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JP4329906B2 - Method and system for removing chlorine compounds contained in bottom ash - Google Patents
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JP4329906B2 - Method and system for removing chlorine compounds contained in bottom ash - Google Patents

Method and system for removing chlorine compounds contained in bottom ash Download PDF

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JP4329906B2
JP4329906B2 JP2005027093A JP2005027093A JP4329906B2 JP 4329906 B2 JP4329906 B2 JP 4329906B2 JP 2005027093 A JP2005027093 A JP 2005027093A JP 2005027093 A JP2005027093 A JP 2005027093A JP 4329906 B2 JP4329906 B2 JP 4329906B2
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濬▲教▼ 鄭
廷憙 張
▲教▼誠 李
昇勳 ▲呉▼
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
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Description

本発明は焼却炉から排出される底灰を再利用するため、塩素化合物を含む底灰から塩素化合物を除去する方法及びシステムに関し、特に塩素化合物を含む底灰を溶解水と混合し、前記底灰内の塩素化合物を溶解水に溶出させた後、塩素化合物が溶出した溶解水を底灰から分離することによって底灰から塩素化合物を除去する方法及びシステムに関する。   The present invention relates to a method and system for removing chlorine compounds from bottom ash containing chlorine compounds in order to reuse bottom ash discharged from an incinerator, and in particular, mixing bottom ash containing chlorine compounds with dissolved water, The present invention relates to a method and a system for removing chlorine compounds from bottom ash by eluting chlorine compounds in ash into dissolved water and then separating the dissolved water from which chlorine compounds are eluted from bottom ash.

生活廃棄物の焼却によって生じる底灰は、焼却場の排出部位に応じて焼却炉から排出される底灰と燃焼ガス中に含まれる粉じんなどの飛灰とに分けられる。このうち、底灰は平均水分含量基準で焼却廃棄物の10重量%乃至15重量%、飛灰は1乃至1.5重量%の割合で生じ、生活廃棄物の増加によって焼却で生じる底灰の量も増加する趨勢にあり、底灰を再利用しようとする努力が多角的になされている。   The bottom ash generated by incineration of domestic waste is divided into bottom ash discharged from the incinerator and fly ash such as dust contained in the combustion gas according to the discharge site of the incinerator. Of these, bottom ash is 10% to 15% by weight of incineration waste on the basis of average moisture content, fly ash is 1 to 1.5% by weight, and bottom ash generated by incineration due to an increase in domestic waste. The amount is increasing, and efforts to recycle bottom ash are made in many ways.

特に、最近、発ガン物質として知られるダイオキシンの濃度などで問題になっている飛灰とは異なり、底灰は重金属とダイオキシンの含有量が少なく、再利用化に適している。実際に、底灰は駐車場、自転車道路建設、道路建設における粒子性下層包装材として使用され、堤防、防音及び防音壁などにも使用されている。オランダの場合、1995年に建設物質に対する規定を制定して底灰の90%以上を道路堤防の盛土材、道路基層材として使用しており、特に、雨水浸透を最小化するために積極的に用いている。   In particular, unlike fly ash, which has recently become a problem due to the concentration of dioxin known as a carcinogen, bottom ash has a low content of heavy metals and dioxins and is suitable for reuse. Actually, bottom ash is used as a particulate lower layer packaging material in parking lots, bicycle road construction, road construction, and also used for embankments, soundproofing and soundproofing walls. In the case of the Netherlands, regulations on construction materials were established in 1995, and more than 90% of bottom ash is used as embankment material and road base material for road embankments, especially in order to minimize rainwater infiltration. Used.

しかし底灰には焼却廃棄物の種類に応じて差はあるが、塩素成分が1乃至3重量%含まれており、底灰を一部再利用するのに障害となる。例えば、底灰をセメント原料として再利用する場合、底灰の成分がセメントと同一でなければならないが、表1に見られるように塩素の組成が大きく異なり、再利用が不可能である。   However, there is a difference in the bottom ash depending on the type of incineration waste, but it contains 1 to 3% by weight of the chlorine component, which is an obstacle to partially reusing the bottom ash. For example, when bottom ash is reused as a raw material for cement, the components of bottom ash must be the same as cement. However, as shown in Table 1, the composition of chlorine is greatly different and reuse is impossible.

Figure 0004329906
Figure 0004329906

従って、底灰から塩素成分を除去し、適正塩素イオン濃度である1,000mg/Kg以下に処理する必要がある。このために、一部の処理企業では底灰を野積した後、上部から水を撒水する方法を採用しているが、処理用量が限定され、効率が低くて経済性が落ち、環境的にも問題点を有しているのが実情である。   Therefore, it is necessary to remove the chlorine component from the bottom ash and treat it to an appropriate chlorine ion concentration of 1,000 mg / Kg or less. For this reason, some processing companies have adopted a method in which bottom ash is piled up and then watered from the top, but the treatment dose is limited, the efficiency is low, the economy is low, and the environment is also low. The fact is that there is a problem.

本発明は前記した問題点を解決するために案出されたものであって、本発明の目的は底灰内に含まれる塩素成分を効率的に除去する方法とシステムを提供することである。   The present invention has been devised to solve the above-mentioned problems, and an object of the present invention is to provide a method and system for efficiently removing chlorine components contained in bottom ash.

本発明による底灰に含まれる塩素化合物の除去方法は、塩素化合物を含む底灰を溶解水と混合し、前記底灰内の塩素化合物を脱離させて溶解水に溶解させる溶出段階及び塩素化合物が溶解した溶解水を底灰から分離する固液分離段階を含むことを特徴とする。   The method for removing chlorine compounds contained in bottom ash according to the present invention includes a step of mixing a bottom ash containing chlorine compounds with dissolved water, desorbing the chlorine compounds in the bottom ash and dissolving them in the dissolved water, and chlorine compounds And a solid-liquid separation step of separating the dissolved water from the bottom ash.

本発明は底灰に含まれる塩素イオン濃度を低めるために塩素成分を溶出する3つの方法を提示する。第一は超音波を用いた方法であり、第二は水の脈動を用いた方法であり、第三は高圧の空気を用いた方法である。前記3つの方法は各々独立して実施したり、選択的または順次に実施できる。しかし、底灰に含有される1乃至3%の塩素イオン濃度を1,000mg/Kg以下に低める場合、前記3つの溶出段階を全て含んで構成するのが望ましい。   The present invention presents three methods for eluting the chlorine component in order to reduce the chlorine ion concentration contained in the bottom ash. The first is a method using ultrasonic waves, the second is a method using water pulsation, and the third is a method using high-pressure air. The three methods can be performed independently, or can be performed selectively or sequentially. However, when the concentration of 1 to 3% of chlorine ions contained in the bottom ash is lowered to 1,000 mg / Kg or less, it is desirable to include all three elution steps.

超音波を用いた溶出は、底灰を水槽に貯蔵した溶解水に入れ、超音波を照射して毛細気孔内の塩素化合物と水との接触効果を増大させ、底灰中の塩素化合物を前記底灰から速かに脱離して前記溶解水に溶解させる方法である。水の脈動を用いた方法は、底灰を水槽に貯蔵した溶解水に入れ、溶解水の水面を底灰が位置する区間を含む区間で上下に脈動させて底灰中の塩素化合物を脱離し、前記溶解水に溶解させる方法である。高圧空気を衝突させる方法は、底灰を溶解水と共に管へ流れるようにし、管に高圧空気を注入して底灰中の塩素化合物を脱離し、溶解水に溶解させる方法である。
また、水の脈動を用いて底灰から塩素化合物を脱離する際には、注入される底灰を載せる所定のメッシュの傾いたスクリーンと、底灰から落ちて浮遊する異物質を分離するために水槽上部に設ける異物質分離管と、スクリーンを通過したスクリーンのメッシュより小さい直径の底灰を外部へ排出させる水槽底面に設ける排出溝と、傾いた前記スクリーンに沿って移動した前記スクリーンのメッシュより大きい直径の底灰を外部へ排出させる流出口とを有する水槽を使用することが好ましい。
In elution using ultrasonic waves, bottom ash is placed in dissolved water stored in a water tank, and ultrasonic waves are irradiated to increase the contact effect between chlorine compounds in capillary pores and water. It is a method of quickly desorbing from the bottom ash and dissolving in the dissolved water. In the method using water pulsation, the bottom ash is put in dissolved water stored in a water tank, and the surface of the dissolved water is pulsated up and down in the section including the section where the bottom ash is located to desorb chlorine compounds in the bottom ash. And a method of dissolving in the dissolving water. The method of making high-pressure air collide is a method in which bottom ash flows into a pipe together with dissolved water, and high-pressure air is injected into the pipe to desorb chlorine compounds in the bottom ash and dissolve in dissolved water.
Also, when removing chlorine compounds from bottom ash using the pulsation of water, to separate the screen with a predetermined mesh on which the bottom ash to be injected is placed and the foreign substances that fall off the bottom ash and float A foreign substance separation tube provided in the upper part of the water tank, a discharge groove provided in the bottom of the water tank for discharging the bottom ash having a diameter smaller than the mesh of the screen that has passed through the screen, and the mesh of the screen moved along the inclined screen. It is preferable to use a water tank having an outlet for discharging bottom ash having a larger diameter to the outside.

本発明による底灰に含まれる塩素化合物の除去方法によれば、底灰に含有された塩素化合物を効率的に所望の水準の濃度に減少することができる。また、連続段階で処理できるので、大容量を処理することができ、処理費用を節減できる効果がある。   According to the method for removing a chlorine compound contained in bottom ash according to the present invention, the chlorine compound contained in the bottom ash can be efficiently reduced to a desired level of concentration. Moreover, since it can process in a continuous stage, it can process a large capacity | capacitance and there exists an effect which can reduce processing cost.

図1は本発明による塩素化合物を含む底灰から塩素化合物を除去する手順を示す図であって、第1、2、3の溶出方法を全て含む手順を示す。これによれば、底灰を投入し(S1)、投入された底灰に金属が含まれている場合は金属を除去(S2)した後、底灰から塩素成分の溶出を行なう。塩素成分の溶出は超音波を用いた方法(S3)、水の脈動を用いた方法(S4)、高圧の空気を用いた方法(S5)の順に進行する。溶出過程を完了すると、遠心力と比重差とを用いて塩素成分が溶出した溶液と底灰とを分離する固液分離過程(S6)を行い、固液分離過程(S6)以後には高圧の水を用いた底灰の洗浄及び脱水過程(S7)を行なう。そして、最後に底灰に含有される塩素成分が目標濃度以下(S8)になると、再利用物質(S9)として使用する。   FIG. 1 is a diagram showing a procedure for removing a chlorine compound from bottom ash containing a chlorine compound according to the present invention, and shows a procedure including all of the first, second and third elution methods. According to this, bottom ash is thrown in (S1), and when a metal is contained in the thrown bottom ash, the metal is removed (S2), and then the chlorine component is eluted from the bottom ash. The elution of the chlorine component proceeds in the order of a method using ultrasonic waves (S3), a method using water pulsation (S4), and a method using high-pressure air (S5). When the elution process is completed, a solid-liquid separation process (S6) is performed to separate the solution from which the chlorine component is eluted from the bottom ash using centrifugal force and specific gravity difference. After the solid-liquid separation process (S6), a high-pressure separation is performed. The bottom ash is washed and dehydrated using water (S7). And finally, when the chlorine component contained in bottom ash becomes below a target concentration (S8), it will be used as a reuse substance (S9).

以下、本発明の望ましい実施例を添付図面を参照しながらより詳細に説明する。図2は本発明による底灰に含まれる塩素化合物の除去方法の一実施例を示す工程図であり、図3は本発明による底灰に含まれる塩素化合物の除去システムの一実施例を示す装置工程図である。本発明による底灰中の塩素化合物の除去方法は、導入段階(S10)と、金属分離段階(S20)と、粉砕段階(S30)と、第1の溶出段階(S40)と、第2の溶出段階(S50)と、第3の溶出段階(S60)と、第1の固液分離段階(S70)と、第1の脱水段階(S80)と、洗浄段階(S90)と、第2の固液分離段階(S100)と、第2の脱水段階(S110)とから構成される。   Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. FIG. 2 is a process diagram showing an embodiment of a method for removing chlorine compounds contained in bottom ash according to the present invention, and FIG. 3 is an apparatus showing an embodiment of a system for removing chlorine compounds contained in bottom ash according to the present invention. It is process drawing. The method for removing chlorine compounds from bottom ash according to the present invention comprises an introduction step (S10), a metal separation step (S20), a pulverization step (S30), a first elution step (S40), and a second elution. A step (S50), a third elution step (S60), a first solid-liquid separation step (S70), a first dehydration step (S80), a washing step (S90), and a second solid-liquid It consists of a separation stage (S100) and a second dehydration stage (S110).

導入段階(S10)と金属分離段階(S20)と粉砕段階(S30)とは、前処理段階に該当する段階である。導入段階(S10)において底灰は直径30mm以下で導入するのが望ましく、この時、底灰導入のためにホッパー110を使用する。金属分離段階(S20)は、導入された底灰中の金属類を分別して底灰から金属類を分離する段階であって、金属類を分離する装置としては例えば磁力選別機120を使用する。粉砕段階(S30)は、底灰を粉砕機130で直径5mm以下に粉砕する過程であって、それにより底灰と溶解水との接触効率を増加させる。   The introduction stage (S10), the metal separation stage (S20), and the pulverization stage (S30) are stages corresponding to the pretreatment stage. In the introduction step (S10), it is desirable to introduce the bottom ash with a diameter of 30 mm or less. At this time, the hopper 110 is used to introduce the bottom ash. The metal separation step (S20) is a step of separating the metals from the bottom ash by separating the metals in the introduced bottom ash. For example, a magnetic separator 120 is used as an apparatus for separating the metals. The pulverization step (S30) is a process of pulverizing the bottom ash to a diameter of 5 mm or less by the pulverizer 130, thereby increasing the contact efficiency between the bottom ash and the dissolved water.

溶出段階は、底灰を溶解水と混合し、底灰内の塩素化合物を脱離して水に溶出する段階であって、第1の溶出段階(S40)と第2の溶出段階(S50)と第3の溶出段階(S60)とからなる。第1の溶出段階(S40)後、溶解水を底灰と分離した上、第2の溶出段階(S50)に移行して第2の溶出段階(S50)を行い、第2の溶出段階(S50)後、底灰を溶解水と共に第3の溶出段階(S60)に移行して第3の溶出段階(S60)を行なう。   The elution step is a step in which bottom ash is mixed with dissolved water, a chlorine compound in the bottom ash is desorbed and eluted in water, and the first elution step (S40) and the second elution step (S50) It consists of a 3rd elution step (S60). After the first elution step (S40), the dissolved water is separated from the bottom ash, and then the process proceeds to the second elution step (S50) to perform the second elution step (S50), and the second elution step (S50). ) After that, the bottom ash is transferred to the third elution step (S60) together with the dissolved water to perform the third elution step (S60).

第1の溶出段階(S40)では、第1の水槽210の底面に超音波振動子が設けられ、溶解水へ流入される底灰に超音波を照射して毛細気孔を生じて塩素化合物と水との接触効果を増大させ、塩素化合物を速かに溶解水に溶解させる。この時、使用する超音波の周波数は底灰の処理量と水槽の高さに応じて変えることができる。好ましくは10乃至100kHzの周波数を利用する。   In the first elution step (S40), an ultrasonic vibrator is provided on the bottom surface of the first water tank 210, and ultrasonic waves are radiated to the bottom ash flowing into the dissolved water to produce capillary pores, thereby producing chlorine compound and water. The contact effect is increased and the chlorine compound is quickly dissolved in the dissolved water. At this time, the frequency of the ultrasonic wave to be used can be changed according to the processing amount of bottom ash and the height of the water tank. A frequency of 10 to 100 kHz is preferably used.

第1の水槽210の溶解水は、超音波の照射によって溶出された塩素濃度が過度に濃縮されないように連続的に流入及び流出するようにするのが望ましいが、本実施例では溶解水及び後述する第2のハイドロサイクロン260の上部排出口261から排出される低塩素濃度の溶解水を回収して連続的に流入する流入水の一部として使用し、濃縮された溶解水は水処理段階へ連続的に流出する。この時、水槽内の塩素濃度は塩素イオン濃度センサーまたは電気伝導度センサーを用いて測定し、測定時、塩素濃度が一定濃度以上の場合には水槽内の溶解水全量を入れ替るのが望ましい。   It is desirable that the dissolved water in the first water tank 210 is continuously flowed in and out so that the chlorine concentration eluted by the irradiation of ultrasonic waves is not excessively concentrated. The low-chlorine-concentrated dissolved water discharged from the upper outlet 261 of the second hydrocyclone 260 is collected and used as a part of the inflowing water that flows continuously, and the concentrated dissolved water goes to the water treatment stage. It flows out continuously. At this time, the chlorine concentration in the water tank is measured using a chlorine ion concentration sensor or an electrical conductivity sensor, and it is desirable to replace the total amount of dissolved water in the water tank when the chlorine concentration is a certain concentration or more.

底灰中の塩素化合物を超音波を発振して脱離させる効果は著しく、表2は超音波発振による底灰内の塩素化合物の除去率を示す。   The effect of detaching chlorine compounds in bottom ash by oscillating ultrasonic waves is remarkable, and Table 2 shows the removal rate of chlorine compounds in bottom ash by ultrasonic oscillation.

Figure 0004329906
Figure 0004329906

第1の溶出段階(S40)を完了すると、底灰は無軸のスクリューコンベヤ211に載せて次の第2の溶出段階(S50)に移動するが、この時、塩素化合物が溶出した溶解水を底灰から分離して第1の溶出段階(S40)へ隔離することで、高濃度の塩素化合物が溶解した溶解水が次の段階に移行するのを阻み、溶解水の使用量を最小化することができる。   When the first elution step (S40) is completed, the bottom ash is placed on the non-axial screw conveyor 211 and moved to the next second elution step (S50). At this time, the dissolved water from which the chlorine compound is eluted is used. By separating from the bottom ash and segregating to the first elution stage (S40), the dissolved water in which the high concentration chlorine compound is dissolved is prevented from moving to the next stage, and the amount of dissolved water used is minimized. be able to.

第2の溶出段階(S50)では、底灰を第2の水槽に貯蔵された溶解水に入れ、溶解水の水面を底灰が位置する区間を含む区間で上下に脈動させ、底灰中の塩素化合物を脱離して前記溶解水に溶解させる。   In the second elution step (S50), the bottom ash is put into dissolved water stored in the second water tank, and the surface of the dissolved water is pulsated up and down in a section including the section where the bottom ash is located. A chlorine compound is desorbed and dissolved in the dissolved water.

図4は第2の水槽をより詳細に示した構成図である。図4に示すように、第2の水槽220は、水槽タンク222と、前記水槽タンク222の上部へ底灰を流入する流入口221から底灰を流出する流出口223まで傾斜して形成したスクリーン224と、流出口223の上部に設けた異質物排出管228と、水槽タンク222の底面に形成した排出溝225と、水槽タンク222の一側面に設けた補助タンク227とから構成される。   FIG. 4 is a configuration diagram showing the second water tank in more detail. As shown in FIG. 4, the second water tank 220 includes a water tank 222 and a screen formed by inclining from an inlet 221 for flowing bottom ash to the upper part of the tank tank 222 to an outlet 223 for discharging bottom ash. 224, a foreign matter discharge pipe 228 provided at the top of the outlet 223, a discharge groove 225 formed on the bottom surface of the aquarium tank 222, and an auxiliary tank 227 provided on one side of the aquarium tank 222.

スクリーン224は、流入する底灰のうち、スクリーン224のメッシュの間隔より大きい直径の底灰を傾いたスクリーン224に沿って流出口223へ移動させ、スクリーン224のメッシュの間隔より小さい直径の底灰はスクリーン224を通過させる。スクリーン224を通過した底灰は水槽タンク222の底面に形成された排出溝225を通じて外部へ排出する。この時、流出口223から排出される底灰と合流して第3の溶出段階へ移動する。一方、異質物排出管228は底灰内の密度が低くて浮遊した物質を分離する。   The screen 224 moves bottom ash having a diameter larger than the mesh interval of the screen 224 among the inflowing bottom ash to the outlet 223 along the inclined screen 224, and bottom ash having a diameter smaller than the mesh interval of the screen 224. Passes through the screen 224. The bottom ash that has passed through the screen 224 is discharged to the outside through a discharge groove 225 formed on the bottom surface of the water tank 222. At this time, it merges with the bottom ash discharged from the outlet 223 and moves to the third elution stage. On the other hand, the extraneous matter discharge pipe 228 separates suspended substances having a low density in the bottom ash.

補助タンク227は、水槽タンク222と連通した連通孔226を有しており、空気を注入することにより水槽タンク222の水位を調節できる空気注入管229及び空気排出管229′を備えている。   The auxiliary tank 227 has a communication hole 226 communicating with the water tank 222, and includes an air injection pipe 229 and an air discharge pipe 229 ′ that can adjust the water level of the water tank tank 222 by injecting air.

第2の溶出段階(S50)で溶解水の上下脈動は、補助タンク227内に空気を注入、排出することによってなされる。補助タンク227に空気を注入すると(P)、補助タンク227内の溶解水が連通孔226を通じて水槽タンク222内に移動し、水槽タンク222の水位を上昇(L)させ、補助タンク227から空気を排出すると(P)、水槽タンク222内の溶解水が連通孔226を通じて補助タンク227に移動し、水槽タンク222の水位が下降(L)する。従って、空気の注入と排出とを繰り返すことによりスクリーン224に載せられた底灰が水面に浸るか浸らないようになる脈動過程を繰り返すようになる。脈動過程を介して底灰と溶解水との間に摩擦力が生じて底灰の塩素化合物成分は再び溶出する。 In the second elution step (S50), the up and down pulsation of the dissolved water is performed by injecting and discharging air into the auxiliary tank 227. When air is injected into the auxiliary tank 227 (P H ), the dissolved water in the auxiliary tank 227 moves into the aquarium tank 222 through the communication hole 226, raises the water level of the aquarium tank 222 (L H ), and from the auxiliary tank 227. When the air is discharged (P L ), the dissolved water in the aquarium tank 222 moves to the auxiliary tank 227 through the communication hole 226, and the water level in the aquarium tank 222 is lowered (L L ). Therefore, the pulsation process in which the bottom ash placed on the screen 224 is immersed or not immersed in the water surface by repeating the injection and discharge of air is repeated. A frictional force is generated between the bottom ash and the dissolved water through the pulsation process, and the chlorine compound component of the bottom ash is eluted again.

第2の溶出段階(S50)が完了すると、溶解水に溶解した底灰は流出口223へ流出して第3の溶出段階(S60)に移動する。   When the second elution step (S50) is completed, the bottom ash dissolved in the dissolved water flows out to the outlet 223 and moves to the third elution step (S60).

第3の溶出段階(S60)では、底灰を溶解水と共に空圧管230へ流し、前記管に高圧の空気を注入して底灰中の塩素化合物を脱離して溶解水に溶解させる。   In the third elution step (S60), the bottom ash is caused to flow together with dissolved water to the pneumatic tube 230, and high-pressure air is injected into the tube to desorb chlorine compounds in the bottom ash and dissolve in the dissolved water.

図5aは空圧管を詳細に示す構成図であり、図5bは図5aのA−A′断面図である。図5a、5bに示すように、空圧管230は、多孔性材質で形成した下部区間233と一般の非多孔性材質で形成した上部区間232とを接合して形成し、内面上部には三角打撃板236を備えた内部管231と、内部管231との間に一定空間を形成しながら内部管231を囲む空気チャンバ235とから構成される。   FIG. 5a is a configuration diagram showing the pneumatic tube in detail, and FIG. 5b is a cross-sectional view taken along the line AA 'in FIG. 5a. As shown in FIGS. 5a and 5b, the pneumatic tube 230 is formed by joining a lower section 233 formed of a porous material and an upper section 232 formed of a general non-porous material. The inner tube 231 includes a plate 236 and an air chamber 235 that surrounds the inner tube 231 while forming a fixed space between the inner tube 231.

下部区間233は、多孔性材質で構成して微細気孔が形成されるので、微細気孔へ空気を流入できる。下部区間233は、内部管231の最低部から左右それぞれ60゜の区間を占めるように形成するのが望ましい。この時、上部区間232は、残りの240゜の区間を占めるようになる。   Since the lower section 233 is made of a porous material and has fine pores, air can flow into the fine pores. The lower section 233 is preferably formed so as to occupy sections of 60 ° to the left and right from the lowest part of the inner tube 231. At this time, the upper section 232 occupies the remaining 240 ° section.

内部管231の内側上部には、内部管231を側面から見た時、三角形を成す三角打撃板236を連続して軸方向へ設ける。三角打撃板236は、内部管231の内側上部から打撃板236端部までの長さが管直径の1/3程度に形成するのが望ましい。   A triangular striking plate 236 that forms a triangle when the inner tube 231 is viewed from the side is continuously provided in the inner upper portion of the inner tube 231 in the axial direction. The triangular striking plate 236 is preferably formed so that the length from the inner upper portion of the inner tube 231 to the end of the striking plate 236 is about 1/3 of the tube diameter.

空気チャンバ235は、内部管231との間に一定な空間を有しながらその外周を包むように形成し、底部に空気を流入し得る空気流入口237を多数個形成する。   The air chamber 235 is formed so as to wrap the outer periphery of the air chamber 235 while having a certain space between the inner tube 231 and a plurality of air inlets 237 through which air can flow into the bottom.

空圧管230で溶解水と共に内部管231の内部へ流れた底灰は、空気流入口237から流入し、内部管231の下部区間233に形成された微細気孔を通じて内部管231の内部へ流入する高圧の空気により三角打撃板236と衝突し、底灰に付いている微量の塩素化合物を再び溶出させて溶出を極大化する。   The bottom ash that flows into the inner pipe 231 together with the dissolved water in the pneumatic pipe 230 flows in from the air inlet 237 and flows into the inner pipe 231 through the fine pores formed in the lower section 233 of the inner pipe 231. The air collides with the triangular striking plate 236 and elutes a trace amount of chlorine compound attached to the bottom ash again to maximize the elution.

第3の溶出段階(S60)が完了すると、空圧管230を通過した溶解水とそれに溶解した底灰とを第1のハイドロサイクロン240へ移動し、第1の固液分離段階(S70)を始める。   When the third elution step (S60) is completed, the dissolved water that has passed through the pneumatic tube 230 and the bottom ash dissolved therein are moved to the first hydrocyclone 240, and the first solid-liquid separation step (S70) is started. .

第1の固液分離段階(S70)は、塩素化合物が溶出した溶解水を底灰から分離する段階であって、ハイドロサイクロンを用いる。ハイドロサイクロンは、遠心力を用いた固液分離装置であって、その構造及び作用は当該技術分野の通常の知識を持つ者(以下、当業者という)には周知であるため、これに対する詳細な説明は省略する。溶解水と共に底灰が第1のハイドロサイクロン240を通過すると、上部排出口241には溶解水が、下部排出口242には底灰が排出される。下部排出口242へ排出された底灰は、第1の脱水スクリーン250によって水分が除去する第1の脱水段階(S80)を経ると、洗浄段階(S90)に入る。   The first solid-liquid separation step (S70) is a step of separating the dissolved water from which the chlorine compound is eluted from the bottom ash, and uses a hydrocyclone. A hydrocyclone is a solid-liquid separation device using centrifugal force, and its structure and operation are well known to those skilled in the art (hereinafter referred to as those skilled in the art). Description is omitted. When the bottom ash together with the dissolved water passes through the first hydrocyclone 240, the dissolved water is discharged to the upper outlet 241 and the bottom ash is discharged to the lower outlet 242. The bottom ash discharged to the lower discharge port 242 enters the washing step (S90) after passing through the first dehydration step (S80) in which moisture is removed by the first dehydration screen 250.

洗浄段階(S90)は、底灰を濯ぐ段階であって、高圧の清浄水Pと第2のハイドロサイクロン260とを用いる。即ち、第1の脱水段階(S80)の第1の脱水スクリーン250で排出されるものに高圧の清浄水Pを直角方向へ噴射して底灰の表面を洗浄し、高圧の清浄水Pを底灰に噴射して底灰と底灰との間に存在する塩素イオンが含有された溶解水を清浄水Pに置換する。   The washing step (S90) is a step of rinsing the bottom ash, and uses high-pressure clean water P and the second hydrocyclone 260. That is, the surface of the bottom ash is washed by spraying high-pressure clean water P onto the one discharged from the first dewatering screen 250 in the first dewatering step (S80), and the high-pressure clean water P is bottomed. The dissolved water containing chlorine ions present between the bottom ash and sprayed on the ash is replaced with clean water P.

清浄水Pで洗滌された底灰は第2の固液分離段階(S100)の第2のハイドロサイクロン260で固液分離する。この時にも上部排出口261には洗滌水が排出され、下部排出口262には底灰が排出される。下部排出口262へ排出された底灰は再び第2の脱水段階(S110)の第2の脱水スクリーン270を通過しながら脱水された後、再利用物質として利用される。   The bottom ash washed with the clean water P is solid-liquid separated by the second hydrocyclone 260 in the second solid-liquid separation step (S100). At this time, washing water is discharged to the upper outlet 261 and bottom ash is discharged to the lower outlet 262. The bottom ash discharged to the lower discharge port 262 is again dehydrated while passing through the second dehydration screen 270 of the second dehydration step (S110), and then used as a reuse material.

一方、第1の固液分離段階(S70)の第1のハイドロサイクロン240の上部排出口241へ排出された溶解水は、第1の溶出段階(S40)の第1の水槽210へ回収し、第2の固液分離段階(S100)の第2のハイドロサイクロン260の上部排出口261へ排出された洗滌水は、第2の溶出段階(S50)の第2の水槽220へ回収して再使用するのが廃水再利用の次元から望ましい。前述したように第1の溶出段階(S40)で使用された溶解水は水処理段階へ移動するが、水処理段階は通常、沈澱タンク310を経る沈澱段階(S210)と、フィルタープレス320を経る濾過段階(S220)とから構成され、最終的に下水処理場へ送られる。沈澱段階(S210)及び濾過段階(S220)は当業者に周知の技術であるので、これに対する詳細な説明は省略する。   On the other hand, the dissolved water discharged to the upper outlet 241 of the first hydrocyclone 240 in the first solid-liquid separation stage (S70) is collected in the first water tank 210 in the first elution stage (S40), The washing water discharged to the upper outlet 261 of the second hydrocyclone 260 in the second solid-liquid separation stage (S100) is recovered and reused in the second water tank 220 in the second elution stage (S50). This is desirable from the dimension of wastewater reuse. As described above, the dissolved water used in the first elution stage (S40) moves to the water treatment stage. Usually, the water treatment stage passes through the precipitation stage (S210) through the precipitation tank 310 and the filter press 320. The filtration step (S220) is finally sent to the sewage treatment plant. Since the precipitation step (S210) and the filtration step (S220) are techniques well known to those skilled in the art, a detailed description thereof will be omitted.

本発明は主に前記実施例を基準として説明したが、発明の要旨と範囲を逸脱せずに、多くの他の修正や変形が可能である。例えば、各段階の一部手順を変更したり、洗浄を追加したり、脱水段階などの追加または削減が可能である。あるいは上記の工程のうち、著しい効果を発生しない化学物質の注入、三角打撃板の模様の変更、本実施例において説明されたものと同一の機能を有する他の装置の利用など、当業者には容易に変更が可能であろう。   Although the present invention has been described primarily with reference to the above embodiments, many other modifications and variations are possible without departing from the spirit and scope of the invention. For example, it is possible to change a part of the procedure at each stage, add washing, or add or reduce a dehydration stage. Or, among those described above, those skilled in the art, such as injecting chemical substances that do not produce significant effects, changing the pattern of the triangular striking plate, and using other devices having the same functions as those described in the present embodiment, etc. It can be easily changed.

従って前述した発明に対する権利範囲は特許請求の範囲で決まり、明細書本文の記載に拘束されず、請求の範囲の均等範囲に属する変形と変更とは全て本発明の範囲に属するものとする。   Accordingly, the scope of the right of the invention described above is determined by the scope of the claims, and is not restricted by the description of the specification, and all modifications and changes belonging to the equivalent scope of the claims shall belong to the scope of the present invention.

本発明による底灰中の塩素化合物の除去方法の順序を示す図である。It is a figure which shows the order of the removal method of the chlorine compound in bottom ash by this invention. 本発明による底灰中の塩素化合物の除去方法の一実施例を示す工程図である。It is process drawing which shows one Example of the removal method of the chlorine compound in the bottom ash by this invention. 本発明による底灰中の塩素化合物の除去システムの一実施例を示す装置工程図である。It is an apparatus process figure which shows one Example of the removal system of the chlorine compound in the bottom ash by this invention. 本発明による底灰中の塩素化合物の除去システムの第2の水槽の一実施例を示す構造図である。It is a block diagram which shows one Example of the 2nd water tank of the removal system of the chlorine compound in the bottom ash by this invention. 本発明による底灰中の塩素化合物の除去システムの空圧管の一実施例を示す一部切開正面図である。It is a partial cutaway front view which shows one Example of the pneumatic tube of the removal system of the chlorine compound in the bottom ash by this invention. 図5aのA−A′断面図である。It is AA 'sectional drawing of FIG. 5a.

符号の説明Explanation of symbols

110 ホッパー
120 磁力選別機
130 粉砕機
210 第1の水槽
220 第2の水槽
221 流入口
222 水槽タンク
223 流出口
224 スクリーン
225 排出溝
226 連通孔
227 補助タンク
228 異質物排出管
229 空気注入管
229′ 空気排出管
230 空圧管
231 内部管
232 上部区間
233 下部区間
235 空気チャンバ
236 三角打撃板
237 空気流入口
240 第1のハイドロサイクロン
250 第1の脱水スクリーン
260 第2のハイドロサイクロン
270 第2の脱水スクリーン
310 沈澱タンク
320 フィルタープレス
110 Hopper 120 Magnetic separator 130 Crusher 210 First water tank 220 Second water tank
221 Inflow port 222 Water tank 223 Outlet port 224 Screen 225 Discharge groove 226 Communication hole 227 Auxiliary tank 228 Heterogeneous material discharge pipe 229 Air injection pipe 229 ′ Air discharge pipe 230 Pneumatic pipe 231 Internal pipe 232 Upper section 233 Lower section 235 Air chamber 236 Triangle striking plate 237 Air inlet 240 First hydrocyclone 250 First dewatering screen 260 Second hydrocyclone 270 Second dewatering screen 310 Precipitation tank 320 Filter press

Claims (7)

塩素化合物を含む底灰を溶解水が貯蔵された水槽に入れ、溶解水の水面を底灰が位置する区間を含む区間で上下に脈動させ、底灰中の塩素化合物を脱離して前記溶解水に溶解させる溶出段階と
記塩素化合物が溶解された溶解水を底灰から分離する固液分離段階と、を備え、
前記水槽は、注入される底灰を載せる所定のメッシュの傾いたスクリーンと、前記底灰から落ちて浮遊する異物質を分離するために前記水槽上部に設ける異物質分離管と、前記スクリーンを通過した前記スクリーンのメッシュより小さい直径の底灰を外部へ排出させる水槽底面に設ける排出溝と、傾いた前記スクリーンに沿って移動した前記スクリーンのメッシュより大きい直径の底灰を外部へ排出させる流出口とを有することを特徴とする底灰に含まれる塩素化合物の除去方法。
Placed in a water bath dissolve water stored bottom ash containing chlorine compounds, dissolved water surface of the water in the section where the bottom ash contains a section that is located by pulsing up and down of the dissolution eliminated chlorine compounds in the bottom ash and elution stage that Ru is dissolved in water,
Comprising a solid-liquid separation step of separating the dissolved water before Symbol chlorine compound is dissolved from the bottom ash, the,
The water tank has a predetermined mesh inclined screen on which the bottom ash to be injected is placed, a foreign substance separation pipe provided on the upper part of the water tank to separate foreign substances that fall from the bottom ash, and passes through the screen. A discharge groove provided on the bottom of the water tank for discharging bottom ash having a diameter smaller than the mesh of the screen to the outside, and an outlet for discharging bottom ash having a diameter larger than the mesh of the screen moved along the inclined screen to the outside A method for removing a chlorine compound contained in bottom ash, comprising:
前記底灰を溶解水と共に高圧の空気を注入する空圧に流し、底灰中の塩素化合物を脱離して前記溶解水に溶解させる溶出段階を更に備えたことを特徴とする請求項1に記載の底灰に含まれる塩素化合物の除去方法。 The bottom ash is flowed into pneumatic tubes for injecting high pressure air along with dissolved water, to claim 1, further comprising a dissolution step of dissolving the chlorine compounds in bottom ash to the dissolved water desorbed The removal method of the chlorine compound contained in the bottom ash of description. 前記空圧管は、多孔性材質から形成された下部区間と、一般の非多孔性材質から形成された上部区間とを接合して形成され、内面上部に三角打撃板を備えた内部管と、前記内部管との間に一定空間を形成しながら前記内部管を囲む空気チャンバとから構成されることを特徴とする請求項に記載の底灰に含まれる塩素化合物の除去方法。 The pneumatic pipe is formed by joining a lower section formed of a porous material and an upper section formed of a general non-porous material, and an inner pipe provided with a triangular striking plate on the inner surface, The method for removing chlorine compounds contained in bottom ash according to claim 2 , comprising: an air chamber surrounding the inner pipe while forming a fixed space with the inner pipe. 底灰を導入する導入段階と、
導入された前記底灰に含まれた金属類を選別する金属分離段階と、
金属分離された前記底灰をより小さい直径に粉砕する粉砕段階と、
前記底灰を第1の水槽へ連続的に流入及び流出される第1の溶解水に入れ、超音波を照射してキャビテーションにより前記底灰に含まれる塩素化合物を前記底灰から脱離し、前記溶解水に溶解させる第1の溶出段階と、
前記第1の溶出段階を通過した後、水分の除去された底灰を第2の溶解水が流入される第2の水槽に入れ、第2の水槽の水位を底灰が位置する区間を含む区間で上下に脈動させて底灰に含まれる塩素化合物を脱離し、前記溶解水に溶解させる第2の溶出段階と、
前記第2の溶出段階を通過した底灰を第2の溶解水と共に空圧管に流し、前記空圧管に高圧の空気を注入して底灰中の塩素化合物を脱離し、前記溶解水に溶解させる第3の溶出段階と、
前記第3の溶出段階を通過した底灰と塩素化合物が溶解した第2の溶解水とを互いに分離する第1の固液分離段階と、
前記第1の固液分離段階で分離される前記底灰から水分を除去する第1の脱水段階と、
前記第1の脱水段階後の前記底灰を高圧の洗滌水で濯ぐ洗浄段階と、
前記洗浄段階を通過した底灰と洗滌水とを互いに分離する第2の固液分離段階と、
前記第2の固液分離段階で排出される前記底灰から水分を除去する第2の脱水段階と、を備え、
前記第2の水槽は、注入される底灰を載せる所定のメッシュの傾いたスクリーンと、前記底灰から落ちて浮遊する異物質を分離するために前記水槽上部に設ける異物質分離管と、前記スクリーンを通過した前記スクリーンのメッシュより小さい直径の底灰を外部へ排出させる水槽底面に設ける排出溝と、傾いた前記スクリーンに沿って移動した前記スクリーンのメッシュより大きい直径の底灰を外部へ排出させる流出口とを有することを特徴とする底灰に含まれる塩素化合物の除去方法。
An introduction stage for introducing bottom ash;
A metal separation step of selecting metals contained in the introduced bottom ash;
Crushing step of crushing the metal-separated bottom ash to a smaller diameter;
Put the bottom ash into the first dissolved water continuously flowing into and out of the first water tank, irradiate ultrasonic waves and desorb chlorine compounds contained in the bottom ash by cavitation, A first elution step of dissolving in dissolved water;
After passing through the first elution stage, the bottom ash from which moisture has been removed is placed in a second water tank into which the second dissolved water is introduced, and includes a section where the bottom ash is located at the water level of the second water tank. A second elution step in which the chlorine compound contained in the bottom ash is released by pulsating up and down in the section, and dissolved in the dissolved water;
The bottom ash that has passed through the second elution stage is caused to flow into the pneumatic tube together with the second dissolved water, and high-pressure air is injected into the pneumatic tube to desorb chlorine compounds in the bottom ash and dissolve in the dissolved water. A third elution stage;
A first solid-liquid separation step for separating the bottom ash that has passed through the third elution step and the second dissolved water in which the chlorine compound is dissolved;
A first dehydration step of removing moisture from the bottom ash separated in the first solid-liquid separation step;
A washing step of rinsing the bottom ash after the first dehydration step with high-pressure washing water;
A second solid-liquid separation step for separating the bottom ash and the washing water that have passed through the washing step from each other;
A second dehydration stage for removing moisture from the bottom ash discharged in the second solid-liquid separation stage ,
The second water tank includes a tilted screen having a predetermined mesh on which the bottom ash to be injected is placed, a foreign substance separation pipe provided on the upper part of the water tank to separate foreign substances falling from the bottom ash and floating, A drain groove provided on the bottom of the water tank that discharges bottom ash having a diameter smaller than the screen mesh that has passed through the screen to the outside, and bottom ash having a diameter larger than the mesh of the screen moved along the inclined screen is discharged to the outside. A method for removing a chlorine compound contained in bottom ash, wherein
前記第1の固液分離段階で分離される第2の溶解水を前記第1の溶出段階の第1の溶解水へ回収することを特徴とする請求項に記載の底灰に含まれる塩素化合物の除去方法。 The chlorine contained in bottom ash according to claim 4 , wherein the second dissolved water separated in the first solid-liquid separation stage is recovered into the first dissolved water in the first elution stage. Compound removal method. 前記第2の固液分離段階で分離される洗滌水を前記第2の溶出段階の第2の溶解水へ回収することを特徴とする請求項に記載の底灰に含まれる塩素化合物の除去方法。 6. The removal of chlorine compounds contained in bottom ash according to claim 5 , wherein the washing water separated in the second solid-liquid separation stage is recovered into the second dissolved water in the second elution stage. Method. 底灰を導入するホッパーと、
前記ホッパーに導入された前記底灰に含まれた金属類を選別する磁力選別機と、
前記磁力選別機で金属分離された前記底灰をより小さい直径に粉砕する粉砕機と、
底面に超音波振動子を設け、前記粉砕機から流入される前記底灰に超音波を照射して前記底灰に含まれる塩素化合物を脱離させ、溶解水に溶解させる第1の水槽と、
前記第1の水槽から注入される前記底灰が載せられる所定メッシュの傾いたスクリーンと、前記底灰から落ちて浮遊する異質物を分離するために上部に設けられる異質物分離管と、前記スクリーンを通過した前記スクリーンのメッシュより小さい直径の底灰を外部へ排出させる底面に設ける排出溝と、傾いた前記スクリーンに沿って移動した前記スクリーンのメッシュより大きい直径の底灰を外部へ排出させる流出口とを含んで構成され、水位を前記底灰が位置する区間を含む区間で上下に脈動させて前記底灰に含まれる塩素化合物を脱離させ、溶解水に溶解させる第2の水槽と、
前記第2の水槽を通過した底灰と溶解水とが通過し、多孔性材質から形成された下部区間と、一般の非多孔性材質から形成された上部区間とを接合して形成され、内面上部に三角打撃板を備えた内部管と、前記内部管との間に一定空間を形成しながら前記内部管を囲む空気チャンバとから構成され、前記内部管に高圧の空気を注入して前記底灰に含まれる塩素化合物を脱離させ、前記溶解水に溶解させる空圧管と、
前記空圧管を通過した底灰と塩素化合物が溶解した溶解水とを互いに分離する第1のハイドロサイクロンと、
前記第1のハイドロサイクロンで分離された前記底灰から水分を除去する第1の脱水スクリーンと、
前記第1の脱水スクリーンを経た前記底灰を高圧の洗滌水で濯ぐ洗浄機と、
前記洗浄機を通過した底灰と洗滌水とを互いに分離する第2のハイドロサイクロンと、
前記第2のハイドロサイクロンから排出される前記底灰から水分を除去する第2の脱水スクリーンと、を含んで構成される底灰に含まれる塩素化合物の除去システム。
A hopper for introducing bottom ash,
A magnetic separator for selecting metals contained in the bottom ash introduced into the hopper;
A pulverizer for pulverizing the bottom ash separated into metals by the magnetic separator to a smaller diameter;
An ultrasonic vibrator is provided on the bottom, a first water tank for irradiating the bottom ash flowing from the pulverizer with ultrasonic waves to desorb chlorine compounds contained in the bottom ash and dissolving in dissolved water;
A screen having a predetermined mesh on which the bottom ash injected from the first water tank is placed; a foreign matter separation pipe provided at an upper portion for separating the foreign matter falling from the bottom ash and floating; and the screen. A discharge groove provided on the bottom surface for discharging the bottom ash having a diameter smaller than the mesh of the screen that has passed through the screen, and a flow for discharging the bottom ash having a diameter larger than the mesh of the screen moved along the inclined screen to the outside. A second water tank configured to include an outlet, pulsate up and down in a section including a section where the bottom ash is located, desorb chlorine compounds contained in the bottom ash, and dissolve in dissolved water;
The bottom ash and the dissolved water that have passed through the second water tank pass through, and are formed by joining a lower section made of a porous material and an upper section made of a general non-porous material, An inner tube having a triangular striking plate at the top, and an air chamber surrounding the inner tube while forming a fixed space between the inner tube and injecting high-pressure air into the inner tube A pneumatic tube for desorbing chlorine compounds contained in the ash and dissolving in the dissolved water;
A first hydrocyclone for separating the bottom ash that has passed through the pneumatic tube and the dissolved water in which the chlorine compound is dissolved;
A first dewatering screen for removing moisture from the bottom ash separated by the first hydrocyclone;
A washing machine for rinsing the bottom ash having passed through the first dehydration screen with high-pressure washing water;
A second hydrocyclone for separating the bottom ash and the washing water that have passed through the washing machine from each other;
A system for removing chlorine compounds contained in bottom ash, comprising: a second dewatering screen that removes moisture from the bottom ash discharged from the second hydrocyclone.
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