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The heating performance and kinetic behaviour of oil shale during microwave pyrolysis

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  • He, Lu
  • Ma, Yue
  • Yue, Changtao
  • Li, Shuyuan
  • Tang, Xun

Abstract

In this study, the microwave pyrolysis of oil shales (MPOS) from Estonian Kukersite, Moroccan Tarfaya, Chinese Longkou, and Chinese Barkol were investigated. The heating performance of MPOS was also examined. A comparison study between MPOS and conventional oil shale pyrolysis (CPOS) was conducted, which included comparing the temperature profile, heating rate, weight loss at the same temperature, and the organic decomposition kinetic parameters. Results indicate that, under MPOS, both the maximum temperature (Tm) and average heating rate (γ) were influenced by the organic matter content in oil shale, and the effects were more significant at higher microwave powers (400–700 W) than at lower powers (200–400 W). Furthermore, both Tm or γ were linearly and/or exponentially correlated with microwave power with a breakpoint of 400 W in each correlation. Compared with CPOS, MPOS provided higher γ based on the same input powers and higher weight loss at the same temperatures. This demonstrates that MPOS requires much less processing time and a lower input energy than CPOS. Additionally, the kinetics of oil shale pyrolysis were modelled using the Kissinger method. For organic matter decomposition, MPOS decreased the activation energy by 13–39% and increased the reaction rate constant by at least 65%, compared to CPOS. This implies that under MPOS, higher powers are necessary to establish oil shale thermal reactivity and higher reaction rates can be obtained, thereby causing greater weight loss than with CPOS.

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  • He, Lu & Ma, Yue & Yue, Changtao & Li, Shuyuan & Tang, Xun, 2022. "The heating performance and kinetic behaviour of oil shale during microwave pyrolysis," Energy, Elsevier, vol. 244(PB).
    • Handle: RePEc:eee:energy:v:244:y:2022:i:pb:s0360544221032709
    DOI: 10.1016/j.energy.2021.123021
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    1. Kostas, Emily T. & Beneroso, Daniel & Robinson, John P., 2017. "The application of microwave heating in bioenergy: A review on the microwave pre-treatment and upgrading technologies for biomass," Renewable and Sustainable Energy Reviews, Elsevier, vol. 77(C), pages 12-27.
    2. Huang, Yu-Fong & Chiueh, Pei-Te & Kuan, Wen-Hui & Lo, Shang-Lien, 2016. "Microwave pyrolysis of lignocellulosic biomass: Heating performance and reaction kinetics," Energy, Elsevier, vol. 100(C), pages 137-144.
    3. Han, X.X. & Jiang, X.M. & Cui, Z.G., 2009. "Studies of the effect of retorting factors on the yield of shale oil for a new comprehensive utilization technology of oil shale," Applied Energy, Elsevier, vol. 86(11), pages 2381-2385, November.
    4. Jiang, X.M. & Han, X.X. & Cui, Z.G., 2007. "New technology for the comprehensive utilization of Chinese oil shale resources," Energy, Elsevier, vol. 32(5), pages 772-777.
    5. Appleton, T.J. & Colder, R.I. & Kingman, S.W. & Lowndes, I.S. & Read, A.G., 2005. "Microwave technology for energy-efficient processing of waste," Applied Energy, Elsevier, vol. 81(1), pages 85-113, May.
    6. Peng, Huadong & Chen, Hongzhang & Qu, Yongshui & Li, Hongqiang & Xu, Jian, 2014. "Bioconversion of different sizes of microcrystalline cellulose pretreated by microwave irradiation with/without NaOH," Applied Energy, Elsevier, vol. 117(C), pages 142-148.
    7. Muley, P.D. & Henkel, C.E. & Aguilar, G. & Klasson, K.T. & Boldor, D., 2016. "Ex situ thermo-catalytic upgrading of biomass pyrolysis vapors using a traveling wave microwave reactor," Applied Energy, Elsevier, vol. 183(C), pages 995-1004.
    8. Williams, Paul T. & Ahmad, Nasir, 2000. "Investigation of oil-shale pyrolysis processing conditions using thermogravimetric analysis," Applied Energy, Elsevier, vol. 66(2), pages 113-133, June.
    9. Greene, David L. & Hopson, Janet L. & Li, Jia, 2006. "Have we run out of oil yet? Oil peaking analysis from an optimist's perspective," Energy Policy, Elsevier, vol. 34(5), pages 515-531, March.
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    1. Hao Wang & Jianzheng Su & Jingyi Zhu & Zhaozhong Yang & Xianglong Meng & Xiaogang Li & Jie Zhou & Liangping Yi, 2022. "Numerical Simulation of Oil Shale Retorting Optimization under In Situ Microwave Heating Considering Electromagnetics, Heat Transfer, and Chemical Reactions Coupling," Energies, MDPI, vol. 15(16), pages 1-14, August.
    2. Zhan, Honglei & Yang, Qi & Qin, Fankai & Meng, Zhaohui & Chen, Ru & Miao, Xinyang & Zhao, Kun & Yue, Wenzheng, 2022. "Comprehensive preparation and multiscale characterization of kerogen in oil shale," Energy, Elsevier, vol. 252(C).
    3. Huang, HanWei & Yu, Hao & Xu, WenLong & Lyu, ChengSi & Micheal, Marembo & Xu, HengYu & Liu, He & Wu, HengAn, 2023. "A coupled thermo-hydro-mechanical-chemical model for production performance of oil shale reservoirs during in-situ conversion process," Energy, Elsevier, vol. 268(C).

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