JP2004299962A - Method for removing fluorine in gypsum - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To remove fluorine from desulfurized gypsum effectively utilized for a building material such as a gypsum board. <P>SOLUTION: Fluorine-containing gypsum is cleaned with cleaning water with weak acidity or preferably, of pH in the range of 4 to 5 in which an aluminum compound such as aluminum sulfate (Al<SB>2</SB>(SO<SB>4</SB>)<SB>3</SB>-18H<SB>2</SB>O) is dissolved, so that fluorine is eluted from the gypsum into the cleaning water. The fluorine eluted into the cleaning water is subjected to flocculation precipitation with lime water (Ca(OH)<SB>2</SB>) or calcium carbonate (Ca(CO<SB>3</SB>)<SB>2</SB>), and is removed from the cleaning water. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

【００３６】
【表２】

【００３７】
【表３】

【００３８】
表３に示したように、硫酸バンド５重量％添加後のｐＨが６．４の試料Ｄにおいては、洗浄水中のアルミニウムイオンが水酸化アルミニウムとなって沈殿し、フッ素イオンと錯体を生成できないため、フッ素除去率が水洗浄のみの場合と同程度であった。それ以外の試料Ａ，Ｂ，Ｇ，Ｈ，Ｌ，Ｍ，Ｑ，Ｒ，ＳはいずれもｐＨが３．９〜５．５の弱酸性の範囲にあることから、アルミニウムイオンとフッ素イオンとがフルオロ錯体（主としてＡｌＦ_２ ^＋とＡｌＦ_３ ^０）を生成し、ＣａＦ_２の溶解度積（Ｋｓｐ＝一定値）によって規定されるフッ素イオンの量以上のフッ素を洗浄水中に溶出させ、フッ素除去率を大幅（比較例の１０倍以上）に改善された大きなフッ素除去率が得られた。
【００３９】
【発明の効果】
本発明においては、フッ素含有石こうをアルミニウムイオンを含む洗浄水、例えばアルミニウム化合物を含有する洗浄水で弱酸性の条件下で洗浄することにより、フッ素含有石こう中のフッ素をアルミニウムイオンとの錯体を生成させてＣａＦ_２の溶解度積で規定されるフッ素イオンの量以上に溶出させることで高効率で除去可能とする。その結果、たとえ安定型廃棄物として廃棄された場合にも、環境に有害なフッ素を溶出する怖れの少ない安全な回収石こうを建築材料等として提供することができる。
【００４０】
しかも、不純物としてのアルミニウム化合物を石こう材料中に大量に含むことがなく、廃水処理において生じる凝集沈殿物の脱水ケーキだけが廃棄物として生じるので、全体として廃棄物量が低減できる。
【００４１】
また、フッ素含有洗浄排水中のフッ素も中和処理するだけで、放流可能な程度まで除去することができる。すなわち、この洗浄排水は、洗浄水としてリサイクルできることを意味する。しかも、凝集沈殿物には石こうは含まれずフッ素だけであるので、脱水ケーキ量が少量となり、廃棄物量が減容化できる。
【００４２】
上記したように、本発明はフッ素含有石こう中のフッ素の除去方法を提供するものであり、その産業的意義、特に石炭燃焼路の排煙脱硫分野や建築材料分野における意義は極めて大きい。
【図面の簡単な説明】
【図１】本発明の石こう中のフッ素の除去方法のフローチャートである。
【図２】本発明の実施例で得られた洗浄水中のアルミニウムイオン濃度とフッ素除去率との関係を示すグラフである。[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a method for removing fluorine in gypsum. More specifically, the present invention relates to a method for removing fluorine in a fluorine-containing gypsum such as a desulfurized gypsum produced by a flue gas desulfurization apparatus using a lime-gypsum method.
[0002]
[Prior art]
Lime SO ₂ in the combustion exhaust gas discharged from coal fired power plants in the flue gas desulfurization unit - (called a desulfurized gypsum) gypsum produced as a by-product when removing the gypsum method and, from phosphate rock Gypsum by-produced when phosphoric acid is produced by the wet phosphoric acid method often contains a fluorine compound.
[0003]
Conventionally, this type of gypsum has been effectively used as a building material such as a gypsum board without being discarded as it is. When the paper on the surface of the gypsum board is peeled off, it is regarded as "ceramic waste", and can be disposed of together with glass waste, debris, etc. in a uniformly stable disposal site. Therefore, it has been pointed out that in a state where gypsum still contains fluorine, there is a possibility that fluorine is eluted by rainwater or the like when the gypsum is disposed of as stable waste. At present, gypsum board can be disposed of in a stable disposal form, so there is no problem with the amount of fluorine contained in the gypsum board. It is desired to reduce the elution amount due to removal of fluorine from the board and insolubilization.
[0004]
To solve this problem, a fluorine-containing gypsum material or a gypsum material derived from sludge is mixed with a maximum of 0.5 mol of an aluminum compound, specifically aluminate or sodium aluminate, per mol of calcium sulfate. There has been proposed a technique for producing a fluorine-insoluble gypsum composition by using the method (JP-A-2001-253755). This gypsum composition / plaster board does not elute harmful fluorine even when discarded, and enables safe and efficient treatment. Although the detailed mechanism of fluorine insolubilization is not disclosed, a large amount of the contained aluminum compound reacts with rainwater to become aluminum hydroxide and precipitates around gypsum, which binds with fluorine and elutes fluorine outside. It is presumed that they were expected not to be fixed in gypsum without doing so.
[0005]
[Patent Document 1]
JP 2001-253755 A
[Problems to be solved by the invention]
However, this fluorine insolubilization technology involves the emission of a large amount (up to 0.5 mol per mol of calcium sulfate) of gypsum from aluminum coal, which would otherwise be an impurity, from coal-fired power plants. Despite reducing the amount of waste by effectively utilizing desulfurized gypsum and other products produced as a by-product from the desulfurization equipment in the flue gas that is produced, it is necessary to increase the total amount of waste. turn into.
[0007]
In addition, adding an aluminum compound which is a large amount of impurities as much as 0.5 mol per 1 mol of calcium sulfate to the gypsum material in advance may affect the quality and properties of the gypsum material, the processing step and the like.
[0008]
Furthermore, even if the intention is to insolubilize fluorine from the gypsum material by adding a large amount of aluminum compounds as impurities, the waste gypsum board still contains fluorine, so a sufficient understanding can be obtained. Includes issues that can give you vague anxiety without a second thought.
[0009]
On the other hand, since the fluorine compound in the desulfurized gypsum is soluble in water, fluorine can be removed by washing the gypsum material with water. However, since the solubility of the fluorine compound in water is defined by the solubility product, when the fluorine content in the gypsum is small, the elution rate of fluorine by the water washing treatment tends to be large, but when the fluorine content is large. Therefore, even if the washing process is repeated, the fluorine content in the gypsum does not decrease so much, and the number of washing processes must be considerably increased. However, in that case, the gypsum component itself dissolves and disappears, which is meaningless from the viewpoint of effective use of desulfurized gypsum.
[0010]
An object of the present invention is to provide a method for removing fluorine from gypsum, which removes fluorine from a gypsum-containing gypsum material and reduces the amount of fluorine contained therein to such an extent that elution of fluorine is not a problem. It is still another object of the present invention to provide a method for removing fluorine from fluorine-containing wastewater discharged along with the fluorine removal treatment.
[0011]
[Means for Solving the Problems]
As a result of intensive studies on the elution characteristics of fluorine from desulfurized gypsum, the present inventors have found that the fluorine concentration in the elution water increases as the amount of the aluminum compound contained as an impurity increases.
[0012]
The method for removing fluorine from gypsum according to the present invention is based on this finding, and is characterized in that fluorine-containing gypsum is washed with washing water containing aluminum ions. More specifically, fluorine-containing gypsum is washed with weakly acidic washing water in which an aluminum compound is dissolved. Here, the aluminum compound is preferably a sulfate band (Al ₂ (SO ₄ ) ₃ .18H ₂ O), and the pH of the washing water is preferably maintained in the range of 4 to 5.
[0013]
The dissolution of fluorine in gypsum in washing water is a dissolution reaction of CaF ₂ in water with the reaction shown in Chemical Formula 1 as a main reaction.
Embedded image
CaF ₂ → Ca ₂ ⁺⁺ 2F ⁻
Here, the fluorine concentration in water is defined by the solubility product of CaF ₂ (Ksp = constant value) (correctly, it is defined not by the concentration but by the activity), and is represented by the following chemical formula 2.
Embedded image
Ksp = [Ca ^{2 +} concentration] [F ⁻ concentration] ²
[0014]
However, the aluminum ions coexist in water, fluoride ion produces a fluoro complex (mainly _AlF ^{2 +} and _AlF ^{3 0).} As a result, since fluorine ions can be dissolved in the form of a fluoro complex, more fluorine than the amount defined by the above-mentioned solubility product (the amount of fluorine in the F ^- form below) as shown in Chemical Formula 3 is actually obtained. the be eluted from CaF _2.
Embedded image
Total fluorine amount eluted from CaF ₂ = F ^- form of the fluorine amount + _AlF ^{2 +} form of the fluorine amount + _AlF ^{3 0} form of fluorine content Therefore, a small number of washes, usually desired fluorine removal rate is obtained at once.
[0015]
Further, the method for removing fluorine from the washing wastewater of the present invention is characterized in that the washing wastewater after separating and recovering the washed gypsum from the washing water is neutralized, and a flocculant is added to the neutralized washing wastewater to thereby remove the fluorine-containing sludge. Is coagulated and precipitated, and the coagulated sediment is concentrated and dehydrated and filtered to obtain a dehydrated cake of fluorine-containing sludge. On the other hand, the washing wastewater from which fluorine has been removed is filtered and discharged or recycled as washing water. Therefore, the fluorine eluted in the washing wastewater is further concentrated and collected, and the washing water is rendered harmless and recycled as wastewater or further washing water.
[0016]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, the configuration of the present invention will be described in detail based on an example of an embodiment shown in the drawings.
[0017]
As shown in FIG. 1, the method for removing fluorine from gypsum according to the present invention roughly includes a fluorine removing step S1 and a wastewater treatment step S2. Furthermore, the fluorine removing step S1 is an aluminum compound to the fluorine-containing plaster and the wash water was added, with the addition of further acid optionally, step S ₁₁ for cleaning the fluorine-containing gypsum under weakly _acidic, and gypsum separation the step S ₁₂ of the wash water to recover the gypsum which is the removal of the separated fluorine with machine comprises at least.
[0018]
Also, waste water treatment step S2 is a fluorine-containing detergent drain after gypsum separation is fluorine removed (simply, washing and drainage called) step S ₂₁ to neutralize the added _alkali, aggregation fluorine-containing washing waste water is neutralized step S ₂₂ that agent to aggregate precipitate a fluorine-containing sludge was _added, the waste water process S ₂₃ and fluorine is removed by coagulation-sedimentation was concentrated dehydrated filtered obtain dehydrated cake of the fluorine-containing sludge is filtered and purified water comprising at least a purification step S _24, so that recycled as discharged or washing water as water harmless removal of the fluorine-containing.
[0019]
In the present invention, the fluorine-containing gypsum to be treated is recovered gypsum recovered by a flue gas desulfurization apparatus using a lime-gypsum method for treating flue gas from a coal combustion furnace such as a thermal power plant, and a wet-type phosphoric acid production facility. It is a by-product gypsum and the like, and is a gypsum in the form of dihydrate (gypsum) and １ ／ -hydrate (gypsum gypsum). For example, the gypsum from flue gas desulfurization apparatus, fluorine 0.01 to 5 mg / g is present mainly in the form of calcium fluoride (CaF _2).
[0020]
By washing the fluorine-containing gypsum with a weakly acidic washing water in which an aluminum compound is dissolved, a large amount of fluorine is eluted in the washing water at a higher fluorine removal rate as compared with the case of washing using only water (FIG. 2), most of the fluorine in the gypsum is removed. Therefore, by washing at least once, and in some cases multiple times, it is possible to collect gypsum that does not elute fluorine in an amount exceeding the groundwater environmental standard, and dispose of it when it is effectively used as building materials. You don't have to worry about time problems.
[0021]
The aluminum compound is an aluminum compound soluble in water or acidic water. Examples of the aluminum compound include aluminum sulfate (sulfuric acid band), alum, aluminum chloride, polyaluminum chloride, and the like, and these can be used alone or as a mixture of two or more. In particular, the sulfate band (Al ₂ (SO ₄ ) ₃ .18H ₂ O) is inexpensive and easily available, and its aqueous solution shows weak acidity, and the sulfate ion concentration in the washing water increases, thereby suppressing the dissolution of gypsum. can be suitably used for (solubility of gypsum, the solubility product Ksp = ^{[Ca 2 +} concentration] ^- defined by _[sO ^{4 2} concentration]).
[0022]
The amount of the aluminum compound used depends on the fluorine content in the fluorine-containing gypsum and other impurities and their contents, but is at least 1% by weight or more, preferably 5% by weight, based on the weight of the fluorine-containing gypsum to be treated. It is about. If it exceeds 5% by weight, an increase in the fluorine removal rate cannot be expected in spite of an increase in the cost of the aluminum compound, so that about 5% by weight is desirable from an economic viewpoint.
[0023]
The washing water containing aluminum ions is to be kept weakly acidic, preferably in a range of 3.9 to 5.5, more preferably 4 to 5, and still more preferably 4.5 to 5. When the pH is higher than 5.5, aluminum ions in the washing water become aluminum hydroxide (Al (OH) ₃ ) and precipitate on the surface of the gypsum or between particles, and fluorine contained in the gypsum elutes into the washing water. If it is less than 3.9, the recovered gypsum raw material after removal of fluorine will be acidic and there will be a problem of equipment corrosion. It is not preferable because a large amount of alkali is required for the neutralization treatment of the washing wastewater after separation. Many aqueous solutions of aluminum compounds are weakly acidic, but when the pH of the washing water increases during washing, the pH is adjusted and maintained by adding an inorganic acid, preferably sulfuric acid. Usually, it becomes weakly acidic just by dissolving aluminum sulfate in water. This is because hydrolysis of aluminum ions (Al ³⁺ ) occurs. However, if the gypsum contains a large amount of a substance that neutralizes an acid such as calcium carbonate, the gypsum does not become acidic and aluminum hydroxide may precipitate. In the case of such gypsum, it is necessary to adjust the pH to about 4 to 5 by adding an acid (hydrochloric acid or sulfuric acid).
[0024]
The amount of washing water varies depending on the washing apparatus, but is usually an amount that maintains the gypsum slurry concentration at 10 to 30% by weight. By increasing the amount of washing water and lowering the gypsum slurry concentration, great washing efficiency can be expected, but the apparatus becomes large including the washing and draining step which is a subsequent step, and the amount of gypsum dissolved is also unfavorable. . On the other hand, if the amount of washing water is too small, not only is the fluorine concentration in the washing water too high and the elution rate of fluorine is reduced, but also the gypsum slurry concentration becomes too high and an excessive load is applied to the apparatus.
[0025]
The fluorine-containing gypsum cleaning device is not particularly limited, and a known cleaning device such as a stirring cleaning device or a fluid cleaning device can be used. These cleaning devices may be single-stage cleaning devices or multi-stage cleaning devices. When a multi-stage washing apparatus is used, the aluminum compound may be added to each of the stages. These cleaning devices are preferably made of stainless steel, rubber lining, or the like having corrosion resistance under acidic conditions.
[0026]
By separating the gypsum slurry washed by the above method into gypsum and fluorine-containing washing wastewater using a gypsum separator, gypsum from which fluorine has been removed is recovered. The gypsum separator is not particularly limited as long as it can separate gypsum and wash water, and a centrifuge is usually used. In particular, a continuous reciprocating (Escher-Wiss) centrifuge is suitably used.
[0027]
Further, since the washed wastewater after collecting the gypsum contains the eluted fluorine, it is removed in the next wastewater treatment step S2. First, the neutralization step S ₂₁ fluorine containing detergent drain on slaked lime or alkali to be added pH of 6 or more in, preferably 7-8, more preferably neutralization is adjusted to 7 neutral. Then, the coagulating sedimentation step S _22, by adding a polymer flocculant to agglomerate precipitate a fluorine-containing sludge in the fluorine-containing washing waste water which has been neutralized. The aluminum content in the fluorine-containing cleaning wastewater forms aluminum hydroxide (Al (OH) ₃ ) flocs, and the flocs adsorb fluorine. By separating the fluorine-adsorbed flocs from the washing wastewater, the fluorine is removed from the washing wastewater. In the dehydration step S _23, to obtain a dehydrated cake of the fluorine-containing sludge by concentrating the suspended solids were dried filtered. Furthermore, wastewater fluorine has been removed and purified water through the filter in the purification step S _24. As a result, it can be discharged as harmless water from which fluorine contained has been removed or recycled as washing water.
[0028]
As the alkali for neutralization, hydroxides of alkali metals or alkaline earth metals, carbonates thereof, ammonium hydroxide and the like can be used. In particular, hydroxides or carbonates of alkaline earth metals that produce metal fluorides having low solubility in water upon neutralization, such as calcium hydroxide (lime water) or calcium carbonate (slaked lime), are preferably used.
[0029]
The aluminum hydroxide flocs adsorbing the fluorine are coagulated by adding a polymer coagulant to the washing wastewater containing the flocs, coagulating the coagulated sediment, and allowing the coagulated sediment to collect. Through the concentration and dehydration step, the water is separated from the washing waste water as a dehydration cake containing fluorine. Since the fluorine in the dewatered cake is not easily eluted, the dewatered cake can be a waste. Further, it may be used as a raw material for producing fluoroglass.
[0030]
On the other hand, the wastewater from the coagulation sedimentation step and the concentration dehydration step is recycled as washing water or discharged after passing through a step of filtering and removing solids.
[0031]
Thus, in the present invention, the acid (H ⁺ ) and the aluminum ion (Al ³⁺ ) act synergistically by washing the fluorine-containing gypsum with the washing water in which the aluminum compound is dissolved, under acidic conditions. Fluorine fixed therein in the form of calcium fluoride (CaF ₂ ) is extracted and released as fluorine ions (F ⁻ ). Further aluminum ions ^{(Al 3+)} is liberated fluorine ions (F ^-) captured aluminum fluoro complex ions and _(AlF ^{n m} (here, n represents an integer from 1 to 6, m is 2 + ～3-)) And is eluted into the washing water in a stable form. As a result, a fluorine removal rate in gypsum of 10 times or more can be obtained as compared with the case where the fluorine-containing gypsum is washed with only water. Therefore, it can be recovered as gypsum material from which fluorine has been removed, and even if building materials such as gypsum boards are effectively discarded as stable waste, even if fluorine remaining in gypsum is eluted by rainwater etc. The amount does not exceed the groundwater environmental standard.
[0032]
On the other hand, since the fluorine eluted in the washing wastewater contains aluminum in the washing wastewater, simply neutralizing the fluorine generates a floc of aluminum hydroxide, and the fluorine in the washing wastewater is adsorbed on the floc. Fixed. As a result, by separating and removing the aluminum hydroxide floc to which fluorine has been adsorbed and fixed by a known means, for example, a method such as coagulation and sedimentation, it is possible to obtain a drainage water of which the fluorine is removed and which can be discharged. This wastewater can of course be recycled and used as washing water. In addition, since the coagulated sediment does not contain gypsum but contains only fluorine, the amount of dewatered cake is reduced, and the volume of waste can be reduced.
[0033]
【Example】
The present invention will be described in more detail with reference to Examples and Comparative Examples.
Example 1 and Comparative Example 1
To each of 60 g of recovered gypsum samples A to S having different fluorine contents from the flue gas desulfurization apparatus shown in Table 1, 600 ml of distilled water and 0.6 g or 3.0 g of sulfuric acid band (1% by weight and 5% by weight of recovered gypsum) Was added and the recovered gypsum was washed by shaking for 6 hours. For comparison, only 600 ml of distilled water was added to 60 g of each of the collected gypsum samples A to S, and the collected gypsum was washed by shaking for 6 hours. Gypsum was separated by filtration, and the fluorine concentration in the filtrate was measured by steam distillation separation-lanthanum alizarin complexone spectrophotometry. The pH of the washing water during the washing was not adjusted. Table 2 shows the content of fluorine, calcium, sulfate and impurities in the desulfurized gypsum of Samples A to S and the content of fluorine in the coal used.
[0034]
Table 3 shows the washing results. Table 3 shows the fluorine removal rate of the comparative example in which only water was washed, the fluorine removal rate when the sulfuric acid band was contained at 1 wt%, the fluorine removal rate when the sulfuric acid band was contained at 5 wt%, and the washing water when the sulfuric acid band was contained at 5 wt%. Indicates pH. The test results are shown in FIG. 2 as a relationship between the aluminum ion concentration in the washing water and the fluorine removal rate. Here, the horizontal axis of FIG. 2 shows the concentration of aluminum ions contained in the washing water. Since a small amount of aluminum (<4 mg / L) is contained as an impurity in the gypsum, it is dissolved in the washing water. Therefore, aluminum ions are contained without adding aluminum sulfate. The F removal rate on the vertical axis is a ratio of the amount of removed fluorine to the total amount of fluorine in the gypsum. The result is a removal rate by one washing.
[0035]
[Table 1]

[0036]
[Table 2]

[0037]
[Table 3]

[0038]
As shown in Table 3, in Sample D having a pH of 6.4 after the addition of 5% by weight of the sulfuric acid band, aluminum ions in the washing water were precipitated as aluminum hydroxide and could not form a complex with fluorine ions. And the fluorine removal rate was almost the same as in the case of only water washing. Since the other samples A, B, G, H, L, M, Q, R and S all have a pH of 3.9 to 5.5 in a weakly acidic range, aluminum ions and fluorine ions are separated. It generates a fluoro complex (mainly _AlF ^{2 +} and _AlF ^{3 0),} eluted fluorine amount or more fluorine ions defined by CaF ₂ solubility product (Ksp = constant value) in the wash water, greatly fluorine removal rate A large fluorine removal rate improved (10 times or more of the comparative example) was obtained.
[0039]
【The invention's effect】
In the present invention, a complex with aluminum ions is generated by washing fluorine-containing gypsum with washing water containing aluminum ions, for example, washing water containing an aluminum compound under weakly acidic conditions. Then, elution is performed at an amount equal to or more than the amount of fluorine ions defined by the solubility product of CaF ₂ , thereby enabling high-efficiency removal. As a result, even if the waste is discarded as stable waste, safe recovered gypsum with less fear of eluting fluorine harmful to the environment can be provided as a building material or the like.
[0040]
In addition, the gypsum material does not contain a large amount of aluminum compound as an impurity, and only the dewatered cake of the coagulated precipitate generated in the wastewater treatment is generated as waste, so that the amount of waste can be reduced as a whole.
[0041]
In addition, fluorine in the fluorine-containing cleaning wastewater can be removed to the extent that it can be discharged only by neutralizing. That is, the washing wastewater can be recycled as washing water. In addition, since the coagulated sediment does not contain gypsum but contains only fluorine, the amount of dewatered cake is reduced, and the volume of waste can be reduced.
[0042]
As described above, the present invention provides a method for removing fluorine in fluorine-containing gypsum, and its industrial significance is extremely large, particularly in the field of flue gas desulfurization of coal combustion passages and the field of building materials.
[Brief description of the drawings]
FIG. 1 is a flowchart of a method for removing fluorine from gypsum according to the present invention.
FIG. 2 is a graph showing a relationship between an aluminum ion concentration in cleaning water and a fluorine removal rate obtained in an example of the present invention.

Claims (5)

A method for removing fluorine from gypsum, comprising washing gypsum containing fluorine with washing water containing aluminum ions. A method of removing fluorine from gypsum, comprising washing fluorine-containing gypsum with weakly acidic washing water in which an aluminum compound is dissolved. Method for removing fluorine of said aluminum compound in gypsum according to claim 2, wherein the aluminum sulfate _{(Al 2 (SO 4) 3} · 18H 2 O). The method for removing fluorine from gypsum according to claim 2, wherein the pH of the washing water is maintained in a range of 4 to 5. The method for removing fluorine from gypsum according to claim 1 or 2, wherein the washing wastewater after separating and recovering the washed gypsum from the washing water is neutralized, and a coagulant is added to the neutralized washing wastewater. Agglomerating and precipitating the fluorine-containing sludge, concentrating the coagulated sediment and performing dehydration filtration to obtain a dehydrated cake of the fluorine-containing sludge, while filtering the washing wastewater from which fluorine has been removed and discharging the sludge or recycling as washing water. A method for removing fluorine from gypsum.

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