Systematic investigation of SO2 adsorption and desorption by porous powdered activated coke: Interaction between adsorption temperature and desorption energy consumption

doi:10.1016/j.cjche.2021.08.002

Chinese Journal of Chemical Engineering ›› 2022, Vol. 48 ›› Issue (8): 140-148.DOI: 10.1016/j.cjche.2021.08.002

Previous Articles Next Articles

Systematic investigation of SO₂ adsorption and desorption by porous powdered activated coke: Interaction between adsorption temperature and desorption energy consumption

Jun Li¹, Liqiang Zhang¹, Xiao Zhu¹, Mengze Zhang¹, Tai Feng², Xiqiang Zhao¹, Tao Wang¹, Zhanlong Song¹, Chunyuan Ma¹

1. National Engineering Laboratory for Reducing Emissions from Coal Combustion, Engineering Research Center of Environmental Thermal Technology of Ministry of Education, Shandong Key Laboratory of Energy Carbon Reduction and Resource Utilization, School of Energy and Power Engineering, Shandong University, Jinan 250061, China;
2. College of Mechanical and Electronic Engineering, Shandong University of Science and Technology, Qingdao 266590, China

Received:2021-06-09 Revised:2021-07-27 Online:2022-09-30 Published:2022-08-28
Contact: Liqiang Zhang,E-mail:zhlq@sdu.edu.cn;Zhanlong Song,E-mail:zlsong@sdu.edu.cn
Supported by:
This work was supported by the National Key Research and Development Program of China (2017YFB0602901).

Systematic investigation of SO₂ adsorption and desorption by porous powdered activated coke: Interaction between adsorption temperature and desorption energy consumption

Jun Li¹, Liqiang Zhang¹, Xiao Zhu¹, Mengze Zhang¹, Tai Feng², Xiqiang Zhao¹, Tao Wang¹, Zhanlong Song¹, Chunyuan Ma¹

1. National Engineering Laboratory for Reducing Emissions from Coal Combustion, Engineering Research Center of Environmental Thermal Technology of Ministry of Education, Shandong Key Laboratory of Energy Carbon Reduction and Resource Utilization, School of Energy and Power Engineering, Shandong University, Jinan 250061, China;
2. College of Mechanical and Electronic Engineering, Shandong University of Science and Technology, Qingdao 266590, China

通讯作者: Liqiang Zhang,E-mail:zhlq@sdu.edu.cn;Zhanlong Song,E-mail:zlsong@sdu.edu.cn
基金资助:
This work was supported by the National Key Research and Development Program of China (2017YFB0602901).

Abstract

Abstract: Porous carbon materials have been widely used for the removal of SO₂ from flue gas. The main objective of this work is to clarify the effects of adsorption temperature on SO₂ adsorption and desorption energy consumption. Coal-based porous powdered activated coke (PPAC) prepared in the drop-tube reactor was used in this study. The N₂ adsorption measurements and Fourier transform infrared spectrometer analysis show that PPAC exhibits a developed pore structure and rich functional groups. The experimental results show that with a decrease in adsorption temperature in the range of 50–150?℃, the adsorption capacity of SO₂ increases linearly; meanwhile, the adsorption capacity of H₂O increases, resulting in the increase in desorption energy consumption per unit mass of adsorbent. The processes of SO₂ and H₂O desorption were determined by the temperature-programmed desorption test, and the desorption energies for each species were calculated. Considering the energy consumption per unit of desorption and the total amount of adsorbent, the optimal adsorption temperature yielding the minimum total energy consumption of regeneration is calculated. This study systematically demonstrates the effect of adsorption temperature on the adsorption–desorption process, providing a basis for energy saving and emission reduction in desulfurization system design.

Key words: Activated coke, SO₂ adsorption, Desorption energy consumption, Optimal adsorption temperature

摘要： Porous carbon materials have been widely used for the removal of SO₂ from flue gas. The main objective of this work is to clarify the effects of adsorption temperature on SO₂ adsorption and desorption energy consumption. Coal-based porous powdered activated coke (PPAC) prepared in the drop-tube reactor was used in this study. The N₂ adsorption measurements and Fourier transform infrared spectrometer analysis show that PPAC exhibits a developed pore structure and rich functional groups. The experimental results show that with a decrease in adsorption temperature in the range of 50–150?℃, the adsorption capacity of SO₂ increases linearly; meanwhile, the adsorption capacity of H₂O increases, resulting in the increase in desorption energy consumption per unit mass of adsorbent. The processes of SO₂ and H₂O desorption were determined by the temperature-programmed desorption test, and the desorption energies for each species were calculated. Considering the energy consumption per unit of desorption and the total amount of adsorbent, the optimal adsorption temperature yielding the minimum total energy consumption of regeneration is calculated. This study systematically demonstrates the effect of adsorption temperature on the adsorption–desorption process, providing a basis for energy saving and emission reduction in desulfurization system design.

关键词: Activated coke, SO₂ adsorption, Desorption energy consumption, Optimal adsorption temperature

Jun Li, Liqiang Zhang, Xiao Zhu, Mengze Zhang, Tai Feng, Xiqiang Zhao, Tao Wang, Zhanlong Song, Chunyuan Ma. Systematic investigation of SO₂ adsorption and desorption by porous powdered activated coke: Interaction between adsorption temperature and desorption energy consumption[J]. Chinese Journal of Chemical Engineering, 2022, 48(8): 140-148.

References

[1] S.C. Ma, J.J. Yao, L. Gao, X.Y. Ma, Y. Zhao, Experimental study on removals of SO2 and NOx using adsorption of activated carbon/microwave desorption, J Air Waste Manag. Assoc. 62 (9) (2012) 1012–1021
[2] K.Q. Jiang, H. Yu, L.H. Chen, M.X. Fang, M. Azzi, A. Cottrell, K.K. Li, An advanced, ammonia-based combined NOx/SOx/CO2 emission control process towards a low-cost, clean coal technology, Appl. Energy 260 (2020) 114316
[3] J.M. Ou, J. Meng, J.Y. Zheng, Z.F. Mi, Y.H. Bian, X. Yu, J.R. Liu, D.B. Guan, Demand-driven air pollutant emissions for a fast-developing region in China, Appl. Energy 204 (2017) 131–142
[4] S. Wu, W.L. Wang, C.Z. Ren, X.L. Yao, Y.G. Yao, Q.S. Zhang, Z.F. Li, Calcination of calcium sulphoaluminate cement using flue gas desulfurization gypsum as whole calcium oxide source, Constr. Build. Mater. 228 (2019) 116676
[5] F.H. Yang, R.T. Yang, Ab initio molecular orbital study of the mechanism of SO2 oxidation catalyzed by carbon, Carbon 41 (11) (2003) 2149–2158
[6] J.R. PliegoJr, S.M. Resende, E. Humeres, Chemisorption of SO2 on graphite surface: A theoretical ab initio and ideal lattice gas model study, Chem. Phys. 314 (1–3) (2005) 127–133
[7] E. Raymundo-Pi?ero, D. Cazorla-Amorós, A. Linares-Solano, Temperature programmed desorption study on the mechanism of SO2 oxidation by activated carbon and activated carbon fibres, Carbon 39 (2) (2001) 231–242
[8] E. Richter, Modelling of thermal desorption of active coke loaded with sulphuric acid and ammonium sulphate, Chem. Eng. Technol. 13 (1) (1990) 101–112
[9] F. Sun, J.H. Gao, X. Liu, X.F. Tang, S.H. Wu, A systematic investigation of SO2 removal dynamics by coal-based activated cokes: The synergic enhancement effect of hierarchical pore configuration and gas components, Appl. Surf. Sci. 357 (2015) 1895–1901
[10] X.X. Pi, F. Sun, J.H. Gao, Z.B. Qu, A.N. Wang, Z.P. Qie, L.J. Wang, H. Liu, A new insight into the SO2 adsorption behavior of oxidized carbon materials using model adsorbents and DFT calculations, Phys. Chem. Chem. Phys. 21 (18) (2019) 9181–9188
[11] Z.B. Qu, F. Sun, J.H. Gao, X.X. Pi, Z.P. Qie, G.B. Zhao, A new insight into SO2 low-temperature catalytic oxidation in porous carbon materials: Non-dissociated O2 molecule as oxidant, Catal. Sci. Technol. 9 (16) (2019) 4327–4338
[12] B. Rubio, M.T. Izquierdo, Coal fly ash based carbons for SO2 removal from flue gases, Waste Manag. 30 (7) (2010) 1341–1347
[13] Y.S. Wang, L. Zhang, L. Zhang, M.M. Qiang, Y.X. Sun, X.N. Xi, Effects of CuO- base metal supporting catalyst on flue gas desulfurization performance, Ind. Saf. Environ. Prot. (2015) 41(8)100–102. (in Chinese)
[14] J.H. Qi, K.H. Han, Q. Wang, J. Gao, Carbonization of biomass: Effect of additives on alkali metals residue, SO2 and NO emission of chars during combustion, Energy 130 (2017) 560–569
[15] K.X. Li, L.C. Ling, L. Liu, B.J. Zhang, Z.Y. Liu, Desulfurization activity of activated carbon fiber modified by heat treatment, Chin. J. Catal. (03) (2000) 71-75. (in Chinese)
[16] X.X. Pi, F. Sun, J.H. Gao, Y.W. Zhu, L.J. Wang, Z.B. Qu, H. Liu, G.B. Zhao, Microwave irradiation induced high-efficiency regeneration for desulfurized activated coke: A comparative study with conventional thermal regeneration, Energy Fuels 31 (9) (2017) 9693–9702
[17] F. Salvador, N. Martin-Sanchez, R. Sanchez-Hernandez, M.J. Sanchez-Montero, C. Izquierdo, Regeneration of carbonaceous adsorbents. Part I: Thermal regeneration, Microporous Mesoporous Mater. 202 (2015) 259–276
[18] F. Sun, J.H. Gao, Y.W. Zhu, Y.K. Qin, Mechanism of SO2 adsorption and desorption on commercial activated coke, Korean J. Chem. Eng. 28 (11) (2011) 2218–2225
[19] S.J. Liu, X.N. Yu, G.X. Lin, R.Y. Qu, C.H. Zheng, X. Gao, Insights into the effect of adsorption–desorption cycles on SO2 removal over an activated carbon, Aerosol Air Qual. Res. 19 (2) (2019) 411–421
[20] G.L. Song, S.B. Yang, W.J. Song, X.B. Qi, Release and transformation behaviors of sodium during combustion of high alkali residual carbon, Appl. Therm. Eng. 122 (2017) 285–296
[21] B. Li, J.M.Xue, Y.Y. Xu, H.L. Wang, C.Y. Ma, J.M. Chen. Equilibrium, kinetics and thermodynamics of SO2 adsorption activated carbon, J. China Coal Soc.10 (2014) 2100-2106. (in Chinese)
[22] A.M. Kisiela, K.M. Czajka, W. Moroń, W. Rybak, C. Andryjowicz, Unburned carbon from lignite fly ash as an adsorbent for SO2 removal, Energy 116 (2016) 1454–1463
[23] Z. Zhang, T. Wang, L. Ke, X.Q. Zhao, C.Y. Ma, Powder-activated semicokes prepared from coal fast pyrolysis: Influence of oxygen and steam atmosphere on pore structure, Energy Fuels 30 (2) (2016) 896–903
[24] J.P. Fu, B.X. Zhou, Z. Zhang, T. Wang, X.X. Cheng, L.T. Lin, C.Y. Ma, One-step rapid pyrolysis activation method to prepare nanostructured activated coke powder, Fuel 262 (2020) 116514
[25] R.Q. Long, R.T. Yang, Carbon nanotubes as superior sorbent for dioxin removal, J. Am. Chem. Soc. 123 (9) (2001) 2058–2059
[26] Y.Y. Guo, Y.R. Li, T.Y. Zhu, M. Ye, Investigation of SO2 and NO adsorption species on activated carbon and the mechanism of NO promotion effect on SO2, Fuel 143 (2015) 536–542
[27] Y.L. Xu, B.L. Chen, Investigation of thermodynamic parameters in the pyrolysis conversion of biomass and manure to biochars using thermogravimetric analysis, Bioresour. Technol. 146 (2013) 485–493
[28] E. Müsellim, M.H. Tahir, M.S. Ahmad, S. Ceylan, Thermokinetic and TG/DSC-FTIR study of pea waste biomass pyrolysis, Appl. Therm. Eng. 137 (2018) 54–61
[29] A.A.D. Maia, L.C. de Morais, Kinetic parameters of red pepper waste as biomass to solid biofuel, Bioresour. Technol. 204 (2016) 157–163
[30] E. Cetin, B. Moghtaderi, R. Gupta, T.F. Wall, Influence of pyrolysis conditions on the structure and gasification reactivity of biomass chars, Fuel 83 (16) (2004) 2139–2150
[31] J. Chen, D.D. Fang, F. Duan, Pore characteristics and fractal properties of biochar obtained from the pyrolysis of coarse wood in a fluidized-bed reactor, Appl. Energy 218 (2018) 54–65
[32] B.X. Zhou, T. Wang, C. Li, J.P. Fu, Z. Zhang, Z.L. Song, C.Y. Ma, Multi-objective optimization of the preparation parameters of the powdered activated coke for SO2 adsorption using response surface methodology, J. Anal. Appl. Pyrolysis 146 (2020) 104776
[33] Z. Zhang, T. Wang, X.H. Pan, B.X. Zhou, C.Y. Ma, Effect of temperature on pore structure evolution during powder-activated coke preparation by flue gas activation, J. China Coal Soc. 44 (11) (2019) 3564-3570. (in Chinese)
[34] J.J. Li, N. Kobayashi, Y.Q. Hu, The activated coke preparation for SO2 adsorption by using flue gas from coal power plant, Chem. Eng. Process.: Process. Intensif. 47 (1) (2008) 118–127
[35] S.G. Herawan, M.S. Hadi, M.R. Ayob, A Putra, Characterization of activated carbons from oil-palm shell by CO2 activation with no holding carbonization temperature, Scientific World J. 2013 (2013) 624865
[36] N.R. Candido, M.J. Prauchner, A.D.O. Vilela, V.M.D. Pasa, The use of gases generated from eucalyptus carbonization as activating agent to produce activated carbon: An integrated process, J. Environ. Chem. Eng. 8 (4) (2020) 103925
[37] J.F. González, S. Román, C.M. González-García, J.M.V. Nabais, A.L. Ortiz, Porosity development in activated carbons prepared from walnut shells by carbon dioxide or steam activation, Ind. Eng. Chem. Res. 48 (16) (2009) 7474–7481
[38] Y.X. Guo, Z.Y. Liu, Q.Y. Liu, Z.G. Huang, Regeneration of a vanadium pentoxide supported activated coke catalyst-sorbent used in simultaneous sulfur dioxide and nitric oxide removal from flue gas: Effect of ammonia, Catal. Today 131 (1–4) (2008) 322–329
[39] S. Ding, Y. Li, T. Zhu, Y. Guo, Regeneration performance and carbon consumption of semi-coke and activated coke for SO? and NO removal, J. Environ. Sci. (China) 34 (2015) 37–43
[40] L.Q. Zhang, H.T. Jiang, B. Li, L. Chen, C.Y. Ma, Desorption mechanism and kinetics of SO2 loaded activatedcarbon by microwave irradiation, J. China Coal Soc. 37 (11) (2012) 1920-1924. (in Chinese)
[41] D.H. Zhang, C.Y. Song, L. Zhang, Q.Y. Gu, Effect of approach to adiabatic saturation temperature on flue gas desulfurization by PAN-ACF, J. Univ. Sci. Technol. Beijing, (02) (2012) 196-201. (in Chinese)
[42] H. Zhang, Study on adsorption of sulfur dioxide over zeolites, M.S. Thesis, Harbin Institute of Technology, China, 2008. (in Chinese).
[43] D.D. Do, H.D. Do, A model for water adsorption in activated carbon, Carbon 38 (5) (2000) 767–773
[44] K. Kaneko, Y. Hanzawa, T. Iiyama, T. Kanda, T. Suzuki, Cluster-mediated water adsorption on carbon nanopores, Adsorption 5 (1) (1999) 7–13
[45] H.L. Chiang, J.H. Tsai, C.L. Tsai, Y.C. Hsu, Adsorption characteristics of alkaline activated carbon exemplified by water vapor, H2S, and CH3SH gas, Sep. Sci. Technol. 35 (6) (2000) 903–918
[46] G.S. Szymanski, Z. Karpinski, S. Biniak, A. Swi?tkowski, The effect of the gradual thermal decomposition of surface oxygen species on the chemical and catalytic properties of oxidized activated carbon, Carbon 40 (14) (2002) 2627–2639
[47] J.M. Rosas, R. Ruiz-Rosas, J. Rodríguez-Mirasol, T. Cordero, Kinetic study of SO2 removal over lignin-based activated carbon, Chem. Eng. J. 307 (2017) 707–721
[48] Bashkova S, Bagreev A, Locke DC, Bandosz TJ, Adsorption of SO2 on sewage sludge-derived materials, Environ. Sci. Technol. 35 (15) (2001) 3263–3269
[49] S.C. Turmanova, S.D. Genieva, A.S. Dimitrova, L.T. Vlaev, Non-isothermal degradation kinetics of filled with rise husk ash polypropene composites, Express Polym. Lett. 2 (2) (2008) 133–146
[50] Y. He, X.B. Zhang, W. Chen, B. Zhang, Z. Zhang, Experimental study and thermal analysis of the combustion characteristics of powder-activated cokes, Powder Technol. 356 (2019) 640–648
[51] S.M. Yang, W.Q. Tao, Heat Transfer, China Higher Education Press, Beijing, 2006, pp. 563-564. (in Chinese)
[52] K.S. Hong, E.H. Wei, Mathematical model of common physical property data in sulfuric acid process calculation, Sulphuric Acid Ind. 4 (1986) 59-64. (in Chinese)

Systematic investigation of SO₂ adsorption and desorption by porous powdered activated coke: Interaction between adsorption temperature and desorption energy consumption

Systematic investigation of SO₂ adsorption and desorption by porous powdered activated coke: Interaction between adsorption temperature and desorption energy consumption

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 0

Recommended Articles

Metrics

Comments