて、曝気効果が
向上するものである。そこで従来の曝気では、汚泥が汚
水中の有機物を吸着し、次第にこれを酸化分解して汚泥
を沈下せしめて上澄液を放流または次処理行程へ送るよ
うになっているが、本発明のものは、逆に流入汚水中の
懸濁物質に微細気泡を付着せしめて見掛け比重を小さく
し、浮上分離するものであり、浮上した浮渣は、これを
連続的に掻き集めて排出する設備23等により槽外へ排
出されるようになっている。尚、曝気時間は普通6時間
程度で充分である。
First, the process of wastewater treatment will be explained based on the drawings. Sewage discharged from the cafeteria and stored in the water receiving tank 1 is flowed into the aeration tank 2 by the pump P. For aeration, air pressurized by a compressor 21 is sent to a gas outlet 22.
to fine bubbles (e.g. 0.1-0.2 microns in diameter)
The so-called wet high-pressure oxidation method, which has a structure in which water is ejected into the sewage inside the tank, may be used. However, as shown in the figure, this method is a method in which the water is ejected upward from the bottom side of the water receiving tank 2. It is preferable to use a sewage system, which injects air forcefully upwards against the wastewater flowing in the falling direction, and because it is a facing method known as "super convection aeration", there is more gas-liquid contact and oxidation by air is prevented. The action is significantly accelerated and the aeration effect is improved. Therefore, in conventional aeration, the sludge adsorbs organic matter in the sewage, gradually oxidizes and decomposes it, causes the sludge to settle, and the supernatant liquid is discharged or sent to the next treatment process, but the present invention On the other hand, microbubbles are attached to the suspended solids in the inflowing wastewater to reduce their apparent specific gravity, and the floating substances are separated by flotation. It is designed to be discharged outside the tank. Note that an aeration time of about 6 hours is usually sufficient.

【0010】尚、BOD、CODが1000ppm  
以上含まれた汚水に対しては、空気に替えてオゾンを使
用すると極めて効率が良く,曝気時間、槽滞留時間を短
縮する事が出来て能率が極めて良いことは勿論であるが
、この浮上分離に加圧浮上法を応用すれば更に、その効
果は顕著である。
[0010] Furthermore, BOD and COD are 1000 ppm.
For wastewater containing the above, it is extremely efficient to use ozone instead of air, and it is possible to shorten aeration time and tank retention time, which is extremely efficient. If the pressure levitation method is applied to this, the effect will be even more remarkable.

【0011】曝気による一次処理済み液はポンプPによ
り配管9を通って反応槽3の酸処理槽31に流入する。 薬液タンク32中には酸性薬剤として硫酸25%溶液ま
たは「ロックス(商品名)」液が準備される。この「ロ
ックス」は風化花崗岩、蛇紋岩等を硫酸抽出して製造さ
れるものであり、溶融金属イオンや溶融物質の特性に夫
々対応した酸性液になるように酸性薬剤が添加調整され
攪拌機33により充分に攪拌される。これにより微粒子
の浮遊物質を凝集させ、沈降速度を迅速化せしめ次のア
ルカリ処理槽34へと流入し、ここでは薬液タンク35
に貯蔵されたアルカリ性薬剤のアラレ石系の石灰石(天
然産出する斜方系炭酸カルシュームで純度98%)また
は消石灰がpH計36の指令により適宜添加され攪拌機
33により攪拌されることにより、溶液は酸性からアル
カリ性へと変換し、この際に、更に溶融有機物を凝固抽
出し、さらにpH計の指令により処理済み液は中和され
る。この二次処理の前段、後段の夫々の行程で生じた浮
渣の槽外排出機構は図示を省略してある。尚、酸、アル
カリ性等の薬剤は他の特別な凝集剤を添加する必要がな
いので、生成される汚泥量は極めて少量であり、注入薬
剤は経済的となる。また、沈澱汚泥に就いても、この行
程での摘出が可能ではあるが、槽底であることや、攪拌
機33の作動や滞留時間の関係で、この行程では汚泥排
出を行わず、次の沈降分離槽4で一括して行うようにし
てあるので、分離も有効確実で、極めて経済的である。
[0011] The liquid that has been primarily treated by aeration flows into the acid treatment tank 31 of the reaction tank 3 through the pipe 9 by the pump P. In the chemical liquid tank 32, a 25% sulfuric acid solution or "ROX (trade name)" liquid is prepared as an acidic chemical. This "ROX" is manufactured by extracting weathered granite, serpentinite, etc. with sulfuric acid, and an acidic agent is added and adjusted to create an acidic liquid that corresponds to the characteristics of the molten metal ions and molten substances, respectively, and is mixed with a stirrer 33. Stir thoroughly. As a result, suspended particles of fine particles are aggregated, speeding up the sedimentation rate, and flowing into the next alkaline treatment tank 34, where the chemical solution tank 35
Araleite-based limestone (naturally occurring orthorhombic calcium carbonate, purity 98%) or slaked lime, which is an alkaline agent stored in At this time, the molten organic matter is further coagulated and extracted, and the treated liquid is further neutralized according to the commands of the pH meter. Mechanisms for discharging floats generated in the first and second stages of this secondary treatment to the outside of the tank are not shown. It should be noted that since there is no need to add other special coagulants to acidic, alkaline, etc. chemicals, the amount of sludge produced is extremely small, making the injection of chemicals economical. In addition, although it is possible to extract settled sludge in this process, due to the fact that it is at the bottom of the tank, the operation of the agitator 33, and the residence time, sludge is not discharged in this process, and the sludge is not discharged in the next process. Since the separation is carried out all at once in the separation tank 4, the separation is effective and reliable, and is extremely economical.

【0012】沈降分離槽4においては、二次処理液の主
として凝固された汚泥を沈澱濃縮せしめ、排出機41を
作動して適時槽外の汚泥処理装置8の汚泥用タンク81
へ排出し、この汚泥は圧縮脱水及び乾燥機構82により
運搬便利な粒体等となり、肥料として利用されたり、あ
るいは廃棄される。
In the sedimentation separation tank 4, mainly the coagulated sludge of the secondary treatment liquid is sedimented and concentrated, and the discharger 41 is operated to remove the sludge from the sludge tank 81 of the sludge treatment device 8 outside the tank.
This sludge is turned into granules that can be conveniently transported by a compression dewatering and drying mechanism 82, and is used as fertilizer or discarded.

【0013】上記沈澱分離槽4で三次処理を経た液は、
更に処理水槽5に入る。この槽5の設置は、必要に応じ
て薬品処理、滞留時間処理や濾過処理により更に高度の
水質を得るための設備である。
The liquid that has undergone the tertiary treatment in the sedimentation separation tank 4 is
Furthermore, it enters the treated water tank 5. This tank 5 is installed to obtain a higher quality of water by chemical treatment, residence time treatment, and filtration treatment as necessary.

【0014】処理水槽5までの前行程で除去できなかっ
た微量の懸濁物を更に除去して清澄な水を得るために、
先ず砂濾過塔6、次いで多段式活性炭濾過塔7により最
終処理が行われる。この組合せは、直接活性炭濾過を行
うことによる活性炭の早期劣化を防止するための装置で
もあって、この砂濾過槽6の濾過剤61には砂の他にザ
クロ石、アンスライト等の粒状のものを混入して用いて
もよいことは当然である。
[0014] In order to obtain clear water by further removing trace amounts of suspended solids that could not be removed in the previous step up to the treated water tank 5,
Final treatment is performed first in a sand filtration tower 6 and then in a multi-stage activated carbon filtration tower 7. This combination is also a device for preventing early deterioration of activated carbon due to direct activated carbon filtration. Of course, it is also possible to mix and use.

【0015】最終行程の多段式活性炭濾過塔7は本実施
例では3個設けてあるが、複数であればよい。先ず砂濾
過塔6から送られた水は、例えば複数列に併設された配
管9を経て複数の切替弁71の操作により活性炭濾過塔
の第1塔72,第2塔73,第3塔74の順位で通過濾
過されるようになっている。この塔の順位は新しい濾過
剤(活性炭)75が充填された塔程後順位に通過するよ
うに複数の切替弁71を切替えて行われるものである。 即ち第1塔72に充填されたの活性炭75が有機物を吸
着して破過点に達したら活性炭75を新炭と交換し、今
度は通水を第2塔73、第3塔74、第1塔72の順位
に切替て行う。これにより多段式活性炭濾過塔7の全体
としての吸着力の変動を抑え、常に所期の吸着効率を維
持することができる。この様に多段式活性炭濾過槽7を
経由した浄化水は基準値或いは所期値までに浄化されて
排水口76へと放流される。ここで、充填する活性炭に
は、椰子殻から製造した活性炭を使用すると効率が良い
。また、本実施例では第3番目も常時使用するようにし
たが、槽1個は予備として置き、活性炭75が破過点に
達した塔を流経路外にする際に交替させて、上記の様に
通水順位を変えるようにすることも自由である。尚、こ
の活性炭濾過の行程では主として、前記機構で抽出され
なかった有機物、COD,BOD,SSの除去や、食堂
等の排出水に比較的多く含まれるノルマルヘキサンや残
留塩素等の吸着除去し更に、脱臭、脱色、脱硫等が行わ
れることは勿論である。
Although three multi-stage activated carbon filtration towers 7 for the final stage are provided in this embodiment, a plurality of them may be used. First, water sent from the sand filtration tower 6 passes through, for example, pipes 9 installed in multiple rows, and is transferred to the first tower 72, second tower 73, and third tower 74 of the activated carbon filtration tower by operating a plurality of switching valves 71. It is designed to be passed through and filtered based on the ranking. The order of the columns is determined by switching a plurality of switching valves 71 so that new filtering agent (activated carbon) 75 is passed through the column after the column filled with it. That is, when the activated carbon 75 packed in the first column 72 adsorbs organic matter and reaches a breakthrough point, the activated carbon 75 is replaced with fresh carbon, and water is then passed through the second column 73, the third column 74, and the first column. The order is switched to tower 72. This suppresses fluctuations in the adsorption power of the multi-stage activated carbon filtration tower 7 as a whole, making it possible to always maintain the desired adsorption efficiency. In this way, the purified water that has passed through the multi-stage activated carbon filtration tank 7 is purified to a standard value or a desired value and is discharged to the drain port 76. Here, it is efficient to use activated carbon manufactured from coconut shells as the activated carbon to be filled. In addition, in this example, the third tank was always used, but one tank was kept as a reserve and replaced when the tower in which the activated carbon 75 reached the breakthrough point was removed from the flow path. You are also free to change the order of water flow. In addition, this activated carbon filtration process mainly removes organic substances, COD, BOD, and SS that were not extracted by the above mechanism, adsorbs and removes normal hexane and residual chlorine, which are relatively abundant in waste water from cafeterias, etc. Of course, deodorization, decolorization, desulfurization, etc. are performed.

【0016】[0016]

【発明の効果】以上の如く、本発明による排水処理装置
は、先ず、曝気槽に於いて、微細粒の気泡が排水の流れ
に対向して噴出されることにより、気液が充分に接触す
るので数時間の滞留時間でも充分酸化が促進され、その
酸化物を浮上せしめて排出するので、沈下排出する場合
の如く、槽底から沈下物を取り出す機器を設置する必要
もなく経済的であり、特にBODやCODが高い排水の
場合には、空気に替えてオゾンを用いて酸化促進を図る
ことも出来、更に最終行程の多段式活性炭濾過塔は、切
替弁操作により通水順位を自在に切替可能としたので、
新規活性炭を充填した濾過塔を常に最終順位にすること
が出来、もって濾過機構全体としての活性炭吸着効率を
常に変動しないよう保持することができる。また凝集剤
等の他薬剤を使用しないので、汚泥量も少なくて済み、
使用薬剤によっては汚泥までも別方面への利用が可能と
なり、所期の排水浄化を設備費、運転費等の面で経済的
に行うことが出来ると共に汚泥の廃棄等取扱が極めて容
易になるものである。
[Effects of the Invention] As described above, in the wastewater treatment apparatus according to the present invention, firstly, fine air bubbles are ejected in the aeration tank in the opposite direction to the flow of wastewater, so that gas and liquid come into sufficient contact with each other. Therefore, oxidation is sufficiently promoted even with a residence time of several hours, and the oxides are floated and discharged, so there is no need to install equipment to take out the sediment from the bottom of the tank, as is the case with sinking discharge, making it economical. Particularly in the case of wastewater with high BOD and COD, ozone can be used instead of air to promote oxidation, and the multi-stage activated carbon filtration tower in the final stage can freely switch the water flow order by operating the switching valve. Since it was possible,
The filtration tower filled with the new activated carbon can always be placed in the final rank, thereby making it possible to maintain the activated carbon adsorption efficiency of the entire filtration mechanism so as not to fluctuate at all times. In addition, since other chemicals such as flocculants are not used, the amount of sludge can be reduced.
Depending on the chemicals used, even sludge can be used for other purposes, making it possible to carry out the desired wastewater purification economically in terms of equipment costs, operating costs, etc., and making sludge disposal and other handling extremely easy. It is.

【0017】[0017]

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

【図1】排水処理装置の概略図である。FIG. 1 is a schematic diagram of a wastewater treatment device.

【符号の説明】[Explanation of symbols]

1    汚水受水槽 2    曝気槽 3    反応槽 4    沈降分離槽 5    処理槽 6    砂濾過塔 7    多段式活性炭濾過塔 8    汚泥処理装置 1 Sewage receiving tank 2 Aeration tank 3 Reaction tank 4 Sedimentation separation tank 5 Processing tank 6 Sand filter tower 7 Multi-stage activated carbon filtration tower 8 Sludge treatment equipment

Claims (1)

【特許請求の範囲】[Claims] 【請求項1】  排水を曝気、酸処理、アルカリ処理し
た後に濾過することにより浄化する排水処理装置におい
て、上記曝気には微細直径気泡の噴射設備を設け、また
、上記濾過は、上流側に砂濾過塔と、下流側に弁切り替
えにより常時、最新の濾過剤を充填した濾過塔が最終濾
過順位になるように接続した複数の濾過塔を設けてなる
ことを特徴とする排水処理装置。
Claim 1: A wastewater treatment device that purifies wastewater by aeration, acid treatment, and alkali treatment and then filtering the wastewater, wherein the aeration is equipped with injection equipment for fine-diameter bubbles, and the filtration is carried out using sand on the upstream side. A wastewater treatment device comprising a filtration tower and a plurality of filtration towers connected downstream by valve switching so that the filtration tower filled with the latest filtration agent is always in the final filtration order.
JP3069879A 1991-04-02 1991-04-02 Waste water treating device Pending JPH04305300A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP3069879A JPH04305300A (en) 1991-04-02 1991-04-02 Waste water treating device

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP3069879A JPH04305300A (en) 1991-04-02 1991-04-02 Waste water treating device

Publications (1)

Publication Number Publication Date
JPH04305300A true JPH04305300A (en) 1992-10-28

Family

ID=13415503

Family Applications (1)

Application Number Title Priority Date Filing Date
JP3069879A Pending JPH04305300A (en) 1991-04-02 1991-04-02 Waste water treating device

Country Status (1)

Country Link
JP (1) JPH04305300A (en)

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH0664703U (en) * 1993-02-22 1994-09-13 バイタル・ジャパン株式会社 Filtration device
WO2002006168A1 (en) * 2000-06-30 2002-01-24 Fuelling Rainer Method and device for purifying and treating waste water in order to obtain drinking water
JP2009119374A (en) * 2007-11-15 2009-06-04 Panasonic Corp Treatment apparatus and method of drainage
JP2012192331A (en) * 2011-03-16 2012-10-11 Toyota Motor East Japan Inc Treatment method for aqueous coating material waste liquid
CN102826675A (en) * 2011-06-16 2012-12-19 张家港市贝尔机械有限公司 Simple and practical water treatment facility
WO2017115423A1 (en) * 2015-12-28 2017-07-06 三菱重工業株式会社 Water treatment system and water treatment method
CN107162176A (en) * 2017-06-05 2017-09-15 浙江水利水电学院 A kind of activated sludge ecological sewage cleaning system and its processing method

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH0664703U (en) * 1993-02-22 1994-09-13 バイタル・ジャパン株式会社 Filtration device
WO2002006168A1 (en) * 2000-06-30 2002-01-24 Fuelling Rainer Method and device for purifying and treating waste water in order to obtain drinking water
JP2009119374A (en) * 2007-11-15 2009-06-04 Panasonic Corp Treatment apparatus and method of drainage
JP2012192331A (en) * 2011-03-16 2012-10-11 Toyota Motor East Japan Inc Treatment method for aqueous coating material waste liquid
CN102826675A (en) * 2011-06-16 2012-12-19 张家港市贝尔机械有限公司 Simple and practical water treatment facility
WO2017115423A1 (en) * 2015-12-28 2017-07-06 三菱重工業株式会社 Water treatment system and water treatment method
CN107162176A (en) * 2017-06-05 2017-09-15 浙江水利水电学院 A kind of activated sludge ecological sewage cleaning system and its processing method

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