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Environmental Earth Sciences

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01-07-2014 | Original Article

Occurrence modes and cleaning potential of sulfur and some trace elements in a high-sulfur coal from Pu’an coalfield, SW Guizhou, China

Authors: Wei Cheng, Qin Zhang, Ruidong Yang, Yingzhong Tian

Published in: Environmental Earth Sciences | Issue 1/2014

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Abstract

In this research, a float-sink test was applied to a Late Permian high-sulfur coal collected from Pu’an coalfield, Southwest in Guizhou, China. To investigate the occurrence modes and the mobility of various trace elements, as well as the cleaning potential of some harmful elements in density separation, coal quality parameters and concentrations of 46 elements of 7 density fractionated samples were determined and statistically analyzed. Results show that larger size and higher density fractions have higher total sulfur content and ash yield than the smaller and lower ones. In fact, most (74.39 %) of the total sulfur occurs in the inorganic matter. Affinity and correlation analysis show that Mo and Ni have apparently strong organic affinity, whereas Rh, Cs, Sr, Co, Nb, Zr, V, Ga, Sc, Be, Ge, Hf, Th, U, Ag, As, In, Cu, Cd, Ta, Li, TI, and Ba are mostly in the heavy fractions. Rare earth element (REE) patterns for the seven density fractions present good uniformity and show that they are of right-inclined pattern type characterized by Light REE (LREE, La ~ Eu) enrichment relative to Heavy REE (HREE, Gd ~ Lu) and pronounced negative δ _Eu anomalies. This suggests that REE was mainly derived from basalt-weathered materials. LRREE/HREE ratio variations reveal that LREE has stronger affinity with the organic matter relative to the HREE, while high LRREE/HREE in heavy fractions may be related to pyrite. Supposing the maximum sulfur content of the cleaned coal is 1.00 %, the theoretical removal ratios of Co, TI, and Ba are as high as 90.94, 93.73, and 92.29 %, respectively, while those of As, Ni and Mo are only 56.33, 48.85, and 45.05 %, respectively. As these figures change with different maximum sulfur contents required for the cleaned coal, not only the decrease of sulfur and ash in coal washing, but also the mobility of some harmful trace elements should be taken into consideration.

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Birk D, White JC (1991) Rare earth elements in bituminous coals and underclays of the Sydney Basin, Nova Scotia: element sites, distribution, mineralogy. Int J Coal Geol 19:219–251CrossRef

Cheng W, Yang RD, Zhang Q, Cui YC, Gao JB (2013) Distribution characteristics, occurrence modes and controlling factors of eleven trace elements in Late Permian coals from Bijie City, Guizhou province. J China Coal Soc 38(1):103–113 (in Chinese with English abstract)

Dai SF, Li WW, Tang YG, Zhang Y, Feng P (2007) The sources, pathway, and preventive measures for fluorosis in Zhijin County, Guizhou, China. Appl Geochem 22:1017–1024CrossRef

Dai SF, Tian LW, Chou C-L, Zhou YP, Zhang MQ, Zhao L, Wang JM, Yang Z, Cao HZ, Ren DY (2008) Mineralogical and compositional characteristics of Late Permian coals from an area of high lung cancer rate in Xuan Wei, Yunnan, China: occurrence and origin of quartz and chamosite. Int J Coal Geol 76:318–327CrossRef

Dai SF, Ren DY, Chou C-L, Finkelman RB, Seredin VV, Zhou YP (2012) Geochemistry of trace elements in Chinese coals: a review of abundances, genetic types, impacts on human health, and industrial utilization. Int J Coal Geol 94:3–21CrossRef

Eskenazy GM (1987) Rare earth elements in a sampled coal from the Pirin deposit, Bulgaria. Int J Coal Geol 7:301–314CrossRef

Feng XB, Hong Y (1999) Modes of occurrence of mercury in coals from Guizhou, People’s Republic of China. Fuel 78:1181–1188CrossRef

Feng XB, Hong Y, Hong B, Ni J (2000) Mobility of some potentially toxic trace elements in the coal of Guizhou, China. Environ Geol 39(3–4):372–377CrossRef

Finkelman RB (1993) Trace and minor elements in coal. In: Engel MH, Macko SA (eds) Organic geochemistry. Plenum, New York, pp 593–607CrossRef

Finkelman RB, Orem W, Castranova V, Tatu CA, Belkin HE, Zheng BS, Lerch HE, Maharaj SV, Bates AL (2002) Health impacts of coal and coal use: possible solutions. Int J Coal Geol 50:425–443CrossRef

Huang WH, Yang Q, Tang DZ (2000) Rare earth element geochemistry of Late Palaeozoic coals in north China. Acta Geol Sinica 74(1):74–83

Ketris MP, Yudovich YE (2009) Estimation of Clarkes for Carbonaceous biolithes: word averages for trace element contents in black shales and coals. Int J Coal Geol 78:135–148CrossRef

Kolker A (2011) Minor element distribution in iron disulfides in coal: a geochemical review. Int J Coal Geol 94:32–43CrossRef

Kortenski J, Bakardjiev S (1993) Rare earth and radioactive elements in some coals from the Sofia, Svoge and Pernik Basins, Bulgaria. Int J Coal Geol 22:237–246CrossRef

Li J, Zhuang XG, Querol X (2011) Trace element affinities in two high-Ge coals from China. Fuel 90:240–247CrossRef

Liu GJ, Zheng LG, Qi CC, Zhang Y (2007) Environmental geochemistry and health of fluorine in Chinese coals. Environ Geol 52(7):1307–1313CrossRef

Qi L, Hu J, Gregoire DC (2000) Determination of trace elements in granites by inductively coupled plasma mass spectrometry. Talanta 51:507–513CrossRef

Querol X, Klika Z, Weiss Z, Finkelman RB, Alastuey A, Juan R, López-Soler A, Plana F, Kolker A, Chenery SRN (2001) Determination of element affinities by density fractionation of bulk coal sample. Fuel 80:83–96CrossRef

Ren DY, Zhao FH, Dai SF, Zhang JY, Luo KL (2006) Geochemistry of trace elements in coal. Science Press, Beijing, pp 9–60 (in Chinese with English abstract)

Schatzel SJ, Stewart BW (2003) Rare earth elements sources and modification in the Lower Kittanning coal bed, Pennsylvania: implications for the origin of coal mineral matter and rare earth element exposure in underground mines. Int J Coal Geol 54:223–251CrossRef

Seredin VV, Dai SF (2012) Coal deposits as potential alternative sources for lanthanides and yttrium. Int J Coal Geol 94:67–93CrossRef

Seredin VV, Finkelman RB (2008) Metalliferous coals: a review of the main genetic and geochemical types. Int J Coal Geol 76:253–289CrossRef

Song DY, Qin Y, Wang WF, Zhang JY, Zheng CG (2007) Geochemistry and modes of occurrence of hazardous trace elements in the No. 11 Coal Seam, Antaibao Surface Mine, Shanxi Province. Acta Geol Sinica 81(1):135–140

Spear DA, Martinez-Tarazona MR (1993) Geochemical and mineralogical characteristics of a power station feed-coal, Eggborough, England. Int J Coal Geol 22:1–20CrossRef

Vejahati F, Xu ZH, Gupta R (2010) Trace elements in coal: association with coal and minerals and their behavior during coal utilization. Fuel 89:904–911CrossRef

Wagner NJ, Tlotleng MT (2012) Distribution of selected trace elements in density fractioned Waterberg coals from South Africa. Int J Coal Geol 94:225–237CrossRef

Wang Q, Yang RD (2008) Study on REEs as tracer for Late Permian coal measures in Bijie city, Guizhou Province, China. J Rare Elements 26:121–126

Wang Q, Yang RD, Bao M (2008a) Rare elements stratigraphic significance in Late Permian coal measures from Bijie City, Guizhou Province, China. J Rare Elements 26(5):760–764

Wang WF, Qin Y, Sang SS, Zhu YM, Wang CY, Weiss DJ (2008b) Geochemistry of rare earth elements in a marine influenced coal and its solvent extracts from the Antaibao mining district, Shanxi, China. Int J Coal Geol 76:309–317CrossRef

Wang L, Ju YW, Liu GJ, Chou C-L, Zheng LG, Qi CC (2010) Selenium in Chinese coal: distribution, occurrence and health impact. Environ Earth Sci 60(8):1641–1651CrossRef

Yang J (2006a) Concentrations and modes of occurrence of trace elements in the Late Permian coals from the Pu’an Coalfield, southwestern Guizhou, China. Environ Geochem Health 28:567–576CrossRef

Yang J (2006b) Modes of occurrence and origins of noble metals in the Late Permian coals from the Pu’an Coalfield, Guizhou, southwest China. Fuel 85:1679–1684CrossRef

Yang RD, Liu L, Wei HR, Cui YC, Cheng W (2011) Geochemical characteristics of Guizhou Permian coal measure strata and analysis of the control factors. J Coal Sci Eng (China) 17:55–68CrossRef

Yudovich YE, Ketris MP (2006) Valuable trace elements in coal. Komi Scientific Center/Institute of Geology/Ural Division, RAS, Ekaterinburg, pp 1–538 (in Russian)

Zhang JY, Ren DY, Zheng CG, Zeng RS, Chou C-L, Liu J (2002) Trace element abundances in major minerals of Late Permian coals from southwestern Guizhou Province, China. Int J Coal Geol 53:55–64CrossRef

Zhang JY, Ren DY, Zhu YM, Chou C-L, Zeng RS, Zheng BS (2004) Mineral matter and potentially hazardous trace elements in coals from Qianxi Fault Depression Area in southwestern Guizhou, China. Int J Coal Geol 57:49–61CrossRef

Zhang Q, Tian YZ, Qiu YQ, Cao JX, Xiao TC (2011) Study on the washability of the Kaitai coal, Guizhou province China. Fuel Process Technol 92:692–698CrossRef

Zheng BS, Ding ZH, Huang RG, Zhu JM, Yu XY, Wang AM, Zhou DX, Mao DJ (1999) Issues of health and disease relating to coal use in southwest China. Int J Coal Geol 40(2–3):119–132CrossRef

Zheng LG, Liu GJ, Chou C-L, Qi CC, Zhang Y (2007) Geochemistry of rare earth elements in Permian coals from the Huaibei Coalfield, China. J Asian Earth Sci 31:167–176CrossRef

Zhuang XG, Querol X, Plana F, Alastuey A, López-Soler A, Wang H (2003) Determination of elemental affinities by density fractionation of bulk coal samples from the Chongqing coal district, Southwestern China. Int J Coal Geol 55:103–115CrossRef

Title: Occurrence modes and cleaning potential of sulfur and some trace elements in a high-sulfur coal from Pu’an coalfield, SW Guizhou, China
Authors: Wei Cheng
Qin Zhang
Ruidong Yang
Yingzhong Tian
Publication date: 01-07-2014
Publisher: Springer Berlin Heidelberg
Published in: Environmental Earth Sciences / Issue 1/2014
Print ISSN: 1866-6280
Electronic ISSN: 1866-6299
DOI: https://doi.org/10.1007/s12665-013-2934-6

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