| 光谱学与光谱分析 |
|
|
|
|
|
| Study on the Spectrum Research on the Process of Oil Shale Pyrolysis |
| LAN Xin-zhe1, 2, LUO Wan-jiang1, SONG Yong-hui1, ZHANG Qiu-li1, ZHOU Jun1* |
1. Xi’an University of Architecture and Technology, Research Center of Metallurgical Engineering & Technology of Shaanxi Province,Xi’an 710055, China
2. Shaanxi Radio & TV University,Xi’an 710068, China |
|
|
|
|
Abstract Spectral analysis is an important and unique advantageous method for the analysis of matter’s structure and composition. Aiming to discuss the change characteristic and evolution mechanism of mineral structure of oil shale, kerogen and sime-coke from oil shale pyrolysis under different temperature, the oil shale sample was obtained from Yaojie located in Gansu province, and the oil shale after pyrolysis experiments and acid washing were investigated and analyzed in detail withpolarizing microscope, Fourier transform spectroscopy (FTIR), X-Ray diffraction (XRD) and scanning electron microscope (SEM). The result shows that the mainly minerals of oil shale include quartz, clay and pyrite; kerogen is randomly distributed as mainly strip-shaped or blocky in inorganic minerals. The metamorphic degree of kerogen is higher, and rich in aliphatic structures and aromatic structures. Experiments of oil shale pyrolysis(temperature: 300~1 000 ℃, heating rate: 10 ℃·min-1) with temperature increasing, the composition of mineral begins to dissolve, kaolinite turning into metakaolinite with dehydration at 300 ℃, clay minerals such as kaolinite and montmorillonite completely turn into metakaolinite at 650 ℃. The silica-alumina spinel and amorphous SiO2, generated from the decomposition of metakaolinite at 1 000 ℃, and the amorphous SiO2, tends to react with iron mineral to form relative low melting point mixture on the semi-coke surfaces, such as FeO—Al2O3—SiO2. kerogen break down with increasing temperature, the infrared spectra intensity of C—H band of aliphatic and aromatic is reduced, while the intensity of C—C band aromatic is increased, and more carbonaceous residue as gully-shaped that remains in the mineral matrix after pyrolysis. These results are important for both the study of structure evolution of kerogen and minerals on the process of oil shale pyrolysis and will benefit for the subsequent processing and utilization of shale oil resource.
|
|
Received: 2015-06-09
Accepted: 2015-10-06
|
|
|
|
Corresponding Authors:
ZHOU Jun
E-mail: xazhoujun@126.com
|
|
[1] Jacob H Bauman, Milind D Deo. Energy Fuels, 2011, 25(2): 251.
[2] Han Xiangxin, Indrek Kulaots, Jiang Xiumin, et al. Fuel, 2014: 126(2): 143.
[3] Yamur S, Durusoy T. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects 2009, 31(14): 1227.
[4] WANG Qing, HUANG Zong-yue, CHI Ming-shu, et al(王 擎, 黄宗越, 迟铭书, 等). CIESC Journal(化工学报), 2015, 66(5): 1861.
[5] Tiikma L, Zaidensal A, Tensorer M. Oil Shale, 2007, 24(4): 535.
[6] WANG Jun, LIANG Jie, WANG Ze, et al(王 军, 梁 杰, 王 泽, 等). Coal Conversion(煤炭转化),2010, 33(1): 65.
[7] WANG Qing, SUN Bin, LIU Hong-peng, et al(王 擎, 孙 斌, 刘洪鹏, 等). Journal of Fuel Chemistry and Technology(燃料化学学报),2013, 41(2): 163.
[8] Rose H R, Smith D R. Energy and Fuels, 1993,(7): 319.
[9] QIAN Jia-lin, YIN Liang, WANG Jian-qiu, et al(钱家麟, 尹 亮, 王剑秋, 等). Oil Shale-the Complementary Energy of Petroleum. Beijing: China Petrochemical Press(北京: 中国石油出版社), 2008.
[10] BAI Yun-lai, LI Wei-hong, TANG Hua, et al(白云来, 李卫红, 汤 桦, 等). Gansu Geology(甘肃地质), 2011, 20(4): 46.
[11] Ravindra Kumar, Veena Bansal, Badhe R M, et al. Fuel, 2013, 113(6): 610.
[12] Chen Jieyu, Yan Chunjie, Tu Jing, et al. Non-Metallic Mines(非金属矿), 2009, 32(2): 21.
[13] LI Yan, YU Qing-chun, YANG Bin, et al(李 艳, 郁青春, 杨 斌, 等). Journal of Vacuum Science and Technology(真空科学与技术学报), 2012, 32(7): 599.
[14] ZHANG Nai-xian, LI You-qin, ZHAO Hui-min, et al(张乃娴, 李幼琴, 赵慧敏, 等). Research Methods of Clay Minerals. Beijing: Science Press(北京:科学出版社), 1990.
[15] QIN Kuang-zong, GUO Shao-hui(秦匡宗, 郭绍辉). Journal of Fuel Chemistry and Technology(燃料化学学报),1987, 19(1): 1. |
| [1] |
CHENG Jia-wei1, 2,LIU Xin-xing1, 2*,ZHANG Juan1, 2. Application of Infrared Spectroscopy in Exploration of Mineral Deposits: A Review[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 15-21. |
| [2] |
LIU Shu-hong1, 2, WANG Lu-si3*, WANG Li-sheng3, KANG Zhi-juan1, 2,WANG Lei1, 2,XU Lin1, 2,LIU Ai-qin1, 2. A Spectroscopic Study of Secondary Minerals on the Epidermis of Hetian Jade Pebbles From Xinjiang, China[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 169-175. |
| [3] |
GUO Na1, 2, WANG Xin-chen3*. Different Types of Deposits in Porphyry Metallogenic System Identified by 2 200 nm Al—OH Group Vibration[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(11): 3492-3496. |
| [4] |
WAN Huang-xu1, 2, LIU Ji-qiang1*, HAN Xi-qiu1, 2, LIANG Jin-long2, ZHOU Ya-dong1, FAN Wei-jia1, WANG Ye-jian1, QIU Zhong-yan1, MENG Fan-wei3. Ultrastructure and Mineral Composition of Bathymodiolus Shell From Wocan-1 Hydrothermal Vent, Northwest Indian Ocean[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(11): 3497-3503. |
| [5] |
XU Ya-fen1, LIU Xian-yu1*, CHEN Quan-li2, XU Chang3. Study on Mineral Composition and Spectral Characteristics of “Middle East Turquoise”[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(09): 2862-2867. |
| [6] |
YU Lian-gang1, LIU Xian-yu2*, CHEN Quan-li3. Gemstone Mineralogical and Spectroscopic Characteristics of
Quartzose Jade (“Mianlv Yu”)[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(08): 2543-2549. |
| [7] |
CAO Miao-cong1, CHEN Tao2*, QIN Hong-yu1, LIU Rui1, ZHANG Hai-jun3, GU Zhong-yuan1. The Spectra and Mineralogy Study of Changbai Colored Jade[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(07): 2202-2209. |
| [8] |
LI Quan-lun1, CHEN Zheng-guang1*, JIAO Feng2. Prediction of Oil Content in Oil Shale by Near-Infrared Spectroscopy Based on Stacking Ensemble Learning[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(04): 1030-1036. |
| [9] |
ZHANG Li-qian1, 2, LIU Yang-jie2, 3, LIN Bing-lan2, DUAN Jun1. Comparative Study on Mineralogical Identification and Spectral
Characteristics of Halloysitum Album, a Commercial Mineral
Medicine[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(03): 897-902. |
| [10] |
YAN Li-dong1, ZHU Ya-ming1*, CHENG Jun-xia1, GAO Li-juan1, BAI Yong-hui2, ZHAO Xue-fei1*. Study on the Correlation Between Pyrolysis Characteristics and Molecular Structure of Lignite Thermal Extract[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(03): 962-968. |
| [11] |
XIA Tong, LIU Yi-wei, GAO Yuan, CHENG Jie*, YIN Jian. Model-Fitting Methods for Mineral Raman Spectra Classification[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(02): 583-589. |
| [12] |
FU Ming-hai1, 2, DAI Jing-jing1*, WANG Xian-guang3, HU Zheng-hua4, PENG Bo1, WAN Xin3, ZHANG Zhong-xue2, ZHAO Long-xian1, 2. A Study on the Thermal Infrared Spectroscopy Characteristics of the Skarn Minerals in Zhuxi Tungsten Deposit, Jiangxi Province[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(01): 70-77. |
| [13] |
ZHAO Jian-ming, YANG Chang-bao, HAN Li-guo*, ZHU Meng-yao. The Inversion of Muscovite Content Based on Spectral Absorption
Characteristics of Rocks[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(01): 220-224. |
| [14] |
ZHANG Li-qian1, 2, LIU Yang-jie2, 3. Comparative Study on Mineralogical Identification and Spectral
Characteristics of Four Iron-Containing Mineral Medicines[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(09): 2884-2889. |
| [15] |
LUO Jie1, 2, YUE Su-wei1, 2*, GUO Hong-ying1, LIU Jia-jun3. Spectroscopic Characteristics and Coloring Mechanism of Smithsonite
Jade[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(06): 1886-1890. |
|
|
|
|
