JP2009293098A - Method for charging raw material into blast furnace - Google Patents

Method for charging raw material into blast furnace Download PDF

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JP2009293098A
JP2009293098A JP2008149718A JP2008149718A JP2009293098A JP 2009293098 A JP2009293098 A JP 2009293098A JP 2008149718 A JP2008149718 A JP 2008149718A JP 2008149718 A JP2008149718 A JP 2008149718A JP 2009293098 A JP2009293098 A JP 2009293098A
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raw material
coke
charging
blast furnace
furnace
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JP5217650B2 (en
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Naoyuki Takeuchi
直幸 竹内
Akinori Murao
明紀 村尾
Yasuhei Nouchi
泰平 野内
Michitaka Sato
道貴 佐藤
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JFE Steel Corp
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Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for charging a raw material of ores and coke from a top furnace bunker into a blast furnace while uniformly mixing them, by using a bell-less type charging apparatus. <P>SOLUTION: This charging method includes: cutting out each of the raw material 1 of ores and the coke 2 on a charging conveyer 13; transporting them to the furnace top bunker 14; and charging them into the blast furnace 10 through a slewing chute 16 of the bell-less type charging apparatus 15, with a successive tilting charging method. In the step, the method for cutting out the raw material 1 of the ores and the coke 2 includes cutting out the raw material 1 of the ores into a belt shape along a transporting direction thereof on the charging conveyer 13, and cutting out the coke 2 into a belt shape so as to be stacked on a downstream part in the transporting direction including a downstream end part A in the transporting direction out of the raw material 1 of the ores which have been cut out into the belt shape. A length of the coke 2 cut out into the belt shape in the transporting direction is controlled to 50% or shorter of a length of the raw material 1 of the ores cut out into the belt shape in the transporting direction. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

本発明は、鉄鉱石から銑鉄を製造する高炉にベルレス式装入装置を用いて焼結鉱,ペレット,塊鉱石等の鉱石類原料とコークスとを混合しつつ装入する方法に関する。   The present invention relates to a method of charging a blast furnace for producing pig iron from iron ore using a bell-less charging device while mixing ore raw materials such as sintered ore, pellets, and lump ore with coke.

高炉の生産性を増大させ、また使用する塊コークス量を低減するためには、鉱石類原料の粒径低下や還元性向上などによるガス利用効率の向上、周辺流量の適正化による熱バランス改善などが有効である。また、羽口からの微粉炭の吹込み量を増大させることによっても塊コークス比の低減が可能である。しかしながら、これらの操業時には高炉内の鉱石類原料とコークスとの存在比(以降はO/Cと記す) が大きくなり、高炉上部での通気性の悪化、融着帯の変形や肥大化による高炉下部の通気性の悪化等が引き起こされることが知られている。   In order to increase the productivity of the blast furnace and reduce the amount of coke used, improve the gas utilization efficiency by reducing the particle size of the ore raw materials and improving the reducibility, and improve the heat balance by optimizing the peripheral flow rate. Is effective. It is also possible to reduce the lump coke ratio by increasing the amount of pulverized coal blown from the tuyere. However, during these operations, the abundance ratio of ore materials and coke in the blast furnace (hereinafter referred to as O / C) increases, resulting in deterioration of air permeability at the top of the blast furnace, deformation of the cohesive zone, and enlargement of the blast furnace. It is known that the lowering of the air permeability of the lower part is caused.

また、低被還元性原料の使用比率を増加させた場合は、融着帯の肥大化やホールドアップの増加、未還元スラグの高炉下部への滴下などの問題が引き起こされる。
これらの問題の対策として、高炉内の鉱石類原料層中にコークスを混合する方法がある。これは、軟化融着帯において、混合したコークスがスペーサーとなって通気性が向上すること、還元中のFeO系の融液がコークスと接触して溶融還元されて還元特性が向上することなどを利用する技術である。
Moreover, when the use ratio of the low reducible raw material is increased, problems such as enlargement of the cohesive zone, increase in hold-up, and dripping of unreduced slag to the bottom of the blast furnace are caused.
As a countermeasure for these problems, there is a method in which coke is mixed in the ore raw material layer in the blast furnace. This is because, in the softened cohesive zone, the mixed coke serves as a spacer to improve air permeability, the FeO-based melt being reduced comes into contact with the coke, is melted and reduced, and the reduction characteristics are improved. The technology to use.

しかしながら、焼結鉱などの鉱石類原料とコークスとでは粒径や比重が異なるために、均一に混合することが非常に難しい。一般的に使用されるコークスは高炉で使用する塊コークスの篩下であり、その粒度は鉱石類原料よりも比較的粗い。さらに、両者を混合しても、原料槽やコンベア, 炉頂バンカーなど高炉炉頂の堆積面に至るまでのハンドリング中、あるいは高炉炉頂の堆積面で両者が分離してしまう。   However, since ore raw materials such as sintered ore and coke have different particle sizes and specific gravity, it is very difficult to uniformly mix them. Commonly used coke is under sieve of bulk coke used in a blast furnace, and its particle size is relatively coarser than ore raw materials. Furthermore, even if both are mixed, they are separated during handling up to the deposition surface of the blast furnace top, such as the raw material tank, conveyor, and furnace bunker, or at the deposition surface of the blast furnace top.

そのため、高炉内における装入物の半径方向のO/C分布が制御できず、また高炉中心に流れ込んだコークスが高炉下部の炉芯に入り込んでその空隙率を低下させるという問題がある。すなわち、実際の高炉操業においては混合層の分離によるコークスの高炉中心への流れ込みがもっとも大きな問題となっており、コークス混合率は工業的には質量比率で4%程度を上限とするに留まっている。このような混合層の分離を防止するため、従来から様々な技術が開発されている。なお、コークス混合率とは、装入する鉱石類原料の質量に対する比率であり、以降も同様の意味で用いる。   Therefore, there is a problem that the O / C distribution in the radial direction of the charge in the blast furnace cannot be controlled, and coke that has flowed into the center of the blast furnace enters the core of the lower part of the blast furnace and decreases its porosity. In other words, in actual blast furnace operation, coke flow into the center of the blast furnace due to separation of the mixed layer is the biggest problem, and the coke mixing ratio is limited to an upper limit of about 4% in terms of mass ratio industrially. Yes. In order to prevent such separation of the mixed layer, various techniques have been conventionally developed. In addition, a coke mixing rate is a ratio with respect to the mass of the ore raw material to charge, and is used by the same meaning hereafter.

特許文献1には、ベルレス式高炉の鉱石類原料にコークスを混合させる装入法が開示されている。すなわち、図8の(a)に示すように、複数個ある原料ホッパのうち下流側の数個にコークスを貯蔵し、上流側の原料ホッパから鉱石コンベア上に先に切り出した鉱石類原料の下流側に連続してコークスを切り出す方法が開示されている。そして、この方法によれば、鉱石類原料とコークスとが混合された混合原料が炉頂バンカーから高炉内へ排出される際に、混合原料中の鉱石類原料とコークスとの混合状況が均一になるとされている。   Patent Document 1 discloses a charging method in which coke is mixed with an ore raw material of a bell-less blast furnace. That is, as shown in FIG. 8 (a), coke is stored in several downstream hoppers out of a plurality of raw hoppers, and downstream of the ore raw materials previously cut out on the ore conveyor from the upstream raw hoppers. A method of cutting coke continuously to the side is disclosed. According to this method, when the mixed raw material in which the ore raw material and the coke are mixed is discharged from the furnace top bunker into the blast furnace, the mixing state of the ore raw material and the coke in the mixed raw material is uniform. It is supposed to be.

しかしながら、鉱石類原料よりも平均粒度の大きいコークスを使用する場合は、混合された鉱石類原料とコークスとは鉱石コンベア後のリザービングホッパ, 装入コンベア,及び炉頂バンカーを通過する際に、粒度差, 比重差に起因する偏析で分離する。特に、鉱石類原料の排出挙動がファンネルフローである炉頂バンカーにおいては、図8の(b)に示すように、鉱石類原料よりも平均粒度の大きいコークスが、堆積面でのパーコレーションにより炉頂バンカー内において初期に排出される領域と末期に排出される領域のみに偏析してしまい、中期に排出される領域にはコークスがほとんど存在しないと考えられる。それゆえ、炉頂バンカーから高炉内に順傾動で混合原料を装入する段階で、排出末期の混合原料中のコークス混合率が増加するため、混合されたコークスの大半が高炉中心部に偏析すると考えられる。   However, when using coke having a larger average particle size than the ore raw material, the mixed ore raw material and coke pass through the reserve hopper after the ore conveyor, the charging conveyor, and the furnace top bunker. Separation is caused by segregation due to particle size difference and specific gravity difference. In particular, in the furnace bunker where the discharge behavior of the ore raw material is funnel flow, as shown in FIG. 8 (b), coke having an average particle size larger than that of the ore raw material is caused by percolation on the deposition surface. In the bunker, segregation occurs only in the area discharged at the initial stage and the area discharged at the end stage, and it is considered that there is almost no coke in the area discharged in the middle period. Therefore, at the stage of charging the mixed raw material from the top bunker into the blast furnace with a forward tilt, the mixing ratio of coke in the mixed raw material at the end of discharge increases, so that most of the mixed coke segregates in the center of the blast furnace. Conceivable.

次に、特許文献2には、図9の(a)に示すように、鉱石コンベアではなく装入コンベアに先ずコークスを切り出して炉頂バンカーに装入し、引続き鉱石類原料を同じ炉頂バンカーに装入することにより、下部にコークス層、上部に鉱石類原料層と、所定割合で2層構造(図9の(b)を参照)を形成させ、この炉頂バンカーから旋回シュートを介して高炉内に装入する過程において鉱石類原料とコークスとを混合せしめる装入法が開示されている。   Next, in Patent Document 2, as shown in FIG. 9 (a), the coke is first cut out into the charging conveyor instead of the ore conveyor and charged into the furnace top bunker, and the ore raw material is continuously supplied to the same furnace top bunker. To form a two-layer structure (see FIG. 9 (b)) at a predetermined ratio with a coke layer at the bottom and an ore raw material layer at the top, and from this furnace top bunker through a turning chute A charging method in which ore raw materials and coke are mixed in the process of charging into a blast furnace is disclosed.

しかしながら、この方法では、炉頂バンカーから混合原料が排出される際に、炉頂バンカーの下部に集中しているコークスのみが初期に排出されてしまい、炉頂バンカーで鉱石類原料に混合されたコークスは、高炉の炉壁部のみに装入されると考えられる。
さらに、特許文献3には、特許文献2に開示の装入方法を2度繰り返す方法が開示されている。その結果、コークス−鉱石類原料−コークス−鉱石類原料と4 度に分割して炉頂バンカーに原料が装入されるため、図10に示すように4層構造が形成される。
However, in this method, when the mixed raw material is discharged from the top bunker, only the coke concentrated in the lower part of the top bunker is discharged in the initial stage, and is mixed with the ore raw material by the top bunker. It is thought that coke is charged only in the blast furnace wall.
Furthermore, Patent Document 3 discloses a method of repeating the charging method disclosed in Patent Document 2 twice. As a result, since the raw material is charged into the furnace top bunker by dividing the coke-ore raw material-coke-ore raw material into four degrees, a four-layer structure is formed as shown in FIG.

しかしながら、この方法は、炉頂バンカーから混合原料を高炉内に装入する段階で混合原料中のコークスが鉱石類原料に限りなく均一に混合し得るものの、リザービングホッパから装入コンベアへの切り出し回数が多いため、出銑量の低下に繋がるという問題を有していると考えられる。
これら特許文献1〜3の技術によれば、高炉炉頂の堆積面での鉱石類原料とコークスとの分離に影響を与えるが、鉱石類原料とコークスとの混合物である混合原料が旋回シュートに至るまでのベルトコンベアや炉頂バンカーでの堆積時の分離やそれによる偏在を抑制することはできない。そのため、目標のコークス混合率分布を実現することは難しい。
However, in this method, although the coke in the mixed raw material can be uniformly mixed with the ore raw material at the stage of charging the mixed raw material from the furnace bunker into the blast furnace, it is cut out from the reserve hopper to the charging conveyor. Since there are many times, it is thought that it has the problem of leading to the fall of the amount of tapping.
According to the techniques of these patent documents 1 to 3, the separation of the ore material and the coke on the deposition surface at the top of the blast furnace is affected, but the mixed material that is a mixture of the ore material and the coke is turned into the swivel chute. Separation at the time of deposition on a belt conveyor or furnace top bunker or uneven distribution due to this cannot be suppressed. Therefore, it is difficult to realize the target coke mixing ratio distribution.

一方、特許文献4には、ベル式, ベルレス式高炉原料として平均粒度1〜5mmの細粒の鉱石類原料を全量の1〜30%程度使用する際に、全鉱石類原料層の平均粒度16〜20mmと同範囲にある平均粒度3〜25mmの小塊コークスを混合することにより、細粒焼結使用による高炉内での通気悪化に起因する還元効率の低下を防止する方法が開示されている。
この方法は、比較的粒度の小さいコークスを鉱石類原料に混合することにより高炉内におけるコークスの偏析を抑制するものであり、還元効率の向上に効果を発揮すると考えられる。
On the other hand, in Patent Document 4, when a fine ore raw material having an average particle size of 1 to 5 mm is used as a bell-type or bell-less type blast furnace raw material, about 1 to 30% of the total amount, the average particle size 16 of the whole ore raw material layer is 16 A method for preventing reduction in reduction efficiency due to deterioration of aeration in a blast furnace due to the use of fine-grain sintering is disclosed by mixing small coke with an average particle size of 3 to 25 mm in the same range as ~ 20 mm. .
This method suppresses the segregation of coke in the blast furnace by mixing coke having a relatively small particle size with the ore raw material, and is considered to be effective in improving the reduction efficiency.

しかしながら、一般的に粒度の小さいコークスは塊コークスの篩下を使用し、塊コークスと同じライン上で製造していることから、粒度の小さいコークスを高炉の必要量確保するためには、節目調節による塊コークスの粒度の低下が生じるおそれがあるとともに、粉砕設備の新設, ライン増強といった大幅な設備工事を要する。
以上の理由などにより、鉱石類原料へのコークスの混合率を一定値以上に向上することは困難であった。
特開平3−211210号公報 特開平2−259005号公報 特開平2−250909号公報 特開平8−295907号公報
However, since coke with a small particle size is generally produced on the same line as the block coke, the coke with a small particle size is adjusted in order to secure the required amount of blast furnace for coke with a small particle size. This may cause a drop in the grain size of the coke breeze, and it will require significant equipment construction such as the establishment of a new crushing facility and line expansion.
For the reasons described above, it has been difficult to improve the mixing ratio of coke to the ore raw material to a certain value or more.
JP-A-3-211210 JP-A-2-259005 JP-A-2-250909 JP-A-8-295907

装入物の半径方向のO/C分布の制御が困難である理由としては、貯鉱槽や計量ホッパなどリザービングホッパの上流側で混合しても、炉頂バンカーに入るまでに混合状況が変化してしまうこと、炉頂バンカー内でも混合原料が山状に堆積するために粒径の大きな粒子が炉頂バンカーの壁際などに偏祈すること、などがあげられる。
そこで、本発明は、上記のような従来技術が有する問題点を解決し、ベルレス式装入装置を用いて、鉱石類原料とコークスとを均一に混合しつつ炉頂バンカーから高炉に装入する原料装入方法を提供することを課題とする。
The reason why it is difficult to control the O / C distribution in the radial direction of the charge is that even if mixing on the upstream side of the reserve hopper, such as a storage tank or weighing hopper, the mixing status is before the furnace bunker is entered. For example, the mixed raw material accumulates in a mountain shape in the furnace top bunker, so that particles having a large particle size pray to the wall of the furnace top bunker.
Therefore, the present invention solves the problems of the prior art as described above, and charges the blast furnace from the top bunker while uniformly mixing the ore raw material and the coke using a bell-less charging device. It is an object to provide a raw material charging method.

前記課題を解決するため、本発明は次のような構成からなる。すなわち、本発明に係る高炉への原料装入方法は、焼結鉱,ペレット,及び塊鉱石の少なくとも一つからなる鉱石類原料とコークスとをそれぞれ切り出して、装入コンベアで炉頂バンカーに搬送し、旋回シュートを旋回させつつ傾動させて高炉への装入物の装入を炉壁側から炉中心側へと順に行うベルレス式装入装置を用いて、前記炉頂バンカー内の前記鉱石類原料及び前記コークスを高炉に装入するに際して、前記鉱石類原料を前記装入コンベア上にその搬送方向に沿って帯状に切り出した上、帯状に切り出された前記鉱石類原料のうち搬送方向下流側端部を含む搬送方向下流側部分の上に前記コークスを積層するように帯状に切り出すとともに、帯状に切り出された前記コークスの搬送方向長さを、帯状に切り出された前記鉱石類原料の搬送方向長さの50%以下とすることを特徴とする。   In order to solve the above problems, the present invention has the following configuration. That is, in the raw material charging method to the blast furnace according to the present invention, the ore raw material and coke made of at least one of sintered ore, pellets, and lump ore are cut out and conveyed to the furnace top bunker by the charging conveyor. The ores in the top bunker using a bellless type charging device that tilts the swivel chute while swirling to sequentially charge the blast furnace from the furnace wall side to the furnace center side. When charging the raw material and the coke into a blast furnace, the ore raw material is cut into a strip shape along the transport direction on the charging conveyor, and the downstream side in the transport direction of the ore raw material cut into the strip shape Cut out in a strip shape so as to stack the coke on the downstream portion in the transport direction including the end, and the length in the transport direction of the coke cut out in the strip shape of the ore raw material cut out in the strip shape Characterized by a 50% length of the feed below.

本発明の高炉への原料装入方法は、ベルレス式装入装置を用いて鉱石類原料とコークスとを炉頂バンカーから高炉に装入するに際して、鉱石類原料とコークスとを均一に混合することができる。   The raw material charging method to the blast furnace of the present invention is to uniformly mix the ore raw material and coke when charging the ore raw material and coke into the blast furnace from the top bunker using a bell-less charging device. Can do.

本発明に係る高炉への原料装入方法の実施の形態を、図面を参照しながら詳細に説明する。図1は、本発明の高炉への原料装入方法の一実施形態を模式的に示す図である。
高炉10には、焼結鉱,ペレット,及び塊鉱石の少なくとも一つからなる鉱石類原料1を貯蔵する鉱石類原料ホッパ11と、コークス2を貯蔵するコークスホッパ12と、鉱石類原料ホッパ11及びコークスホッパ12から切り出された鉱石類原料1及びコークス2(以降においては、鉱石類原料1及びコークス2を合わせて原料と記すこともある)を炉頂へ搬送する装入コンベア13と、搬送された原料を一時貯蔵する1個以上の炉頂バンカー14(図1には2個の例が示してある)と、炉頂バンカー14から排出された原料を高炉10に装入するベルレス式装入装置15と、が備えられている。
An embodiment of a raw material charging method to a blast furnace according to the present invention will be described in detail with reference to the drawings. FIG. 1 is a diagram schematically showing an embodiment of a method for charging a raw material into a blast furnace according to the present invention.
The blast furnace 10 includes an ore raw material hopper 11 for storing an ore raw material 1 made of at least one of sintered ore, pellets, and lump ore, a coke hopper 12 for storing coke 2, an ore raw material hopper 11 and The ore raw material 1 and the coke 2 cut out from the coke hopper 12 (hereinafter, the ore raw material 1 and the coke 2 may be collectively referred to as raw materials) and a charging conveyor 13 for conveying to the furnace top are conveyed. One or more top bunker 14 (two examples are shown in FIG. 1) for temporarily storing the raw material, and a bell-less type charging for charging the blast furnace 10 with the raw material discharged from the top bunker 14 And a device 15.

鉱石類原料ホッパ11及びコークスホッパ12から装入コンベア13上に切り出された鉱石類原料1及びコークス2は、装入コンベア13により高炉10の炉頂に搬送され、レシービングシュート20を介して炉頂バンカー14に搬入される。そして、炉頂バンカー14から流量調整ゲート21により所定の流量に調整されて排出された原料は、集合ホッパ22を介してベルレス式装入装置15に送られ、ベルレス式装入装置15の旋回シュート16により高炉10内に装入される。   The ore raw material 1 and the coke 2 cut out from the ore raw material hopper 11 and the coke hopper 12 onto the charging conveyor 13 are conveyed to the furnace top of the blast furnace 10 by the charging conveyor 13, and passed through the receiving chute 20. It is carried into the bunker 14. Then, the raw material discharged from the furnace top bunker 14 after being adjusted to a predetermined flow rate by the flow rate adjusting gate 21 is sent to the bellless charging device 15 via the collecting hopper 22, and the turning chute of the bellless charging device 15 is sent. 16 is charged into the blast furnace 10.

この旋回シュート16は、図1中の矢印に示すように、高炉10の中心軸を中心に旋回すると同時に高炉10の炉壁側から炉中心側へ向かって傾動するようになっているので、炉頂バンカー14から排出された原料は、炉壁側から炉中心側へと順に装入を行う順傾動装入方式で装入される。
このような原料の高炉10への装入においては、鉱石類原料ホッパ11及びコークスホッパ12からの鉱石類原料1及びコークス2の切り出しは、以下のようにして行う。まず、鉱石類原料1を鉱石類原料ホッパ11から装入コンベア13上に排出し、装入コンベア13の搬送方向に沿う帯状に切り出す。次に、コークス2をコークスホッパ12から排出して前記搬送方向に沿う帯状に切り出すが、その際には、先に帯状に切り出された鉱石類原料1の上に積層する。
As indicated by the arrow in FIG. 1, the turning chute 16 turns around the central axis of the blast furnace 10 and simultaneously tilts from the furnace wall side of the blast furnace 10 toward the furnace center side. The raw material discharged from the top bunker 14 is charged by a forward tilt charging method in which charging is performed in order from the furnace wall side to the furnace center side.
In charging the raw material into the blast furnace 10, the ore raw material 1 and the coke 2 are cut out from the ore raw material hopper 11 and the coke hopper 12 as follows. First, the ore raw material 1 is discharged from the ore raw material hopper 11 onto the charging conveyor 13, and is cut into a strip shape along the conveying direction of the charging conveyor 13. Next, the coke 2 is discharged from the coke hopper 12 and cut into a strip shape along the transport direction. In this case, the coke 2 is laminated on the ore raw material 1 previously cut into a strip shape.

帯状に切り出された鉱石類原料1のうちコークス2が積層されているのは、搬送方向下流側端部AからB点までの搬送方向下流側部分であり、帯状に切り出されたコークス2の搬送方向長さは、帯状に切り出された鉱石類原料1の搬送方向長さの50%以下である。つまり、搬送方向下流側端部AからB点までの搬送方向長さは、帯状に切り出された鉱石類原料1の搬送方向長さの50%以下である。   Of the ore raw material 1 cut into a strip shape, the coke 2 is laminated at the downstream portion in the transport direction from the downstream end A to the point B in the transport direction, and the transport of the coke 2 cut into a strip shape. The length in the direction is 50% or less of the length in the conveyance direction of the ore raw material 1 cut out in a band shape. That is, the conveyance direction length from the conveyance direction downstream end A to the point B is 50% or less of the conveyance direction length of the ore raw material 1 cut out in a band shape.

このように切り出した鉱石類原料1及びコークス2を炉頂バンカー14に搬送し、ベルレス式装入装置15を用いて順傾動装入方式で高炉10に装入すると、高炉10内においては鉱石類原料1とコークス2とが均一に混合されているとともに、高炉10内における原料の半径方向のO/C分布(コークス混合率分布)が均一に制御される。その結果、ガス利用効率の向上や通気改善がなされるため、安定で高性能な高炉操業を図ることが可能である。なお、上記のような鉱石類原料1とコークス2との均一な混合及び半径方向のO/C分布の均一な制御という効果を十分に得るためには、帯状に切り出されたコークス2の搬送方向長さは、帯状に切り出された鉱石類原料1の搬送方向長さの1%以上とすることが好ましい。   When the ore raw material 1 and the coke 2 cut out in this way are conveyed to the furnace top bunker 14 and charged into the blast furnace 10 by the forward tilt charging method using the bell-less charging device 15, the ores are in the blast furnace 10. The raw material 1 and the coke 2 are uniformly mixed, and the O / C distribution (coke mixing ratio distribution) in the radial direction of the raw material in the blast furnace 10 is uniformly controlled. As a result, gas utilization efficiency is improved and ventilation is improved, so that stable and high-performance blast furnace operation can be achieved. In order to sufficiently obtain the effects of uniform mixing of the ore raw material 1 and the coke 2 and uniform control of the O / C distribution in the radial direction as described above, the conveying direction of the coke 2 cut into a strip shape is obtained. The length is preferably 1% or more of the length in the transport direction of the ore raw material 1 cut out in a strip shape.

〔実施例1〕
図1の高炉10と同様の構成を有する高炉模型(実高炉の1/17のサイズ)を用いて、高炉への原料の装入実験を行った。
まず、炉頂バンカーから排出された原料のコークス混合率の調査を、以下のようにして行った。ベルレス式装入装置から旋回シュートを取り外し、トップリングの下部にベルトコンベアを設置した。このベルトコンベア上に多数のサンプリングボックスを搬送方向に沿って並べ、炉頂バンカーから次々に排出される原料が、ベルトコンベアにより送られるサンプリングボックスに順次装入されるようにした(図2を参照)。そして、サンプリングボックスに採取された原料を、各サンプリングボックス毎にヨウ化ナトリウム水溶液を用いて比重分離して、鉱石類原料と小中塊コークスとに分け、それぞれについて粒度毎に分級して質量を計測した。
[Example 1]
Using a blast furnace model (1/17 the size of the actual blast furnace) having the same configuration as that of the blast furnace 10 in FIG. 1, a raw material charging experiment was conducted.
First, the coke mixing ratio of the raw material discharged from the furnace top bunker was investigated as follows. The swivel chute was removed from the bellless charging device, and a belt conveyor was installed under the top ring. A large number of sampling boxes are arranged on the belt conveyor along the conveying direction so that raw materials discharged one after another from the furnace top bunker are sequentially charged into the sampling boxes sent by the belt conveyor (see FIG. 2). ). The raw material collected in the sampling box is separated into specific gravity using a sodium iodide aqueous solution for each sampling box, divided into ore raw materials and small and medium-sized coke, and each is classified according to particle size to determine the mass. Measured.

また、高炉への原料の装入実験は、想定した実験条件に基づいて所定の装入量などを決定して行った。例えば、鉱石類原料とコークスとを各バッチに分割して装入する場合は、それぞれの装入量を模型の縮尺比率によって粒径分布毎に決め、ホッパからの排出速度を相似条件に応じて決定した。また、旋回シュートの傾動角パターンや旋回速度は、パターンに応じて自動的に変化させるように制御した。   In addition, the raw material charging experiment into the blast furnace was performed by determining a predetermined charging amount based on the assumed experimental conditions. For example, when ore materials and coke are charged in batches, the amount of each charge is determined for each particle size distribution according to the scale ratio of the model, and the discharge rate from the hopper is determined according to the similarity conditions. Were determined. Further, the tilt angle pattern and the turning speed of the turning chute were controlled so as to automatically change according to the pattern.

原料の落下運動は、慣性力と重力との比であるフルード数を実機と一致させ、また、原料堆積時の条件については、内部摩擦力と重力との比、ガス抗力と重力との比をそれぞれ一致させた。装入中、各バッチ毎にレーザー式プロフィール計を用いて炉頂の堆積形状を測定した。1サイクルの実験前後の堆積形状が一致するまで(前回の装入時の最終堆積形状と今回の最終堆積形状とが一致するまで) 、装入を行った。装入の終了後、炉頂の堆積面上の径方向に沿って直径30mm,高さ150mmの円筒管を差し込んで、上部から吸い込んで原料を採取した。採取した原料は比重分離し、鉱石類原料とコークスそれぞれについて粒度分析を行った。   The falling motion of the raw material matches the Froude number, which is the ratio of inertial force and gravity, with the actual machine, and the conditions at the time of material deposition are the ratio of internal friction force to gravity and the ratio of gas drag to gravity. Each was matched. During charging, the deposition shape at the top of the furnace was measured for each batch using a laser profile meter. The charging was performed until the deposition shapes before and after the one-cycle experiment were matched (until the final deposition shape at the previous charging and the final deposition shape were matched). After the completion of charging, a cylindrical tube having a diameter of 30 mm and a height of 150 mm was inserted along the radial direction on the deposition surface at the top of the furnace, and the raw material was collected by sucking from the top. The collected raw materials were separated by specific gravity, and the particle size analysis was performed for each of the ore raw materials and the coke.

装入諸元は、コークス比は370kg/t、1チャージ当りの塊コークス量は14.8t、鉱石類原料は88.14tとし、鉱石類原料は4.1tのコークスを混合して2回に分割して装入した。
本発明者らは、上記の高炉模型を用いて、鉱石類原料及びコークスの装入方法と原料のコークス混合率との関係を調査した。その結果、少なくとも2つ以上の炉頂バンカーを有するベルレス式装入装置を用いるとともに、鉱石類原料とコークスの混合方法を、装入コンベアに切り出した鉱石類原料の上にコークスを積層させる方法とし、先立って切り出した鉱石類原料のうち搬送方向下流側端部を含む搬送方向下流側部分の上に長さを調節しつつコークスを積層すれば、炉頂バンカー下部のコークス混合率を変化させ、炉頂バンカーからの原料の排出時のコークス混合率の経時変化を制御できることを見出した。
The charging specifications are as follows: coke ratio is 370 kg / t, lump coke amount per charge is 14.8 t, ore raw material is 88.14 t, ore raw material is mixed with 4.1 t coke twice. Divided and charged.
The present inventors investigated the relationship between the ore raw material and coke charging method and the raw material coke mixing ratio using the above blast furnace model. As a result, while using a bell-less charging device having at least two furnace top bunker, the mixing method of ore material and coke is a method of laminating coke on ore material cut out on the charging conveyor. If the coke is laminated while adjusting the length of the ore raw material cut out in advance in the conveyance direction downstream portion including the downstream end portion in the conveyance direction, the coke mixing ratio at the bottom of the top bunker is changed, It was found that the change with time of the coke mixing ratio at the time of discharging the raw material from the furnace top bunker can be controlled.

ベルレスパラレルタイプの炉頂バンカーの排出挙動は、図3に示すようにファンネルフローであり、炉頂バンカー内に装入された原料は、その位置によって排出される順序が異なる。ここで、本発明におけるコークスを装入コンベア上で混合する方法において、鉱石類原料の上に積層するコークスの切り出し長さを図4に示すように変化させる調査を行った。また、その結果として、炉頂バンカーから排出された原料のコークス混合率を、図5のグラフに示す。   The discharge behavior of the bellless parallel type furnace top bunker is a funnel flow as shown in FIG. 3, and the order in which the raw materials charged in the furnace top bunker are discharged differs depending on their positions. Here, in the method of mixing the coke in the present invention on the charging conveyor, an investigation was conducted to change the cut length of the coke laminated on the ore raw material as shown in FIG. As a result, the coke mixing ratio of the raw material discharged from the furnace top bunker is shown in the graph of FIG.

図5のグラフの横軸は、炉頂バンカー内に装入された原料に対する炉頂バンカーから排出された原料の質量割合であり、グラフの左側が排出初期を意味し、右側が排出末期を意味する。また、縦軸は、排出された原料のコークス混合率を示す。ここで、コークス混合率は、作業過程での外乱の影響を少なくするため、全質量で規格化した無次元の値を示している。よって、平均のコークス混合率は1となり、これが目標値となる。   The horizontal axis of the graph in FIG. 5 is the mass ratio of the raw material discharged from the top bunker to the raw material charged in the top bunker, the left side of the graph means the initial stage of discharge, and the right side means the end stage of discharge. To do. The vertical axis represents the coke mixing ratio of the discharged raw material. Here, the coke mixing ratio is a dimensionless value normalized by the total mass in order to reduce the influence of disturbance in the work process. Therefore, the average coke mixing ratio is 1, which is the target value.

図5から分かるように、原料のコークス混合率は、何れの切り出し方法であっても、排出末期に大幅に増加する傾向が見られた。積層するコークスの切り出し長さを変化させた結果、積層長さが短くなるほど排出末期のコークス混合率の増加が抑制され、その分排出中期のコークス混合率が増加して平均値に近づいた。しかし、条件4のように鉱石類原料に先立ってコークスを炉頂バンカーに装入した場合は(特許文献2と同条件)、炉頂バンカーから排出された原料のコークス混合率が排出初期に高くなっていた。
これらの結果から、条件2や条件3のように、積層する帯状のコークスの長さを鉱石類原料の長さの50%以下とすると、炉頂バンカーから排出された原料の排出末期におけるコークス混合率の増加の抑制に効果を発揮することが明らかとなった。
As can be seen from FIG. 5, the coke mixing ratio of the raw material tended to increase significantly at the end of discharge, regardless of the cutting method. As a result of changing the cut length of the coke to be stacked, the increase in the coke mixing rate at the end of discharge was suppressed as the stacking length became shorter, and the coke mixing rate in the middle discharge was correspondingly increased and approached the average value. However, when coke is charged into the furnace bunker prior to the ore raw material as in Condition 4 (the same condition as Patent Document 2), the coke mixing ratio of the raw material discharged from the furnace bunker is high at the initial stage of discharge. It was.
From these results, if the length of the strip-shaped coke to be stacked is 50% or less of the length of the ore raw material as in Condition 2 and Condition 3, the coke mixing at the end of discharge of the raw material discharged from the furnace bunker It became clear that it was effective in suppressing the increase in rate.

次に、原料の切り出しを図4の条件1と条件3で行った場合において、高炉内に装入された原料のコークス混合率の半径方向分布を図6に示す。図6のグラフの横軸は、高炉中心からの半径方向距離rを炉口半径Rにて規格化したr/Rを示し、縦軸は原料のコークス混合率を示す。高炉内でのコークス混合率の調査においては、前述した手法により、炉中心側から炉壁側まで堆積面8点のサンプリングを行った。   Next, FIG. 6 shows the radial distribution of the coke mixing ratio of the raw material charged in the blast furnace when the raw material is cut out under conditions 1 and 3 in FIG. The horizontal axis of the graph of FIG. 6 indicates r / R in which the radial distance r from the blast furnace center is normalized by the furnace port radius R, and the vertical axis indicates the coke mixing ratio of the raw material. In the investigation of the coke mixing ratio in the blast furnace, 8 points of deposition surfaces were sampled from the furnace center side to the furnace wall side by the method described above.

切り出し方法を図4の条件1とした場合は、コークスは炉頂バンカーから排出された際に既に鉱石類原料と分離し、旋回シュートで炉中心部に原料を装入している排出末期に多量に排出されるため、高炉内においても中心部に偏析している。一方、条件3の場合は、排出末期におけるコークスの偏祈が抑制されているため、高炉内においても炉中心部への偏析が抑制されていた。また、コークスの炉中心部への偏析が抑制されている分、高炉の半径方向でいう中間部に当る領域のコークス混合率が増加していた。   When the cutting method is Condition 1 in FIG. 4, the coke is already separated from the ore raw material when discharged from the furnace bunker, and a large amount is discharged at the end of discharge when the raw material is charged into the center of the furnace with a turning chute. Therefore, it is segregated in the center even in the blast furnace. On the other hand, in the case of condition 3, segregation of the coke at the end of discharge was suppressed, so segregation to the center of the furnace was suppressed even in the blast furnace. In addition, since the segregation of coke to the furnace center is suppressed, the coke mixing ratio in the region corresponding to the intermediate part in the radial direction of the blast furnace is increased.

以上のように、本発明の高炉への原料装入方法を用いれば、炉頂バンカーからの排出時の原料のコークス混合率が制御でき、高炉内の鉱石類原料とコークスとが均一に混合した状態となるので、コークスの炉中心部への流れ込みによるガス流阻害や炉芯空隙率の低下などの悪影響を招くことがなく、原料の還元性の向上、ガス利用効率の向上、還元剤比の低減、高炉内通気性の向上などの効果が期待できる。   As described above, if the raw material charging method to the blast furnace of the present invention is used, the coke mixing ratio of the raw material at the time of discharge from the top bunker can be controlled, and the ore raw material and the coke in the blast furnace are uniformly mixed. Therefore, there is no adverse effect such as inhibition of gas flow due to inflow of coke into the center of the furnace or a decrease in the core porosity of the coke, improving the reducibility of the raw material, improving the gas utilization efficiency, reducing the reducing agent ratio. Effects such as reduction and improvement of air permeability in the blast furnace can be expected.

〔実施例2〕
本発明の効果を確認するため、実機高炉を用いて試験を行った。実機試験に用いた高炉は、内容積が2828m3 の中型高炉である。本試験では、鉱石類原料ホッパから鉱石類原料を装入コンベア上に先立って帯状に切り出し、その搬送方向下流側に設置されたコークスホッパからコークス60kg/thmを鉱石類原料の上に帯状に切り出して積層した。コークスは、帯状の鉱石類原料の搬送方向下流側端部を含む搬送方向下流側部分の上に積層し、積層する帯状のコークスの長さを鉱石類原料の長さの25%とした
[Example 2]
In order to confirm the effect of the present invention, a test was conducted using an actual blast furnace. The blast furnace used for the actual machine test is a medium-sized blast furnace with an internal volume of 2828 m 3 . In this test, the ore raw material is cut out from the ore raw material hopper in a strip form on the charging conveyor, and 60 kg / thm of coke is cut out from the ore raw material in a strip form from the coke hopper installed downstream in the conveying direction. And laminated. The coke is laminated on the downstream portion in the conveyance direction including the end portion on the downstream side in the conveyance direction of the strip-shaped ore raw material, and the length of the laminated strip-like coke is 25% of the length of the ore raw material.

炉頂バンカー内に装入された原料を、ベルレス式装入装置の旋回シュートを通じて高炉内に装入し、炉頂ガスをサンプリングすることによりガス利用効率ηCOの変化を調査した。結果を図7のグラフに示す。
図7のグラフから分かるように、上記のような本発明の原料装入方法によれば、従来の原料装入方法(切り出し方法を前述の条件1と同様に行うもの)よりもガス利用効率ηCOが向上している。これは、従来の原料装入方法では炉中心部にコークスが多量に偏析していたのに対し、本発明の原料装入方法では原料中のコークスの混合状況が改善されたことにより、ソリューションロス反応で発生するCOガスを効率的に鉱石の還元反応に利用することができたためであると考えられる。
The raw materials were charged into the furnace top in the bunker, was charged into the blast furnace through the swivel chute bell-less ShikiSo inserting apparatus to examine variation in the gas utilization efficiency eta CO by sampling the top gas. The results are shown in the graph of FIG.
As can be seen from the graph of FIG. 7, according to the raw material charging method of the present invention as described above, the gas utilization efficiency η is higher than that of the conventional raw material charging method (the cutting method is performed in the same manner as the above-mentioned condition 1). CO is improving. This is because, in the conventional raw material charging method, a large amount of coke was segregated in the center of the furnace, whereas in the raw material charging method of the present invention, the mixing situation of coke in the raw material was improved, resulting in a solution loss. This is probably because the CO gas generated by the reaction could be efficiently used for the reduction reaction of the ore.

以上の結果により、本発明の原料装入方法を用いて高炉操業を行えば、ガス利用効率の向上による還元剤比低下と通気改善による安定操業が図れることが確認された。   From the above results, it was confirmed that if the blast furnace operation was performed using the raw material charging method of the present invention, a reduction in the reducing agent ratio due to an improvement in gas utilization efficiency and a stable operation due to aeration improvement could be achieved.

本発明の高炉への原料装入方法の一実施形態を模式的に示す図である。It is a figure which shows typically one Embodiment of the raw material charging method to the blast furnace of this invention. 炉頂バンカーから排出される原料のサンプリング方法を説明する図である。It is a figure explaining the sampling method of the raw material discharged | emitted from a furnace top bunker. ベルレスパラレルタイプの炉頂バンカーの排出挙動を示す図である。It is a figure which shows the discharge | emission behavior of a bell-less parallel type furnace top bunker. 切り出し方法の条件を説明する図である。It is a figure explaining the conditions of a cutting-out method. 炉頂バンカーから排出された原料のコークス混合率を示すグラフである。It is a graph which shows the coke mixing rate of the raw material discharged | emitted from the furnace top bunker. 高炉内に装入された原料のコークス混合率の半径方向分布を示すグラフである。It is a graph which shows the radial direction distribution of the coke mixing rate of the raw material charged into the blast furnace. ガス利用効率ηCOの変化を調査した結果を示すグラフである。It is a graph which shows the result of having investigated the change of gas utilization efficiency (eta) CO . 従来の原料装入方法を説明する図である。It is a figure explaining the conventional raw material charging method. 別の従来の原料装入方法を説明する図である。It is a figure explaining another conventional raw material charging method. さらに別の従来の原料装入方法を説明する図である。It is a figure explaining another conventional raw material charging method.

符号の説明Explanation of symbols

1 鉱石類原料
2 コークス
10 高炉
11 鉱石類原料ホッパ
12 コークスホッパ
13 装入コンベア
14 炉頂バンカー
15 ベルレス式装入装置
16 旋回シュート
A 搬送方向下流側端部
DESCRIPTION OF SYMBOLS 1 Ore raw material 2 Coke 10 Blast furnace 11 Ore raw material hopper 12 Coke hopper 13 Loading conveyor 14 Furnace top bunker 15 Bellless type charging device 16 Turning chute A A downstream end part of conveyance direction

Claims (1)

焼結鉱,ペレット,及び塊鉱石の少なくとも一つからなる鉱石類原料とコークスとをそれぞれ切り出して、装入コンベアで炉頂バンカーに搬送し、旋回シュートを旋回させつつ傾動させて高炉への装入物の装入を炉壁側から炉中心側へと順に行うベルレス式装入装置を用いて、前記炉頂バンカー内の前記鉱石類原料及び前記コークスを高炉に装入するに際して、
前記鉱石類原料を前記装入コンベア上にその搬送方向に沿って帯状に切り出した上、帯状に切り出された前記鉱石類原料のうち搬送方向下流側端部を含む搬送方向下流側部分の上に前記コークスを積層するように帯状に切り出すとともに、帯状に切り出された前記コークスの搬送方向長さを、帯状に切り出された前記鉱石類原料の搬送方向長さの50%以下とすることを特徴とする高炉への原料装入方法。
Ore materials and coke made of at least one of sintered ore, pellets, and massive ore are cut out and conveyed to the furnace top bunker by a charging conveyor, and the swiveling chute is swung and tilted while being loaded into the blast furnace. When charging the ore raw material and the coke in the furnace top bunker into a blast furnace using a bell-less charging device that sequentially performs charging from the furnace wall side to the furnace center side,
The ore raw material is cut into a strip shape along the transport direction on the charging conveyor, and on the downstream portion in the transport direction including the downstream end portion in the transport direction of the ore raw material cut out in the strip shape. The coke is cut into a strip shape so as to be laminated, and the length of the coke that has been cut into a strip shape is 50% or less of the length of the ore raw material that has been cut into a strip shape. Raw material charging method to blast furnace.
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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2010133008A (en) * 2008-10-31 2010-06-17 Jfe Steel Corp Method for charging raw material into bell-less blast furnace

Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH03211210A (en) * 1990-01-16 1991-09-17 Kawasaki Steel Corp Method for charging raw material in bell-less blast furnace
JP2002003910A (en) * 2000-06-23 2002-01-09 Nippon Steel Corp Method for operating blast furnace
JP2005133170A (en) * 2003-10-31 2005-05-26 Jfe Steel Kk Method for discharging raw material for blast furnace and method for operating blast furnace

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH03211210A (en) * 1990-01-16 1991-09-17 Kawasaki Steel Corp Method for charging raw material in bell-less blast furnace
JP2002003910A (en) * 2000-06-23 2002-01-09 Nippon Steel Corp Method for operating blast furnace
JP2005133170A (en) * 2003-10-31 2005-05-26 Jfe Steel Kk Method for discharging raw material for blast furnace and method for operating blast furnace

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2010133008A (en) * 2008-10-31 2010-06-17 Jfe Steel Corp Method for charging raw material into bell-less blast furnace

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