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ZHANG Duo, CEN Xiaoxin, ZHAO Ju, DAI Aiping, ZHAI Xiaowei, YANG Xueshan. Experimental study on flow characteristics of gasification ash slag grouting[J]. Safety in Coal Mines, 2022, 53(4): 29-35,44.
Citation: ZHANG Duo, CEN Xiaoxin, ZHAO Ju, DAI Aiping, ZHAI Xiaowei, YANG Xueshan. Experimental study on flow characteristics of gasification ash slag grouting[J]. Safety in Coal Mines, 2022, 53(4): 29-35,44.
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Experimental study on flow characteristics of gasification ash slag grouting

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  • Published Date: April 19, 2022
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  • This paper analyzes the elements and chemical components contained in the gasification ash through elemental analysis and X-ray fluorescence spectroscopy, and proposes that the gasification ash should be poured into underground goaf as grouting fire prevention material. In order to solve the problem that the gasification ash slurry is easy to block the pipeline during the long-distance transportation process, the polymer surfactant carboxymethyl cellulose(CMC) is used as the suspending agent. Water separation rate and fluidity of the slurry are tested by suspension and flow experiments under different water-cement ratios and suspending agent additions. The results show that the gasification ash contains a variety of metal elements and non-metal elements. These elements mainly exist in the form of oxides. The oxides with higher content are SiO2, Fe2O3, CaO and Al2O3. When the amount of gasification ash and CMC increased, the water extraction rate and fluidity of grout decreased gradually. Through the suspension test, when the slurry water-cement ratio is 1∶0.2, the CMC addition amount should be greater than 1.25%. When the water-cement ratio is 1∶0.4, 1∶0.6 or 1∶0.8, the CMC addition amount should be greater than 0.5%. If the water-cement ratio is 1∶1, the addition amount of CMC should be greater than 0.25%. If the water-cement ratio exceeds 1∶1, the slurry appears as paste, which does not meet the requirements of grouting.
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  • [1]
    王学云,胡发亭,王光耀.煤间接液化合成油技术研究现状及展望[J].洁净煤技术,2020,26(1):110-120.

    WANG Xueyun, HU Fating, WANG Guangyao. Research status and prospect of coal indirect liquefaction synthetic oil technology[J]. Clean Coal Technology, 2020, 26(1): 110-120.
    [2]
    张龙,薛振华,李正兰.煤间接液化残渣基多孔陶瓷的制备及对Pb2+吸附性能的研究[J].陶瓷学报,2016, 37(1):58-62.

    ZHANG Long, XUE Zhenhua, LI Zhenglan. Adsorption of Pb2+ and preparation of porous ceramic materials with indirect coal liquefaction residue[J]. Journal of Ceramics, 2016, 37(1): 58-62.
    [3]
    刘大锐,朱丹丹.煤气化渣对磷酸根的吸附与解吸性能研究[J].无机盐工业,2021,53(2):84-87.

    LIU Darui, ZHU Dandan. Study on adsorption and desorption of phosphate by coal gasification slag[J]. Inorganic Chemicals Industry, 2021, 53(2): 84-87.
    [4]
    刘奥灏,张磊,张贺,等.燃煤锅炉掺烧气化灰渣试验研究[J].热力发电,2020,49(4):19-24.

    LIU Aohao, ZHANG Lei, ZHANG He, et al. Experimental research on co-firing gasified ash and slag in coal-fired boiler[J]. Thermal Power Generation, 2020, 49(4): 19-24.
    [5]
    国家发展和改革委员会.关于“十四五”大宗固体废弃物综合利用的指导意见(发改环资〔2021〕381号)[EB/OL].[2021-3-30]. https://www.ndrc.gov.cn/xxgk/zcfb/tz/202103/t20210324_1270286.html.
    [6]
    杭美艳,吕学涛,郭艳梅,等.煤气化渣微粉胶凝体系水化机理研究[J].混凝土与水泥制品,2019(2):94.

    HANG Meiyan, LYU Xuetao, GUO Yanmei, et al. Research on hydration mechanism of cementitious system of coal gasification slag micropowder[J]. China Concrete and Cement Products, 2019(2): 94.
    [7]
    汤云,袁蝴蝶,尹洪峰,等.几种典型煤气化炉渣的碳热还原氮化过程[J].煤炭学报,2016,41(12):3136.

    TANG Yun, YUAN Hudie, YIN Hongfeng, et al. Carbothermal reduction nitridation process of several typical coal gasification slag[J]. Journal of China Coal Society, 2016, 41(12): 3136.
    [8]
    Jiupeng Zhang, JING Zuo, Weidong Ai, et al. Preparation of a new high-efficiency resin deodorant from coal gasification fine slag and its application in the removal of volatile organic compounds in polypropylene composites[J]. Journal of Hazardous Materials, 2020, 384: 121347.
    [9]
    Weidong Ai, Bing Xue, Cundi Wei, et al. Mechanical and thermal properties of coal gasification fine slag reinforced low density polyethylene composites[J]. Journal of Applied Polymer Science, 2018, 135(17): 46203.
    [10]
    徐振.煤制甲醇气化灰渣灌浆特性实验研究[D].西安:西安科技大学,2018.
    [11]
    常福军.气化细灰渣超细研磨制高浓度水煤浆的实验研究[J].煤质技术,2019,34(2):20-23.

    CHANG Fujun. Experimental study on utilizing gasification fine slag ultrafine grinding to make the high concentration coal water slurry[J]. Coal Quality Technology, 2019, 34(2): 20-23.
    [12]
    曲江山,张建波,孙志刚,等.煤气化渣综合利用研究进展[J].洁净煤技术,2020,26(1):184-193.

    QU Jiangshan, ZHANG Jianbo, SUN Zhigang, et al. Research progress on comprehensive utilization of coal gasification slag[J]. Clean Coal Technology, 2020, 26(1): 184-193.
    [13]
    邓军,李贝,王凯,等.我国煤火灾害防治技术研究现状及展望[J].煤炭科学技术,2016,44(10):1-7.

    DENG Jun, LI Bei, WANG Kai, et al. Research status and outlook on prevention and control technology of coal fire disaster in China[J]. Coal Science and Technology, 2016, 44(10): 1-7.
    [14]
    曹健.基于光纤测温技术的蒙西地区侏罗纪煤层采空区火区探测研究[D].廊坊:华北科技学院,2017.
    [15]
    朱红青,胡超,张永斌,等.我国矿井内因火灾防治技术研究现状[J].煤矿安全,2020,51(3):88-92.

    ZHU Hongqing, HU Chao, ZHANG Yongbin, et al. Research status on prevention and control technology of coal spontaneous fire in China[J]. Safety in Coal Mines, 2020, 51(3): 88-92.
    [16]
    赵建会,张辛亥.矿用灌浆注胶防灭火材料流动性能的实验研究[J].煤炭学报,2015,40(2):383-388.

    ZHAO Jianhui, ZHANG Xinhai. Experimental study of mine grout injection plastic fire prevention materials flow properties[J]. Journal of China Coal Society, 2015, 40(2): 383-388.
    [17]
    殷素红,管海宇,胡捷,等.碱激发粉煤灰-矿渣灌浆材料的流变性与流动性[J].华南理工大学学报(自然科学版),2019,47(8):120-128.

    YIN Suhong, GUAN Haiyu, HU Jie, et al. Rheological properties and fluidity of alkali-activated fly ash-slag grouting material[J]. Journal of South China University of Technology (Natural Science Edition), 2019, 47(8): 120-128.
    [18]
    刘英学,邬培菊.黄泥灌浆防止采空区遗煤自燃的机理分析与应用[J].中国安全科学学报,1997(1):36.

    LIU Yingxue, WU Peiju. Mechanism and application of thick loess fluid pouring for prevention of spontaneous combustion of residual coal in goaf[J]. China Safety Science Journal, 1997(1): 36.
    [19]
    金永飞,晏立,张典,等.矿用防灭火发泡水泥固化充填材料优化配比研究[J].安全与环境学报,2020,20(5):1743-1751.

    JIN Yongfei, YAN Li, ZHANG Dian, et al. On proportionality of curing filling for mining fire extinguishing foamed cement material[J]. Journal of Safety and Environment, 2020, 20(5): 1743-1751.
    [20]
    M Aineto, A Acosta, J Ma. Rincón, et al. Thermal expansion of slag and fly ash from coal gasification in IGCC power plant[J]. Fuel, 2006, 85(16): 2352.
    [21]
    纪丽媛.气化灰渣的理化性质及石油焦催化气化反应特性研究[D].上海:华东理工大学,2014.
    [22]
    吴阳,赵世永,李博.宁东煤气流床气化残渣特性研究[J].煤炭工程,2017,49(3):115-118.

    WU Yang, ZHAO Shiyong, LI Bo. Study on the residue features of Ningdong coal in entrained flow gasifiers[J]. Coal Engineering, 2017, 49(3): 115-118.
    [23]
    刘艳芳,崔龙鹏,郎子轩,等.Shell粉煤气化灰渣环境风险评价[J/OL].石油学报(石油加工). https://kns.cnki.net/kcms/detail/11.2129.TE.20210423.1745. 002.htm1.

    LIU Yanfang, CUI Longpeng, LANG Zixuan, et al. Environmental risk assessment of ash and slag from shell pulverized coal gasification[J/OL]. Acta Petrolei Sinica(Petroleum Processing Section). https://kns.cnki.net/kcms/detail/11.2129.TE.20210423.1745.002.htm1.
    [24]
    李和平,张晓光,吴佳芮,等.水煤浆添加剂的特性参数测定与筛选[J].煤炭转化,2017,40(4):48-56.

    LI Heping, ZHANG Xiaoguang, WU Jiarui, et al. Characteristic parameters test and selection of coal water slurry additives[J]. Coal Conversion, 2017, 40(4): 48-56.
    [25]
    赵先科.煤泥灌浆防灭火技术研究[D].西安:西安科技大学,2016.
    [26]
    杭美艳,吕学涛,郭艳梅,等.煤气化渣微粉活性激发效果的试验研究[J].硅酸盐通报,2019,38(3):878.

    HANG Meiyan, LYU Xuetao, GUO Ynamei, et al. Experimental study on activation effect of micropowder of coal gasification slag[J]. Bulletin of the Chinese Ceramic Society, 2019, 38(3): 878.
    [27]
    郭照恒,杨文,祝小靓,等.不同比表面积煤气化渣掺合料活性及力学性能研究[J].硅酸盐通报,2020,39(11):3567-3573.

    GUO Zhaoheng, YANG Wen, ZHU Xiaoliang, et al. Activity and mechanical properties of coal gasification slag admixture with different specific surface area[J]. Bulletin of the Chinese Ceramic Society, 2020, 39(11): 3567-3573.
    [28]
    侯贺子,李翠平,王少勇,等.尾矿浓密中泥层沉降速度变化及颗粒沉降特性[J].中南大学学报(自然科学版),2019,50(6):1428-1436.

    HOU Hezi, LI Cuiping, WANG Shaoyong, et al. Settling velocity variation of mud layer and particle settling characteristics in thickening of tailings[J]. Journal of Central South University(Science and Technology), 2019, 50(6): 1428-1436.
    [29]
    T Phenrat, N Saleh, K Sirk, et al. Stabilization of aqueous nanoscale zerovalent iron dispersions by anionic polyelectrolytes: adsorbed anionic polyelectrolyte layer properties and their effect on aggregation and sedimentation[J]. Journal of Nanoparticle Research, 2008(5):795-814.
    [30]
    冯博,王金庆,汪惠惠.羧甲基纤维素对滑石的抑制作用及影响因素[J].硅酸盐通报,2015,34(6):1475-1479.

    FENG Bo, WANG Jinqing, WANG Huihui. Depression effect of CMC on talc and its influence factors[J]. Bulletin of the Chinese Ceramic Society, 2015, 34(6): 1475-1479.
    [31]
    陈广林,刘德福,陈涛,等.CeO2纳米粒子抛光液分散稳定性及其化学机械抛光特性研究[J].表面技术,2016,45(11):187.

    CHEN Guanglin, LIU Defu, CHEN Tao, et al. Dispersion stability of CeO2 nano particles polishing agent and its properties in chemical mechanical polishing process[J]. Surface Technology, 2016, 45(11): 187.
    [32]
    王韧,孙金声,孙慧翠,等.不同驱动力条件下改性淀粉、羧甲基纤维素钠和黄原胶对水合物形成的影响[J].中国石油大学学报(自然科学版),2021,45(1):127-136.

    WANG Ren, SUN Jinsheng, SUN Huicui, et al. Effects of modified starch, CMC and XC on hydrate formation under different driving forces[J]. Journal of China University of Petroleum(Edition of Natural Science), 2021, 45(1): 127-136.
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