1. Technical Center for Industrial Product and Raw Material Inspecting and Testing of Shanghai Customs, Shanghai 200135, China; 2. College of Chemistry and Chemical Engineering, Donghua University, Shanghai 201620, China; 3. Comprehensive Technology Service Center of Shengsi Customs,Shengsi 202450, China
Abstract:Indonesia is the largest source country of imported coal in China, and its coal resources are mainly concentrated in Sumatra Island and Kalimantan Island. The quality characteristics, trace element characteristics and geological genesis of Indonesian coal were summarized. The results showed that Indonesian coal had the quality characteristics of high moisture, low ash, low sulfur and high volatile matter, and its trace element content was generally lower than the average value of the world coal, showing the characteristics of ultra-low fluorine, ultra-low phosphorus, ultra-low chlorine, ultra-low arsenic and ultra-low mercury. Indonesia is located near the equator, and its unique peat environment is an important reason for high moisture, low ash content, low sulfur content, high volatile matter and low trace element content of Indonesian coal. In addition, the intrusion of igneous rock, volcanic ash and seawater could also cause great differences in the quality and trace element of Indonesian coal in local area. The comprehensive utilization of imported Indonesian coal was prospected from the aspects of coal blending and burning, clean utilization, etc. It was suggested to carry out the scientific evaluation according to different blending and burning scenarios. Moreover, the clean utilization of inferior coal in local areas should be paid attention to. Due to the differences of paleoenvironment and geological origin, the trace element content of coals from different origins had the characteristic of "fingerprint", which could be applied to the origin tracing of Indonesian coal.
[1] 谢尚克,伊海生,杨永飞,等.印度尼西亚矿业开发现状研究[J].中国矿业,2022,31(2):46-50. XIE Shangke,YI Haisheng,YANG Yongfei,et al.Research on the current situation of mining development in Indonesia[J].China Mining Magazine,2022,31(2):46-50. [2] Refi P,Consumption C,Trade P.BP statistical review of world energy June 2012[J].Annex,2012:1-48. [3] 梁富康,苏新旭.印度尼西亚的煤炭资源及开发前景[J].中国煤炭,2019,45(4):128-132. LIANG Fukang,SU Xinxu.Coal resources and development prospect in Indonesia[J].China Coal,2019,45(4):128-132. [4] 冯立群.中国煤炭进口来源分析[D].呼和浩特:内蒙古大学,2012. [5] 刘叶琳.中国煤炭进口量将现下滑[N].国际商报,2022-01-12(3). [6] 数字说话[J].中国煤炭工业,2022,38(2):41. Number Talking[J].China Coal Industry,2022,38(2):41. [7] 牟晓龙.印尼煤品质相关性研究[J].内蒙古煤炭经济,2019,37(4):57-58. MU Xiaolong.Study on the correlation of coal quality in Indonesia [J].Inner Mongolia Coal Economy,2019,37(4):57-58. [8] 苏彩珠,蔡英俊,陈晓翔.进口印尼动力煤品质分析[J].煤质技术,2007,22(4):4-8. SU Caizhu,CAI Yingjun,CHEN Xiaoxiang.Quality analysis for imported Indonesian steam coal[J].Coal Quality Technology,2007,22(4):4-8. [9] BELKIN H E,TEWAL S J,HOWER J C,et al.Geochemistry and petrology of selected coal samples from Sumatra,Kalimantan,Sulawesi,and Papua,Indonesia[J].International Journal of Coal Geology,2009,77(3-4):260-268. [10] SINGH A L,SINGH P K,SINGH M P,et al.Environmentally sensitive major and trace elements in indonesian coal and their geochemical significance[J].Energy Sources,Part A:Recovery,Utilization,and Environmental Effects,2015,37(17):1836-1845. [11] LESTIANI D D,SANTOSO M,KURNIAWATI S,et al.Characteristics of feed coal and particulate matter in the vicinity of coal-fired power plant in Cilacap,Central Java,Indonesia[J].Procedia Chemistry,2015,16:216-221. [12] 邓建军.进口煤炭商品知识及检验监管 [J].中国海关,2021,33(1):48-51. DENG Jianjun.Commodity knowledge and inspection supervision of imported coal[J].China Customs,2021,33(1):48-51. [13] NALENDRA S,NASUTION F P.Characterization of coal quality based on ash content from M2 Coal-Seam Group, Muara Enim Formation, South Sumatra Basin[J].Journal of Geoscience,Engineering,Environment,and Technology,2017,2(3):203-209. [14] 陈文华,陈亮伟,皮志强.印尼中加里曼丹DBK矿区煤炭资源特征及评价[J].江西煤炭科技,2018,40(2):61-64. CHEN Wenhua,CHEN Liangwei,PI Zhiqiang.Characteristics and evaluation of coal resources of DBK Mining Area in Kalimantan,the middle part of Indonesia[J].Jiangxi Coal Science & Technology,2018,40(2):61-64. [15] 龚露,罗吉国.煤质分析中发热量与固定碳的简易互算[J].广州化工,2009,37(3):69-70. GONG Lu,LUO Jiguo.Simple mutual calculation between the calorific capacity and the fixed carbon in anthracite analysis[J].Guangzhou Chemical Industry,2009,37(3):69-70. [16] CHOU C L.Sulfur in coals: A review of geochemistry and origins[J].International Journal of Coal Geology,2012,100:1-13. [17] ANGGAYANA K,RAHMAD B,ARIE NAFTALI H H,et al.Limnic condition in ombrotrophic peat type as the origin of Muara Wahau coal, Kutei basin, Indonesia[J].Journal of the Geological Society of India,2014,83(5):555-562. [18] ZAMRONI A,SUGARBO O,PRASTOWO R,et al.The relationship between Indonesian coal qualities and their geologic histories[C]//2nd International Conference on Earth Science,Mineral,and Energy,2020. [19] 汤进.印尼煤低温氧化热值损耗及温升变化的研究[D].杭州:浙江大学,2020. [20] 刘丽萍,苏新旭,梁富康.印度尼西亚煤炭资源概况[J].重庆科技学院学报(自然科学版),2013,15(5):76-78. LIU Liping,SU Xinxu,LIANG Fukang.Overviews of coal resources in Indonesia[J].Journal of Chongqing University of Science and Technology(Natural Sciences Edition),2013,15(5):76-78. [21] 周强.中国煤中微量元素的研究[J].洁净煤技术,2010,16(1):12-15. ZHOU Qiang.Research on trace elements in Chinese coal[J].Clean Coal Technology,2010,16(1):12-15. [22] 曹庆一,任文颖,梁朝铭,等.中国煤中有害微量元素含量的空间分布[J].煤田地质与勘探,2022,50(5):13-22. CAO Qingyi,REN Wenying,LIANG Chaoming,et al.Spatial distribution of harmful trace elements in Chinese coals[J].Coal Geology & Exploration,2022,50(5):13-22. [23] FINKELMAN R B.Trace and Minor Elements in Coal[M].Boston:Springer US,1993. [24] 唐修义,黄文辉.中国煤中微量元素[M].北京:商务出版社,2004. [25] KETRIS M P,YUDOVICH Y E.Estimations of Clarkes for Carbonaceous biolithes:world averages for trace element contents in black shales and coals[J].International Journal of Coal Geology,2009,78(2):135-148. [26] ANGGARA F,AMIJAYA D H,HARIJOKO A,et al.Rare earth element and yttrium content of coal in the Banko coalfield,South Sumatra Basin,Indonesia:contributions from tonstein layers[J].International Journal of Coal Geology,2018,196:159-172. [27] 刘曙,沈劼,周海明,等.电感耦合等离子体质谱-原子荧光光谱法研究上海口岸进口印度尼西亚煤炭微量元素的赋存形态特征[J].岩矿测试,2015,34(4):436-441. LIU Shu,SHEN Jie,ZHOU Haiming,et al.Study on occurrence status characteristics of trace elements in imported Indonesia coals of Shanghai Port using inductively coupled plasma-mass spctrometry and atomic fluorescence spectrometry[J].Rock and Mineral Analysis,2015,34(4):436-441. [28] ANGGARA F,T B M PETRUS H,PATRIA A A,et al.Preliminary study of rare earth element and yttrium (REY) content of coal in Sangatta Coalfield, East Kalimantan, Indonesia[J].Indonesian Journal on Geoscience,2020,7(3):305-314. [29] 陈宁,孙儒瑞,王艺.高温燃烧水解-离子色谱法同时测定印尼动力煤中氟和氯[J].辽宁化工,2018,47(11):1181-1183. CHEN Ning,SUN Rurui,WANG Yi.Simultaneous determination of fluoride content and chloride content in Indonesia power coal by high temperature combustion hydrolysis-ion chromatography[J].Liaoning Chemical Industry,2018,47(11):1181-1183. [30] 刘烨,陈杰锋,赖志彬,等.浅析新沙口岸进口印度尼西亚褐煤品质[J].煤质技术,2018,33(3):25-27. LIU Ye,CHEN Jiefeng,LAI Zhibin,et al.Analysis on the quality of imported Indonesia lignite at Xinsha port[J].Coal Quality Technology,2018,33(3):25-27. [31] DAI S,BECHTEL A,EBLE C F,et al.Recognition of peat depositional environments in coal:A review[J].International Journal of Coal Geology,2020,219:103383-103449. [32] 车飞翔,樊婷婷,胡驰,等.南疆三地州同一构造背景下三个盆地煤中元素特征及其地质意义[J].矿产勘查,2021,12(12):2361-2367. CHE Feixiang,FAN Tingting,HU Chi,et al.Element characteristics and geological significance of coal in three basins under the same tectonic setting in the three tectonic states of southern Xinjiang[J].Mineral Exploration,2021,12(12):2361-2367. [33] 冀华丽,何中波,卫三元,等.微量元素在鹤岗盆地早白垩世沉积环境分析中的应用 [J].矿产勘查,2020,11(1):21-27. JI Huali,HE Zhongbo,WEI Sanyuan,et al.Indicative significance of trace element analysis in early Cretaceous sedimentary environment of Hegang Basin[J].Mineral Exploration,2020,11(1):21-27. [34] GUO Q,FINK R,LITTKE R,et al.Methane sorption behaviour of coals altered by igneous intrusion, South Sumatra Basin[J].International Journal of Coal Geology,2019,214:103250-103267. [35] AMIJAYA H,LITTKE R.Microfacies and depositional environment of Tertiary Tanjung Enim low rank coal,South Sumatra Basin,Indonesia[J].International Journal of Coal Geology,2005,61(3-4):197-221. [36] DAI S,WARD C R,GRAHAM I T,et al.Altered volcanic ashes in coal and coal-bearing sequences:a review of their nature and significance[J].Earth-Science Reviews,2017,175:44-74. [37] CARITAT P D,REIMANN C,SMITH D B,et al.Chemical elements in the environment:multi-element geochemical datasets from continental-to national-scale surveys on four continents[J].Applied Geochemistry,2018,89:150-159. [38] SWAINE D J,GOODARZI F.Environmental aspects of trace elements in coal[M].Netherlands:Energy & Environment,1995. [39] WIDODO S,OSCHMANN W,BECHTEL A,et al.Distribution of sulfur and pyrite in coal seams from Kutai Basin (East Kalimantan, Indonesia):implications for paleoenvironmental conditions[J].International Journal of Coal Geology,2010,81(3):151-162. [40] 赵俊杰,吴豪,周健,等.基于煤质与燃烧特性优化火力电站配煤掺烧方法[J].能源科技,2019,17(5):89-93. ZHAO Junjie,WU Hao,ZHOU Jian,et al.Optimizing coal blending method of thermal power station that based on the quality of coal and combustion characteristics[J].Energy Science and Technology,2019,17(5):89-93. [41] 任吉平,高慧芳.电厂锅炉混煤掺烧技术的实践分析[J].现代工业经济和信息化,2021,11(12):234-235. REN Jiping,GAO Huifang.Analysis of coal blending technology in power plant boilers[J].Modern Industrial Economy and Informationization,2021,11(12):234-235.
