Mechanisms of solidification of cadmium in municipal solid waste incineration fly ash usinga slag cemented backfill agent
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摘要: 膠結充填采礦協同利用垃圾焚燒飛灰是解決飛灰日益激增的新思路,可大量資源化利用飛灰并固化其中的重金屬離子.本文以礦渣-鋼渣基膠凝材料(簡稱冶金渣膠凝材料)分別結合4種城市垃圾焚燒(MSWI)飛灰制備膠凝材料,并以全尾砂作為骨料制成膠結充填料,測定充填料試樣的流動度、抗壓強度以及Cd2+浸出質量濃度:冶金渣-垃圾焚燒飛灰基充填料試樣的流動度為240~265 mm,滿足礦山充填的泵送要求;28 d抗壓強度均大于8.88 MPa,滿足一般礦山充填1~6.5 MPa的強度要求;Cd2+浸出液質量濃度低于飲用水標準5 μg·L-1的限值.通過X射線衍射(XRD)、紅外光譜(IR)和熱重-差示掃描量熱法(TG-DSC)分析表明膠凝材料的主要水化產物組成為鈣礬石、Friedel鹽和C-S-H凝膠;通過X射線光電子能譜(XPS)發現Cd2+對Al2+的結合能有較大影響,鈣礬石、Friedel鹽可能對鎘離子有固化作用.Abstract: In cement production, the synergistic use of municipal solid waste incineration (MSWI) fly ash provides a novel approach to solve the problem of the increasing productions of fly ash and heavy metal ions. In this study, slag-steel slag based cementitious material (referred to as metallurgical slag cementitious materials) was combined with four types of MSWI fly ash for preparing cementitious materials, all of which use sand as a binder. According to the determination of fluidity, compressive strength and Cd2+ leaching concentration of filler samples, the following are found:(1) the flow rate of filler material prepared from metallurgical slag and fly ash is 240-265 mm, which fulfills the pumping requirement of mine filling; (2) the 28-day compressive strength values are>8.88 MPa, which meets the general mine filling strength requirements (1-6.5 MPa); and (3) the Cd2+ leachate concentration is lower than the drinking water standard of 5 μg·L-1 limit. The results of X-ray diffraction, infrared spectroscopy, and thermogravimetry-differential scanning calorimetry show that the leading hydration products of gelling materials are ettringite, Friedel, and C-S-H. Furthermore, X-ray photoelectron spectroscopy results reveal that Cd2+ has a great effect on the binding energy of Al3+. Ettringite and Friedel salts are found to have a curing effect on cadmium ions.
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Key words:
- metallurgical slag /
- waste incineration fly ash /
- cementitious materials /
- cadmium
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參考文獻
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