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一种用于煤自燃全过程抑制的抑制剂的协同抑制效应及作用机制

Synergistic inhibition effect and mechanism of an inhibitor for entire process inhibition of coal spontaneous combustion.

作者信息

Hu Xincheng, Cai Jiawen, Yu Zhaoyang, Liu Jianguo, Wei Shanyang, Yang Shengqiang, Huang Guangping

机构信息

Mining College, Guizhou University, Guiyang, 550025, China.

Research Institute of Macro-Safety Science, University of Science and Technology Beijing, Beijing, 100083, China.

出版信息

Sci Rep. 2024 Oct 24;14(1):25139. doi: 10.1038/s41598-024-77355-0.

DOI:10.1038/s41598-024-77355-0
PMID:39448767
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11502782/
Abstract

Traditional coal spontaneous combustion (CSC) inhibitors, while effective, have limitations such as frequent application or short-term efficacy. To this end, we developed a slow-release and water-soluble synergistic inhibitor (SWSI) to achieve long-term CSC inhibition. The SWSI was formulated by integrating synergistic antioxidants (SA) composed of ascorbic acid (AsA) and Fe-superoxide dismutase (Fe-SOD) dissolved in a super absorbent polymer (SAP) encapsulated within hydrogel microcapsules. The effectiveness of SWSI was evaluated through simultaneous thermal analysis and in-situ free radical tests. The formulation optimization demonstrated that AsA and Fe-SOD had the maximum synergistic inhibition effect at a 1:1 molar ratio. The optimal SA: SAP ratio of 3:1 achieved the lowest oxygen consumption rate and highest inhibition rate. The encapsulation formulation, consisting of 3% SA, 6% PAM, 1% CaCl, and 0.5% citric acid, generated the highest swelling ratio. Simultaneous thermal analysis and in-situ free radical tests indicated that SWSI greatly increased feature temperatures and the apparent activation energy, lowered reaction heat, and substantially reduced free radical concentration in the full oxidation process. The newly developed SWSI offers a significant advancement in long-term CSC prevention by integrating physical and chemical inhibition, which provides sustained and effective inhibition throughout the entire oxidation process.

摘要

传统的煤炭自燃抑制剂虽然有效,但存在诸如频繁应用或短期效果等局限性。为此,我们开发了一种缓释且水溶性的协同抑制剂(SWSI)以实现长期的煤炭自燃抑制。SWSI是通过将由抗坏血酸(AsA)和铁超氧化物歧化酶(Fe-SOD)组成的协同抗氧化剂(SA)整合到溶解在水凝胶微胶囊内的高吸水性聚合物(SAP)中而制成的。通过同步热分析和原位自由基测试评估了SWSI的有效性。配方优化表明,AsA和Fe-SOD在1:1摩尔比时具有最大的协同抑制效果。3:1的最佳SA:SAP比例实现了最低的耗氧率和最高的抑制率。由3% SA、6% PAM、1% CaCl和0.5%柠檬酸组成的包封配方产生了最高的溶胀率。同步热分析和原位自由基测试表明,SWSI在整个氧化过程中大大提高了特征温度和表观活化能,降低了反应热,并大幅降低了自由基浓度。新开发的SWSI通过整合物理和化学抑制,在长期煤炭自燃预防方面取得了重大进展,在整个氧化过程中提供持续有效的抑制。

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2
Study on the thermal release characteristics and the correlation transformation mechanism of microscopic active groups of oxidized coal combustion in a deep mined-out area.深部采空区氧化煤燃烧微观活性基团热释放特性及关联转化机制研究。
Sci Total Environ. 2023 Sep 10;890:164354. doi: 10.1016/j.scitotenv.2023.164354. Epub 2023 May 23.
3
Managing arsenic (V) toxicity by phosphate supplementation in rice seedlings: modulations in AsA-GSH cycle and other antioxidant enzymes.
用磷酸盐补充剂来管理水稻幼苗中的砷(V)毒性:对 AsA-GSH 循环和其他抗氧化酶的调节。
Environ Sci Pollut Res Int. 2022 Feb;29(10):14418-14429. doi: 10.1007/s11356-021-16587-3. Epub 2021 Oct 6.
4
Underground coal fire emission of spontaneous combustion, Sandaoba coalfield in Xinjiang, China: Investigation and analysis.中国新疆三垅坝煤田煤炭自燃地下火排放:调查与分析。
Sci Total Environ. 2021 Jul 10;777:146080. doi: 10.1016/j.scitotenv.2021.146080. Epub 2021 Feb 26.
5
The involvement of carbon-centered radicals in the aging process of coals under atmospheric conditions: an EPR study.在大气条件下,碳中心自由基在煤的老化过程中的作用:EPR 研究。
Phys Chem Chem Phys. 2018 Oct 31;20(42):27025-27035. doi: 10.1039/c8cp04098b.