JP2015067497A - Method for treating cement kiln extraction gas, and chlorine bypass system - Google Patents

Method for treating cement kiln extraction gas, and chlorine bypass system Download PDF

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JP2015067497A
JP2015067497A JP2013203429A JP2013203429A JP2015067497A JP 2015067497 A JP2015067497 A JP 2015067497A JP 2013203429 A JP2013203429 A JP 2013203429A JP 2013203429 A JP2013203429 A JP 2013203429A JP 2015067497 A JP2015067497 A JP 2015067497A
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cement kiln
extraction
extracted
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JP6153258B2 (en
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肇 和田
Hajime Wada
肇 和田
淳一 寺崎
Junichi Terasaki
淳一 寺崎
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Taiheiyo Cement Corp
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Abstract

PROBLEM TO BE SOLVED: To remove the sulfur content in chlorine bypass exhaust gas without increasing a heat loss in a cement firing device and to avoid jumboization of an extraction probe or a post-stage facility.SOLUTION: A part G1 of combustion gas is extracted from a kiln exhaust gas flow passage extended from a kiln tail of a cement kiln 2 to a lowermost-stage cyclone. The extracted gas is cooled to 600°C or lower by using air A1, A2 and a liquid (the liquid/a water mist M) as a cooling medium of the extracted gas. The dust in the cooled extracted gas G2 is recovered and discharged to the outside of the cement kiln. It does not matter if the liquid is sprayed in the air for cooling the extracted gas or the cooled air is introduced into the extracted gas. It is preferable that the liquid be sprayed in the extracted gas so that the moisture content in the extracted gas is adjusted within 2-30%.

Description

本発明は、塩素の除去を目的として、セメントキルンの窯尻から最下段サイクロンに至るまでのキルン排ガス流路より抽気した燃焼ガスを処理する方法及び塩素バイパスシステムに関する。   The present invention relates to a method and a chlorine bypass system for treating a combustion gas extracted from a kiln exhaust gas passage from a kiln bottom of a cement kiln to a lowermost cyclone for the purpose of removing chlorine.

近年、廃棄物のセメント原料化及び燃料化が推進されているが、廃棄物の処理量が増加するのに伴い、セメントキルンに持ち込まれる塩素等の揮発成分の量も増加している。そのため、セメント製造設備におけるプレヒータの閉塞等の問題を引き起こす原因になると共に、製品の品質に影響を与える塩素分を除去する塩素バイパスシステムが不可欠となっている。   In recent years, the use of waste as a raw material for cement and fuel has been promoted, but as the amount of waste processed increases, the amount of volatile components such as chlorine brought into the cement kiln also increases. For this reason, a chlorine bypass system that removes the chlorine component that causes problems such as blockage of the preheater in the cement manufacturing facility and affects the quality of the product is indispensable.

この塩素バイパスシステムは、図2に示すように、セメントキルン22の窯尻から最下段サイクロン(不図示)に至るまでのキルン排ガス流路より燃焼ガスの一部G21をプローブ23で抽気すると同時に、冷却ファン24からの冷風で抽気ガスG21を急冷し、サイクロン25で粗粉D21を分離した後の抽気ガスG23に含まれる、塩素が濃縮した微粉D22をバグフィルタ28で微粉D24として回収する。この微粉D24と、冷却器26から回収された微粉D23とを塩素バイパスダストD25として系外に排出し、効率よく塩素を除去する一方、バグフィルタ28の排ガスG24を排気ファン30によってセメントキルン22の排ガス系に戻す(特許文献1、2)。   As shown in FIG. 2, this chlorine bypass system bleeds part G21 of the combustion gas from the kiln exhaust gas flow path from the kiln bottom of the cement kiln 22 to the lowermost cyclone (not shown) with the probe 23, The extraction gas G21 is rapidly cooled by the cold air from the cooling fan 24, and the fine powder D22 enriched in chlorine contained in the extraction gas G23 after the coarse powder D21 is separated by the cyclone 25 is recovered as the fine powder D24 by the bag filter 28. The fine powder D24 and the fine powder D23 recovered from the cooler 26 are discharged out of the system as chlorine bypass dust D25, and chlorine is efficiently removed, while the exhaust gas G24 of the bag filter 28 is removed from the cement kiln 22 by the exhaust fan 30. Return to exhaust gas system (Patent Documents 1 and 2).

特開2000−354838号公報JP 2000-354838 A 特開2010−195660号公報JP 2010-195660 A

上述のように、塩素バイパスシステムの排ガス(以下「塩素バイパス排ガス」という。)は、セメントキルンの排ガス系に戻されるが、塩素バイパス排ガスに含まれる硫黄分を除去するため、プレヒータの800℃以上の高温部に150℃程度の塩素バイパス排ガスを戻すとセメント焼成装置での熱損失が増大する。一方、塩素バイパス排ガスをプレヒータの出口側に戻した場合は、排ガス中の硫黄分が増加して環境汚染を引き起こす虞がある。   As described above, the exhaust gas of the chlorine bypass system (hereinafter referred to as “chlorine bypass exhaust gas”) is returned to the cement kiln exhaust gas system, but in order to remove sulfur contained in the chlorine bypass exhaust gas, the preheater has a temperature of 800 ° C. or higher. When the chlorine bypass exhaust gas of about 150 ° C. is returned to the high temperature part, the heat loss in the cement baking apparatus increases. On the other hand, when the chlorine bypass exhaust gas is returned to the outlet side of the preheater, the sulfur content in the exhaust gas may increase and cause environmental pollution.

また、セメントキルン22に持ち込まれる塩素等の揮発成分の量が増加するのに伴い、抽気プローブや後段の設備が大型化する傾向にあった。そのため、設備の設置場所に制約が生じたり、メンテナンスのための作業量が増加するといった問題点が生じていた。   In addition, as the amount of volatile components such as chlorine brought into the cement kiln 22 increases, the extraction probe and the subsequent equipment tend to increase in size. For this reason, there are problems such as restrictions on the installation location of the equipment and an increase in the amount of work for maintenance.

そこで、本発明は、上記従来の技術における問題点に鑑みてなされたものであって、セメント焼成装置での熱損失の増大を招くことなく塩素バイパス排ガス中の硫黄分を除去すると共に、抽気プローブや後段の設備の大型化を回避することを目的とする。   Therefore, the present invention has been made in view of the above-described problems in the prior art, and removes the sulfur content in the chlorine bypass exhaust gas without causing an increase in heat loss in the cement baking apparatus, and the extraction probe. The purpose is to avoid the enlargement of the equipment in the latter stage.

上記目的を達成するため、本発明は、セメントキルン抽気ガスの処理方法であって、セメントキルンの窯尻から最下段サイクロンに至るまでのキルン排ガス流路より燃焼ガスの一部を抽気し、該抽気ガスの冷却媒体として空気及び液体を用いて該抽気ガスを600℃以下に冷却し、該冷却後の抽気ガス中のダストを回収して前記セメントキルンの系外へ排出することを特徴とする。   In order to achieve the above object, the present invention is a method for treating a cement kiln extraction gas, wherein a part of the combustion gas is extracted from a kiln exhaust gas passage from the bottom of the cement kiln to the bottom cyclone, The extraction gas is cooled to 600 ° C. or lower using air and liquid as a cooling medium for the extraction gas, and dust in the extracted extraction gas is recovered and discharged out of the cement kiln system. .

本発明によれば、抽気ガスの冷却媒体として空気に加えて液体を用いて抽気ガス中の水分を増加させることで、抽気ガス中のダストに含まれるカルシウム分と水とで生ずる消石灰の量を増加させることができる。これによって、セメント焼成装置での熱損失の増大を招くことなく、塩素バイパス排ガスの脱硫を行うことができる。   According to the present invention, the amount of slaked lime generated by the calcium and water contained in the dust in the extraction gas is increased by increasing the moisture in the extraction gas using a liquid in addition to air as a cooling medium for the extraction gas. Can be increased. Thereby, desulfurization of the chlorine bypass exhaust gas can be performed without increasing the heat loss in the cement baking apparatus.

また、空気のみで冷却する場合に比較して、冷却に用いられる液体の蒸発潜熱の分だけ抽気ガスを冷却した後のガス量が低下するため、抽気プローブや後段の設備の大型化を回避することもできる。   Also, compared to cooling with air alone, the amount of gas after cooling the extracted gas by the amount of latent heat of vaporization of the liquid used for cooling is reduced, so the size of the extraction probe and subsequent equipment is avoided. You can also.

前記抽気ガスを冷却する空気に液体を噴霧し、該冷却空気を前記抽気ガス中に導入することができる。これにより、簡易な装置を用いて冷却媒体としての液体を抽気ガス中に導入することができる。   Liquid can be sprayed onto the air that cools the extraction gas, and the cooling air can be introduced into the extraction gas. Thereby, the liquid as a cooling medium can be introduce | transduced in extraction gas using a simple apparatus.

前記冷却後の抽気ガス中の水分を2%以上30%以下に調整することができ、塩素バイパス排ガスの脱硫に必要な消石灰を該排ガス中に生じさせることができる。   The moisture in the extracted gas after cooling can be adjusted to 2% or more and 30% or less, and slaked lime necessary for desulfurization of the chlorine bypass exhaust gas can be generated in the exhaust gas.

前記抽気ガス中に噴霧する液体として廃液を用いることができ、廃液を処理しながらセメントキルン抽気ガスを処理することができる。   Waste liquid can be used as the liquid sprayed into the extraction gas, and the cement kiln extraction gas can be processed while processing the waste liquid.

前記冷却後の抽気ガスに消石灰を添加することができ、冷却媒体として用いた液体によって生じた消石灰の量が不足している場合に、これを補うことができる。   Slaked lime can be added to the extracted gas after cooling, and this can be compensated for when the amount of slaked lime generated by the liquid used as the cooling medium is insufficient.

また、本発明は、塩素バイパスシステムであって、セメントキルンの窯尻から最下段サイクロンに至るまでのキルン排ガス流路より燃焼ガスの一部を抽気し、該抽気ガスの冷却媒体として空気及び液体を用いて該抽気ガスを冷却する抽気装置と、該抽気装置で抽気及び冷却したガス中のダストを回収する集塵装置とを備えることを特徴とする。本発明によれば、セメント焼成装置での熱損失の増大を招くことなく、塩素バイパス排ガスの脱硫を行うことができると共に、抽気プローブや後段の設備の大型化を回避することができる。   Further, the present invention is a chlorine bypass system, in which a part of combustion gas is extracted from a kiln exhaust gas passage from a kiln bottom of a cement kiln to a lowermost cyclone, and air and liquid are used as a cooling medium for the extracted gas. And a dust collector for collecting dust in the gas extracted and cooled by the extraction device. According to the present invention, it is possible to desulfurize the chlorine bypass exhaust gas without causing an increase in heat loss in the cement baking apparatus, and it is possible to avoid an increase in the size of the extraction probe and the subsequent equipment.

以上のように、本発明によれば、セメント焼成装置での熱損失の増大を招くことなく塩素バイパス排ガス中の硫黄分を除去すると共に、抽気プローブや後段の設備の大型化を回避することができる。   As described above, according to the present invention, it is possible to remove the sulfur content in the chlorine bypass exhaust gas without causing an increase in heat loss in the cement baking apparatus, and to avoid an increase in the size of the extraction probe and the subsequent equipment. it can.

本発明に係る塩素バイパスシステムの一実施形態を示す全体構成図である。It is a whole lineblock diagram showing one embodiment of a chlorine bypass system concerning the present invention. 従来の塩素バイパスシステムの一例を示す全体構成図である。It is a whole block diagram which shows an example of the conventional chlorine bypass system.

図1は、本発明に係る塩素バイパスシステムの一実施形態を示し、この塩素バイパスシステム1は、セメントキルン2の窯尻から最下段サイクロンに至るまでのキルン排ガス流路より燃焼ガスの一部G1を冷却しながら抽気する抽気装置としてのプローブ3と、プローブ3から排出された抽気ガスG2から粗粉D1を分離するための分級機としてのサイクロン6と、サイクロン6から排出された微粉D2を含む抽気ガスG3を冷却する冷却器7と、冷却器7から排出された排ガスG4から微粉を回収するバグフィルタ8と、バグフィルタ8の排ガスG5を系外に排出する排気ファン9等で構成される。   FIG. 1 shows an embodiment of a chlorine bypass system according to the present invention. This chlorine bypass system 1 is a part of a combustion gas G1 from a kiln exhaust gas passage from a kiln bottom of a cement kiln 2 to a lowermost cyclone. A probe 3 for extracting air while cooling, a cyclone 6 as a classifier for separating the coarse powder D1 from the extracted gas G2 discharged from the probe 3, and a fine powder D2 discharged from the cyclone 6 A cooler 7 for cooling the extracted gas G3, a bag filter 8 for collecting fine powder from the exhaust gas G4 discharged from the cooler 7, an exhaust fan 9 for discharging the exhaust gas G5 of the bag filter 8 out of the system, and the like. .

プローブ3は、セメントキルン2の窯尻からセメントキルン2の排ガス流路の一部として上方へ向かう立上り部に突設され、抽気ガスG1を冷却するため1次冷却ファン4と2次冷却ファン5とが付設される。また、1次冷却ファン4からプローブ3に冷却媒体として供給する冷却空気A1がプローブ3に導入される前の配管に、液体・水ミストMを噴霧するための噴霧装置(不図示)が設けられる。2次冷却ファン5からの冷却空気にも、プローブ3に導入する前に液体・水ミストを噴霧してもよい。   The probe 3 protrudes upward from the kiln bottom of the cement kiln 2 as a part of the exhaust gas flow path of the cement kiln 2 and rises upward, and cools the extracted gas G1 with the primary cooling fan 4 and the secondary cooling fan 5. And are attached. Further, a spraying device (not shown) for spraying the liquid / water mist M is provided in the pipe before the cooling air A1 supplied as a cooling medium from the primary cooling fan 4 to the probe 3 is introduced into the probe 3. . Liquid / water mist may also be sprayed onto the cooling air from the secondary cooling fan 5 before being introduced into the probe 3.

サイクロン6、冷却器7、バグフィルタ8、排気ファン9は、図2に示した従来の塩素バイパスシステム21のサイクロン25、冷却器26、バグフィルタ28、排気ファン30と同様の構造を有する。   The cyclone 6, the cooler 7, the bag filter 8, and the exhaust fan 9 have the same structure as the cyclone 25, the cooler 26, the bag filter 28, and the exhaust fan 30 of the conventional chlorine bypass system 21 shown in FIG.

次に、上記構成を有する塩素バイパスシステム1の動作について、図1を参照しながら説明する。   Next, operation | movement of the chlorine bypass system 1 which has the said structure is demonstrated, referring FIG.

セメントキルン2の窯尻から最下段サイクロンに至るまでのキルン排ガス流路より燃焼ガスの一部G1をプローブ3で抽気すると同時に、800〜1100℃程度の抽気ガスG1を1次冷却ファン4からの冷却空気A1及び液体・水ミストM、及び2次冷却ファン5からの冷却空気A2でKCl等の塩素化合物の融点である600℃以下、好ましくは400℃以下にまで冷却する。これによって、抽気ガスG1中のKCl等の塩素化合物が析出して抽気ガスG2中の微粉の表面等に付着する。   A part of the combustion gas G1 is extracted by the probe 3 from the kiln exhaust gas flow path from the kiln bottom of the cement kiln 2 to the lowest cyclone, and at the same time, the extraction gas G1 of about 800 to 1100 ° C. is extracted from the primary cooling fan 4. The cooling air A1, the liquid / water mist M, and the cooling air A2 from the secondary cooling fan 5 are cooled to 600 ° C. or lower, preferably 400 ° C. or lower, which is the melting point of a chlorine compound such as KCl. As a result, a chlorine compound such as KCl in the extraction gas G1 is deposited and adheres to the surface of the fine powder in the extraction gas G2.

また、液体・水ミストMの添加により、以下に示すように、抽気ガスG1等のダストに含まれるカルシウム分と水とで消石灰が生成され、消石灰と抽気ガスG1等に含まれるSO2とが反応して石膏が生成され、抽気ガスG1等の脱硫が行われる。 Further, by adding the liquid / water mist M, as shown below, slaked lime is generated by the calcium content and water contained in the dust such as the extracted gas G1, and the SO 2 contained in the slaked lime and the extracted gas G1 and the like. Reacting produces gypsum and desulfurization of the extracted gas G1 and the like is performed.

SO2+Ca(OH)2→CaSO3・1/2H2O+1/2H2
CaSO3・1/2H2O+1/2O2+3/2H2O→CaSO4・2H2
次に、抽気ガスG2をサイクロン6に導入し、粗粉D1と、微粉D2を含む抽気ガスG3とに分離し、粗粉D1をセメントキルン2系に戻すと共に、上記反応式で示した反応の効率を考慮し、抽気ガスG3を冷却器7で100〜200℃、好ましくは140〜170℃、また抽気ガスG3の水分が2〜30%、好ましくは10〜15%となるように冷却する。
SO 2 + Ca (OH) 2 → CaSO 3 .1 / 2H 2 O + 1 / 2H 2 O
CaSO 3 · 1 / 2H 2 O + 1 / 2O 2 + 3 / 2H 2 O → CaSO 4 · 2H 2 O
Next, the extraction gas G2 is introduced into the cyclone 6 and separated into the coarse powder D1 and the extraction gas G3 containing the fine powder D2. The coarse powder D1 is returned to the cement kiln 2 system, and the reaction shown in the above reaction formula is performed. In consideration of efficiency, the extraction gas G3 is cooled by the cooler 7 so that the moisture of the extraction gas G3 is 2 to 30%, preferably 10 to 15%.

上記サイクロン6で分離された粗粉D1には、上記反応式によって生じた硫黄分も含まれているが、この硫黄分は粗粉D1と共にセメントキルン2に戻され、プレーヒータ等で脱硫されたり、セメントキルン2とサイクロン6との間を循環する。   The coarse powder D1 separated by the cyclone 6 also contains the sulfur content generated by the above reaction formula. This sulfur content is returned to the cement kiln 2 together with the coarse powder D1 and desulfurized by a preheater or the like. Circulate between the cement kiln 2 and the cyclone 6.

次に、冷却器7の排ガスG4をバグフィルタ8に導入して微粉D4を回収し、冷却器7から回収した微粉D3と共に塩素バイパスダストD5とする。バグフィルタ8の排ガスG5は、排気ファン9によって排ガスG6としてセメントキルン2の排ガス系に戻す。   Next, the exhaust gas G4 of the cooler 7 is introduced into the bag filter 8 to collect the fine powder D4, and together with the fine powder D3 collected from the cooler 7, the chlorine bypass dust D5 is obtained. The exhaust gas G5 of the bag filter 8 is returned to the exhaust gas system of the cement kiln 2 as exhaust gas G6 by the exhaust fan 9.

上記塩素バイパスダストD5には、析出した塩素化合物に加え、硫黄分(CaSO4・2H2O)が濃縮しているため、塩素バイパスダストD5をセメント粉砕工程でセメントクリンカと共に粉砕することで硫黄分を系外に除去することができる。また、塩素バイパスダストD5を水洗して塩素を除去した後、セメント原料等として利用した場合には、硫黄分を系外に除去することはできないが、排気ファン9の排ガスG6をプレヒータの高温部に戻す必要がなく、セメント焼成装置での熱損失の増大を回避することができる。 In the chlorine bypass dust D5, the sulfur content (CaSO 4 · 2H 2 O) is concentrated in addition to the precipitated chlorine compound. Can be removed out of the system. Further, when chlorine bypass dust D5 is washed with water to remove chlorine and then used as a cement raw material or the like, the sulfur content cannot be removed out of the system, but the exhaust gas G6 of the exhaust fan 9 is removed from the high temperature portion of the preheater. Therefore, it is possible to avoid an increase in heat loss in the cement baking apparatus.

また、1次冷却ファン4からの冷却空気A1に液体・水ミストMを添加して抽気ガスG1を冷却しているため、従来のように空気のみで冷却する場合に比較して、冷却に用いられる水の蒸発潜熱の分だけ抽気ガスG1を冷却した後のガス量が低下するため、抽気プローブ3や後段のサイクロン6等の設備の大型化を回避することもできる。   Further, since the extraction gas G1 is cooled by adding the liquid / water mist M to the cooling air A1 from the primary cooling fan 4, it is used for cooling as compared with the case where cooling is performed only with air as in the prior art. Since the amount of gas after cooling the extraction gas G1 is reduced by the amount of latent heat of vaporization of the generated water, it is possible to avoid an increase in the size of the extraction probe 3, the subsequent cyclone 6 and the like.

上記液体・水ミストMの添加により生じる消石灰に加え、排気ファン9の排ガスG6に補助的に消石灰粉末を噴霧してもよい。上記反応式で示した脱硫反応は、ガス中の相対湿度が高い方が効率よく行われるため、ガスの低温側に消石灰を添加することが効率的である。そこで、150℃程度の排ガスG6に消石灰粉末を噴霧し、上記反応により硫黄分が濃縮したダストを集塵して系外に除去することができる。また、上述のように排ガスG6をセメントキルン2の排気系に戻してもよい。尚、既に高温側で液体・水ミストMを添加して排ガスG6の相対湿度を高めているため、効率よく脱硫を行うことができる。   In addition to the slaked lime generated by the addition of the liquid / water mist M, the slaked lime powder may be sprayed auxiliary to the exhaust gas G6 of the exhaust fan 9. Since the desulfurization reaction shown in the above reaction formula is performed efficiently when the relative humidity in the gas is high, it is efficient to add slaked lime to the low temperature side of the gas. Therefore, slaked lime powder can be sprayed on the exhaust gas G6 at about 150 ° C., and the dust enriched in sulfur by the above reaction can be collected and removed out of the system. Further, the exhaust gas G6 may be returned to the exhaust system of the cement kiln 2 as described above. In addition, since the relative humidity of the exhaust gas G6 is already increased by adding the liquid / water mist M on the high temperature side, desulfurization can be performed efficiently.

尚、上述の理由により、また、塩素バイパスダストD5の回収量の増加を伴わないため、排気ファン9の排ガスG6に消石灰粉末を噴霧することが好ましいが、さらに上流側の排ガスG2、G3には消石灰スラリーを噴霧してもよい。   In addition, for the above-mentioned reasons, and because there is no increase in the recovery amount of the chlorine bypass dust D5, it is preferable to spray slaked lime powder on the exhaust gas G6 of the exhaust fan 9, but further upstream exhaust gases G2 and G3 Slaked lime slurry may be sprayed.

また、1次冷却ファン4からの冷却空気A1に噴霧する液体・水ミストMには、工業用水の他、石油精製における脱硫、植物油の生成によって排出される工場廃液や、有機物含有廃液、含油廃液等を用いてもよい。   The liquid / water mist M sprayed on the cooling air A1 from the primary cooling fan 4 includes industrial water, factory waste liquid discharged by petroleum refining, production of vegetable oil, organic substance-containing waste liquid, and oil-containing waste liquid. Etc. may be used.

1 塩素バイパスシステム
2 セメントキルン
3 プローブ
4 1次冷却ファン
5 2次冷却ファン
6 サイクロン
7 冷却器
8 バグフィルタ
9 排気ファン
1 Chlorine bypass system 2 Cement kiln 3 Probe 4 Primary cooling fan 5 Secondary cooling fan 6 Cyclone 7 Cooler 8 Bag filter 9 Exhaust fan

Claims (6)

セメントキルンの窯尻から最下段サイクロンに至るまでのキルン排ガス流路より燃焼ガスの一部を抽気し、該抽気ガスの冷却媒体として空気及び液体を用いて該抽気ガスを600℃以下に冷却し、該冷却後の抽気ガス中のダストを回収して前記セメントキルンの系外へ排出することを特徴とするセメントキルン抽気ガスの処理方法。   A part of the combustion gas is extracted from the kiln exhaust gas passage from the bottom of the kiln of the cement kiln to the lowermost cyclone, and the extracted gas is cooled to 600 ° C. or lower using air and liquid as a cooling medium for the extracted gas. A method for treating a cement kiln extraction gas, wherein dust in the extraction gas after cooling is collected and discharged out of the cement kiln system. 前記抽気ガスを冷却する空気に液体を噴霧し、該冷却空気を前記抽気ガス中に導入することを特徴とする請求項1に記載のセメントキルン抽気ガスの処理方法。   The method for treating a cement kiln extraction gas according to claim 1, wherein a liquid is sprayed on the air for cooling the extraction gas, and the cooling air is introduced into the extraction gas. 前記冷却後の抽気ガス中の水分を2%以上30%以下に調整することを特徴とする請求項1又は2に記載のセメントキルン抽気ガスの処理方法   The method for treating a cement kiln extraction gas according to claim 1 or 2, wherein moisture in the extraction gas after cooling is adjusted to 2% or more and 30% or less. 前記抽気ガス中に噴霧する液体として廃液を用いることを特徴とする請求項2又は3に記載のセメントキルン抽気ガスの処理方法。   The method for treating a cement kiln extraction gas according to claim 2 or 3, wherein a waste liquid is used as the liquid sprayed into the extraction gas. 前記冷却後の抽気ガスに消石灰を添加することを特徴とする請求項1乃至4のいずれかに記載のセメントキルン抽気ガスの処理方法。   The method for treating a cement kiln extraction gas according to any one of claims 1 to 4, wherein slaked lime is added to the extraction gas after cooling. セメントキルンの窯尻から最下段サイクロンに至るまでのキルン排ガス流路より燃焼ガスの一部を抽気し、該抽気ガスの冷却媒体として空気及び液体を用いて該抽気ガスを冷却する抽気装置と、
該抽気装置で抽気及び冷却したガス中のダストを回収する集塵装置とを備えることを特徴とする塩素バイパスシステム。
A bleeder for extracting a part of the combustion gas from the kiln exhaust gas flow path from the bottom of the kiln of the cement kiln to the lowermost cyclone, and cooling the bleed gas using air and liquid as a cooling medium for the bleed gas;
A chlorine bypass system comprising: a dust collecting device that collects dust in gas extracted and cooled by the extraction device.
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