JP4008105B2 - Production equipment for dechlorinated fuel - Google Patents

Description

【００５２】
【表２】

【００５３】
上記廃棄物１１を粉砕機１２で細粒化しているが、脱塩素炉１７として、例えば異方向回転式二軸スクリュー等を用いる場合には、攪拌が容易なように、３０〜２０ｍｍ以下としている。また粉砕粒径は小さい方が望ましく、５ｍｍ程度であれば粉砕動力に大幅な負担がなく、好ましい。
なお、脱塩素炉１７として、例えばロータリーキルン等の脱塩素炉を用いる場合には、２０ｍｍ以下とする必要はなく、例えば１００ｍｍ程度とすればよい。
【００５４】
上記脱塩素炉１６では、上記予熱された細粒化廃棄物を熱分解しているが、熱分解条件は３００〜４５０℃とするのが好ましい。これは４５０℃を超えた場合には、脱塩素反応以外に、プラスチック自身の分解が進行し、好ましくないからであり、一方、３００℃未満では脱塩素能率が悪く、共に好ましくないからである。
上記脱塩素炉１７の加熱方法は、特に限定されるものではないが、例えば直接加熱方式の他に間接加熱方式等を挙げることができる。
直接加熱方式の場合には、導入するガスは、酸素濃度（Ｏ₂ の量）が低いガスまたは酸素を含まないガスを流通させることが発火防止の点から好ましい。但し、窒素ガス雰囲気下で直接加熱を行う場合には、この限りではない。
なお、直接加熱方式は、ガス流量が大きく、発生する排ガスの量が増大するので、装置のコンパクト化の点からは間接加熱方法の方が好ましい。
【００５５】
また、熱分解脱塩素処理において分解したHCl ガスは、廃棄物内に含まれる金属類と反応して塩素化合物を副生することを防止するために、上記脱塩素炉内を減圧処理することにより、HCl ガスの系外への拡散速度を増加させている。
減圧の条件としては、真空度0.１kg/cm²以下が好ましい。
【００５６】
次に、図２に各種プラスチックの熱分解における重量減少率を示す（三菱重工技報，10(5) P787（1973）参照）。一般に、熱可塑性プラスチックは、約１２０〜２３０℃で軟化・溶融し、それ以後の高温で熱分解する。また、熱硬化樹脂は、軟化・溶融せずに加熱によりそのまま熱分解する。
廃棄物１１の内で塩素を含有するプラスチックとしては、ポリ塩化ビニル（ＰＶＣ）、ポリ塩化ビニリデンがある。これらの塩素含有プラスチックは、約１７０℃〜３５０℃の領域で大半の塩素を塩化水素として脱離し、その後高温になると他成分の熱分解が進行する。下記「化３」に示す反応式（５）に塩素脱離のモデルを示す。
【００５７】
【化３】

【００５８】
図３にＰＶＣ（ポリ塩化ビニル）脱HCl 速度を示す。この図３から、３００℃以上でほぼ１００％脱HCl するが、数十分の長時間の滞留時間が必要である。
前記のように、プラスチック混合物は約２５０℃近傍から急激に熱分解を開始し、約５００℃までに大半が分解する。
【００５９】
そこで、本発明はまず粉砕して細粒化した廃棄物１３を出来る限りプラスチック中の炭化水素の熱分解速度が遅く、塩素Clの熱分解速度が速い温度領域（約２６０〜３６０℃）で廃棄物中の塩素分のみを分解処理し、初期塩素含有量の８０〜９０wt％以上の高脱塩素率で塩素を分解・分離している。
この場合、炭化水素成分を主体とする残留固体中には、初期塩素含有量の約２０wt％の塩素が含まれているが、この塩素は廃棄物中に当初から含まれているアルカリ化合物と反応（前記（１）〜（４）の反応参照）して塩素化合物を生成し、塩素Clが固定化される。この時生成される塩化物は、上記水洗槽２４において、水に容易に溶解され、固体と分離される。
【００６０】
熱分解の脱塩素炉１７の構造としては、粉砕されたプラスチック等１５の熱交換性能を向上させるために、熱分解炉１７内に混合物を撹拌・混合する機構を設けたものを用いるのが好ましい。
このように、上記脱塩素炉１７内に攪拌・混合機構を設けることにより、壁面に付着するものを常時擦り取る状態となるため、壁面へのコーキングも同時に防止できる。
【００６１】
また、脱塩素炉１７として例えばロータリキルン型のように容器自体が回転することにより撹拌・混合能力を有するものを用いてもよい。
このように、廃棄物を脱塩素炉全体を回転させる場合には、前記と同様の効果を得ることができる。
【００６２】
さらに、脱塩素炉１７の構造として、二重構造で加熱媒体を外筒に流通し、間接加熱による熱分解処理を行うことも可能である。
【００６３】
脱塩素炉１７により分解処理された分解物１８は溶融状態のまま分離器２１に移され、ここで排ガス１９と脱塩素化固形物２０とに分離する。
上記分離器２１より分離された排ガス１９は、二次燃焼炉２７で燃焼され熱分解により発生した塩化水素を含むガスを完全燃焼させている。
この二次燃焼炉２７の燃焼条件は、７５０〜１０００℃、好ましくは８００〜９００℃としている。これは、７５０℃未満では炭化水素の分解が開始せず、好ましくなく、一方１０００℃を超えて分解させてもガス中の分解生成物が再縮合したり、煤が発生し、さらに、炉の耐久性の点から問題があり、好ましくないからである。
また、燃焼時間は８５０℃で２秒程度とすることにより、排ガス中のダイオキシン類を完全分解でき、好ましい。
【００６４】
分離器２１より分離された脱塩素化固形物２０は粉砕機２２により粉砕される。この粉砕は固形物２０の内部に含有された塩化物（CaCl₂ ，CaCl₂ ，NaCl，KCl 等）を効率よく除去するために、微細化するものであり、微細化する粉砕粒径としては、１０ｍｍ以下、好ましくは１〜５ｍｍ以下にする方がよい。
なお、１ｍｍ以下とする場合には、いわゆるヘドロ状となって効率的な攪拌が不能となるので、好ましくない。
【００６５】
以上の方法により、廃棄物１１の脱塩処理ができる共に、残渣中にも塩化物が少量しか残存しないために、発生ガス及び残渣の無公害化が容易になる。
また、得られたスラリー状燃料２６は、ポンプ等の移送手段を用いてそのままの状態でハンドリングでき、例えば水に懸濁した石炭燃料（ＣＷＭ（Coal Water Miture)：高濃度石炭−水スラリ（例えば石炭：70％、水：30％））と共に燃焼させた場合でも、発生するガス中には脱塩素化されているので例えばダイオキシン類等の有害物質は存在せず、クリーンな排気ガスとなる。
【００６６】
［第２の実施の形態］
本実施の形態では、第１の実施の形態と同様に、塩素を含む廃棄物を熱分解脱塩素した後、一旦水洗して、副生した無機塩化物を水に溶解させて分離したものを更に、乾燥炉で乾燥させるものである。また、乾燥によりスラリー状の燃料とは異なる形態の脱塩素化された固形燃料を得るようにしたものである。さらに、本実施の形態では、二次燃焼炉から排出されるガスの排熱を脱塩素処理工程で有効利用を図るようにしたものである。
【００６７】
図４は第２の実施の形態にかかる脱塩素化燃料の製造装置の概略である。
図４に示すように、塩素を含む廃棄物１１を所定サイズ以下（例えば２０ｍｍ以下）に細粒化する粉砕機１２と、粉砕された廃棄物１３を予熱する予熱機１４と、予熱された細粒化された廃棄物１５を水蒸気導入手段１６から導入された水蒸気濃度が高い状態で加熱して脱塩素処理を行う脱塩素炉１７と、上記脱塩素炉で熱分解された分解物１８を、排ガス１９と脱塩素化された固形物２０とに分離する分離器２１と、分離された脱塩素化固形物２０を所定サイズ以下に微粉化（例えば５ｍｍ以下）する粉砕機２２と、微細化された脱塩素化固形物２３を水洗し無機塩を除去する水洗槽２４と、水洗後の固形分を乾燥する乾燥炉４１とからなるものである。該乾燥炉４１で乾燥された固形分は、脱塩素化固形燃料４２として利用できる。
【００６８】
また、本実施の形態では、二次燃焼炉２７と排ガス処理装置２９との間に熱交換器４３を設け、燃焼熱を回収し、給水手段を有する蒸気発生器４４で水蒸気を発生させている。ここで得られた水蒸気１６は、上記脱塩素炉１７内に導入して塩化物の発生を抑制するようにしている。
【００６９】
また、本実施の形態では、別途導入された加熱ガス４５を脱塩素炉１７の加熱用の熱源として利用している。この脱塩素炉１７での加熱後のガスは予熱機１４の熱源及び乾燥炉４１の熱源としてライン４６，４７を経由して供給している。なお、乾燥炉４１における排ガス４８は別途排ガス処理されている。
【００７０】
以上の方法で廃棄物１１の脱塩素処理ができる共に、残渣中にも塩化物が少量しか残存しないために、発生ガス及び残渣の無公害化が容易になる。
また、脱塩素化固形燃料４２は、次のガス化，油化等の工程に導かれて、有機物（炭化水素）がガス化または油化処理される。一方、これを燃料として燃焼する場合には、脱塩素化されているので発生するガスは無害であり、残渣中にも塩化物が少量しか残存しないために、残渣の無公害化が容易になる。
また、熱交換器４３の設置により、排熱を有効利用することができると共に、得られた熱で蒸気を発生させ、該蒸気を脱塩素炉１７で使用でき、熱の有効利用が可能となる。
【００７１】
［第３の実施の形態］
本実施の形態では、第２の実施の形態と同様に、塩素を含む廃棄物を熱分解脱塩素した後、一旦水洗して、副生した無機塩化物を水に溶解させて分離したものを更に、乾燥炉で乾燥させることにより、脱塩素化された固形燃料を得るようにしたものであるが、二次燃焼炉から排出されるガスの排熱の利用の形態が異なるものである。
【００７２】
図５は第３の実施の形態にかかる脱塩素化燃料の製造装置の概略である。
図５に示すように、塩素を含む廃棄物１１を所定サイズ以下（例えば２０ｍｍ以下）に細粒化する粉砕機１２と、粉砕された廃棄物１３を予熱する予熱機１４と、予熱された細粒化された廃棄物１５を水蒸気導入手段１６から導入された水蒸気濃度が高い状態で加熱して脱塩素処理を行う脱塩素炉１７と、上記脱塩素炉で熱分解された分解物１８を、排ガス１９と脱塩素化された固形物２０とに分離する分離器２１と、分離された脱塩素化固形物２０を所定サイズ以下に微粉化（例えば５ｍｍ以下）する粉砕機２２と、微細化された脱塩素化固形物２３を水洗し無機塩を除去する水洗槽２４と、水洗後の固形分を乾燥する乾燥炉４１とからなり、乾燥炉４１で乾燥された固形分を脱塩素化燃料４２として得るものである。
【００７３】
また、本実施の形態では、二次燃焼炉２７と排ガス処理装置２９との間に熱交換器５１を設け、送風機５２により導入された空気５３を加熱し、別途導入された加熱ガス５４と共に、脱塩素炉１７の加熱用の熱源として利用している。
なお、第２の実施の形態と同様に、脱塩素炉１７での加熱後のガスは予熱機１４の熱源及び乾燥炉４１の熱源としてライン４６を経由して供給している。
また、脱塩素炉１７での加熱後のガスは予熱機１４の熱源及び乾燥炉４１の熱源としてライン５５，５６を経由して供給している。なお、乾燥炉４１における排ガス４８は別途排ガス処理されている。
【００７４】
以上の方法で脱塩素処理（熱分解）後の脱塩素化燃料４２は、次のガス化，油化または燃焼工程に導かれて、有機物（炭化水素）がガス化，油化または燃焼処理される。この燃焼の際、脱塩素化されているので発生するガスは無害であり、残渣中にも塩化物が少量しか残存しないために、残渣の無公害化が容易になる。また、熱交換器４３の設置により、排熱を有効利用することができると共に、得られた熱で蒸気を発生させ、該蒸気を脱塩素炉１７で使用でき、熱の有効利用が可能となる。
【００７５】
［第４の実施の形態］
本実施の形態では、第３の実施の形態と同様に、塩素を含む廃棄物を熱分解脱塩素した後、一旦水洗して、副生した無機塩化物を水に溶解させて分離したものを更に、乾燥炉で乾燥させ、脱塩素化された固形燃料を得ると共に、二次燃焼炉での排熱の利用を図ったものであるが、処理する対象を単なる廃棄物からＲＤＦ（Rdfuse Derived Fuel:ゴミ固化燃料) を用いた点が異なるものである。なお、ＲＰＦ（廃プラスチック固形燃料）を用いても同様であるので、本発明では、以下、ＲＤＦを用いて本発明の内容を説明する。
【００７６】
図６は第４の実施の形態にかかる脱塩素化燃料の製造装置の概略である。
図６に示すように、塩素を含むＲＤＦ（ゴミ固化燃料）６１を水蒸気導入手段１６により導入された水蒸気濃度が高い状態で加熱して脱塩素処理を行う脱塩素炉１７と、上記脱塩素炉で熱分解された分解物１８を、排ガス１９と脱塩素化された固形物２０とに分離する分離器２１と、分離された脱塩素化固形物２０を所定サイズ以下に微粉化（例えば５ｍｍ以下）する粉砕機２２と、微細化された脱塩素化固形物２３を水洗し無機塩を除去する水洗槽２４と、水洗後の固形分を乾燥する乾燥炉４１とからなり、塩素を含むＲＤＦ（ゴミ固化燃料）６１を脱塩素処理すると共に、乾燥炉４１で乾燥された固形分を脱塩素化燃料４２として得るものである。
【００７７】
また、本実施の形態では、二次燃焼炉２７と排ガス処理装置２９との間に熱交換器５１を設け、送風機５２により導入された空気５３を加熱し、別途導入された加熱ガス５４と共に、脱塩素炉１７の加熱をしている。なお、第２の実施の形態と同様に、脱塩素炉１７での加熱後のガスは予熱機１４の熱源及び乾燥炉４１の熱源としてライン５５，５６を経由して供給している。
【００７８】
以上の方法によれば、塩素を含むＲＤＦ（ゴミ固化燃料）６１を加熱分解処理し、脱塩素処理（熱分解）後の脱塩素化燃料４２は、次のガス化または燃焼工程に導かれて、有機物（炭化水素）がガス化または燃焼処理される。この燃焼の際、脱塩素化されているので発生するガスは無害であり、残渣中にも塩化物が少量しか残存しないために、残渣の無公害化が容易になる。
また、熱交換器４３の設置により、排熱を有効利用することができると共に、得られた熱で蒸気を発生させ、該蒸気を脱塩素炉１７で使用でき、熱の有効利用と共に、無機塩化物の生成を抑制している。
【００７９】
［第５の実施の形態］
本実施の形態では、第４の実施の形態と同様に、処理する対象をＲＤＦ（ゴミ固化燃料）を用いたものであり、脱塩素処理方法は第２の実施の形態と同様である。
【００８０】
図７は第５の実施の形態にかかる脱塩素化燃料の製造装置の概略である。
図７に示すように、塩素を含むＲＤＦ（ゴミ固化燃料）６１を水蒸気導入手段１６により導入された水蒸気濃度が高い状態で加熱して脱塩素処理を行う脱塩素炉１７と、上記脱塩素炉で熱分解された分解物１８を、排ガス１９と脱塩素化された固形物２０とに分離する分離器２１と、分離された脱塩素化固形物２０を所定サイズ以下に微粉化（例えば５ｍｍ以下）する粉砕機２２と、微細化された脱塩素化固形物２３を水洗し無機塩を除去する水洗槽２４と、水洗後の固形分を乾燥する乾燥炉４１とからなり、塩素を含むＲＤＦ（ゴミ固化燃料）６１を脱塩素処理すると共に、乾燥炉４１で乾燥された固形分を脱塩素化燃料４２として得るものである。
【００８１】
また、本実施の形態では、二次燃焼炉２７と排ガス処理装置２９との間に熱交換器４３を設け、燃焼熱を回収し、蒸気発生器４４で水蒸気を発生させ、該水蒸気を脱塩素炉１７に供給するようにしている。また、蒸気発生器４４での交換熱は別途導入された加熱ガス４５と共に、脱塩素炉１７の加熱をしている。また、脱塩素炉１７での加熱後のガスは予熱機１４の熱源及び乾燥炉４１の熱源としてライン４６を経由して供給している。
【００８２】
以上の方法によれば、塩素を含むＲＤＦ（ゴミ固化燃料）６１を加熱分解処理し、脱塩素処理（熱分解）後の脱塩素化燃料４２は、次のガス化または燃焼工程に導かれて、有機物（炭化水素）がガス化または燃焼処理される。この燃焼の際、脱塩素化されているので発生するガスは無害であり、残渣中にも塩化物が少量しか残存しないために、残渣の無公害化が容易になる。
【００８３】
【実施例】
以下、本発明の効果を示す好適な実施例について説明するが、本発明はこれに限定されるものではない。
【００８４】
本発明の一実施例を図４に示す装置を用いて説明する。
図４に示すように、ポリ塩化ビニル，ポリ塩化ビニリデン等の塩素を含有するプラスチックを含む廃棄物１１を粉砕機１２に供給し、約２０mm以下に粉砕する。当該粉砕後の廃棄物を予熱機３に供給し、２５０〜２８０℃程度に予熱する。予熱された廃棄物１５は、脱塩素炉１７に供給され、３２０〜３３０℃に加熱され、塩素含有プラスチック中の塩素部分が主体的に分解されてHCl ガスとなる。熱分解により発生したガス（HCl を含む）１９は溶融状態のまま分離器２１で分離され、二次燃焼炉２７に供給した。ここで排ガス１９中の可燃性ガスが８５０℃で燃焼処理した。この燃焼は２秒とした。さらに燃焼ガス２８は、熱交換器４３に導かれ、排ガス処理装置２９でHCl ガスを分離・除去した後、排ガス３０及び排水３１として排出した。
【００８５】
一方、脱塩素炉１７で脱塩素処理された廃棄物は、分離器２１で排ガスを分離した後、固形物２０となり、次に粉砕機２２に供給され、約５mm以下の微細物に粉砕した。粉砕された固形物２３は、水洗槽２４に投入され、水に可溶性の塩類が溶解・分離される。水洗後の固形物は、乾燥炉４１で乾燥され、脱塩素化固形燃料４２として取り出しる。その後、ガス化，油化，燃焼工程に供給される。 二次燃焼炉２７で発生した燃焼熱は、熱交換器（回収温度：８００℃）４３及び蒸気発生器４４で水蒸気として回収され、回収された水蒸気１６は脱塩素炉１７のパージガスとして利用した。
【００８６】
［実施例１〜８］
上記装置を用い、下記「表３」の性状の廃棄物を原料及び条件で脱塩素処理を行った場合を、実施例１〜４とした。
その結果、残留脱塩素濃度が低い固形燃料を製造することができた。
これらの結果を「表３」に示す。
また、実施例１〜４と同様な条件で脱塩素炉１７に圧力をかけて減圧下で脱塩素処理を行った場合を、実施例５〜８とした。
これらの結果を「表４」に示す。
ここで、本実施例で用いた上記脱塩素炉１７は、二軸撹拌翼付き加熱炉を用い、外筒熱媒加熱による間接加熱方式としており、脱塩素炉処理規模は３００（kg/d）である。
【００８７】
なお、脱塩素炉１７より分離した固形物２０を粉砕工程及び水洗工程を行わなかったものを比較例１〜４とした。
これらの結果を「表５」に示す。
【００８８】
【表３】

【表４】

【表５】

【００８９】
「表３」乃至「表５」に示すように、本実施例の場合では、残留Ｃｌ濃度が0.０８〜0.２１重量％と極めて低いものであったが、比較例の場合には、0.７８重量％以上と高いものであり、本実施例により残留塩素濃度の低い固形燃料を製造することができた。
また、減圧処理を行うことにより、脱塩素処理の効率が大幅に向上することが判明した。
【００９０】
［実施例９］
下記「表６」の組成からなるＣＳＤ（カーシュレッダーダスト）を原料として脱塩素処理をした。
ここで、本実施例で用いた上記脱塩素炉１７は、ロータリーキルン型熱分解炉（内径 350×長さ 4,100（mm））であり、運転条件は、キルン入口温度を 420℃，出口温度を 330℃とした。なお、キルン内平均滞留時間は 26minとした。
【００９１】
【表６】

【００９２】
本実施例によれば、固形燃料回収率が73.5（wt%)であり、残留塩素濃度0.２１（wt％）の固形燃料を製造することができた。
また、ロータリーキルンの内壁を観察したところ、壁面へのプラスチックの融着やコーキング等は殆ど確認されなかった。
【００９３】
【発明の効果】
以上説明したように、本発明の［請求項１］の脱塩素化燃料の製造装置によれば、ゴミ固形燃料（ＲＤＦ）を熱分解すると共に脱塩素処理を行う脱塩素炉と、脱塩素化固形物と熱分解ガスとを分離する分離器と、分離された脱塩素化固形物を微細化する粉砕機と、該粉砕された脱塩素化固形物を水洗し無機塩を除去する水洗槽とからなり、塩素を含むゴミ固形燃料（ＲＤＦ）から脱塩素化されたスラリー状の燃料を効率的に製造できる。
【０１１５】
［請求項２］によれば、請求項１において、上記水洗工程の後に、水洗後の脱塩素化固形物を乾燥する乾燥工程を有し、塩素を含む廃棄物から脱塩素化固形燃料を得るので、脱塩素化固形燃料を廃棄物から効率的に製造できる。
【０１１６】
［請求項３］によれば、請求項１において、脱塩素炉に水蒸気導入手段を設けたので、脱塩素反応における塩素の無機塩素化を防止するができる。
【０１１７】
［請求項４］によれば、請求項１において、脱塩素炉内を減圧する減圧手段を設けたので、分解したHCl ガスの廃棄物内に含まれる金属類と反応して塩素無機化合物の副生を抑制し、HCl ガスの系外への拡散速度を増加させることができる。
【０１１８】
［請求項５］によれば、請求項１において、脱塩素炉自体を回転可能又は炉内部を攪拌可能とするので、脱塩素反応を効率的に行うことができる。
【図面の簡単な説明】
【図１】本発明の第１の実施の形態の脱塩素化燃料の製造装置の概略図を示す。
【図２】各種プラスチックの熱分解における重量減少率を示すグラフである。
【図３】ＰＶＣ（ポリ塩化ビニル）の脱HCl 速度を示すグラフである。
【図４】本発明の第２の実施の形態の脱塩素化燃料の製造装置の概略図を示す。
【図５】本発明の第３の実施の形態の脱塩素化燃料の製造装置の概略図を示す。
【図６】本発明の第４の実施の形態の脱塩素化燃料の製造装置の概略図を示す。
【図７】本発明の第５の実施の形態の脱塩素化燃料の製造装置の概略図を示す。
【符号の説明】
１１ 廃棄物
１２ 粉砕機
１３ 細粒化廃棄物
１４ 予熱機
１５ 予熱された細粒化廃棄物
１６ 水蒸気導入手段
１７ 脱塩素炉
１８ 分解物
１９ 排ガス
２０ 脱塩素化固形物
２１ 分離器
２２ 粉砕機
２３ 脱塩素化固形物
２４ 水洗槽
２５ 排水
２６ スラリー状燃料
２７ 二次燃焼炉
２８ 燃焼ガス
２９ 排ガス処理装置
３０ 排ガス
３１ 排水
３２ 排水処理設備
４１ 乾燥炉
４２ 脱塩素化固形燃料
４３ 熱交換器
４４ 蒸気発生器
４５ 加熱ガス
５１ 熱交換器
５２ 送風機
５３ 空気
５４ 加熱ガス
６１ ＲＤＦ（ゴミ固化燃料）[0001]
BACKGROUND OF THE INVENTION
  The present inventionplaceProduction of dechlorinated fuel that effectively uses scientific productsDressRelated to the position.
[0002]
[Prior art and problems]
In recent years, a large amount of plastic mixtures including chlorine-containing plastics such as polyvinyl chloride and polyvinylidene chloride and wastes containing inorganic components have been discharged, and the amount of waste is constantly increasing. Most of such waste is incinerated or landfilled as it is.
[0003]
When incinerated, harmful substances such as hydrogen chloride and dioxins generated during incineration may be released directly into the atmosphere.
In addition, when landfilled, the active ingredient in the waste is not used, resulting in a loss of resources.
Thus, it has been proposed to recover the active ingredients therein by thermally decomposing these wastes.
[0004]
However, a large amount of chlorine compounds such as hydrogen chloride and chlorine gas are generated by pyrolysis, gasification or combustion of plastic containing chlorine in waste, which not only causes great pollution, but also pyrolysis furnaces, Causes gasification or combustion furnace corrosion. Therefore, in order to remove chlorine compounds by pretreating these wastes, a method of performing thermal decomposition in a decomposition tank by indirect heating with a heat medium or a heater has been proposed.
[0005]
In this method, it is difficult to uniformly heat the solid inside the cracking furnace. Especially in thermoplastics, the parts softened and melted by local heating are fused together to form a lump, and undecomposed hydrogen chloride is melted in the plastic. The hydrogen chloride is left behind and cannot be completely removed.
In addition, by adding an alkali metal compound such as Ca, Na, K or the like to these wastes and pyrolyzing, gasifying or burning them, a chlorine compound (CaCl) with an alkali metal as shown in “Chemical Formula 1” below.₂ , NaCl, KCl, etc.) have been proposed.
[0006]
[Chemical 1]
Ca (OH)₂+ 2HCl → CaCl₂ + 2H₂O (1)
CaCO_Three  + 2HCl → CaCl₂ + H₂O + CO₂    ... (2)
NaOH + HCl → NaCl + H₂O (3)
KOH + HCl → KCl + H₂O ... (4)
[0007]
However, in order to cause the entire amount of hydrogen chloride HCl generated from waste to react with alkali metals to be decomposed as a chlorine compound, in consideration of the reaction rate, conventionally, about four times the equivalent amount of alkali metals is added. It was. As a result, a large amount of residue was discharged due to the addition of excess alkali metals, which was a problem.
[0008]
In addition, when waste containing metal such as car shredder dust is pretreated by this method and then the by-product chlorine compound or metal-containing residue is treated again in a melting furnace, etc., these metals are recovered. There is also a problem that the compound is in a molten state at a high temperature of about 750 ° C. or more, and this scatters as mist and causes corrosion upon contact with the metal. In particular, in a method in which a waste containing a large amount of chlorine is burned as it is and an alkali metal compound is added thereto, the amount of by-produced chlorine compounds increases and the problem of corrosion due to the melt also increases.
[0009]
Furthermore, since plastics contain trace amounts of heavy metals as plasticizers, stabilizers or paints, there is a problem in disposing of these combustion residues as they are.
[0010]
[Means for Solving the Problems]
  [Claim 1] of the present invention to solve the above-mentioned problems.Dechlorinated fuel production equipmentThe inventionA dechlorination furnace that thermally decomposes solid waste fuel (RDF) and dechlorinates, a separator that separates dechlorinated solids and pyrolysis gas, and refines the separated dechlorinated solids A pulverizer and a water rinsing tank that removes inorganic salts by washing the pulverized dechlorinated solids with water, and obtaining dechlorinated fuel from waste solid fuel (RDF) containing chlorine.It is characterized by that.
[0032]
  [Claims2The invention of claim1In the present invention, after the water washing step, there is a drying step of drying the dechlorinated solid after the water washing, and dechlorinated solid fuel is obtained from waste containing chlorine.
[0033]
  [Claims3The invention of claim1In the present invention, a steam introduction means is provided in the dechlorination furnace.
[0034]
  [Claims4The invention of claim1And a depressurizing means for depressurizing the inside of the dechlorination furnace.
[0035]
  [Claims5The invention of claim1The dechlorination furnace itself can be rotated or the inside of the furnace can be stirred.
[0036]
The present invention will be described below with an outline of main specific items of means for solving the above-mentioned problems.
[0037]
1) A fine process is provided after the dechlorination process.
In the dechlorination process by thermal decomposition, about 80 wt% or more of the chlorine contained in the waste is dechlorinated and separated as hydrogen chloride. Therefore, the amount of chlorine initially contained in the solid after dechlorination has been reduced. Less than 20 wt% chlorine remains. This residual chlorine reacts with alkali metals contained in the waste (reaction formulas (1) to (4) shown in the following “Chemical Formula 2”) to generate chloride. Since this chloride has a melting point of about 700 to 850 ° C., it melts in the gasification or combustion process and is carried as mist in the gas, condensing in the low temperature part of the subsequent process, and causing corrosion and the like. Become.
[0038]
[Chemical 2]
Ca (OH)₂+ 2HCl → CaCl₂ + 2H₂O (1)
CaCO_Three  + 2HCl → CaCl₂ + H₂O + CO₂    ... (2)
NaOH + HCl → NaCl + H₂O (3)
KOH + HCl → KCl + H₂O ... (4)
[0039]
Therefore, in the present invention, after the dechlorination step, the separated solid is washed with water to dissolve / separate water-soluble chloride. At this time, since a solid is contained in the solid, the cleaning effect is enhanced by providing a fine process to pulverize the solid to obtain a fine diameter, followed by washing with water. Here, the pulverized particle size to be refined is 10 mm or less, preferably 1 to 5 mm or less.
[0040]
2) In the dechlorination step, thermal decomposition is performed in a steam atmosphere.
In the pyrolytic dechlorination treatment, the reverse reaction of the above reaction formulas (1) to (4) occurs in a steam atmosphere.
Therefore, in the present invention, a gas containing water vapor is used as the purge gas supplied to the dechlorination furnace containing the waste. At this time, a higher water vapor concentration is preferable.
Note that water vapor can be supplied by effectively utilizing the exhaust heat in the treatment method of the present invention.
[0041]
3) In the dechlorination step, the inside of the furnace is depressurized.
The HCl gas decomposed in the thermal decomposition and dechlorination treatment reacts with metals contained in the waste to produce a chlorine compound as a by-product.
Therefore, in the present invention, in order to prevent this, the inside of the dechlorination furnace containing the waste is decompressed to increase the diffusion rate of HCl gas outside the system.
[0042]
4) In the dechlorination step, a stirring mechanism is provided inside the furnace.
As an internal structure of the pyrolysis dechlorination furnace, in order to suppress the generation of waste plastic nodules softened and melted by heating, a stirring mechanism is provided in the furnace in the present invention. In addition, this mechanism can efficiently diffuse and degas the HCl gas generated by pyrolysis from the inside of the waste layer.
[0043]
5) In the dechlorination step, a mechanism for rotating the furnace itself is provided.
By rotating a dechlorination furnace that holds waste, it has the effect of separating the deposits on the wall surface of the high-boiling components generated by thermal decomposition with the moving waste particles.
[0044]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, although an embodiment of the present invention is described, the present invention is not limited to this.
[0045]
[First Embodiment]
In this embodiment, after pyrolyzing and dechlorinating chlorine-containing waste, it is once washed with water, and by-product inorganic chloride is dissolved in water and separated to obtain a dechlorinated fuel and discarded. The product is designed to be dechlorinated. Moreover, the fuel dechlorinated by this process can be obtained. Furthermore, the obtained dechlorinated fuel can be burned without being damaged by chloride as a fuel for subsequent gasification or combustion process, and no harmful substances such as dioxins are generated. It enables clean processing.
[0046]
FIG. 1 is an outline of an apparatus for performing a dechlorination treatment of waste according to the first embodiment. This apparatus is also an outline of a dechlorinated fuel production apparatus.
As shown in FIG. 1, a pulverizer 12 that refines chlorine-containing waste 11 to a predetermined size or less (for example, 20 mm or less), a preheater 14 that preheats the pulverized waste 13, and a preheated finer. A dechlorination furnace 17 for performing dechlorination by heating the granulated waste 15 in a state where the water vapor concentration introduced from the water vapor introduction means 16 is high, and a decomposition product 18 thermally decomposed in the dechlorination furnace, A separator 21 that separates the exhaust gas 19 and the dechlorinated solid 20, a pulverizer 22 that pulverizes the separated dechlorinated solid 20 to a predetermined size or less (5 mm or less), and a finer structure. It comprises a water washing tank 24 for washing the dechlorinated solid material 23 to remove inorganic salts, and the waste 11 is dechlorinated. Further, excess water in the slurry after washing in the washing tank 24 is removed as drainage 25 to obtain a slurry fuel 26 which is a dechlorinated fuel.
[0047]
The exhaust gas 19 separated by the separator 21 is burned at a high temperature in a secondary combustion furnace 27 to completely decompose aromatic chlorine compounds and the like in the gas, and the combustion gas 28 is then cooled at a high temperature, and the exhaust gas treatment device 29 In the HCl absorption tower, the chlorine gas is removed and discharged to the outside as the exhaust gas 30. On the other hand, the waste water 31 that has absorbed the chlorine gas is treated in the waste water treatment facility 32 together with the waste water from the washing tank 24.
[0048]
Here, the preheater 14 is melted to promote dechlorination, and may not be provided depending on the contents of the waste 11.
Further, a preheating means may be provided integrally with the dechlorination furnace 17. That is, when supplying the next dechlorination furnace 17 without passing through the preheater 14, the inlet portion of the dechlorination furnace 17 may be a preheating section, and the required length of the dechlorination furnace 17 may be increased.
The preheating temperature of the preheater 14 may be about 200 to 300 ° C, preferably about 250 ° C.
[0049]
Here, the following examples are given as the waste 11 containing chlorine.
(1) NaCl, MgCl₂Garbage discharged from households mixed with inorganic chlorine compounds such as chlorine and plastics containing chlorine.
(2) A plastic mixture containing a plastic containing chlorine such as vinyl chloride.
(3) So-called Car Shredder Dust (hereinafter referred to as “CSD”) mainly composed of plastic after the removal of automobile metals.
[0050]
General waste discharged from households contains about 1 to 3 wt% of chlorine. In addition, about 2 to 5 wt% of chlorine is contained in plastic waste discharged from households collected separately in some areas.
Examples of components of CSD are as follows, and polyvinyl chloride (PVC) is used as an instrumentation wire, and about 0.5 to 5 wt% is contained as chlorine in the CSD.
[0051]
[Table 1]

[0052]
[Table 2]

[0053]
Although the waste 11 is refined by the pulverizer 12, when the dechlorination furnace 17 is, for example, a bi-directional rotating twin screw or the like, it is set to 30 to 20 mm or less so as to facilitate stirring. . Further, it is desirable that the pulverized particle size is small, and if it is about 5 mm, there is no significant burden on the pulverization power, which is preferable.
For example, when a dechlorination furnace such as a rotary kiln is used as the dechlorination furnace 17, it is not necessary to set it to 20 mm or less, and it may be, for example, about 100 mm.
[0054]
In the dechlorination furnace 16, the preheated finely divided waste is pyrolyzed, but the pyrolysis condition is preferably 300 to 450 ° C. This is because when the temperature exceeds 450 ° C., decomposition of the plastic itself proceeds in addition to the dechlorination reaction, which is not preferable. On the other hand, when the temperature is lower than 300 ° C., the dechlorination efficiency is low and both are not preferable.
The heating method of the dechlorination furnace 17 is not particularly limited. For example, in addition to the direct heating method, an indirect heating method can be used.
In the case of the direct heating method, the introduced gas is oxygen concentration (O₂From the viewpoint of preventing ignition, it is preferable to circulate a gas having a low amount) or a gas not containing oxygen. However, this is not the case when direct heating is performed in a nitrogen gas atmosphere.
In the direct heating method, since the gas flow rate is large and the amount of exhaust gas generated increases, the indirect heating method is preferable from the viewpoint of downsizing the apparatus.
[0055]
In addition, the HCl gas decomposed in the thermal decomposition and dechlorination treatment is subjected to a reduced pressure treatment in the dechlorination furnace in order to prevent the generation of chlorine compounds by reaction with metals contained in the waste. This increases the diffusion rate of HCl gas out of the system.
As a condition for depressurization, the degree of vacuum is 0.1 kg / cm.²The following is preferred.
[0056]
Next, Fig. 2 shows the weight loss rate in the thermal decomposition of various plastics (see Mitsubishi Heavy Industries Technical Review, 10 (5) P787 (1973)). In general, a thermoplastic plastic is softened and melted at about 120 to 230 ° C. and then thermally decomposed at a high temperature thereafter. Further, the thermosetting resin is thermally decomposed as it is by heating without being softened or melted.
Among the waste 11, plastics containing chlorine include polyvinyl chloride (PVC) and polyvinylidene chloride. These chlorine-containing plastics desorb most of the chlorine as hydrogen chloride in the range of about 170 ° C. to 350 ° C., and then the thermal decomposition of other components proceeds at a high temperature. The reaction formula (5) shown in the following “Chemical Formula 3” shows a model of chlorine elimination.
[0057]
[Chemical 3]

[0058]
FIG. 3 shows the PVC (polyvinyl chloride) deHCl rate. From FIG. 3, almost 100% deHCl removal is performed at 300 ° C. or higher, but a tens of minutes of residence time is required.
As described above, the plastic mixture starts to thermally decompose at around about 250 ° C., and most of the plastic mixture decomposes by about 500 ° C.
[0059]
Therefore, the present invention first discards the waste 13 that has been pulverized and refined in a temperature range (about 260 to 360 ° C.) where the thermal decomposition rate of hydrocarbons in plastic is as slow as possible and the thermal decomposition rate of chlorine Cl is as fast as possible. Only the chlorine content in the product is decomposed, and chlorine is decomposed and separated at a high dechlorination rate of 80 to 90 wt% or more of the initial chlorine content.
In this case, the residual solid mainly composed of hydrocarbon components contains about 20 wt% of the chlorine content of the initial chlorine content. This chlorine reacts with the alkali compound originally contained in the waste. (Refer to the reactions (1) to (4) above) to produce a chlorine compound, and chlorine Cl is immobilized. The chloride generated at this time is easily dissolved in water and separated from the solid in the washing tank 24.
[0060]
As the structure of the pyrolysis dechlorination furnace 17, it is preferable to use a structure provided with a mechanism for stirring and mixing the mixture in the pyrolysis furnace 17 in order to improve the heat exchange performance of the pulverized plastic or the like 15. .
As described above, by providing the stirring / mixing mechanism in the dechlorination furnace 17, the material adhering to the wall surface is constantly scraped, so that coking to the wall surface can be prevented at the same time.
[0061]
Further, as the dechlorination furnace 17, for example, a rotary kiln type having a stirring / mixing ability by rotating the container itself may be used.
Thus, when rotating the whole dechlorination furnace for waste, the effect similar to the above can be acquired.
[0062]
Furthermore, as a structure of the dechlorination furnace 17, it is also possible to circulate a heating medium in an outer cylinder in a double structure and perform a thermal decomposition process by indirect heating.
[0063]
The decomposition product 18 decomposed by the dechlorination furnace 17 is transferred to a separator 21 in a molten state, where it is separated into an exhaust gas 19 and a dechlorinated solid material 20.
The exhaust gas 19 separated from the separator 21 completely burns a gas containing hydrogen chloride which is burned in the secondary combustion furnace 27 and generated by thermal decomposition.
The combustion condition of the secondary combustion furnace 27 is set to 750 to 1000 ° C, preferably 800 to 900 ° C. This is because the decomposition of hydrocarbons does not start at less than 750 ° C., which is not preferable. On the other hand, decomposition at a temperature exceeding 1000 ° C. causes recondensation of decomposition products in the gas, generation of soot, and This is because there is a problem in terms of durability, which is not preferable.
In addition, the combustion time is preferably about 2 seconds at 850 ° C., so that dioxins in the exhaust gas can be completely decomposed, which is preferable.
[0064]
The dechlorinated solid 20 separated from the separator 21 is pulverized by a pulverizer 22. This pulverization is performed by using chloride (CaCl) contained in the solid 20.₂ , CaCl₂ , NaCl, KCl, etc.) for efficient removal, the pulverized particle size to be refined is 10 mm or less, preferably 1 to 5 mm or less.
In addition, when it is set to 1 mm or less, since it becomes a so-called sludge shape and efficient stirring becomes impossible, it is not preferable.
[0065]
By the above method, the waste 11 can be desalted, and since only a small amount of chloride remains in the residue, it is easy to make the generated gas and the residue non-polluting.
The obtained slurry fuel 26 can be handled as it is using a transfer means such as a pump. For example, coal fuel suspended in water (CWM (Coal Water Miture): high concentration coal-water slurry (for example, Coal: 70%, water: 30%)), even when burned together, the generated gas is dechlorinated, so there are no harmful substances such as dioxins, and the exhaust gas is clean.
[0066]
[Second Embodiment]
In the present embodiment, as in the first embodiment, the waste containing chlorine is pyrolyzed and dechlorinated, then washed once with water, and the inorganic chloride produced as a by-product is dissolved in water and separated. Further, it is dried in a drying furnace. Further, a dechlorinated solid fuel having a different form from the slurry-like fuel is obtained by drying. Furthermore, in this embodiment, the exhaust heat of the gas discharged from the secondary combustion furnace is effectively used in the dechlorination process.
[0067]
FIG. 4 is an outline of a dechlorinated fuel production apparatus according to the second embodiment.
As shown in FIG. 4, a pulverizer 12 that refines the chlorine-containing waste 11 to a predetermined size or less (for example, 20 mm or less), a preheater 14 that preheats the pulverized waste 13, and a preheated finer. A dechlorination furnace 17 for performing dechlorination treatment by heating the granulated waste 15 in a state where the water vapor concentration introduced from the water vapor introduction means 16 is high, and a decomposition product 18 thermally decomposed in the dechlorination furnace, A separator 21 that separates the exhaust gas 19 and the dechlorinated solid 20, a pulverizer 22 that pulverizes the separated dechlorinated solid 20 to a predetermined size or less (for example, 5 mm or less), The dechlorinated solid 23 is washed with water to remove inorganic salts, and a drying furnace 41 for drying the solid content after washing. The solid content dried in the drying furnace 41 can be used as a dechlorinated solid fuel 42.
[0068]
Further, in the present embodiment, a heat exchanger 43 is provided between the secondary combustion furnace 27 and the exhaust gas treatment device 29, the combustion heat is recovered, and steam is generated by the steam generator 44 having water supply means. . The water vapor 16 obtained here is introduced into the dechlorination furnace 17 to suppress the generation of chloride.
[0069]
In the present embodiment, the separately introduced heating gas 45 is used as a heat source for heating the dechlorination furnace 17. The gas heated in the dechlorination furnace 17 is supplied via lines 46 and 47 as a heat source for the preheater 14 and a heat source for the drying furnace 41. The exhaust gas 48 in the drying furnace 41 is separately treated with exhaust gas.
[0070]
The waste 11 can be dechlorinated by the above method, and since only a small amount of chloride remains in the residue, it is easy to make the generated gas and the residue non-polluting.
In addition, the dechlorinated solid fuel 42 is guided to the next gasification, oil production, and the like, and the organic matter (hydrocarbon) is gasified or oiled. On the other hand, when it is burned as fuel, the generated gas is harmless because it is dechlorinated, and since only a small amount of chloride remains in the residue, it is easy to make the residue pollution-free. .
Moreover, by installing the heat exchanger 43, exhaust heat can be used effectively, steam is generated with the obtained heat, the steam can be used in the dechlorination furnace 17, and heat can be used effectively. .
[0071]
[Third Embodiment]
In the present embodiment, as in the second embodiment, the waste containing chlorine is pyrolyzed and dechlorinated, then washed once with water, and the by-product inorganic chloride is dissolved and separated in water. Furthermore, a solid fuel dechlorinated is obtained by drying in a drying furnace, but the form of utilization of the exhaust heat of the gas discharged from the secondary combustion furnace is different.
[0072]
FIG. 5 is an outline of a dechlorinated fuel production apparatus according to the third embodiment.
As shown in FIG. 5, a pulverizer 12 that refines the chlorine-containing waste 11 to a predetermined size or less (for example, 20 mm or less), a preheater 14 that preheats the pulverized waste 13, and a preheated finer. A dechlorination furnace 17 for performing dechlorination treatment by heating the granulated waste 15 in a state where the water vapor concentration introduced from the water vapor introduction means 16 is high, and a decomposition product 18 thermally decomposed in the dechlorination furnace, A separator 21 that separates the exhaust gas 19 and the dechlorinated solid 20, a pulverizer 22 that pulverizes the separated dechlorinated solid 20 to a predetermined size or less (for example, 5 mm or less), The dechlorinated solid 23 is washed with water to remove inorganic salts, and a drying furnace 41 for drying the solid content after washing with water. The solid content dried in the drying furnace 41 is dechlorinated fuel 42. What you get as
[0073]
In the present embodiment, a heat exchanger 51 is provided between the secondary combustion furnace 27 and the exhaust gas treatment device 29 to heat the air 53 introduced by the blower 52 and together with the separately introduced heating gas 54, It is used as a heat source for heating the dechlorination furnace 17.
As in the second embodiment, the gas after heating in the dechlorination furnace 17 is supplied via a line 46 as a heat source for the preheater 14 and a heat source for the drying furnace 41.
Further, the gas after heating in the dechlorination furnace 17 is supplied via lines 55 and 56 as a heat source for the preheater 14 and a heat source for the drying furnace 41. The exhaust gas 48 in the drying furnace 41 is separately treated with exhaust gas.
[0074]
The dechlorinated fuel 42 after the dechlorination treatment (thermal decomposition) by the above method is guided to the next gasification, oilification or combustion process, and the organic matter (hydrocarbon) is gasified, oiled or burned. The During this combustion, the generated gas is harmless because it is dechlorinated, and since only a small amount of chloride remains in the residue, the residue can be easily polluted. Moreover, by installing the heat exchanger 43, exhaust heat can be used effectively, steam is generated with the obtained heat, the steam can be used in the dechlorination furnace 17, and heat can be used effectively. .
[0075]
[Fourth Embodiment]
In the present embodiment, as in the third embodiment, the waste containing chlorine is pyrolyzed and dechlorinated, then washed once with water, and the by-product inorganic chloride is dissolved and separated in water. Furthermore, the solid fuel is dried in a drying furnace to obtain dechlorinated solid fuel, and the exhaust heat in the secondary combustion furnace is used, but the object to be treated is changed from simple waste to RDF (Rdfuse Derived Fuel). : Waste solidified fuel) is different. In addition, since it is the same even if it uses RPF (waste plastic solid fuel), below, the content of this invention is demonstrated using RDF in this invention.
[0076]
FIG. 6 is an outline of a dechlorinated fuel production apparatus according to the fourth embodiment.
As shown in FIG. 6, a dechlorination furnace 17 that performs dechlorination treatment by heating RDF (garbage solidified fuel) 61 containing chlorine in a state where the water vapor concentration introduced by the water vapor introduction means 16 is high, and the above dechlorination furnace. A separator 21 that separates the pyrolyzed product 18 thermally decomposed in 1 into an exhaust gas 19 and a dechlorinated solid 20, and the separated dechlorinated solid 20 is pulverized to a predetermined size or less (for example, 5 mm or less). ), A water washing tank 24 for washing the refined dechlorinated solid material 23 with water and removing inorganic salts, and a drying furnace 41 for drying the solid content after water washing. The waste solidified fuel) 61 is dechlorinated, and the solid content dried in the drying furnace 41 is obtained as the dechlorinated fuel 42.
[0077]
In the present embodiment, a heat exchanger 51 is provided between the secondary combustion furnace 27 and the exhaust gas treatment device 29 to heat the air 53 introduced by the blower 52 and together with the separately introduced heating gas 54, The dechlorination furnace 17 is heated. As in the second embodiment, the gas after heating in the dechlorination furnace 17 is supplied via lines 55 and 56 as a heat source for the preheater 14 and a heat source for the drying furnace 41.
[0078]
According to the above method, RDF (garbage solidified fuel) 61 containing chlorine is thermally decomposed, and the dechlorinated fuel 42 after dechlorination (thermal decomposition) is guided to the next gasification or combustion process. Organic substances (hydrocarbons) are gasified or burned. During this combustion, the generated gas is harmless because it is dechlorinated, and since only a small amount of chloride remains in the residue, the residue can be easily polluted.
Moreover, by installing the heat exchanger 43, exhaust heat can be used effectively, steam is generated with the obtained heat, and the steam can be used in the dechlorination furnace 17. The production of things is suppressed.
[0079]
[Fifth Embodiment]
In the present embodiment, as in the fourth embodiment, the object to be processed uses RDF (dust solidified fuel), and the dechlorination processing method is the same as in the second embodiment.
[0080]
FIG. 7 is a schematic of a dechlorinated fuel production apparatus according to the fifth embodiment.
As shown in FIG. 7, a dechlorination furnace 17 that performs dechlorination treatment by heating RDF (garbage solidified fuel) 61 containing chlorine in a state where the water vapor concentration introduced by the water vapor introduction means 16 is high, and the above dechlorination furnace. A separator 21 that separates the pyrolyzed product 18 thermally decomposed in 1 into an exhaust gas 19 and a dechlorinated solid 20, and the separated dechlorinated solid 20 is pulverized to a predetermined size or less (for example, 5 mm or less). ), A water washing tank 24 for washing the refined dechlorinated solid material 23 to remove inorganic salts, and a drying furnace 41 for drying the solid content after water washing. The waste solidified fuel) 61 is dechlorinated, and the solid content dried in the drying furnace 41 is obtained as the dechlorinated fuel 42.
[0081]
In the present embodiment, a heat exchanger 43 is provided between the secondary combustion furnace 27 and the exhaust gas treatment device 29, the combustion heat is recovered, steam is generated by the steam generator 44, and the steam is dechlorinated. It is made to supply to the furnace 17. The exchange heat in the steam generator 44 heats the dechlorination furnace 17 together with a separately introduced heating gas 45. The gas after heating in the dechlorination furnace 17 is supplied via a line 46 as a heat source for the preheater 14 and a heat source for the drying furnace 41.
[0082]
According to the above method, RDF (garbage solidified fuel) 61 containing chlorine is thermally decomposed, and the dechlorinated fuel 42 after dechlorination (thermal decomposition) is guided to the next gasification or combustion process. Organic substances (hydrocarbons) are gasified or burned. During this combustion, the generated gas is harmless because it is dechlorinated, and since only a small amount of chloride remains in the residue, the residue can be easily polluted.
[0083]
【Example】
Hereinafter, although the suitable Example which shows the effect of this invention is described, this invention is not limited to this.
[0084]
An embodiment of the present invention will be described using the apparatus shown in FIG.
As shown in FIG. 4, waste 11 containing plastic containing chlorine such as polyvinyl chloride and polyvinylidene chloride is supplied to a pulverizer 12 and pulverized to about 20 mm or less. The crushed waste is supplied to the preheater 3 and preheated to about 250 to 280 ° C. The preheated waste 15 is supplied to the dechlorination furnace 17 and heated to 320 to 330 ° C., and the chlorine portion in the chlorine-containing plastic is mainly decomposed to become HCl gas. A gas (including HCl) 19 generated by thermal decomposition was separated by a separator 21 in a molten state and supplied to a secondary combustion furnace 27. Here, the combustible gas in the exhaust gas 19 was burned at 850 ° C. This combustion was for 2 seconds. Further, the combustion gas 28 was guided to the heat exchanger 43, and after the HCl gas was separated and removed by the exhaust gas treatment device 29, it was discharged as the exhaust gas 30 and the waste water 31.
[0085]
On the other hand, the waste dechlorinated in the dechlorination furnace 17 was separated into exhaust gas by the separator 21 and then turned into a solid 20 and then supplied to the pulverizer 22 where it was pulverized to a fineness of about 5 mm or less. The pulverized solid 23 is put into a water washing tank 24, and water-soluble salts are dissolved and separated. The solid after washing with water is dried in a drying furnace 41 and taken out as a dechlorinated solid fuel 42. Then, it is supplied to gasification, oilification, and combustion processes. The combustion heat generated in the secondary combustion furnace 27 was recovered as water vapor by a heat exchanger (recovery temperature: 800 ° C.) 43 and a steam generator 44, and the recovered water vapor 16 was used as a purge gas for the dechlorination furnace 17.
[0086]
[Examples 1 to 8]
The case where the dechlorination process of the property of the following "Table 3" was performed on the raw material and conditions using the said apparatus was made into Examples 1-4.
As a result, a solid fuel having a low residual dechlorination concentration could be produced.
These results are shown in “Table 3”.
Moreover, the case where the dechlorination process was performed under reduced pressure by applying pressure to the dechlorination furnace 17 under the same conditions as in Examples 1 to 4 was set as Examples 5 to 8.
These results are shown in “Table 4”.
Here, the dechlorination furnace 17 used in the present example uses a heating furnace with a twin-shaft stirring blade and is an indirect heating method by heating an outer cylinder heat medium, and the dechlorination furnace treatment scale is 300 (kg / d) It is.
[0087]
In addition, the thing which did not perform the grinding | pulverization process and the water washing process of the solid substance 20 isolate | separated from the dechlorination furnace 17 was made into Comparative Examples 1-4.
These results are shown in Table 5.
[0088]
[Table 3]

[Table 4]

[Table 5]

[0089]
As shown in “Table 3” to “Table 5”, in this example, the residual Cl concentration was as extremely low as 0.08 to 0.21% by weight, but in the case of the comparative example, It was as high as 0.78% by weight or more, and this example made it possible to produce a solid fuel having a low residual chlorine concentration.
It has also been found that the dechlorination efficiency is greatly improved by performing the decompression treatment.
[0090]
[Example 9]
Dechlorination treatment was performed using CSD (car shredder dust) having the composition shown in Table 6 below as a raw material.
Here, the dechlorination furnace 17 used in this example is a rotary kiln type pyrolysis furnace (inner diameter 350 × length 4,100 (mm)), and operating conditions are a kiln inlet temperature of 420 ° C. and an outlet temperature of 330 ° C. C. The average residence time in the kiln was 26 min.
[0091]
[Table 6]

[0092]
According to this example, it was possible to produce a solid fuel having a solid fuel recovery rate of 73.5 (wt%) and a residual chlorine concentration of 0.21 (wt%).
Moreover, when the inner wall of the rotary kiln was observed, there was hardly any plastic fusion or coking on the wall surface.
[0093]
【The invention's effect】
  As explained above, the present invention[Claim 1]Dechlorinated fuel production equipmentAccording toA dechlorination furnace that thermally decomposes solid waste fuel (RDF) and dechlorinates, a separator that separates dechlorinated solids and pyrolysis gas, and refines the separated dechlorinated solids A pulverizer and a water washing tank for washing the pulverized dechlorinated solids with water to remove inorganic salts, and efficiently removing slurry-like fuel dechlorinated from waste solid fuel (RDF) containing chlorine Can be manufactured.
[0115]
  [Claims2According to claim1In the present invention, after the water washing step, there is a drying step for drying the dechlorinated solid after washing, and the dechlorinated solid fuel is obtained from the waste containing chlorine. Can be manufactured.
[0116]
  [Claims3According to claim1In the present invention, since the steam introduction means is provided in the dechlorination furnace, inorganic chlorination of chlorine in the dechlorination reaction can be prevented.
[0117]
  [Claims4According to claim1, A depressurization means for depressurizing the inside of the dechlorination furnace is provided, so that it reacts with metals contained in the waste of the decomposed HCl gas to suppress the by-production of chlorine inorganic compounds, and the HCl gas is discharged to the outside of the system. The diffusion rate can be increased.
[0118]
  [Claims5According to claim1The dechlorination furnace itself can be rotated or the inside of the furnace can be stirred, so that the dechlorination reaction can be performed efficiently.
[Brief description of the drawings]
FIG. 1 is a schematic view of a dechlorinated fuel production apparatus according to a first embodiment of the present invention.
FIG. 2 is a graph showing the weight reduction rate in the thermal decomposition of various plastics.
FIG. 3 is a graph showing the deHCl rate of PVC (polyvinyl chloride).
FIG. 4 is a schematic view of a dechlorinated fuel production apparatus according to a second embodiment of the present invention.
FIG. 5 is a schematic view of an apparatus for producing a dechlorinated fuel according to a third embodiment of the present invention.
FIG. 6 is a schematic view of a dechlorinated fuel production apparatus according to a fourth embodiment of the present invention.
FIG. 7 is a schematic view of a dechlorinated fuel production apparatus according to a fifth embodiment of the present invention.
[Explanation of symbols]
11 Waste
12 Crusher
13 Fine-grained waste
14 Preheater
15 Preheated refined waste
16 Steam introduction means
17 Dechlorination furnace
18 Decomposition product
19 exhaust gas
20 Dechlorinated solids
21 Separator
22 Crusher
23 Dechlorinated solids
24 Flush tank
25 Drainage
26 Slurry fuel
27 Secondary combustion furnace
28 Combustion gas
29 Exhaust gas treatment equipment
30 exhaust gas
31 Drainage
32 Wastewater treatment facility
41 Drying furnace
42 Dechlorinated solid fuel
43 heat exchanger
44 Steam generator
45 Heating gas
51 heat exchanger
52 Blower
53 Air
54 Heating gas
61 RDF (solid waste fuel)

Claims (5)

A dechlorination furnace that thermally decomposes solid waste fuel (RDF) and dechlorinates, a separator that separates dechlorinated solids and pyrolysis gas, and refines the separated dechlorinated solids A pulverizer and a rinsing tank for removing inorganic salts by washing the pulverized dechlorinated solids with water, and obtaining slurry-like dechlorinated fuel from chlorine-containing solid waste fuel (RDF) Equipment for producing dechlorinated fuel. In claim 1 ,
An apparatus for producing a dechlorinated fuel, comprising a drying step of drying the dechlorinated solid after the water washing step, and obtaining a dechlorinated solid fuel from a waste containing chlorine. In claim 1 ,
An apparatus for producing dechlorinated fuel, characterized in that a steam introduction means is provided in a dechlorination furnace. In claim 1 ,
An apparatus for producing a dechlorinated fuel, comprising a depressurizing means for depressurizing the inside of a dechlorination furnace. In claim 1 ,
An apparatus for producing a dechlorinated fuel, characterized in that the dechlorination furnace itself can be rotated or the inside of the furnace can be stirred.

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