Co-disposal of MSWI fly ash and electrolytic manganese residue based on geopolymeric system

Xinyuan Zhan; Liao Wang; Chaochao Hu; Jian Gong; Tengtun Xu; Jiaxiang Li; Lu Yang; Jisong Bai; Shan Zhong

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Co-disposal of MSWI fly ash and electrolytic manganese residue based on geopolymeric system

机译：基于地质聚合物体系的MSWI粉煤灰与电解锰渣的联合处置

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MSWI fly ash (MSWI FA) and electrolytic manganese residue (EMR) were successfully co-disposed by use of a geopolymeric system. Alkaline products of MSWI FA and NaOH were used to elicit chemical reactions to promote solidification. The best performing formulation of EMR-based geopolymer for immobilization of heavy metals was composed of 75 wt% MSWI FA and 25 wt% EMR with NaOH solution (7.5 M)/solid of 0.5. Solidification was most effective for the heavy metals: Pb  Cu  Cr  Zn  Mn, respectively. The EMR-based geopolymer had high structural stability likely due to the high ratio of SiO2/Al2O3. The Solidification/Stabilization (S/S) mechanism for heavy metals of geopolymers is likely due to alkaline conditions and geopolymeric encapsulation, highlighting the utility and feasibility of this approach.

机译：MSWI粉煤灰（MSWI FA）和电解锰残留物（EMR）通过使用地质聚合物系统成功地共处置。使用MSWI FA和NaOH的碱性产物引发化学反应以促进固化。用于固定重金属的基于EMR的地聚合物的最佳性能配方是75重量％的MSWI FA和25重量％的EMR以及NaOH溶液（7.5 M）/固体含量为0.5。凝固对重金属最有效：分别为Pb +＞ Cu＞ Cr＞ Cr＞ Zn＞ Mn。基于EMR的地质聚合物可能具有较高的结构稳定性，这可能是由于SiO2 / Al2O3的比例较高。地质聚合物中重金属的固化/稳定化（S / S）机制可能是由于碱性条件和地质聚合物封装所致，这突显了该方法的实用性和可行性。

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来源
《Waste Management》 |2018年第12期|62-70|共9页
作者
Xinyuan Zhan; Liao Wang; Chaochao Hu; Jian Gong; Tengtun Xu; Jiaxiang Li; Lu Yang; Jisong Bai; Shan Zhong;
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作者单位

Key Laboratory of Coal Mine Disaster Dynamics and Control, Chongqing University;

College of Environment and Resources, Guangxi Normal University;

College of Resource and Environmental Science, Chongqing University;

Chong Qing Municipal Solid Waste Resource Utilization & Treatment Collaborative Innovation Center;

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正文语种 eng
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关键词
MSWI fly ash; Electrolytic manganese residue; Geopolymeric system; Solidification/Stabilization;

机译：MSWI粉煤灰;电解锰渣;地聚体系;固溶/稳定化;

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专利

1. Enhanced geopolymeric co-disposal efficiency of heavy metals from MSWI fly ash and electrolytic manganese residue using complex alkaline and calcining pre-treatment [J] . Zhan Xinyuan, Wang Liao, Wang Lei, Waste Management . 2019,第Octa期

机译：使用复杂的碱和煅烧预处理提高了MSWI粉煤灰和电解锰残渣中重金属的地质聚合物共处置效率
2. Co-disposal of MSWI fly ash and Bayer red mud using an one-part geopolymeric system [J] . Ye Nan, Chen Ye, Yang Jiakuan, Journal of Hazardous Materials . 2016,第NOVa15期

机译：使用一部分地聚物系统共同处理MSWI粉煤灰和拜耳赤泥
3. Co-sintering MSWI fly ash with electrolytic manganese residue and coal fly ash for lightweight ceramisite [J] . Zhan Xinyuan, Wang Liao, Wang Lei, Chemosphere . 2021,第Pta2期

机译：共烧结MSWI粉煤灰，具有电解锰渣和煤粉煤灰，用于轻质仪烟灰
4. Behaviour and Microstructure of MSWI fly ash solidified by Cement-activated Fluidized Bed Combustion Coal Fly ash [C] . D. Zhang, J. Zhang, X. He Annual conference of the Canadian Society for Civil Engineering . 2012

机译：水泥活化流化床燃烧粉煤灰固化MSWI粉煤灰的行为与微观结构
5. Utilizing a substandard fly ash for a TDOT aggregate-lime-fly ash stabilized base course. [D] . Dillon, Sarah A. 2012

机译：将不合格的粉煤灰用作TDOT骨料-粉煤灰稳定的基层。
6. Hybrid Fly Ash-Based Geopolymeric Foams: Microstructural Thermal and Mechanical Properties [O] . Giuseppina Roviello, Laura Ricciotti, Antonio Jacopo Molino, 2020

机译：杂交粉煤灰的地质聚合物泡沫：微观结构热和机械性能
7. Replacement of 5 of OPC by fly ash and APC residues from MSWI with electrodialytic pre-treatment [O] . Magro Cátia, Kirkelund Gunvor Marie, Guedes Paula, 2016

机译：用电渗析预处理替代来自msWI的飞灰和apC残留物的5％的OpC

Co-disposal of MSWI fly ash and electrolytic manganese residue based on geopolymeric system

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