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JP3442287B2 - Acid gas adsorbent - Google Patents

Acid gas adsorbent

Info

Publication number
JP3442287B2
JP3442287B2 JP17396498A JP17396498A JP3442287B2 JP 3442287 B2 JP3442287 B2 JP 3442287B2 JP 17396498 A JP17396498 A JP 17396498A JP 17396498 A JP17396498 A JP 17396498A JP 3442287 B2 JP3442287 B2 JP 3442287B2
Authority
JP
Japan
Prior art keywords
adsorbent
hydrogen chloride
amount
cracked oil
activated carbon
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.)
Expired - Fee Related
Application number
JP17396498A
Other languages
Japanese (ja)
Other versions
JPH11347398A (en
Inventor
義晴 福西
清人 大塚
弘徳 猪川
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.)
Kuraray Chemical Co Ltd
Kubota Corp
Original Assignee
Kuraray Chemical Co Ltd
Kubota Corp
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 Kuraray Chemical Co Ltd, Kubota Corp filed Critical Kuraray Chemical Co Ltd
Priority to JP17396498A priority Critical patent/JP3442287B2/en
Publication of JPH11347398A publication Critical patent/JPH11347398A/en
Application granted granted Critical
Publication of JP3442287B2 publication Critical patent/JP3442287B2/en
Anticipated expiration legal-status Critical
Expired - Fee Related legal-status Critical Current

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  • Separation, Recovery Or Treatment Of Waste Materials Containing Plastics (AREA)
  • Solid-Sorbent Or Filter-Aiding Compositions (AREA)
  • Treating Waste Gases (AREA)
  • Manufacture Of Porous Articles, And Recovery And Treatment Of Waste Products (AREA)

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】TECHNICAL FIELD OF THE INVENTION

【0002】本発明は酸性ガス吸着剤に関するもので更
に詳しく述べると、活性炭にアルカリ金属炭酸塩を担持
させた酸性ガス吸着剤で、主としてプラスチック廃棄物
を分解して再利用可能な石油系分解油として回収する
際、塩化ビニル或いは塩化ビニリデン等より分解・生成
された塩化水素等酸性ガスの吸着除去用に使用される。
The present invention relates to an acidic gas adsorbent, and more specifically, it is an acidic gas adsorbent in which activated carbon carries an alkali metal carbonate, and is a petroleum-based cracked oil that can be reused mainly by decomposing plastic waste. It is used for adsorption removal of acidic gas such as hydrogen chloride decomposed and produced from vinyl chloride or vinylidene chloride.

【0003】[0003]

【従来の技術】近年、廃棄物処理問題の深刻化によりリ
サイクルに対する要求が高まっている。廃プラスチック
材については特開平3-86791 号公報に開示されているよ
うに、熱分解して再利用可能な石油系分解油として回収
する技術が注目されている。
2. Description of the Related Art In recent years, there has been an increasing demand for recycling due to the serious problem of waste disposal. Regarding the waste plastic material, as disclosed in Japanese Patent Laid-Open No. 3-86791, a technique of thermally decomposing and recovering it as reusable petroleum-based cracked oil is drawing attention.

【0004】この方法によると廃プラスチック材は先ず
溶融槽で溶融された後、熱分解槽に導入され熱分解され
てガス状となり次いで、接触分解槽で合成ゼオライト触
媒により軽質化されて低沸点炭化水素ガスとなり、コン
デンサーで冷却され石油系分解油として回収される。
According to this method, the waste plastic material is first melted in the melting tank, then introduced into the thermal decomposition tank and thermally decomposed into a gas state, and then is lightened by the synthetic zeolite catalyst in the catalytic decomposition tank to be carbonized at a low boiling point. It becomes hydrogen gas, is cooled in a condenser and is recovered as petroleum-based cracked oil.

【0005】しかしながら、廃プラスチック材には塩化
ビニル樹脂、塩化ビニリデン樹脂等の塩素含有プラスチ
ックが通常 5〜10数%混入している。このため溶融ある
いは熱分解の過程で塩化水素が発生し、装置の腐食や接
触分解槽の触媒の被毒、更にはこの処理方法で得られた
石油系分解油を燃料としてボイラーで燃焼する際、ボイ
ラー設備の腐食を起こすおそれがあった。廃プラスチッ
ク材の溶融工程で発生する塩化水素はアルカリを含む水
で中和処理して除去されるが、熱分解過程で発生する塩
化水素は除去する必要があり対策が要望されていた。
However, chlorine-containing plastics such as vinyl chloride resin and vinylidene chloride resin are usually mixed in the waste plastic material in an amount of 5 to 10% by weight. Therefore, hydrogen chloride is generated in the process of melting or thermal decomposition, corrosion of the device and poisoning of the catalyst in the catalytic cracking tank, and further when burning petroleum cracked oil obtained by this treatment method as a fuel in a boiler, There was a risk of corrosion of the boiler equipment. Hydrogen chloride generated in the melting step of the waste plastic material is neutralized and removed with water containing an alkali, but hydrogen chloride generated in the thermal decomposition process needs to be removed, and a countermeasure has been demanded.

【0006】この対策として特開平3-86791 号公報には
熱分解槽と接触分解槽の間に塩化水素を除去する酸性ガ
ス吸着槽を設け、内部に充填した酸化カルシウムによっ
て酸性ガスを吸着・除去する方法が開示されている。
As a countermeasure against this, Japanese Patent Laid-Open No. 3-86791 discloses an acidic gas adsorption tank for removing hydrogen chloride between the thermal decomposition tank and the catalytic decomposition tank, and the acidic gas is adsorbed and removed by calcium oxide filled inside. A method of doing so is disclosed.

【0007】しかし、粉末状または細かい粒子状の酸化
カルシウムをそのまま使用した場合、熱分解ガスに含ま
れるミスト状の重油、タール、ワックスなどの高沸点熱
分解油が酸化カルシウムの表面に沈着して酸化カルシウ
ムの粒子間の空隙を閉塞し、酸性ガス吸着槽の通気抵抗
が増大して分解ガスの浄化が困難となる。このため未反
応の酸化カルシウムを残した状態で頻繁に酸化カルシウ
ムを入替える必要があるため、酸性ガス吸着剤の性能が
充分に発揮されなかったり、交換費用等ランニングコス
トが高くなる欠点があった。
However, when powdery or fine particles of calcium oxide are used as they are, high-boiling pyrolysis oil such as heavy oil, tar and wax contained in pyrolysis gas is deposited on the surface of calcium oxide. The voids between the particles of calcium oxide are blocked, and the ventilation resistance of the acid gas adsorption tank increases, making it difficult to purify the decomposed gas. Therefore, it is necessary to frequently replace the calcium oxide with the unreacted calcium oxide remaining, so that the performance of the acid gas adsorbent is not sufficiently exhibited, and there is a drawback that the running cost such as replacement cost becomes high. .

【0008】そこで酸化カルシウムを長期間安定して使
用するため、特開平7-48576 号公報では酸性ガス吸着槽
の少なくとも入口側に無機質粗粒子槽を設ける改良案
や、特開平7-62353 号公報では原料混合槽で溶融状態の
プラスチックに窒素を吹き込み溶融プラスチック中の塩
素を除去する方法が開示されている。
Therefore, in order to stably use calcium oxide for a long period of time, in JP-A-7-48576, there is an improvement plan in which an inorganic coarse particle tank is provided at least on the inlet side of an acid gas adsorption tank, and JP-A-7-62353. Discloses a method of blowing chlorine into a molten plastic in a raw material mixing tank to remove chlorine in the molten plastic.

【0009】また、特開平9-95678 号公報には酸性ガス
吸着槽にアルミナ粒子を使用する方法が開示されてい
る。しかしこの方法では同公報にも記載されているよう
に、発生する塩化アルミニウムを除去する必要が生じ
る。
Further, Japanese Patent Laid-Open No. 9-95678 discloses a method of using alumina particles in an acidic gas adsorption tank. However, in this method, it is necessary to remove the generated aluminum chloride as described in the publication.

【0010】しかしながら、これらの方法およびそれら
の組み合わせのみでは高沸点熱分解油による酸性ガス吸
着剤粒子間の空隙の閉塞や、高温の塩化水素或いは塩基
性物質による担体の劣化を完全に防止することが困難で
ある。その結果、酸化カルシウム吸着剤の頻繁な交換或
いは、塩化水素の除去率が低い条件での運転に甘んじざ
るを得ない。このため現状では塩化水素残留量の多い低
品質の石油系分解油しか得られていない。
However, only by these methods and their combination, it is possible to completely prevent the clogging of the voids between the adsorbent particles of the acidic gas due to the high boiling point pyrolysis oil and the deterioration of the carrier due to the high temperature hydrogen chloride or the basic substance. Is difficult. As a result, frequent replacement of the calcium oxide adsorbent or operation under conditions where the removal rate of hydrogen chloride is low is inevitable. Therefore, at present, only low-quality petroleum-based cracked oil with a large residual amount of hydrogen chloride is obtained.

【0011】本発明者等は先に「触媒」vol.39 No.4 、
311(1997年) において、適当な前処理を施し乾燥された
廃プラスチックをバッチワイズに溶融槽に投入し、溶融
槽でほぼ完全に塩化水素の除去を完了させた後バッチワ
イズに熱分解槽へ送ることにより、熱分解ガス中の塩化
水素濃度を大幅に低減できる装置を開示した。しかし
尚、熱分解ガス中に微量の塩化水素が残留し、また塩化
水素除去装置の機能を長期間持続させることが困難で更
に除去装置の吸着性が低下した場合、吸着剤の吸着槽か
らの取出作業が困難になる等多くの問題点があった。
The present inventors have previously described "catalyst" vol.39 No.4,
In 311 (1997), waste plastic that had been appropriately pre-treated and dried was batchwise charged into the melting tank, and after almost completely removing hydrogen chloride in the melting tank, it was batchwise transferred to the pyrolysis tank. An apparatus capable of significantly reducing the concentration of hydrogen chloride in the pyrolysis gas by sending it has been disclosed. However, if a small amount of hydrogen chloride remains in the pyrolysis gas, and it is difficult to maintain the function of the hydrogen chloride removal device for a long period of time and the adsorptivity of the removal device further decreases, There were many problems such as difficulty in taking out work.

【0012】[0012]

【発明が解決しようとする課題】本発明は廃プラスチッ
ク材から石油系分解油を製造する装置で発生する塩化水
素等酸性ガスを除去する工程の問題点にかんがみ、熱分
解ガス中の微量の塩化水素を吸着させてほぼ完全に除去
すると共に、吸着剤を長期間使用しても劣化せずまた、
性能が低下した場合の交換作業が容易な酸性ガス吸着剤
を開発して提供しようとするものである。
DISCLOSURE OF THE INVENTION In view of the problem of the step of removing an acidic gas such as hydrogen chloride generated in an apparatus for producing petroleum-based cracked oil from waste plastic material, the present invention considers a small amount of chloride in the pyrolysis gas. It adsorbs hydrogen and removes it almost completely, and it does not deteriorate even if the adsorbent is used for a long time.
The present invention aims to develop and provide an acid gas adsorbent that can be easily replaced when performance deteriorates.

【0013】[0013]

【課題を解決するための手段】本発明者等はこれらの課
題を解決するため残留塩化水素が少ない高品質のプラス
チック分解油を得るために必要な、塩化水素等酸性ガス
の吸着・除去剤について研究した。先ず特開平6-296858
号公報で開示されている炭酸カリウム、炭酸ナトリウム
等のアルカリ金属の炭酸塩を、アルミナ、シリカゲル及
びゼオライト等多孔質の担体に担持させた酸性ガス吸着
剤について試験した。これらの吸着剤の脱塩化水素性能
は良好で塩化水素含有量の少ないプラスチック分解油を
得ることが可能であるが、300 ℃以上の高温で使用する
と担体が次第に崩壊して粉末状となり、更に吸着剤粉子
間の空隙に高沸点分解油が沈着するため通気抵抗が増大
し長期間使用することが困難であることが分かった。ま
た、冷却すると蓄積した高沸点分解油が固化するので吸
着剤の交換作業が著しく困難となり、生産工程への適用
性に問題があった。
[Means for Solving the Problems] To solve these problems, the present inventors have found an adsorbent / removal agent for acidic gas such as hydrogen chloride, which is necessary to obtain a high-quality plastic cracked oil with little residual hydrogen chloride. Researched. First, JP-A-6-296858
Alkali metal carbonates such as potassium carbonate and sodium carbonate disclosed in Japanese Patent Laid-Open Publication No. 2003-242242 were tested on an acidic gas adsorbent supported on a porous carrier such as alumina, silica gel and zeolite. The dehydrochlorination performance of these adsorbents is good, and it is possible to obtain plastic cracked oil with a low hydrogen chloride content, but when used at temperatures above 300 ° C, the carrier gradually disintegrates and becomes a powder, and further adsorption It was found that the high boiling point cracked oil is deposited in the voids between the powder particles, increasing the ventilation resistance and making it difficult to use for a long time. Further, when cooled, the accumulated high-boiling point cracked oil is solidified, so that replacement work of the adsorbent becomes extremely difficult, and there is a problem in applicability to the production process.

【0014】そこで、長期間高い塩化水素除去機能が維
持できると共に、使用後の取出作業も容易な酸性ガス吸
着剤を開発するため更に種々の吸着剤について検討し
た。酸化カルシウム造粒品は塩基性物質含有量が高いた
め酸性ガス吸着機能が高いと予想されたが、塩化水素除
去量は吸着可能容量の計算値よりも大幅に低下するとの
試験結果が得られた。吸着剤は単純に塩基性物質の担持
量を多くするだけではなく、酸性ガスを効果的に吸着で
きるような性状でなければならないと考えられる(比較
例6)。
Therefore, various adsorbents were further studied in order to develop an acid gas adsorbent which can maintain a high hydrogen chloride removing function for a long period of time and is easy to take out after use. The calcium oxide granulated product was expected to have a high acid gas adsorption function due to its high content of basic substances, but the test results showed that the amount of hydrogen chloride removed was significantly lower than the calculated adsorbable capacity. . It is considered that the adsorbent must have a property not only to simply increase the amount of the basic substance supported but also to effectively adsorb the acidic gas (Comparative Example 6).

【0015】更に酢酸カルシウム水溶液をシリカアルミ
ナまたは活性炭に吸着させた後、熱分解して得られる酸
化カルシウムを担持したシリカアルミナ及び活性炭につ
いても試験した。その結果担体の粉末化は起こらないが
吸着剤の調製工程が煩雑で担体の酸化カルシウム担持量
を高めることが困難であり、充分に塩化水素除去容量を
高めることができなかった(比較例2、3)。
Further, silica alumina and activated carbon supporting calcium oxide obtained by thermally decomposing an aqueous solution of calcium acetate adsorbed on silica alumina or activated carbon were also tested. As a result, the carrier was not pulverized, but the adsorbent preparation process was complicated and it was difficult to increase the amount of calcium oxide supported on the carrier, and the hydrogen chloride removal capacity could not be sufficiently increased (Comparative Example 2, 3).

【0016】アルカリ金属の炭酸塩を担持した活性炭は
以前から酸性ガスの吸収剤として使用できることが知ら
れている。しかしながら、本発明者等は廃プラスチック
材を分解して石油系分解油を得る工程において発生する
酸性ガス、主として塩化水素を吸着除去する際には、共
存する広範囲の高沸点分解油および低沸点分解油と吸着
剤の細孔径及び粒子径、粒子間の空隙との関係が大きく
影響することが分かった。このため、アルカリ金属炭酸
塩−活性炭系の吸着剤において炭酸塩の担持量がごく限
られた範囲を外れると急激に塩化水素吸着・除去機能が
低下し、また炭酸塩担持活性炭のベンゼン吸着量が或る
一定の範囲内のものでないと、高い吸着機能が発揮され
ないことを見出した。更に、これらと吸着剤の粒度分布
(充填比重) 等との関係についても検討した結果本発明
に到達した。
It has long been known that activated carbon carrying an alkali metal carbonate can be used as an absorbent for acidic gases. However, when the present inventors adsorb and remove the acidic gas generated in the process of decomposing waste plastic materials to obtain petroleum-derived cracked oil, mainly hydrogen chloride, a wide range of coexisting high-boiling cracked oil and low-boiling cracked oil are decomposed. It was found that the relationship between the pore size and particle size of the oil and the adsorbent, and the voids between the particles had a great influence. Therefore, when the amount of supported carbonate in the alkali metal carbonate-activated carbon type adsorbent is out of a very limited range, the function of adsorbing / removing hydrogen chloride rapidly decreases, and the amount of benzene adsorbed on the activated carbon carrying carbonate is reduced. It has been found that the high adsorption function cannot be exhibited unless it is within a certain range. Furthermore, the particle size distribution of these and the adsorbent
The present invention has been reached as a result of examining the relationship with (filling specific gravity) and the like.

【0017】すなわち、活性炭にアルカリ金属炭酸塩10
重量%以上、30重量%以下を担持せしめてなる、ベンゼ
ン吸着量が20%以上、40%以下であり、充填比重が 0.4
0 g/ml以上、0.60 g/ml 以下である、プラスチックから
石油系分解油を製造する工程の酸性ガス吸着剤である。
That is, alkali metal carbonate 10 is added to activated carbon.
The amount of benzene adsorbed is 20% or more and 40% or less, and the filling specific gravity is 0.4.
It is an acid gas adsorbent in the process of producing petroleum-derived cracked oil from plastic, which is 0 g / ml or more and 0.60 g / ml or less.

【0018】ここで、充填比重は 0.45 g/ml以上である
ことがより好ましく、アルカリ金属炭酸塩としては炭酸
カリウムがより好ましい。吸着剤粒子の粒度分布につい
ては粒径 0.500mm以上、4.75mm以下である吸着剤粒子の
重量比率が 95 %以上であることがより好ましく、更
に、排出ガス中の酸性ガスが塩化水素である場合により
適している。
Here, the filling specific gravity is more preferably 0.45 g / ml or more, and potassium carbonate is more preferable as the alkali metal carbonate. Regarding the particle size distribution of the adsorbent particles, it is more preferable that the weight ratio of the adsorbent particles having a particle size of 0.500 mm or more and 4.75 mm or less is 95% or more, and further, if the acidic gas in the exhaust gas is hydrogen chloride. Is more suitable for.

【0019】以下、本発明について詳しく説明する。The present invention will be described in detail below.

【0020】本発明では活性炭にアルカリ金属炭酸塩を
担持させて得られた酸性ガス吸着剤を使用する必要があ
る。ここで担体として使用される活性炭は通常1gあたり
数100 m2或いはそれ以上の大きな表面積を有し、高い吸
着性を示す炭素材料であれば広範囲に使用できる。活性
炭の原料は通常ヤシ殻または木材等の炭化物或いは石炭
が使用されるが何れでもよい。これらの中、硬度が高い
活性炭が得られるヤシ殻がより好ましい。また賦活法も
水蒸気或いは二酸化炭素により高温でまたは塩化亜鉛、
リン酸、濃硫酸処理等いづれの方法により得られたもの
でもよい。
In the present invention, it is necessary to use an acidic gas adsorbent obtained by supporting activated carbon with an alkali metal carbonate. The activated carbon used as a carrier here generally has a large surface area of several 100 m 2 or more per 1 g, and can be widely used as long as it is a carbon material exhibiting high adsorptivity. As the raw material of the activated carbon, a charcoal such as coconut shell or wood or coal is usually used, but any may be used. Among these, coconut shells, which can provide activated carbon with high hardness, are more preferable. The activation method is also steam or carbon dioxide at high temperature or zinc chloride,
It may be obtained by any method such as treatment with phosphoric acid or concentrated sulfuric acid.

【0021】また形状は破砕炭或いは顆粒炭の何れでも
効果は認められるが、圧損失及び入替等取扱い上、造粒
炭例えば、球状、円柱状、針状等として使用することも
可能である。造粒炭は常法に従って炭素材料100 部に30
〜60部の石油ピッチ或いはコールタール等をバインダー
として加え混和成型後賦活して調整される。活性炭は無
極性吸着剤として極めて優れた吸着性を有する特異な物
質で、殆どすべてのガス状或いは液状物質に対して高い
吸着性を示す。
Although the shape of crushed coal or granular coal is effective, it can be used as granulated coal in terms of pressure loss, replacement, etc., for example, spherical, columnar, needle-shaped and the like. Granulated coal is added to 100 parts of carbon material according to the conventional method.
It is adjusted by adding ~ 60 parts of petroleum pitch or coal tar as a binder, activating after mixing and molding. Activated carbon is a peculiar substance that has extremely excellent adsorptivity as a non-polar adsorbent, and exhibits high adsorptivity for almost all gaseous or liquid substances.

【0022】本発明の酸性ガス吸着剤は活性炭にアルカ
リ金属炭酸塩を10重量%以上、30重量%以下担持させた
ものである必要がある。活性炭の細孔内部は元来疎水性
であるから塩化水素等の酸性ガスよりも熱分解ガスに含
まれる重油、タール、ワックスなどの高沸点分解油がよ
り吸着され易いため、炭酸塩の担持量が10重量%以下で
は廃プラスチック材の熱分解ガス中の塩化水素等酸性ガ
スを中和する能力が不十分となり、酸性ガスの吸着性能
が低下するためと考えられる。
The acidic gas adsorbent of the present invention must be activated carbon loaded with an alkali metal carbonate in an amount of 10% by weight or more and 30% by weight or less. Since the inside of the pores of activated carbon is hydrophobic in nature, it is easier to adsorb heavy oil, tar, wax and other high boiling point cracked oil contained in pyrolysis gas than acid gases such as hydrogen chloride, so the amount of carbonate carried If less than 10% by weight, the ability to neutralize acid gases such as hydrogen chloride in the thermal decomposition gas of the waste plastic material becomes insufficient, and the adsorption performance of acid gas is considered to be reduced.

【0023】また担持量を30重量%以上に増加しても担
持量が増加した割に塩化水素等酸性ガス吸着性能の向上
がみられないのみならず、分解ガス中の塩化水素等の除
去性能はより急激に性能が低下する。これは多量の炭酸
塩の担持により活性炭の細孔が被覆されるため、残存す
る細孔も少量の高沸点分解油の吸着により閉塞され易い
ためと推定される。更に担持量が増加すると炭酸塩を担
持させる工程が煩雑となり、余剰の炭酸塩が粉末となっ
て脱落して、酸性ガス吸着槽の閉塞を起こすおそれがあ
る。これらの点からアルカリ金属の炭酸塩の担持量は本
発明の重要な要件であり、より好ましくは15重量%以上
であり、20重量%以下である。
Further, even if the supported amount is increased to 30% by weight or more, not only is the improved supported amount of the acidic gas such as hydrogen chloride for the increased supported amount, but the removal performance of hydrogen chloride and the like in the decomposed gas Performance drops more rapidly. It is presumed that this is because the pores of the activated carbon are covered by supporting a large amount of carbonate, and the remaining pores are easily blocked by the adsorption of a small amount of high boiling point cracked oil. If the amount of supported carbon is further increased, the step of supporting the carbonate becomes complicated, and the excessive carbonate may be powdered and fall off, resulting in clogging of the acid gas adsorption tank. From these points, the supported amount of the alkali metal carbonate is an important requirement of the present invention, more preferably 15% by weight or more and 20% by weight or less.

【0024】ここでアルカリ金属の種類は特に限定せず
何れも使用可能である。例えば、炭酸リチウム、炭酸ナ
トリウム、炭酸カリウム、炭酸ルビジウム、炭酸セシウ
ム等である。これらの中で水への溶解度が高く活性炭へ
の担持加工が容易で安全性の高い炭酸カリウムがより好
ましい。
The type of alkali metal is not particularly limited, and any of them can be used. For example, lithium carbonate, sodium carbonate, potassium carbonate, rubidium carbonate, cesium carbonate and the like. Of these, potassium carbonate is more preferable because it has a high solubility in water, is easy to support on activated carbon, and is highly safe.

【0025】本発明の吸着剤のベンゼン吸着量の下限は
20%であり、上限は40%である必要がある。一定の条件
下で測定されたベンゼン吸着量は、活性炭系吸着剤の細
孔容積の指標として広く使用されている。活性炭の細孔
内部は元来疎水性であるから塩化水素等の酸性ガスより
も熱分解ガスに含まれる重油、タール、ワックス等の高
沸点分解油がより吸着され易い性質をもっている。この
ため高沸点分解油の吸着による細孔閉塞を防止するため
には、適当な細孔容積を有している必要がある。ベンゼ
ン吸着量が20%より小さいと少量の高沸点分解油により
細孔閉塞が起こり易く、また、吸着量が 40 %より大き
くなると充填比重が低くなるため、塩化水素等酸性ガス
の吸着容量が低下する傾向が認められる。これらの観点
からベンゼン吸着量はより好ましくは25%以上、37%以
下である。
The lower limit of the benzene adsorption amount of the adsorbent of the present invention is
20% and the upper limit needs to be 40%. The benzene adsorption amount measured under a certain condition is widely used as an index of the pore volume of the activated carbon adsorbent. Since the inside of the pores of activated carbon is hydrophobic in nature, it has the property that the high boiling point cracked oil such as heavy oil, tar, wax contained in the pyrolysis gas is more easily adsorbed than the acidic gas such as hydrogen chloride. Therefore, in order to prevent pore clogging due to adsorption of the high boiling point cracked oil, it is necessary to have an appropriate pore volume. When the amount of benzene adsorbed is less than 20%, a small amount of high boiling point cracked oil tends to cause pore blockage, and when the amount of adsorbed benzene exceeds 40%, the filling specific gravity decreases, so the adsorption capacity for acidic gases such as hydrogen chloride decreases. A tendency to do is recognized. From these viewpoints, the benzene adsorption amount is more preferably 25% or more and 37% or less.

【0026】本発明の吸着剤の充填比重は下限が0.40 g
/ml 、上限が0.60 g/ml である必要がある。充填比重が
0.40 g/ml 以下になると一定容積の塩化水素吸着槽への
充填量が減少すること等のため吸着機能の低下が認めら
れる。このため吸着剤の充填比重は 0.45 g/ml以上であ
ることがより好ましい。また、充填比重が0.60 g/ml以
上になると高沸点分解油による細孔閉塞を起こし易く充
分な酸性ガスの吸着機能が発揮されない。
The lower limit of the packing specific gravity of the adsorbent of the present invention is 0.40 g.
/ ml, the upper limit must be 0.60 g / ml. Filling specific gravity
When it becomes 0.40 g / ml or less, the adsorbing function declines because the amount of hydrogen chloride adsorbed in a fixed volume decreases. Therefore, the packing density of the adsorbent is more preferably 0.45 g / ml or more. Further, if the filling specific gravity is 0.60 g / ml or more, pores are likely to be clogged by the high boiling point cracked oil, and a sufficient acid gas adsorption function cannot be exhibited.

【0027】また、酸性ガス吸着槽に本発明の吸着剤を
充填して使用する場合、粒径が0.50mm以上、4.75mm以下
である活性炭粒子の重量比率が95%以上であることが好
ましいとの結果が得られた。更に、粒径が 1.00mm 以上
であればより好ましく、3.35mm以下であればより好まし
い。本発明者等の検討によれば粒度が小さいと処理ガス
量を大きくすることが困難になるため経済的な運転がで
きなくなり、粒度が大きいと高沸点分解油の吸着により
酸性ガス吸着剤の表面が覆われ易くアルカリ金属の含有
量に相関した塩化水素等酸性ガスの吸着性能が発揮され
ない。
When the acidic gas adsorption tank is filled with the adsorbent of the present invention and used, it is preferable that the weight ratio of the activated carbon particles having a particle size of 0.50 mm or more and 4.75 mm or less is 95% or more. The result was obtained. Further, it is more preferable that the particle size be 1.00 mm or more, and it is more preferable that the particle size be 3.35 mm or less. According to the study by the present inventors, if the particle size is small, it becomes difficult to increase the amount of treated gas, so that economical operation cannot be performed, and if the particle size is large, the surface of the acid gas adsorbent is adsorbed by the high boiling point cracked oil. Is easily covered, and the adsorption performance of acidic gases such as hydrogen chloride that correlates with the content of alkali metals is not exhibited.

【0028】ここで、活性炭粒子の材質が総て同一であ
り形状が同一または相似形であれば、すなわち、粒径分
布も同一であれば活性炭の充填比重と平均粒径は一定の
関係を有する筈である。しかし、実際には材質も粒径分
布も粒子形状もそれぞれ異なるため充填比重のみで律す
ることはできないと考えられる。
Here, if the materials of the activated carbon particles are all the same and the shapes are the same or similar, that is, if the particle size distribution is also the same, the filling specific gravity of the activated carbon and the average particle size have a constant relationship. It should be. However, in reality, since the material, the particle size distribution, and the particle shape are different from each other, it is considered that it cannot be limited only by the packing specific gravity.

【0029】本発明の酸性ガス吸着剤はプラスチックか
らの石油系分解油を製造する工程で発生する酸性ガスを
吸着・除去するために使用される。ここで原料のプラス
チックは特に限定しないが、主として廃棄物処理の一環
として処理される廃プラスチック材である。ここで、
「プラスチックから石油系分解油を製造する工程」と
は、プラスチックを分解して原油分留或いはその分解成
分または石油化学製品中間体等に含まれる成分からなる
分解油が得られる工程であれば、広く適用され特に限定
しない。現状では熱分解及び触媒による接触分解を含む
工程が多く採用されている。また、分解油はガソリン及
び灯油、軽油の混合物のような常温で液体の油であり、
塩素含有率が低いのでボイラー、加熱炉等の燃料として
使用可能である。
The acid gas adsorbent of the present invention is used for adsorbing / removing the acid gas generated in the process of producing petroleum cracked oil from plastic. Although the raw material plastic is not particularly limited, it is a waste plastic material that is mainly treated as a part of waste treatment. here,
The "process of producing petroleum-based cracked oil from plastic" is a process of cracking the plastic to obtain cracked oil consisting of crude oil fractionation or cracked components thereof or components contained in petrochemical intermediates, etc. It is widely applied and is not particularly limited. At present, many processes including thermal decomposition and catalytic decomposition using a catalyst are adopted. The cracked oil is an oil that is liquid at room temperature, such as a mixture of gasoline, kerosene, and light oil,
Since it has a low chlorine content, it can be used as fuel for boilers, heating furnaces, etc.

【0030】廃プラスチック材には通常 5〜10数%の塩
化ビニル樹脂、塩化ビニリデン樹脂等の塩素含有プラス
チックが混入している。従って、これらの工程で分解さ
れた塩化水素が発生し装置の腐食や接触分解槽の触媒の
被毒、更には得られた石油系分解油を燃料としてボイラ
ーで燃焼する際ボイラー設備の腐食を起こすおそれがあ
る。本発明の酸性ガス吸着剤はこれらの工程で発生する
主として塩化水素等酸性ガスを吸着・除去するために使
用される。これらの分解ガスの組成から本発明の吸着剤
で吸着・除去すべき酸性ガスの中塩化水素が最も重要な
対象となっている。
The waste plastic material is usually mixed with 5-10% by weight of a chlorine-containing plastic such as vinyl chloride resin or vinylidene chloride resin. Therefore, hydrogen chloride decomposed in these processes is generated, causing corrosion of the equipment, poisoning of the catalyst in the catalytic cracking tank, and corrosion of the boiler equipment when the obtained petroleum cracked oil is burned in the boiler as fuel. There is a risk. The acidic gas adsorbent of the present invention is mainly used for adsorbing / removing acidic gas such as hydrogen chloride generated in these steps. From the composition of these decomposed gases, hydrogen chloride in the acidic gas to be adsorbed and removed by the adsorbent of the present invention is the most important object.

【0031】[0031]

【発明の実施の形態】本発明の酸性ガス吸着剤の使用態
様は特に限定しないが、好ましい態様としてはプラスチ
ック材の溶融、熱分解及び触媒による接触分解を含む工
程において、熱分解槽と接触分解槽の間に設置される酸
性ガス吸着槽に充填して使用される。以下、実施例を挙
げて本発明を更に具体的に説明する。
BEST MODE FOR CARRYING OUT THE INVENTION The mode of use of the acidic gas adsorbent of the present invention is not particularly limited, but a preferred mode is that in a process including melting, thermal decomposition and catalytic catalytic decomposition of a plastic material, a thermal decomposition tank and catalytic decomposition are used. It is used by filling an acid gas adsorption tank installed between the tanks. Hereinafter, the present invention will be described more specifically with reference to examples.

【0032】[0032]

【実施例】(実施例1)活性炭 (クラレケミカル (株)
製、商品名「クラレコールGG」) に、炭酸カリウム水溶
液を吸収させた後に乾燥する操作を繰り返して炭酸カリ
ウム担持量15重量% (以下、単に%という) 、灰分18.4
%、粒径の1.40〜3.35mmの活性炭粒子の重量比が98.1%
であり、ベンゼン吸着量27.6%、充填比重0.527 g/mlの
吸着剤を得た。
[Example] (Example 1) Activated carbon (Kuraray Chemical Co., Ltd.)
Manufactured by Kuraray Coal GG), which absorbs an aqueous solution of potassium carbonate and then repeats drying to carry 15% by weight of potassium carbonate (hereinafter, simply referred to as%) and ash content of 18.4.
%, The weight ratio of activated carbon particles with a particle size of 1.40 to 3.35 mm is 98.1%
Thus, an adsorbent having a benzene adsorption amount of 27.6% and a packing specific gravity of 0.527 g / ml was obtained.

【0033】プラスチック材の溶融工程、熱分解工程、
酸化ガス吸着工程及び触媒による接触分解工程を含む石
油系分解油製造装置のパイロットプラントを使用し、そ
の酸性ガス吸着槽に前記で得られた酸性ガス吸着剤 30k
g を充填して、塩化ビニル樹脂を約10%含む廃プラスチ
ック材を処理して石油系分解油の製造試験を実施した。
この試験で酸性ガス吸着槽の出口から初めて塩化水素が
検知される迄に廃プラスチック材 831.5kgを処理でき
た。それ迄に熱分解工程から発生した塩化水素量は2.41
kgと推定されるため、酸性ガス吸着槽で吸着・除去され
た塩化水素量はほぼ吸着可能量の計算値に相当する。ま
た、吸着槽から塩化水素がリークする状態で運転を継続
したが、吸着剤の固化及び取出作業の支障は認められな
かった。更に、塩化水素の通気試験の結果を図1に示
す。破過時間は57分であった。
A melting step of a plastic material, a pyrolysis step,
Using a pilot plant of petroleum cracked oil production equipment including an oxidizing gas adsorption process and a catalytic cracking process using a catalyst, the acidic gas adsorbent 30 k
A waste plastic material containing about 10% of vinyl chloride resin was treated by filling g, and a production test of petroleum cracked oil was conducted.
In this test, 831.5 kg of waste plastic material could be treated before the first hydrogen chloride was detected from the outlet of the acid gas adsorption tank. Until then, the amount of hydrogen chloride generated from the thermal decomposition process was 2.41.
Since it is estimated to be kg, the amount of hydrogen chloride adsorbed and removed in the acid gas adsorption tank corresponds to the calculated adsorbable amount. Further, although the operation was continued in a state where hydrogen chloride leaked from the adsorption tank, no trouble was found in the solidification and removal work of the adsorbent. Further, the results of the hydrogen chloride aeration test are shown in FIG. The breakthrough time was 57 minutes.

【0034】尚、前記の実施例及び以下の実施例、比較
例において、活性炭の炭酸カリウム含有量は吸着剤の調
製方法より計算した値で示した。分析方法としては室温
の蒸留水で60分間抽出した溶液のイオンクロマト分析か
ら求めることができ、前記の計算値がこの分析値と分析
誤差の範囲内で一致することを確認している。
In the above-mentioned examples and the following examples and comparative examples, the potassium carbonate content of the activated carbon is shown by the value calculated by the method of preparing the adsorbent. As an analysis method, it can be determined by ion chromatographic analysis of a solution extracted with distilled water at room temperature for 60 minutes, and it has been confirmed that the above calculated value agrees with this analytical value within the range of analytical error.

【0035】また、吸着剤の灰分、粒度、ベンゼン吸着
量、充填比重はJIS-K1474 「粒状活性炭試験方法」によ
って求めた値である。すなわち、灰分は活性炭を坩堝中
で高温空気中で燃焼させて残った灰の重量から求め、粒
度は篩い分け後に各篩い上に残った吸着剤粒子の重量か
ら求め、ベンゼン吸着量は吸着剤に所定条件でベンゼン
を吸着させた前後での重量増加から求め、充填比重は振
動させながら100 mlメスシリンダーに充填したときの重
量から求めた。
The ash content, particle size, benzene adsorption amount, and packing specific gravity of the adsorbent are values determined by JIS-K1474 "Granular activated carbon test method". That is, the ash content is obtained from the weight of the ash remaining after burning the activated carbon in the crucible in high temperature air, the particle size is obtained from the weight of the adsorbent particles remaining on each sieve after sieving, and the benzene adsorption amount is determined by the adsorbent. It was calculated from the weight increase before and after adsorbing benzene under a predetermined condition, and the packing specific gravity was calculated from the weight when packed in a 100 ml graduated cylinder while vibrating.

【0036】また、塩化水素吸着量はガラスデシケータ
中に吸着剤を静置し、塩酸を注入して25℃で24時間後に
検知管で濃度を測定して求めた。塩酸中和量は、吸着剤
10.0g を蒸留水50mlで30分振り混ぜた後、濾過して濾液
10mlを0.1 規定塩酸で中和滴定した時の塩酸量(ml)を求
めた。塩化水素通気試験は20mmΦ×50mmカラムに吸着剤
を充填して、20℃、相対湿度50%、カラム入口濃度5000
ppm 、ガス流量 500ml/ 分/cm2で通気したときのカラム
出口濃度を検知管で測定した。塩化水素通気試験の破過
時間は出口濃度が入口濃度の10%を越えた時間とした。
The amount of adsorbed hydrogen chloride was determined by placing the adsorbent in a glass desiccator, injecting hydrochloric acid, and measuring the concentration with a detector tube 24 hours at 25 ° C. Hydrochloric acid neutralization amount is the adsorbent
After mixing 10.0 g with 50 ml of distilled water for 30 minutes, filter and filter
The amount of hydrochloric acid (ml) was determined when 10 ml was neutralized and titrated with 0.1 N hydrochloric acid. The hydrogen chloride aeration test was performed by filling an adsorbent in a 20 mmΦ x 50 mm column, 20 ° C, relative humidity 50%, column inlet concentration 5000
The concentration at the column outlet when aerated with ppm at a gas flow rate of 500 ml / min / cm 2 was measured with a detector tube. The breakthrough time of the hydrogen chloride aeration test was the time when the outlet concentration exceeded 10% of the inlet concentration.

【0037】(実施例2)実施例1と同様な操作で、炭
酸カリウム担持量20%、灰分21.8%、粒径の1.40〜3.35
mmの活性炭粒子の重量比が99.4%であり、ベンゼン吸着
量28.2%、充填比重0.535 g/mlの酸性ガス吸着剤を得
た。
Example 2 By the same operation as in Example 1, the amount of potassium carbonate carried was 20%, the ash content was 21.8%, and the particle size was 1.40 to 3.35.
An acid gas adsorbent having a weight ratio of activated carbon particles of 99.4%, a benzene adsorption amount of 28.2% and a packing specific gravity of 0.535 g / ml was obtained.

【0038】酸性ガス吸着槽には前記で得られた吸着剤
を充填した他、実施例1と同様に塩化ビニル樹脂を約10
%含む廃プラスチック材を処理して石油系分解油を得
た。酸性ガス吸着槽の出口ガス中から塩化水素が検知さ
れる迄に廃プラスチック材870.0kg を処理することがで
きた。炭酸カリウムの含有量を増加しても処理可能な廃
プラスチック材の量は実施例1と比較して、炭酸塩担持
量の増加分に相当するだけの吸着性能の向上は認められ
なかった。このときに熱分解槽から発生した塩化水素量
は2.53kgと推定され、吸着可能容量の計算値の約80%で
あった。
The acid gas adsorption tank was filled with the adsorbent obtained above, and about 10 parts of vinyl chloride resin was used in the same manner as in Example 1.
% Of the waste plastic material was processed to obtain petroleum cracked oil. It was possible to treat 870.0 kg of waste plastic material before hydrogen chloride was detected in the outlet gas of the acid gas adsorption tank. Even if the content of potassium carbonate was increased, the amount of the waste plastic material that could be treated was not improved as much as that of Example 1 in the adsorption performance corresponding to the increased amount of the carried carbonate. At this time, the amount of hydrogen chloride generated from the thermal decomposition tank was estimated to be 2.53 kg, which was about 80% of the calculated adsorbable capacity.

【0039】(実施例3)実施例1で用いた活性炭 (ク
ラレケミカル (株) 製、商品名「クラレコールGG」) を
再賦活して得た活性炭に炭酸カリウム水溶液を吸収乾燥
させ、炭酸カリウム担持量13%、灰分14.6%、粒径の1.
70〜3.35mmの活性炭粒子の重量比が97.6%であり、ベン
ゼン吸着量35.7%、充填比重0.483 g/mlの吸着剤を得
た。この吸着剤の塩化水素の吸着量及び塩酸中和量はそ
れぞれ0.113 g/g 及び41.19 ml/ 10gであった。
(Example 3) Activated carbon used in Example 1 (Kuraray Chemical Co., Ltd., trade name "Kuraray Coal GG") was reactivated to obtain activated carbon, and an aqueous potassium carbonate solution was absorbed and dried to obtain potassium carbonate. Loading amount 13%, ash content 14.6%, particle size 1.
An adsorbent having a weight ratio of activated carbon particles of 70 to 3.35 mm of 97.6%, a benzene adsorption amount of 35.7% and a packing specific gravity of 0.483 g / ml was obtained. The adsorbed amount of hydrogen chloride and the neutralized amount of hydrochloric acid of this adsorbent were 0.113 g / g and 41.19 ml / 10 g, respectively.

【0040】実施例1に記載した石油系分解油製造装置
のパイロットプラントを使用して、酸性ガス吸着槽には
前記で得られた吸着剤 2 kg を充填し、塩化ビニル樹脂
0.5kgと灯油 1.9 kg と軽油 7.6 kg を加熱分解槽で加
熱したときに発生するガス中の塩化水素の除去試験をし
た。酸性ガス吸着槽での塩化水素吸着量は137.3 g/2kg
でありほぼ吸着可能容量の計算値に相当した。試験後の
吸着剤の塩化水素の吸着量及び塩酸中和量はそれぞれ
0.001 g/g (残存性能1%) および0.36 ml/10g(残存性
能0.9 %) であった。
Using the pilot plant of the petroleum-based cracked oil manufacturing apparatus described in Example 1, an acid gas adsorption tank was filled with 2 kg of the adsorbent obtained above, and a vinyl chloride resin was used.
A test was conducted to remove hydrogen chloride in the gas generated when 0.5 kg, kerosene 1.9 kg, and light oil 7.6 kg were heated in a thermal decomposition tank. The amount of hydrogen chloride adsorbed in the acid gas adsorption tank is 137.3 g / 2kg
And almost corresponded to the calculated value of the adsorbable capacity. After the test, the adsorbed amount of hydrogen chloride and the neutralized amount of hydrochloric acid of the adsorbent are respectively
The values were 0.001 g / g (residual performance 1%) and 0.36 ml / 10g (residual performance 0.9%).

【0041】(実施例4)実施例3と同様にして炭酸カ
リウム担持量15%、灰分16.1%、粒径 1.70 〜3.35mmの
活性炭粒子の重量比が97.5%であり、ベンゼン吸着性能
35.3%、充填比重 0.502 g/ml の活性炭を得た。この吸
着剤の塩化水素の吸着量及び塩酸中和量はそれぞれ0.12
5 g/g 及び43.27 ml/10g であった。
Example 4 As in Example 3, the amount of potassium carbonate supported was 15%, the ash content was 16.1%, and the weight ratio of the activated carbon particles having a particle size of 1.70 to 3.35 mm was 97.5%.
Activated carbon with 35.3% and a packing specific gravity of 0.502 g / ml was obtained. The adsorbed amount of hydrogen chloride and the neutralized amount of hydrochloric acid of this adsorbent were 0.12 each.
It was 5 g / g and 43.27 ml / 10 g.

【0042】実施例3と同様に石油系分解油製造装置の
パイロットプラントを使用して、酸性ガス吸着槽には前
記で得られた吸着剤を充填し、実施例3と同様にして発
生するガス中の塩化水素の除去試験をした。酸性ガス吸
着槽の塩化水素吸着量は137.3 g/2 kgであり、ほぼ吸着
可能容量の計算値に相当した。試験後の吸着剤の塩化水
素吸着量及び塩酸中和量はそれぞれ 0.001 g/g (残存性
能1%) 及び 0.25 ml/10g(残存性能0.6 %) であっ
た。
As in Example 3, a pilot plant of a petroleum-based cracked oil production apparatus was used, an acid gas adsorption tank was filled with the adsorbent obtained above, and gas generated in the same manner as in Example 3 was used. A hydrogen chloride removal test was conducted. The amount of hydrogen chloride adsorbed in the acid gas adsorption tank was 137.3 g / 2 kg, which was almost equivalent to the calculated adsorbable capacity. After the test, the amount of adsorbed hydrogen chloride and the amount of neutralized hydrochloric acid of the adsorbent were 0.001 g / g (residual performance 1%) and 0.25 ml / 10 g (residual performance 0.6%), respectively.

【0043】(実施例5)炭酸カリウムの代わりに炭酸
ナトリウムを使用した以外は実施例3と同様にして、炭
酸ナトリウム担持量12%、灰分12.3%、粒径 1.70 〜3.
35mmの吸着剤粒子の重量比率が98.1%であり、ベンゼン
吸着性能 27.0 %、充填比重 0.527 g/mlの活性炭を得
た。この吸着剤の塩化水素の吸着量及び塩酸中和量はそ
れぞれ0.128 g/g 及び52.70 ml/10g であった。
Example 5 The same procedure as in Example 3 except that sodium carbonate was used instead of potassium carbonate, the amount of sodium carbonate supported was 12%, the ash content was 12.3%, and the particle size was 1.70 to 3.
An activated carbon having a weight ratio of 35 mm adsorbent particles of 98.1%, a benzene adsorption performance of 27.0% and a packing specific gravity of 0.527 g / ml was obtained. The adsorbed amount of hydrogen chloride and the neutralized amount of hydrochloric acid of this adsorbent were 0.128 g / g and 52.70 ml / 10 g, respectively.

【0044】実施例3と同様に石油系分解油製造装置の
パイロットプラントを使用して、酸性ガス吸着槽には前
記で得られた吸着剤を充填し、実施例3と同様にして発
生するガス中の塩化水素の除去試験をした。酸性ガス吸
着槽の塩化水素吸着量は137.2 g/2 kgであり、ほぼ吸着
可能容量の計算値に相当した。試験後の吸着剤の塩化水
素吸着量及び塩酸中和量はそれぞれ 0.001 g/g (残存性
能1%) 及び 0.25 ml/10g(残存性能0.6 %) であっ
た。
A gas produced in the same manner as in Example 3 was filled with the adsorbent obtained in the above in an acid gas adsorption tank using a pilot plant for petroleum cracked oil production equipment as in Example 3. A hydrogen chloride removal test was conducted. The amount of hydrogen chloride adsorbed in the acid gas adsorption tank was 137.2 g / 2 kg, which was almost equivalent to the calculated adsorbable capacity. After the test, the amount of adsorbed hydrogen chloride and the amount of neutralized hydrochloric acid of the adsorbent were 0.001 g / g (residual performance 1%) and 0.25 ml / 10 g (residual performance 0.6%), respectively.

【0045】(比較例1)アルミナ (住友化学 (株)
製、NKH 1-24) に炭酸カリウム水溶液を吸着させた後、
乾燥して炭酸カリウム担持量26%、充填比重0.790 g/ml
のアルミナを得た。このようにして得られた吸着剤を酸
性ガス吸着用に使用した。
Comparative Example 1 Alumina (Sumitomo Chemical Co., Ltd.)
Manufactured by NKH 1-24) after adsorbing an aqueous solution of potassium carbonate,
Drying and loading of potassium carbonate 26%, filling specific gravity 0.790 g / ml
Of alumina was obtained. The adsorbent thus obtained was used for acid gas adsorption.

【0046】前記で得られた吸着剤50.4kgを実施例1と
同様にして酸性ガス吸着槽に充填し、石油系分解油製造
装置のパイロットプラントを使用して、廃プラスチック
材の処理試験をした。酸性ガス吸着槽の出口ガス中から
塩化水素が検知される迄の廃プラスチック材の処理量は
1,308 kg で良好であったが、吸着剤が劣化して固化し
入替作業が困難となり、実際の製造装置には使用できな
い。塩化水素の通気試験の結果を図1に示す。破過時間
は15分であった。
50.4 kg of the adsorbent obtained above was filled in an acidic gas adsorption tank in the same manner as in Example 1, and a waste plastic material treatment test was conducted using a pilot plant of a petroleum-based cracked oil production apparatus. . The processing amount of waste plastic material until hydrogen chloride is detected in the outlet gas of the acid gas adsorption tank is
It was good at 1,308 kg, but the adsorbent deteriorated and solidified, making replacement work difficult, and it cannot be used in actual manufacturing equipment. The results of the hydrogen chloride aeration test are shown in FIG. The breakthrough time was 15 minutes.

【0047】(比較例2)シリカアルミナ (水澤化学
製、ネオビードSA) に酢酸カルシウム水溶液を吸着させ
た後、乾燥・熱分解して酸化カルシウム担持量6%、充
填比重0.806 g/mlのシリカアルミナを得た。このように
して得られたシリカアルミナを酸性ガス吸着剤として使
用した。
(Comparative Example 2) Silica alumina (Neobead SA, manufactured by Mizusawa Chemical Co.) was adsorbed with an aqueous calcium acetate solution, dried and pyrolyzed to carry 6% of calcium oxide, and a specific gravity of 0.806 g / ml of silica alumina. Got The silica alumina thus obtained was used as an acid gas adsorbent.

【0048】前記で得られた吸着剤51.4kgを実施例1と
同様にして酸性ガス吸着槽に充填し、石油系分解油製造
装置のパイロットプラントを使用して、廃プラスチック
材の処理試験をした。廃プラスチック材167.5kg は酸性
ガス吸着槽出口から塩化水素がリークすることなしに処
理できたが、更に廃プラスチック材を追加すると酸性ガ
ス吸着槽出口から塩化水素ガスが検出され、酸性ガス吸
着容量が不十分であった。塩化水素の通気試験の結果を
図1に示す。破過時間は2分であった。
51.4 kg of the adsorbent obtained above was filled in an acidic gas adsorption tank in the same manner as in Example 1, and a treatment test of the waste plastic material was conducted using a pilot plant of a petroleum-based cracked oil production apparatus. . 167.5 kg of waste plastic material could be treated without leaking hydrogen chloride from the acid gas adsorption tank outlet.However, when waste plastic material was added, hydrogen chloride gas was detected from the acid gas adsorption tank outlet and the acid gas adsorption capacity was increased. It was insufficient. The results of the hydrogen chloride aeration test are shown in FIG. The breakthrough time was 2 minutes.

【0049】(比較例3)活性炭 (クラレケミカル
(株) 製、商品名「クラレコールGG」) に酢酸カルシウ
ム水溶液を吸着させた後、乾燥熱・分解して酸化カルシ
ウム担持量9%、灰分11.4%、粒径 1.70 〜4.75mmの活
性炭粒子の重量比が98.2%であり、ベンゼン吸着量27.4
%、充填比重0.495 g/mlの吸着剤を得た。
Comparative Example 3 Activated carbon (Kuraray Chemical)
After adsorbing an aqueous solution of calcium acetate on the product name "Kuraray Coal GG" manufactured by K.K., it is dried and decomposed by heating to have a calcium oxide loading of 9%, ash content of 11.4%, and a particle size of 1.70-4.75 mm. The weight ratio is 98.2%, and the benzene adsorption amount is 27.4.
%, And an adsorbent having a packing specific gravity of 0.495 g / ml was obtained.

【0050】前記で得られた吸着剤66kgを実施例1と同
様にして酸性ガス吸着槽に充填し、石油系分解油製造装
置のパイロットプラントを使用して、廃プラスチック材
の処理試験をした。廃プラスチック材 422kgは酸性ガス
吸着槽出口から塩化水素がリークすることなしに処理で
きたが、更に廃プラスチック材を追加すると酸性ガス吸
着槽出口から塩化水素ガスが検出され、酸性ガス吸着容
量が不十分であった。塩化水素の通気試験の結果を図1
に示す。破過時間は11分であった。
66 kg of the adsorbent obtained above was filled in an acidic gas adsorption tank in the same manner as in Example 1, and a treatment test of the waste plastic material was conducted using a pilot plant of a petroleum-based cracked oil production apparatus. 422 kg of waste plastic material could be processed without leaking hydrogen chloride from the acid gas adsorption tank outlet, but when additional waste plastic material was added, hydrogen chloride gas was detected from the acid gas adsorption tank outlet, and the acid gas adsorption capacity was insufficient. Was enough. Figure 1 shows the results of the hydrogen chloride aeration test.
Shown in. The breakthrough time was 11 minutes.

【0051】(比較例4)活性炭 (クラレケミカル
(株) 製、商品名「クラレコールGG」) に炭酸カリウム
水溶液を吸着させた後、乾燥して炭酸カリウム含有量8
%、灰分9.4 %、粒径の1.70〜4.75mmの活性炭粒子の重
量比が96.9%であり、ベンゼン吸着量26.6%、充填比重
0.578 g/mlの吸着剤を得た。
Comparative Example 4 Activated carbon (Kuraray Chemical
(Kuraray Coal GG, manufactured by Co., Ltd.) is adsorbed with an aqueous potassium carbonate solution and then dried to have a potassium carbonate content of 8
%, Ash content 9.4%, weight ratio of activated carbon particles with a particle size of 1.70 to 4.75 mm is 96.9%, benzene adsorption amount 26.6%, packing specific gravity
0.578 g / ml of adsorbent was obtained.

【0052】前記で得られた吸着剤を実施例1と同様に
して酸性ガス吸着槽に充填し、石油系分解油製造装置の
パイロットプラントを使用して、廃プラスチック材の処
理試験をした。しかし、分解油が生成するとほぼ同時に
酸性ガス吸着槽出口から塩化水素ガスが検出されたので
試験を停止した。塩化水素の通気試験の結果を図1に示
す。破過時間は37分であった。
The adsorbent obtained above was filled in an acidic gas adsorption tank in the same manner as in Example 1, and a waste plastic material treatment test was conducted using a pilot plant of a petroleum-based cracked oil production apparatus. However, the hydrogen chloride gas was detected from the outlet of the acid gas adsorption tank almost at the same time when the cracked oil was produced, so the test was stopped. The results of the hydrogen chloride aeration test are shown in FIG. The breakthrough time was 37 minutes.

【0053】(比較例5)活性炭 (クラレケミカル
(株) 製、商品名「クラレコールGG」) に、炭酸カリウ
ム水溶液を吸着させた後に乾燥する操作を繰り返して炭
酸カリウム担持量40%、灰分42.8%、粒径1.40〜3.35mm
の活性炭粒子の重量比が97.2%であり、ベンゼン吸着量
10.2%、充填比重0.618 g/mlの吸着剤を得た。
(Comparative Example 5) Activated carbon (Kuraray Chemical)
(Kuraray Coal GG, manufactured by Co., Ltd.) is adsorbed with an aqueous solution of potassium carbonate and then dried to repeat 40% potassium carbonate loading, 42.8% ash content, and 1.40 to 3.35 mm particle size.
The weight ratio of activated carbon particles is 97.2%, and the amount of benzene adsorbed
An adsorbent with 10.2% and a packing specific gravity of 0.618 g / ml was obtained.

【0054】前記で得られた吸着剤を実施例1と同様に
して酸性ガス吸着槽に充填し、石油系分解油製造装置の
パイロットプラントを使用して、廃プラスチック材の処
理試験をした。しかし、分解油が生成するとほぼ同時に
酸性ガス吸着槽出口から塩化水素ガスが検出されたので
試験を停止した。
The adsorbent obtained above was filled in an acid gas adsorption tank in the same manner as in Example 1, and a treatment test of a waste plastic material was conducted using a pilot plant of a petroleum-based cracked oil production apparatus. However, the hydrogen chloride gas was detected from the outlet of the acid gas adsorption tank almost at the same time when the cracked oil was produced, so the test was stopped.

【0055】(比較例6)活性炭 (クラレケミカル
(株) 製、商品名「クラレコールGG」) に、炭酸カリウ
ム水溶液を吸着させた後に乾燥する操作を繰り返して炭
酸カリウム担持量34%、灰分36.4%、粒径1.40〜3.35mm
の活性炭粒子の重量比が97.0%であり、ベンゼン吸着量
20%、充填比重0.570 g/mlの吸着剤を得た。
Comparative Example 6 Activated carbon (Kuraray Chemical)
(Kuraray Coal GG, manufactured by Co., Ltd.) is repeatedly dried by adsorbing an aqueous solution of potassium carbonate and then carrying 34% potassium carbonate, 36.4% ash, and 1.40 to 3.35 mm in particle size.
The weight ratio of activated carbon particles is 97.0%, and the amount of benzene adsorbed
An adsorbent with 20% and a packing density of 0.570 g / ml was obtained.

【0056】前記で得られた吸着剤を実施例1と同様に
して酸性ガス吸着槽に充填し、石油系分解油製造装置の
パイロットプラントを使用して、廃プラスチック材の処
理試験をした。酸性ガス吸着槽の出口から初めて塩化水
素が検知される迄に廃プラスチック材 215.5kgを処理で
きた。
The adsorbent obtained above was filled in an acid gas adsorption tank in the same manner as in Example 1, and a treatment test of a waste plastic material was conducted using a pilot plant of a petroleum-based cracked oil production apparatus. 215.5 kg of waste plastic material could be treated before hydrogen chloride was detected from the outlet of the acid gas adsorption tank for the first time.

【0057】(比較例7)活性炭 (クラレケミカル
(株) 製、商品名「クラレコールGG」) に、炭酸カリウ
ム水溶液を吸着させて乾燥し炭酸カリウム担持量 5%、
灰分 5.4%、粒径1.40〜3.35mmの活性炭粒子の重量比が
95.5%であり、ベンゼン吸着量 42.0 %、充填比重0.45
0 g/mlの吸着剤を得た。
Comparative Example 7 Activated carbon (Kuraray Chemical
(Kuraray Coal GG, manufactured by Co., Ltd.) is adsorbed with an aqueous solution of potassium carbonate and dried to carry 5% of potassium carbonate,
The ash content is 5.4%, and the weight ratio of activated carbon particles with a particle size of 1.40 to 3.35 mm is
95.5%, benzene adsorption amount 42.0%, packing specific gravity 0.45
0 g / ml of adsorbent was obtained.

【0058】前記で得られた吸着剤を実施例1と同様に
して酸性ガス吸着槽に充填し、石油系分解油製造装置の
パイロットプラントを使用して、廃プラスチック材の処
理試験をした。酸性ガス吸着槽の出口から初めて塩化水
素が検知される迄に廃プラスチック材 272.1kgを処理で
きた。
The adsorbent obtained above was filled in an acid gas adsorption tank in the same manner as in Example 1, and a treatment test of a waste plastic material was carried out using a pilot plant of a petroleum-based cracked oil production apparatus. 272.1 kg of waste plastic material could be treated before hydrogen chloride was detected from the outlet of the acid gas adsorption tank for the first time.

【0059】(比較例8)粒径1.40〜3.35mmの粒子の重
量比が95.4%である水酸化カルシウム造粒品について、
塩化水素の通気試験の結果を図1に示す。破過時間は2
分であった。
(Comparative Example 8) Regarding a calcium hydroxide granulated product in which the weight ratio of particles having a particle size of 1.40 to 3.35 mm is 95.4%,
The results of the hydrogen chloride aeration test are shown in FIG. Breakthrough time is 2
It was a minute.

【0060】前記の実施例1、比較例1〜4、8の塩化
水素の通気試験の結果を図1に示す。この図より実施例
1の活性炭にアルカリ金属炭酸塩を担持させた吸着剤の
機能は、比較例1〜4、8のアルミナ系及びネオビード
系、酸化カルシウム系の吸着剤の機能より遙かに優れて
いることが認められる。
The results of the hydrogen chloride aeration test of Example 1 and Comparative Examples 1 to 4 and 8 are shown in FIG. From this figure, the function of the adsorbent in which the activated carbon of Example 1 is supported by the alkali metal carbonate is far superior to the functions of the alumina-based, neo-bead-based and calcium oxide-based adsorbents of Comparative Examples 1 to 4 and 8. Is recognized.

【0061】図2に実施例1〜4及び比較例4〜7で使
用した吸着剤の炭酸カリウム担持量と塩化水素吸着量の
関係を示す。また、図3に実施例1〜4及び比較例4〜
7で使用した吸着剤のベンゼン吸着量と塩化水素吸着量
の関係を示す。これらの図において実施例のデータは●
で、比較例のデータは○で示した。
FIG. 2 shows the relationship between the amount of potassium carbonate carried and the amount of hydrogen chloride adsorbed by the adsorbents used in Examples 1 to 4 and Comparative Examples 4 to 7. Moreover, in FIG. 3, Examples 1-4 and Comparative Examples 4-
The relationship between the benzene adsorption amount and the hydrogen chloride adsorption amount of the adsorbent used in Example 7 is shown. The data of the examples in these figures are:
The data of the comparative example are indicated by ◯.

【0062】図2においてはそれぞれのデータのベンゼ
ン吸着量がばらついており、また、図3ではそれぞれの
データの炭酸塩担持量がばらついているため、図2及び
図3それぞれのデータはかなりばらつきがあるが、両図
を併せて更に実施例1、2及び比較例4〜7で廃プラス
チック材を処理した場合の塩化水素がリークする迄の処
理可能量も考慮すれば、処理工程に存在する広範囲の高
沸点分解油および低沸点分解油の影響は意外に大きく、
本発明の吸着剤におけるアルカリ金属炭酸塩の担持量及
びベンゼン吸着量の数値限定の顕著な臨界性を有するこ
とが認められる。
In FIG. 2, the benzene adsorption amount of each data varies, and in FIG. 3, the carbonate loading amount of each data varies, so that the data of FIGS. 2 and 3 vary considerably. However, considering both the figures and the treatable amount until hydrogen chloride leaks when the waste plastic materials are treated in Examples 1 and 2 and Comparative Examples 4 to 7, a wide range existing in the treatment process is taken into consideration. The effects of high boiling point cracked oil and low boiling point cracked oil of
It is recognized that the adsorbent of the present invention has a significant criticality in the numerical limitation of the amount of alkali metal carbonate supported and the amount of benzene adsorbed.

【0063】[0063]

【発明の効果】活性炭に特定範囲のアルカリ金属炭酸塩
を担持させた、特定範囲のベンゼン吸着量及び充填比重
を有する吸着剤を、プラスチックから石油系分解油を製
造する工程の酸性ガス吸着剤として使用した場合、高温
で塩化水素および塩基性物質にも安定で且つプラスチッ
クの熱分解ガス中に含まれる重油、タール、ワックス分
等の高沸点分解油による吸着性能の低下や固化すること
がなく、熱分解ガス中の塩化水素等酸性ガスの吸着・除
去に有効である。
EFFECT OF THE INVENTION An adsorbent having a specific range of benzene adsorption amount and a packing specific gravity in which activated carbon is supported on a specific range of an alkali metal carbonate is used as an acidic gas adsorbent in the process of producing petroleum cracked oil from plastic. When used, it is stable to hydrogen chloride and basic substances at high temperatures and does not solidify or solidify the adsorption performance due to heavy boiling cracked oil such as heavy oil, tar and wax contained in the thermal cracked gas of plastic, It is effective for adsorbing and removing acid gases such as hydrogen chloride in pyrolysis gas.

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

【図1】実施例1及び比較例1〜3、8で得られた吸着
剤を使用した塩化水素の通気試験における、通気時間と
通過ガス中の塩化水素濃度の関係を示す。
FIG. 1 shows the relationship between aeration time and hydrogen chloride concentration in a passing gas in a hydrogen chloride aeration test using the adsorbents obtained in Example 1 and Comparative Examples 1 to 3.

【符号の説明】[Explanation of symbols]

1 実施例 1 2 比較例 1 3 〃 2 4 〃 3 5 〃 8 1 Example 1 2 Comparative example 1 3〃 2 4 〃 3 5 to 8

【図2】実施例1〜4、比較例4〜7で得られた吸着剤
の炭酸カリウム担持量と塩化水素吸着量の関係を示す。
FIG. 2 shows the relationship between the amount of potassium carbonate supported and the amount of hydrogen chloride adsorbed by the adsorbents obtained in Examples 1 to 4 and Comparative Examples 4 to 7.

【図3】実施例1〜4、比較例4〜7で得られた吸着剤
の炭酸カリウム担持量と塩化水素吸着量の関係を示す。
FIG. 3 shows the relationship between the amount of supported potassium carbonate and the amount of adsorbed hydrogen chloride of the adsorbents obtained in Examples 1 to 4 and Comparative Examples 4 to 7.

───────────────────────────────────────────────────── フロントページの続き (72)発明者 猪川 弘徳 大阪府枚方市中宮大池1−1−1株式会 社クボタ枚方製造所内 (56)参考文献 特開 平9−86914(JP,A) 特開 昭54−35188(JP,A) 特開 平4−149015(JP,A) 特開 平9−155187(JP,A) 特開 昭54−77290(JP,A) (58)調査した分野(Int.Cl.7,DB名) B01J 20/20 B01D 53/68 C09K 3/00 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Hironori Inagawa 1-1-1 Nakanomiya Oike, Hirakata City, Osaka Prefecture Kubota Hirakata Factory (56) Reference JP-A-9-86914 (JP, A) JP 54-35188 (JP, A) JP 4-149015 (JP, A) JP 9-155187 (JP, A) JP 54-77290 (JP, A) (58) Fields investigated (Int .Cl. 7 , DB name) B01J 20/20 B01D 53/68 C09K 3/00

Claims (4)

(57)【特許請求の範囲】(57) [Claims] 【請求項1】 活性炭にアルカリ金属炭酸塩10重量%以
上、30重量%以下を担持せしめてなる、ベンゼン吸着量
が20%以上、40%以下であり、充填比重が0.40 g/ml 以
上、0.60 g/ml 以下である、プラスチックから石油系分
解油を製造する工程の酸性ガス吸着剤。
1. An activated carbon carrying 10% by weight or more and 30% by weight or less of an alkali metal carbonate, a benzene adsorption amount of 20% or more and 40% or less, and a packing specific gravity of 0.40 g / ml or more, 0.60. Acid gas adsorbent in the process of producing petroleum-based cracked oil from plastic, which is less than g / ml.
【請求項2】 アルカリ金属炭酸塩が炭酸カリウムであ
る、請求項1記載のプラスチックから石油系分解油を製
造する工程の酸性ガス吸着剤。
2. The acidic gas adsorbent in the step of producing a petroleum cracked oil from the plastic according to claim 1, wherein the alkali metal carbonate is potassium carbonate.
【請求項3】 粒径 0.500mm以上、4.75mm以下である吸
着剤粒子の重量比率が95%以上である、請求項1記載の
プラスチックから石油系分解油を製造する工程の酸性ガ
ス吸着剤。
3. The acid gas adsorbent in the step of producing a petroleum cracked oil from a plastic according to claim 1, wherein the weight ratio of the adsorbent particles having a particle size of 0.500 mm or more and 4.75 mm or less is 95% or more.
【請求項4】 排出ガス中の酸性ガスが塩化水素であ
る、請求項1記載のプラスチックから石油系分解油を製
造する工程の酸性ガス吸着剤。
4. The acidic gas adsorbent in the step of producing a petroleum-based cracked oil from the plastic according to claim 1, wherein the acidic gas in the exhaust gas is hydrogen chloride.
JP17396498A 1998-06-04 1998-06-04 Acid gas adsorbent Expired - Fee Related JP3442287B2 (en)

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JP5126946B2 (en) 2007-03-28 2013-01-23 株式会社豊田中央研究所 Sulfur gas removal filter and sulfur gas removal method using the same
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