JP3568351B2 - Restart method of plasma melting furnace - Google Patents

Restart method of plasma melting furnace Download PDF

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Publication number
JP3568351B2
JP3568351B2 JP05970597A JP5970597A JP3568351B2 JP 3568351 B2 JP3568351 B2 JP 3568351B2 JP 05970597 A JP05970597 A JP 05970597A JP 5970597 A JP5970597 A JP 5970597A JP 3568351 B2 JP3568351 B2 JP 3568351B2
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Prior art keywords
plasma
torch
base metal
furnace
granular carbon
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JPH10253266A (en
Inventor
善利 関口
邦夫 佐々木
和範 中村
詞郎 坂田
浩史 小坂
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Hitachi Zosen Corp
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Hitachi Zosen Corp
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  • Gasification And Melting Of Waste (AREA)
  • Vertical, Hearth, Or Arc Furnaces (AREA)
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Description

【0001】
【発明の属する技術分野】
本発明は、ごみ焼却炉から排出される焼却灰や建設廃材などの固体廃棄物を無害加、減容化を目的として加熱溶融するプラズマ式溶融炉における再起動方法に関する。
【0002】
【従来の技術】
従来のツイントーチ式あるいは3本以上のプラズマトーチを有するプラズマ式溶融炉は、炉本体の底部にベースメタルを収容し、炉本体の天壁部に複数のプラズマトーチをベースメタルに接近自在に垂下し、ベースメタルとプラズマトーチの間にプラズマアークを発生させることにより、ベースメタル上に投入される焼却灰や廃棄物を加熱溶融し、溶融スラグをオーバーフローさせて冷却水槽に投入し、水砕スラグを形成することにより焼却灰や廃棄物の無害加、減容化を図っている。
【0003】
【発明が解決しようとする課題】
このプラズマ式溶融炉の立ち上げ(起動)は、炉本体の底部にベースメタルとなる鉄片を投入し、この鉄片とプラズマトーチとの間にプラズマアークを発生されて加熱溶融しベースメタルを形成した後、灰や廃棄物を投入している。
【0004】
しかし、運転停止後のベースメタルおよび溶融スラグは炉本体が冷えることにより凝固し、凝固したベースメタル上に固化スラグ層が形成される。このスラグは溶融状態では導電性を有するが、固化すると導電性が無くなる。そのため、再立ち上げ(再起動)を行う際に、プラズマアークの形成ができず、再起動が困難となるという問題があった。
【0005】
本発明は、上記問題点を解決して、残留固化したスラグ層があっても容易に再起動可能なプラズマ式溶融炉の再起動方法を提供することを目的とする。
【0006】
【課題を解決するための手段】
上記目的を達成するために本発明は、炉底部にベースメタルを収容するとともに、炉天部から陰極トーチと陽極トーチからなる複数のプラズマトーチがベースメタルに接近して垂下され、ベースメタルとプラズマトーチとの間でプラズマアークを発生させてベースメタル上に投入された灰や廃棄物を加熱溶融しスラグを生成するプラズマ式溶融炉を停止後に再起動するに際し、ベースメタル上で固化したスラグ層上の陰極トーチと陽極トーチの間に、前記陰極トーチと陽極トーチの電極間距離L(m)に対して、10×L(kg)以上で30×L(kg)以下の粒状カーボンを投入した後、プラズマトーチに電圧を印加してプラズマアークを形成するものである。
【0007】
上記構成によれば、固化スラグ層上に投入した粒状カーボンにより導電性のある粒状カーボン層を形成し、プラズマトーチと粒状カーボン層との間にプラズマアークを容易に安定して形成することができ、このプラズマアークにより固化スラグ層およびベースメタルを再溶融してプラズマアアークを安定して継続させることができ、溶融炉の再起動を確実に行うことができる。また粒状カーボンとすることで、安価で運転コストも小さく、炉内への投入や取り扱いも容易で、また運転に及ぼす影響も小さい。さらに粒状カーボンの投入量を、陰極トーチと陽極トーチの電極間の距離L(m)に対して、10×L(kg)以上で30×L(kg)以下とすることにより、起動時のプラズマアークの途切れや断続状態もなくなり、また投入された粒状カーボンが炉内に残留する量をわずかにすることができる。
【0012】
【発明の実施の形態】
ここで、本発明に係るプラズマ式灰溶融炉の実施の形態を図1〜図3に基づいて説明する。
【0013】
図1,図2に示すように、架台1上には、支持ピン2aを中心に傾動シリンダ2bにより傾動可能なベースメタル排出用傾動装置2を介して炉本体3が配設されている。この炉本体3の底壁部3aには、ベースメタル4を収容するメタル収容部5が形成されている。また。炉本体3の傾動シリンダ2b側の前壁部3bには、炉本体3のベースメタル4上に焼却灰Aを投入する灰供給口6が形成され、この灰供給口6の入口に臨んで灰供給ホッパ7と灰プッシャー8とが設けられている。また炉本体3の支持ピン2a側の後壁部3cには、ベースメタル4上で溶融された溶融スラグFSを排出するスラグ排出通路9が形成され、スラグ排出通路9下部に溶融スラグFSを水冷して水砕スラグWSを生成するスラグ冷却装置11が配設されている。12はスラグ排出通路9の入口に設けられた排出堰9aに対向して配置された予熱バーナである。
【0014】
炉本体3の上部は水冷ジャケット13で覆われると共に、天壁部3dにたとえば2個のトーチ挿入口14A,14Bが前後方向に所定距離離れて形成され、灰供給口6側のトーチ挿入口14Aにプラズマトーチである陽極トーチ15Aが、スラグ排出通路9側のトーチ挿入口14Bにプラズマトーチである陰極トーチ15Bが垂下されている。これら両プラズマトーチ15A,15Bには安価なカーボン電極が使用され、下端部の消耗に対応して下降させベースメタル4または溶融スラグFSとの距離を所定に保持するトーチ昇降装置16にそれぞれ支持されている。さらに両プラズマトーチ15A,15Bには直流電源装置17が接続されるとともに、作動ガス供給装置18が接続され、両プラズマトーチ15A,15B内を通して炉本体3内に作動ガス(たとえば窒素ガス)を供給するように構成されている。19は一方の側壁部3eに形成された排ガス口で、排ガス処理装置に接続される。
【0015】
また炉本体3の天壁部3dには、再起動時に固化したスラグ層CS上に粒状カーボンCを投入する導電体供給装置21が配設されている。この導電体供給装置21は、側壁部3e寄りでトーチ挿入口14A,14Bの間にプラズマトーチ15A,15Bの下端中央部に向くように傾斜して貫設された導電体供給ノズル21aと、この導電体供給ノズル21aの上端部に投入バルブ21bを介して配設された導電粒体ホッパー21cとで構成される。
【0016】
上記構成において、炉の運転を停止した後、再起動する場合、凝固ベースメタル4上に溶融スラグが固化して固化スラグ層CSが形成されており、トーチ昇降装置16によりプラズマトーチ15A,15Bをそれぞれ少し上昇させた後、導電体供給装置21の投入バルブ21bを開けて炉本体1内に粒状カーボンCを所定量投入し、プラズマトーチ15A,15B間の固化スラグ層CS上に堆積させて粒状カーボン層Cを形成する。そして作動ガス供給装置18からプラズマトーチ15A,15Bを介して炉本体3内に作動ガスを供給するとともに、直流電源装置17からプラズマトーチ15A,15Bに起動電圧を印加して粒状カーボン層Cとプラズマトーチ15A,15Bの間にプラズマアークを発生させ、この熱により固化スラグ層CSを加熱溶融させさらにベースメタル4を溶融させる。
【0017】
上記再起動における粒状カーボンの適正使用量は、上記灰溶融炉を使用して実験した結果、粒状カーボンCの投入量とカーボン残量の関係(図3に示す)が明瞭となった。このグラフの縦軸には、再起動10時間後の炉本体3内のカーボンの残留量が示され、横軸には、電極間距離Lの1m当りの粒状カーボンの投入量が示されている。ここで投入量が少ない3kg/mのa点では、プラズマアークが発生せず、点火できなかった。また投入量6kg/mのb点では、プラズマアークは発生するが不安定で断続し、途中でプラズマアークが消失した。投入量10kg/mのc点および投入量17kg/mのd点では、プラズマアークが良好に発生して再起動がスムーズに行えた。さらに投入量33kg/mのe点では、プラズマアークが良好に発生して再起動がスムーズに行えたが、再起動10時間後にカーボンの残留物が固形物の状態で投入量の約10%程度あるのが確認された。さらにまたf点では、再起動がスムーズであるが、10時間後のカーボン残留量が固形物の状態で投入量の約75%程度あるのが確認された。
【0018】
したがって、粒状カーボンCの投入量は、電極間距離1m当り10〜30kgが適正量であり、この範囲ではプラズマアークが良好に発生して再起動がスムーズに行える。しかし、粒状カーボンCの投入量が10kg未満では、プラズマアークが不安定でプラズマアークが消失しやすい。また、粒状カーボンCの投入量が30kg以上になると、粒状カーボンCがプラズマトーチ15A,15B間ばかりでなく炉全体に広がり、理由はよく分からないが、再起動した時にスラグ層が溶融してもカーボンが溶融せずに溶融スラグ層上部に粒状カーボン層ができ、その上に投入された灰がこのカーボン層に載って溶融しない現象が発生するためである。さらに粒状カーボンCの投入量が65kgを越えると、炉本体3内に固形物の状態で残留するカーボン量が著しく増大する。
【0019】
上記実施の形態によれば、導電性のない固化スラグ層CS上に所定量の粒状カーボンCを投入して導電性のある粒状カーボン層Cを形成し、プラズマトーチ15A,15Bとこの粒状カーボン層Cとの間にプラズマアークを形成するので、プラズマアークを容易に安定して形成することができ、この熱によりその周囲の固化スラグ層CSおよび凝固ベースメタル4を溶融してさらに導電性を改善し、再起動を確実に行うことができる。
【0021】
【発明の効果】
以上に述べたごとく本発明によれば、固化スラグ層上に投入した粒状カーボンにより導電性のある粒状カーボン層を形成し、プラズマトーチと粒状カーボン層との間にプラズマアークを容易に安定して形成することができ、このプラズマアークにより固化スラグ層およびベースメタルを再溶融してプラズマアアークを安定して継続させることができ、溶融炉の再起動を確実に行うことができる。また粒状カーボンとすることで、安価で運転コストも小さく、炉内への投入や取り扱いも容易で、また運転に及ぼす影響も小さい。さらに粒状カーボンの投入量を、陰極トーチと陽極トーチの電極間の距離L(m)に対して、10×L(kg)以上で30×L(kg)以下とすることにより、起動時のプラズマアークの途切れや断続状態もなくなり、また投入された粒状カーボンが炉内に残留する量をわずかにすることができる。
【図面の簡単な説明】
【図1】本発明に係る灰溶融炉の実施の形態を示す縦断面図である。
【図2】図1に示すI−I断面図である。
【図3】粒状カーボン投入量と10時間後のカーボン残留量を示すグラフである。
【符号の説明】
3 炉本体
3d 天壁部
4 ベースメタル
6 灰供給口
9 スラグ排出通路
14A,14B トーチ挿入口
15A プラズマトーチ(陽極トーチ)
15B プラズマトーチ(陰極トーチ)
16 トーチ昇降装置
21 導電体供給装置
21a 導電体供給ノズル
21b 投入バルブ
21c 導電粒体ホッパ
A 灰
FS 溶融スラグ
CS 固化スラグ層
C 粒状カーボン(粒状カーボン層)[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a restart method in a plasma melting furnace for heating and melting solid waste such as incineration ash and construction waste discharged from a refuse incinerator for the purpose of harmless and volume reduction.
[0002]
[Prior art]
A conventional twin torch type or a plasma type melting furnace having three or more plasma torches accommodates a base metal at the bottom of the furnace body, and a plurality of plasma torches hang down on the top wall of the furnace body so as to be accessible to the base metal. Then, by generating a plasma arc between the base metal and the plasma torch, the incineration ash and waste put on the base metal are heated and melted, and the molten slag overflows and is put into the cooling water tank, where the granulated slag is poured. Harmless and reduced volume of incinerated ash and waste.
[0003]
[Problems to be solved by the invention]
When the plasma melting furnace was started (started), an iron piece serving as a base metal was put into the bottom of the furnace body, a plasma arc was generated between the iron piece and a plasma torch, and the base metal was formed by heating and melting. After that, ash and waste are put in.
[0004]
However, the base metal and the molten slag after the operation is stopped are solidified by cooling the furnace body, and a solidified slag layer is formed on the solidified base metal. The slag has conductivity in a molten state, but loses conductivity when solidified. Therefore, when restarting (restarting), there is a problem that a plasma arc cannot be formed and restarting becomes difficult.
[0005]
An object of the present invention is to solve the above problems and to provide a method for restarting a plasma-type melting furnace that can be easily restarted even if there is a residual solidified slag layer.
[0006]
[Means for Solving the Problems]
In order to achieve the above object, the present invention provides a method of accommodating a base metal in a furnace bottom, and a plurality of plasma torches including a cathode torch and an anode torch approaching the base metal from the furnace top, and suspending the base metal and the plasma. A slag layer solidified on the base metal when the plasma melting furnace, which generates a slag by heating and melting ash and waste put on the base metal by generating a plasma arc between the torch and restarting, Granular carbon of 10 × L (kg) or more and 30 × L (kg) or less with respect to the distance L (m) between the electrodes of the cathode torch and the anode torch was charged between the upper cathode torch and the anode torch . Thereafter, a voltage is applied to the plasma torch to form a plasma arc.
[0007]
According to the above configuration, the particulate carbon was charged onto the solidified slag layer to form a granular carbon layer having conductivity, a plasma arc easily and stably can be formed between the plasma torch and the particulate carbon layer In addition, the solidified slag layer and the base metal can be re-melted by the plasma arc, and the plasma arc can be stably continued, and the restart of the melting furnace can be reliably performed. In addition, the use of granular carbon is inexpensive, has low operating costs, is easy to put into and handle in a furnace, and has a small effect on operation. Further, by setting the amount of granular carbon to be not less than 10 × L (kg) and not more than 30 × L (kg) with respect to the distance L (m) between the electrodes of the cathode torch and the anode torch, There is no interruption or discontinuity of the arc, and the amount of the charged granular carbon remaining in the furnace can be reduced.
[0012]
BEST MODE FOR CARRYING OUT THE INVENTION
Here, an embodiment of a plasma type ash melting furnace according to the present invention will be described with reference to FIGS.
[0013]
As shown in FIGS. 1 and 2, a furnace main body 3 is disposed on a gantry 1 via a tilting device 2 for discharging a base metal, which can be tilted about a support pin 2a by a tilting cylinder 2b. A metal housing 5 for housing the base metal 4 is formed on the bottom wall 3 a of the furnace main body 3. Also. An ash supply port 6 for charging incineration ash A on the base metal 4 of the furnace body 3 is formed in the front wall 3b of the furnace body 3 on the side of the tilt cylinder 2b. A supply hopper 7 and an ash pusher 8 are provided. A slag discharge passage 9 for discharging the molten slag FS melted on the base metal 4 is formed in the rear wall portion 3c of the furnace main body 3 on the support pin 2a side, and the molten slag FS is water-cooled below the slag discharge passage 9. A slag cooling device 11 for generating granulated slag WS is provided. Reference numeral 12 denotes a preheating burner arranged opposite to a discharge weir 9a provided at the entrance of the slag discharge passage 9.
[0014]
The upper part of the furnace body 3 is covered with a water-cooling jacket 13 and, for example, two torch insertion ports 14A and 14B are formed on the top wall 3d at a predetermined distance in the front-rear direction, and the torch insertion port 14A on the ash supply port 6 side. An anode torch 15A, which is a plasma torch, and a cathode torch 15B, which is a plasma torch, are suspended from a torch insertion port 14B on the slag discharge passage 9 side. Inexpensive carbon electrodes are used for both of the plasma torches 15A and 15B, and are supported by a torch elevating device 16 which is lowered in accordance with the consumption of the lower end and kept at a predetermined distance from the base metal 4 or the molten slag FS. ing. Further, a DC power supply device 17 is connected to both plasma torches 15A and 15B, and a working gas supply device 18 is connected to supply working gas (for example, nitrogen gas) into furnace body 3 through both plasma torches 15A and 15B. It is configured to Reference numeral 19 denotes an exhaust gas port formed on one side wall 3e, which is connected to an exhaust gas treatment device.
[0015]
Further, on the top wall 3d of the furnace main body 3, a conductor supply device 21 for supplying the granular carbon C onto the solidified slag layer CS at the time of restart is provided. The conductive material supply device 21 includes a conductive material supply nozzle 21a that is inclined and penetrated between the torch insertion ports 14A and 14B toward the center of the lower end of the plasma torches 15A and 15B near the side wall 3e. A conductive particle hopper 21c is provided at the upper end of the conductive material supply nozzle 21a via a charging valve 21b.
[0016]
In the above configuration, when the furnace is stopped and then restarted, the molten slag is solidified on the solidified base metal 4 to form a solidified slag layer CS, and the plasma torches 15A and 15B are moved by the torch elevating device 16. After slightly raising each, the charging valve 21b of the conductor supply device 21 is opened, a predetermined amount of granular carbon C is charged into the furnace main body 1, and the granular carbon C is deposited on the solidified slag layer CS between the plasma torches 15A and 15B. The carbon layer C is formed. A working gas is supplied from the working gas supply device 18 into the furnace body 3 via the plasma torches 15A and 15B, and a starting voltage is applied to the plasma torches 15A and 15B from the DC power supply device 17 so that the granular carbon layer C A plasma arc is generated between the torches 15A and 15B, and the solidified slag layer CS is heated and melted by this heat, and the base metal 4 is melted.
[0017]
As for the appropriate amount of granular carbon used in the restart, an experiment was performed using the ash melting furnace, and as a result, the relationship between the amount of the granular carbon C charged and the remaining amount of carbon (shown in FIG. 3) became clear. The vertical axis of this graph shows the residual amount of carbon in the furnace main body 10 hours after the restart, and the horizontal axis shows the amount of granular carbon injected per meter of the distance L between the electrodes. . Here, at the point a of 3 kg / m where the input amount was small, no plasma arc was generated and ignition was not possible. Further, at the point b where the input amount was 6 kg / m, a plasma arc was generated but was unstable and interrupted, and the plasma arc disappeared halfway. At a point c where the input amount was 10 kg / m and a point d where the input amount was 17 kg / m, the plasma arc was favorably generated and the restart was smoothly performed. Further, at the point e of the charged amount of 33 kg / m, the plasma arc was generated favorably and the restart could be performed smoothly. However, after 10 hours of the restart, the carbon residue remained in a solid state and was about 10% of the charged amount. It was confirmed that there was. Furthermore, at the point f, the restart was smooth, but it was confirmed that the residual carbon amount after 10 hours was about 75% of the charged amount in a solid state.
[0018]
Therefore, the appropriate amount of the granular carbon C is 10 to 30 kg per 1 m of the distance between the electrodes. In this range, a plasma arc is generated favorably and restart can be performed smoothly. However, when the input amount of the granular carbon C is less than 10 kg, the plasma arc is unstable and the plasma arc is likely to disappear. When the amount of the granular carbon C is 30 kg or more, the granular carbon C spreads not only between the plasma torches 15A and 15B but also throughout the furnace, and the reason is not clear. This is because a granular carbon layer is formed on the upper part of the molten slag layer without melting the carbon, and a phenomenon occurs in which the ash charged thereon does not melt on the carbon layer. If the amount of the granular carbon C exceeds 65 kg, the amount of carbon remaining in the furnace main body 3 in the form of solids increases significantly.
[0019]
According to the above embodiment, a predetermined amount of granular carbon C is charged on the non-conductive solidified slag layer CS to form the conductive granular carbon layer C, and the plasma torches 15A and 15B and the granular carbon layers Since a plasma arc is formed between the solidified slag layer C and the solidified base metal 4, the plasma arc can be easily and stably formed. Then, the restart can be reliably performed.
[0021]
【The invention's effect】
According to the as mentioned present invention above, the particulate carbon was placed on the solidified slag layer to form a granular carbon layer having conductivity, and a plasma arc easily and stably between the plasma torch and the particulate carbon layer The solidified slag layer and the base metal can be re-melted by the plasma arc to stably continue the plasma arc, and the melting furnace can be reliably restarted. In addition, the use of granular carbon is inexpensive, has low operating costs, is easy to put into and handle in a furnace, and has a small effect on operation. Further, by setting the amount of granular carbon to be not less than 10 × L (kg) and not more than 30 × L (kg) with respect to the distance L (m) between the electrodes of the cathode torch and the anode torch, There is no interruption or discontinuity of the arc, and the amount of the charged granular carbon remaining in the furnace can be reduced.
[Brief description of the drawings]
FIG. 1 is a longitudinal sectional view showing an embodiment of an ash melting furnace according to the present invention.
FIG. 2 is a sectional view taken along the line II shown in FIG.
FIG. 3 is a graph showing the amount of granular carbon charged and the amount of residual carbon after 10 hours.
[Explanation of symbols]
3 Furnace body 3d Top wall 4 Base metal 6 Ash supply port 9 Slag discharge passages 14A, 14B Torch insertion port 15A Plasma torch (anode torch)
15B Plasma torch (cathode torch)
16 Torch elevating device 21 Conductor supply device 21a Conductor supply nozzle 21b Supply valve 21c Conductive granule hopper A Ash FS Melted slag CS Solidified slag layer C Granular carbon (granular carbon layer)

Claims (1)

炉底部にベースメタルを収容するとともに、炉天部から陰極トーチと陽極トーチからなる複数のプラズマトーチがベースメタルに接近して垂下され、ベースメタルとプラズマトーチとの間でプラズマアークを発生させてベースメタル上に投入された灰や廃棄物を加熱溶融しスラグを生成するプラズマ式溶融炉を停止後に再起動するに際し、
ベースメタル上で固化したスラグ層上の陰極トーチと陽極トーチの間に、前記陰極トーチと陽極トーチの電極間距離L(m)に対して、10×L(kg)以上で30×L(kg)以下の粒状カーボンを投入した後、プラズマトーチに電圧を印加してプラズマアークを形成することを特徴とするプラズマ式溶融炉の再起動方法。Along with storing the base metal in the furnace bottom, a plurality of plasma torches consisting of a cathode torch and an anode torch are hung from the furnace top to approach the base metal, generating a plasma arc between the base metal and the plasma torch. When restarting after stopping the plasma melting furnace that generates slag by heating and melting ash and waste put on the base metal,
Between the cathode torch and the anode torch on the slag layer solidified on the base metal, the distance between the electrodes of the cathode torch and the anode torch L (m) is 10 × L (kg) or more and 30 × L (kg). A) a method of restarting a plasma-type melting furnace, characterized in that after the following granular carbon is charged, a voltage is applied to a plasma torch to form a plasma arc.
JP05970597A 1997-03-14 1997-03-14 Restart method of plasma melting furnace Expired - Lifetime JP3568351B2 (en)

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JP4095774B2 (en) * 2001-01-22 2008-06-04 三菱重工業株式会社 How to restart the plasma ash melting furnace
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