JP4638615B2 - Electroosmosis equipment - Google Patents

Description

【００１０】
また、陰極の電極近傍では通電することで、次に示す式によりアルカリ性を示すようになる。
【化２】

【００１１】
ところで、水酸化アルミニウムは両性物質であり、酸性溶液中及びアルカリ性溶液中では、次の化学反応を起こす。
【化３】

【００１２】
以上のように、酸性もしくはアルカリ性の溶液中では、水酸化アルミニウムは電気分解することになる。このため、水酸化アルミニウムのコロイドが導電性多孔質板に取り込まれても、水酸化アルミニウムは電気分解反応によって分解してイオンとなり、溶液中に拡散する。その結果、導電性多孔質板が目詰まりすることがなくなる。
【００１３】
この目詰まりの防止は、陽極と陰極の電極を導電性多孔質板としたことにより達成することができる。電極板と濾布を別々に使用した場合には、電極板と濾布の距離が離れており、濾布の中では水酸化アルミニウムを電気分解するのに十分な水素イオン、水酸化物イオンを供給することができない。そのため、濾布の中では水酸化アルミニウムの電気分解が進行しづらく、水酸化アルミニウムが蓄積してしまい、濾布の目詰まりを引き起こす。
【００１４】
この発明の電気浸透装置においては、閉塞された処理槽の容積を変更する被処理液押圧手段を設ける。
【００１５】
閉塞された処理槽の容積を変更する被処理液押圧手段を設けると、水の離脱に応じて処理槽の容積を、処理槽内の被処理液に応じて変化させることができる。
【００１６】
このため、電気分解によって発生するガスが処理槽内に充満することを防止することができる。水酸化アルミニウムゲルは脱水が進むと、電気分解によって発生するガスの影響で亀裂を生じることがあり、その亀裂部分では導電性を失うことになる。その結果、水酸化アルミニウムゲルの導電率が低下し、電気浸透現象が進行しづらくなる、電圧を印加しても電流がジュール熱に変化されることが多くなり、エネルギー効率が悪化するという問題があったが、本願発明の電気浸透装置では、水酸化アルミニウムゲルに亀裂が入ることが無く、良好な導電率を維持することができる。この結果、電気浸透効果を持続させることができる。
【００１７】
この発明の電気浸透装置においては、前記導電性多孔質板の外側を減圧する減圧手段を備えると好ましい。
【００１８】
導電性多孔質板の外側を減圧することにより、水酸化アルミニウムゲルを充填した初期の機械的濾過の促進を図ることができる。また、導電性多孔質板の表面からの吸引作用により、より短時間で脱水が行われるようになる。
【００１９】
【発明の実施の形態】
次にこの発明の電気浸透装置を、図面を参照しながら説明する。図２はこの発明の電気浸透装置の内部構造を示す概略図である。
【００２０】
（電気浸透装置の構成）
電気浸透装置１０は、筒状の電気浸透槽本体１１が２枚の正極と負極の濾過部材１２、１３より閉塞されて電気浸透槽を形成している。電気浸透槽本体１１の上部には、被処理液の注入口１５が設けられており、注入口１５は開閉自在に構成されている。そして、陽極の濾過部材１２、陰極の濾過部材１３とも、電気浸透槽に注入される被処理液の液面に対しほぼ垂直方向となるように取り付けられている。この濾過部材としては、ここでは多孔質炭素板（東海カーボン社製）を用いる。
【００２１】
上記のように、陽極および陰極の濾過部材１２、１３としては、多孔質炭素板のような導電性の多孔質の部材を用いることができる。例えば、導電性の炭化ケイ素よりなる多孔質板を用いることができる。また、耐酸性、耐アルカリ性の金属よりなる多孔質板を用いても良い。
【００２２】
また、陽極の濾過部材１２は電気浸透装置本体部に固定され、移動が規制されている。一方、陰極の濾過部材１３には伸縮アーム２０が取り付けられており、電気浸透装置本体の筒内をピストン運動するように可動自在に構成されている。伸縮アーム２０は空気圧、油圧などの手段により伸縮を任意に制御でき、ここでは窒素圧のシリンダーを用いている。これによって、陽極の濾過部材１２を筒内の任意な位置に移動させることが可能となる。そのため、電気浸透槽本体１１の電気浸透槽の容積を任意に変更できる他、電気浸透槽に注入された被処理液に対し、圧力を加えることも可能となる。
【００２３】
さらに、電気浸透槽本体１１の、濾過部材１２、１３によって仕切られた電気浸透槽の外部側の空間１７、１８は閉塞空間となっており、その閉塞空間１７、１８を減圧状態とすることが可能となっている。すなわち、濾過部材１２、１３の外部側の空間はそれぞれ閉塞した空間となっており、それぞれが真空ポンプ１９とつながっている。そこで、真空ポンプ１９を可動して脱気することにより、濾過部材１２、１３の外部側の閉塞空間１７、１８を減圧状態とすることができる。
【００２４】
陽極の濾過部材と陰極の濾過部材は、それぞれ直流電源１５の出力端子と接続しており、両濾過部材の間に所望の直流電圧を印加することができるように構成されている。
【００２５】
（電気浸透装置の動作）
この電気浸透装置の動作について以下に説明する。電気浸透槽の注入口より、従来より知られる方法により得た水酸化アルミニウムゲルを入れる。その後、注入口を閉じ、注入口からは空気が入らないようにする。そして、２枚の濾過部材の間に直流電圧を印加する。
【００２６】
酸性溶液の中和により生成する水酸化アルミニウムコロイドは水に対して多くの場合は正に帯電している。一方、コロイド界面では液は粒子と電荷の符号が反対の対イオン層が形成されている。そこで、被処理液を挟んで陽極および陰極を設置し、電極間に直流電圧を印加すると、電場によって電気浸透現象が起きる。これにより、負に帯電している水は陽極側に流動し、濾過部材を透過して脱水処理される。
【００２７】
また、電気浸透により分離を行っている最中に、陰極の濾過部材を陽極の濾過部材方向に移動させ、被処理液の容積に応じて電気浸透槽の容積を変化させる。
【００２８】
このように、水酸化アルミニウムゲルの容積に応じて電気浸透槽の容積を変化させると、水酸化アルミニウムゲルが電気分解によって発生したガスは電極板を透過して外部に放出されるため、水酸化アルミニウムゲルが発生したガスと接触することがない。そのため、発生したガスと接触することで生じる水酸化アルミニウムゲルの亀裂が起こらなくなり、水酸化アルミニウムゲルは良好な導電性を維持することができる。
【００２９】
また、この陰極の濾過部材を陽極の濾過部材側に移動させた際に、水酸化アルミニウムゲルに圧力を加えるようにすると好ましい。圧力を加えると圧搾作用により、脱水を促進することができる。
【００３０】
さらに、電気浸透槽の外部側の空間を減圧状態にする。減圧状態とすることにより、導電性多孔質板の表面からの吸引作用により脱水促進され、脱水速度が速くなる。また、電気浸透槽内部で発生したガスも、導電性多孔質板の表面からの吸引作用により外部に放出されるため、水酸化アルミニウムゲルの亀裂が起こらなくなる。
【００３１】
以上の電気浸透装置を用いることで、約７５％の含水率の水酸化アルミニウムゲルを得ることができる。その後、風乾、強制乾燥、マイクロ波加熱等によって、所望の水酸化アルミニウムを得ることができる。
【００３２】
【発明の効果】
この発明の電気浸透装置では、水酸化アルミニウムゲルを脱水するのに、導電性多孔質板が目詰まりすること無く、電気浸透現象を長時間続けることができる。この結果、含水率の低い水酸化アルミニウムを得ることができ、その後の乾燥工程も簡略なものになる。
【図面の簡単な説明】
【図１】電気浸透装置の従来例の構造の概略を示す図面である。
【図２】この発明の電気浸透装置の構造の概略を示す図面である。
【符号の説明】
１ 濾板
２ 濾枠
３ 圧搾濾板
４ 陽極側導電板
５ 陰極側導電板
６ 濾布
７ 濾室
１０ 電気浸透装置
１１ 電気浸透槽本体
１２ 濾過部材
１３ 濾過部材
１４ 注入口
１５ 直流電源
１７ 閉塞空間
１８ 閉塞空間
１９ 真空ポンプ
２０ 伸縮アーム[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a structure of an electroosmotic device used for recovering aluminum hydroxide from an aluminum-containing waste liquid in which aluminum is dissolved after aluminum etching or anodizing.
[0002]
[Prior art]
The electrode foil of an electrolytic capacitor is obtained by chemically or electrically etching a high-purity aluminum foil in an etching solution in which hydrochloric acid or the like is dissolved to increase the surface area. Therefore, the etching waste liquid (aluminum-containing waste liquid) after being used for etching dissolves a large amount of aluminum. In addition, in order to form an anodized film on the surface of the etched aluminum foil, the aluminum foil is anodized in a chemical conversion treatment solution to which boric acid or the like is added, but the chemical conversion treatment after the anodizing treatment is performed. In the waste liquid, aluminum is dissolved. Therefore, it is required to reuse aluminum as a resource from such an aluminum-containing waste solution such as an etching solution and a chemical conversion treatment solution.
[0003]
As a method of recovering this aluminum, there is a method of recovering as aluminum hydroxide conventionally. The outline is as follows. First, sodium hydroxide is added to the etching waste liquid after the etching treatment to neutralize it, thereby precipitating aluminum hydroxide. At this time, aluminum hydroxide is a colloid, and a coagulant is added to the neutralized solution to cause aggregation to obtain an aluminum hydroxide suspension. Further, the aluminum hydroxide suspension is compressed and filtered by a method such as a filter press to obtain an aluminum hydroxide gel.
[0004]
Conventional compression and filtration aluminum hydroxide gels contain 80 to 90 percent moisture. It also contains many impurities. Therefore, as a method for separating only aluminum hydroxide from such an aluminum hydroxide gel, an electroosmosis apparatus that performs dehydration and purification using an electroosmosis method is used.
[0005]
As this electroosmotic device, for example, a device described in JP-A-62-57622 is known. The outline of this electroosmosis apparatus is shown in FIG. Referring to the reference numerals in FIG. 1, a dehydration of an object to be processed is performed by applying a DC voltage between an anode and a cathode facing each other with the object to be dehydrated interposed therebetween and utilizing an electroosmosis phenomenon. As an electroosmosis device for performing filtration, a pair of filter frames 2 and 2 are sandwiched between a pair of filter plates 1 and 1 of a squeeze filter press, and a squeeze filter plate 3 is sandwiched between the pair of filter frames 2 and 2, The cathode-side conductive plate 4 is fixed to the opposed surfaces of the filter plates 1, while the squeezed filter plate 3 is provided with the anode-side conductive plate 5 on the surface facing the filter plate 1. The filter cloths 6 and 6 are applied so as to cover each of the filter frames 2 and the filter frames 2 are sandwiched between the filter plates 1 and 3 and surrounded by the filter fabrics 6 and 6 in the frame of the filter frames 2. The filter chamber 7 is formed, and after the stock solution is pressed into the filter chamber 7, a DC voltage is applied to the conductive plates 4 and 5 to The liquid component in the undiluted solution moves to the cathode conductive plate side of the filter plate 1 through the filter cloth 6 and is discharged from the filtrate recovery path of the filter plate 2 to the outside of the machine, and the solid component is compressed. Electro-osmotic dehydration is performed on the stock solution so as to be attracted to the anode conductive plate side of the filter plate 3 and remain in the filter chamber 7.
[0006]
[Problems to be solved by the invention]
However, when dehydrating from aluminum hydroxide gel by a conventional electroosmosis device, the aluminum hydroxide is clogged in the filter cloth, making it difficult for the dehydration to proceed. In some cases, it was completely covered and no voltage was applied to the aluminum hydroxide gel, making it impossible to dewater by electroosmosis.
[0007]
In view of this, the present invention proposes a structure of an electroosmosis device that can reliably perform a dehydration operation with the electroosmosis device.
[Means for Solving the Problems]
[0008]
Therefore, in the present invention, the liquid to be treated is injected into the treatment tank closed by the anode-side filtration member and the cathode-side filtration member, a DC voltage is applied to the anode-side and cathode-side electrodes, and moisture is removed by electroosmosis. The electroosmosis device to be removed is characterized in that the anode-side filtration member and the cathode-side filtration member are each formed of a conductive porous plate.
[0009]
In the vicinity of the anode and cathode electrodes of the electroosmosis device of the present invention, the pH changes by energization. That is, when the current is passed in the vicinity of the anode electrode, it becomes acidic according to the following formula.
[Chemical 1]

[0010]
In addition, when electricity is supplied in the vicinity of the cathode electrode, it becomes alkaline according to the following formula.
[Chemical 2]

[0011]
By the way, aluminum hydroxide is an amphoteric substance and causes the following chemical reaction in an acidic solution and an alkaline solution.
[Chemical 3]

[0012]
As described above, aluminum hydroxide is electrolyzed in an acidic or alkaline solution. For this reason, even if the colloid of aluminum hydroxide is taken into the conductive porous plate, the aluminum hydroxide is decomposed by the electrolysis reaction into ions and diffuses into the solution. As a result, the conductive porous plate is not clogged.
[0013]
This prevention of clogging can be achieved by using an anode and a cathode as conductive porous plates. When the electrode plate and filter cloth are used separately, the distance between the electrode plate and the filter cloth is large, and in the filter cloth, hydrogen ions and hydroxide ions sufficient to electrolyze aluminum hydroxide are contained. It cannot be supplied. Therefore, it is difficult for the aluminum hydroxide to electrolyze in the filter cloth, and the aluminum hydroxide accumulates, causing clogging of the filter cloth.
[0014]
In the electroosmosis device of this invention, a liquid to be processed pressing means for changing the volume of the closed processing tank is provided.
[0015]
If the liquid processing means pressing means for changing the volume of the closed processing tank is provided, the volume of the processing tank can be changed according to the liquid to be processed in the processing tank according to the separation of water.
[0016]
For this reason, it can prevent that the gas generated by electrolysis fills up in a processing tank. When dehydration proceeds, aluminum hydroxide gel may crack due to the influence of gas generated by electrolysis, and the cracked portion loses conductivity. As a result, the electrical conductivity of the aluminum hydroxide gel decreases, the electroosmosis phenomenon does not proceed easily, the current is often changed to Joule heat even when a voltage is applied, and the energy efficiency deteriorates. However, in the electroosmosis device of the present invention, the aluminum hydroxide gel does not crack, and good electrical conductivity can be maintained. As a result, the electroosmotic effect can be maintained.
[0017]
In the electroosmosis device according to the present invention, it is preferable that the electroosmotic device further includes a decompression means for decompressing the outside of the conductive porous plate.
[0018]
By reducing the pressure outside the conductive porous plate, the initial mechanical filtration filled with aluminum hydroxide gel can be promoted. Further, dehydration can be performed in a shorter time due to the suction action from the surface of the conductive porous plate.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
Next, the electroosmosis device of the present invention will be described with reference to the drawings. FIG. 2 is a schematic view showing the internal structure of the electroosmosis device of the present invention.
[0020]
(Configuration of electroosmosis device)
In the electroosmosis device 10, a cylindrical electroosmosis tank body 11 is closed by two positive and negative filter members 12 and 13 to form an electroosmosis tank. At the top of the electroosmotic tank body 11, an inlet 15 for the liquid to be treated is provided, and the inlet 15 is configured to be openable and closable. The anode filtration member 12 and the cathode filtration member 13 are both attached so as to be substantially perpendicular to the liquid surface of the liquid to be treated injected into the electroosmosis tank. Here, a porous carbon plate (manufactured by Tokai Carbon Co., Ltd.) is used as the filter member.
[0021]
As described above, as the anode and cathode filtering members 12 and 13, conductive porous members such as porous carbon plates can be used. For example, a porous plate made of conductive silicon carbide can be used. Moreover, you may use the porous board which consists of acid-proof and alkali-proof metal.
[0022]
Further, the anode filtering member 12 is fixed to the electroosmotic device main body and its movement is restricted. On the other hand, a telescopic arm 20 is attached to the filtering member 13 of the cathode, and is configured to be movable so as to perform a piston motion within the cylinder of the electroosmotic device main body. The telescopic arm 20 can be arbitrarily controlled to expand and contract by means such as air pressure and hydraulic pressure, and here, a nitrogen pressure cylinder is used. Thus, the anode filtering member 12 can be moved to an arbitrary position in the cylinder. Therefore, the volume of the electroosmosis tank of the electroosmosis tank body 11 can be arbitrarily changed, and pressure can be applied to the liquid to be treated injected into the electroosmosis tank.
[0023]
Furthermore, the external spaces 17 and 18 of the electroosmotic tank partitioned by the filtration members 12 and 13 of the electroosmotic tank body 11 are closed spaces, and the closed spaces 17 and 18 may be in a reduced pressure state. It is possible. That is, the spaces on the outside of the filtration members 12 and 13 are closed spaces, and each is connected to the vacuum pump 19. Therefore, by moving the vacuum pump 19 and degassing, the closed spaces 17 and 18 on the outside of the filtration members 12 and 13 can be in a reduced pressure state.
[0024]
The anode filtering member and the cathode filtering member are respectively connected to the output terminal of the DC power supply 15 and are configured so that a desired DC voltage can be applied between both the filtering members.
[0025]
(Operation of electroosmosis device)
The operation of this electroosmosis device will be described below. An aluminum hydroxide gel obtained by a conventionally known method is introduced from the injection port of the electroosmosis tank. Thereafter, the inlet is closed so that air does not enter from the inlet. A DC voltage is applied between the two filter members.
[0026]
Aluminum hydroxide colloids produced by neutralization of acidic solutions are often positively charged with respect to water. On the other hand, at the colloidal interface, the liquid has a counter-ion layer in which the sign of the charge is opposite to that of the particle. Therefore, when an anode and a cathode are placed with the liquid to be treated interposed between them and a DC voltage is applied between the electrodes, an electroosmosis phenomenon occurs due to the electric field. Thereby, the negatively charged water flows to the anode side and permeates through the filter member to be dehydrated.
[0027]
During the separation by electroosmosis, the cathode filtration member is moved toward the anode filtration member, and the volume of the electroosmosis tank is changed according to the volume of the liquid to be treated.
[0028]
Thus, when the volume of the electroosmosis tank is changed according to the volume of the aluminum hydroxide gel, the gas generated by the electrolysis of the aluminum hydroxide gel permeates the electrode plate and is released to the outside. The aluminum gel does not come into contact with the generated gas. Therefore, cracks in the aluminum hydroxide gel caused by contact with the generated gas do not occur, and the aluminum hydroxide gel can maintain good conductivity.
[0029]
Further, it is preferable to apply pressure to the aluminum hydroxide gel when the negative filter member is moved to the positive filter member side. When pressure is applied, dehydration can be promoted by the squeezing action.
[0030]
Furthermore, the space outside the electroosmosis tank is brought into a reduced pressure state. By setting the reduced pressure state, the dehydration is accelerated by the suction action from the surface of the conductive porous plate, and the dehydration speed is increased. Moreover, since the gas generated inside the electroosmosis tank is also released to the outside by the suction action from the surface of the conductive porous plate, the aluminum hydroxide gel does not crack.
[0031]
By using the above electroosmotic apparatus, an aluminum hydroxide gel having a water content of about 75% can be obtained. Thereafter, desired aluminum hydroxide can be obtained by air drying, forced drying, microwave heating or the like.
[0032]
【The invention's effect】
In the electroosmosis device of the present invention, the electroosmosis phenomenon can be continued for a long time without clogging the conductive porous plate when dehydrating the aluminum hydroxide gel. As a result, aluminum hydroxide having a low water content can be obtained, and the subsequent drying process is simplified.
[Brief description of the drawings]
FIG. 1 is a schematic view showing a structure of a conventional example of an electroosmosis device.
FIG. 2 is a drawing showing an outline of the structure of the electroosmotic device of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Filter plate 2 Filter frame 3 Squeeze filter plate 4 Anode side electrically conductive plate 5 Cathode side electrically conductive plate 6 Filter cloth 7 Filter chamber 10 Electroosmotic device 11 Electroosmotic tank body 12 Filter member 13 Filter member 14 Inlet 15 DC power supply 17 Closed space 18 Enclosed space 19 Vacuum pump 20 Telescopic arm

Claims (2)

The aluminum hydroxide suspension is injected into the treatment tank closed by the anode-side filtration member and the cathode-side filtration member, DC voltage is applied to the anode-side and cathode-side electrodes, and water is removed by electroosmosis. In the electroosmosis apparatus, the anode-side filtration member and the cathode-side filtration member are each formed of a conductive porous plate, and a treatment liquid pressing means for changing the volume of the closed treatment tank is provided. Electroosmosis device to do.   The electroosmosis device according to claim 1, further comprising a decompression unit that decompresses the outside of the conductive porous plate.

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