Predictive models for characterizing the atomization process in pyrolysis of methyl ricinoleate

doi:10.1016/j.cjche.2020.02.007

Chinese Journal of Chemical Engineering ›› 2020, Vol. 28 ›› Issue (4): 1023-1028.DOI: 10.1016/j.cjche.2020.02.007

• Fluid Dynamics and Transport Phenomena • Previous Articles Next Articles

Predictive models for characterizing the atomization process in pyrolysis of methyl ricinoleate

Xiaoning Mao, Qinglong Xie, Ying Duan, Shangzhi Yu, Xiaojiang Liang, Zhenyu Wu, Meizhen Lu, Yong Nie

Biodiesel Laboratory of China Petroleum and Chemical Industry Federation, Zhejiang Provincial Key Laboratory of Biofuel, and College of Chemical Engineering, Zhejiang University of Technology, Hangzhou 310014, China

Received:2019-07-30 Revised:2019-12-01 Online:2020-07-27 Published:2020-04-28
Contact: Yong Nie
Supported by:
We are grateful to the National Natural Science Foundation of China (grant number 21776261), the Zhejiang Province Public Welfare Technology Application Research Project (grant number 2017C31016) and the China Postdoctoral Science Foundation (grant number 2017M612029).

Predictive models for characterizing the atomization process in pyrolysis of methyl ricinoleate

Xiaoning Mao, Qinglong Xie, Ying Duan, Shangzhi Yu, Xiaojiang Liang, Zhenyu Wu, Meizhen Lu, Yong Nie

Biodiesel Laboratory of China Petroleum and Chemical Industry Federation, Zhejiang Provincial Key Laboratory of Biofuel, and College of Chemical Engineering, Zhejiang University of Technology, Hangzhou 310014, China

通讯作者: Yong Nie
基金资助:
We are grateful to the National Natural Science Foundation of China (grant number 21776261), the Zhejiang Province Public Welfare Technology Application Research Project (grant number 2017C31016) and the China Postdoctoral Science Foundation (grant number 2017M612029).

Abstract

Abstract: Pyrolysis of methyl ricinoleate (MR) can produce undecylenic acid methyl ester and heptanal which are important chemicals. Atomization feeding favors the heat exchange in the pyrolysis process and hence increases the product yield. Herein, predictive models to characterize the atomization process were developed. The effect of spray distance on Sauter mean diameter (SMD) of atomized MR droplets was examined, with the optimal spray distance to be 40-50 mm. Temperature mainly affected the physical properties of feedstock, with smaller droplet size obtained at increasing temperature. In addition, pressure had significant influence on SMD and higher pressure resulted in smaller atomized droplets. Then, a model for SMD prediction, combining temperature, pressure, spray distance, and structural parameters of nozzle, was developed through dimensionless analysis. The results showed that SMD was a power function of Reynolds number (Re), Ohnesorge number (Oh), and the ratio of spray distance to diameter of swirl chamber in the nozzle (H/d_sc), with the exponents of -1.6618, -1.3205 and 0.1038, respectively. The experimental measured SMD was in good agreement with the calculated values, with the error within ±15%. Moreover, the droplet size distribution was studied by establishing the relationship between the standard deviation of droplet size and SMD. This study could provide reference to the regulation and optimization of the atomization process in MR pyrolysis.

Key words: Atomization, Methyl ricinoleate pyrolysis, Predictive model, Sauter mean diameter (SMD), Spray distance

摘要： Pyrolysis of methyl ricinoleate (MR) can produce undecylenic acid methyl ester and heptanal which are important chemicals. Atomization feeding favors the heat exchange in the pyrolysis process and hence increases the product yield. Herein, predictive models to characterize the atomization process were developed. The effect of spray distance on Sauter mean diameter (SMD) of atomized MR droplets was examined, with the optimal spray distance to be 40-50 mm. Temperature mainly affected the physical properties of feedstock, with smaller droplet size obtained at increasing temperature. In addition, pressure had significant influence on SMD and higher pressure resulted in smaller atomized droplets. Then, a model for SMD prediction, combining temperature, pressure, spray distance, and structural parameters of nozzle, was developed through dimensionless analysis. The results showed that SMD was a power function of Reynolds number (Re), Ohnesorge number (Oh), and the ratio of spray distance to diameter of swirl chamber in the nozzle (H/d_sc), with the exponents of -1.6618, -1.3205 and 0.1038, respectively. The experimental measured SMD was in good agreement with the calculated values, with the error within ±15%. Moreover, the droplet size distribution was studied by establishing the relationship between the standard deviation of droplet size and SMD. This study could provide reference to the regulation and optimization of the atomization process in MR pyrolysis.

关键词: Atomization, Methyl ricinoleate pyrolysis, Predictive model, Sauter mean diameter (SMD), Spray distance

Xiaoning Mao, Qinglong Xie, Ying Duan, Shangzhi Yu, Xiaojiang Liang, Zhenyu Wu, Meizhen Lu, Yong Nie. Predictive models for characterizing the atomization process in pyrolysis of methyl ricinoleate[J]. Chinese Journal of Chemical Engineering, 2020, 28(4): 1023-1028.

References

[1] D.S. Ogunniyi, Castor oil:a vital industrial raw material, Bioresour. Technol. 97(2006) 1086-1091.
[2] S.M. Van, C.V. Stevens, Undecylenic acid:a valuable and physiologically active renewable building block from castor oil, ChemSusChem. 2(2010) 692-713.
[3] B. Vishwanadham, H.S. Rao, D. Sadasivudu, A.A. Khan, Pyrolysis of castor oil methylesters to 10-undecenoic acid and heptaldehyde, Indian J. Chem. Technol. 2(1995) 119-128.
[4] G. Han, Z. Liu, S. Yao, R. Yan, Study of reaction and kinetics in pyrolysis of methyl ricinoleate, J. Am. Oil Chem. Soc. 73(1996) 1109-1112.
[5] H.B. Hu, K.W. Park, Y.M. Kim, J.S. Hong, W.H. Kim, B.K. Hur, J.W. Yang, Optimization of production temperatures of heptaldehyde and methyl undecenoate from methyl ricinoleate by pyrolysis process, J. Ind. Eng. Chem. 6(2000) 238-241.
[6] V. Botton, R. Torres De Souza, V.R. Wiggers, D.R. Scharf, E.L. Simionatto, L. Ender, H.F. Meier, Thermal cracking of methyl esters in castor oil and production of heptaldehyde and methyl undecenoate, J. Anal. Appl. Pyrolysis 121(2016) 387-393.
[7] Y. Nie, Y. Duan, R. Gong, S. Yu, M. Lu, F. Yu, J. Ji, Microwave-assisted pyrolysis of methyl ricinoleate for continuous production of undecylenic acid methyl ester (UAME), Bioresour. Technol. 186(2015) 334-337.
[8] S. Yu, Y. Duan, X. Mao, Q. Xie, G. Zeng, M. Lu, Y. Nie, J. Ji, Pyrolysis of methyl ricinoleate by microwave-assisted heating coupled with atomization feeding, J. Anal. Appl. Pyrolysis (2018) 1-8.
[9] S. Yu, Y. Duan, X. Zhou, Q. Xie, G. Zeng, X. Mao, X. Liang, M. Lu, Y. Nie, J. Ji, Three-dimensional simulation of a novel microwave-assisted heating device for methyl ricinoleate pyrolysis, Appl. Therm. Eng. 153(2019) 341-351.
[10] S. Poozesh, N. Setiawan, N.K. Akafuah, K. Saito, P.J. Marsac, Assessment of predictive models for characterizing the atomization process in a spray dryer's bi-fluid nozzle, Chem. Eng. Sci. 180(2018) 42-51.
[11] N. Ashgriz, Handbook of Atomization and Sprays, Theory and Applications, 3th ed. Springer, New York, US, 2011215-231.
[12] S.M. Hosseinalipour, H. Karimaei, E. Movahednejad, Droplets diameter distribution using maximum entropy formulation combined with a new energy-based submodel, Chin. J. Chem. Eng. 24(2016) 1625-1630.
[13] R. Kolodnytska, S. Skurativskyi, P. Moskvin, Maximum entropy method for biodiesel spray droplet istribution, 28th European Conference on Liquid Atomization and Spray Systems (ILASS), Univ Politecnica Valencia, Valencia, Spain 06-08(Sep. 2017) 464-471.
[14] D. Sivakumar, S.K. Vankeswaram, R. Sakthikumar, B.N. Raghunandan, Analysis on the atomization characteristics of aviation biofuel discharging from simplex swirl atomizer, Int. J. Multiphase Flow 72(2015) 88-96.
[15] A. Sadeghi, M. Hassan, H. Veisi, M. Fattahi, Thermally developing electroosmotic flow of power-law fluids in a parallel plate microchannel, Int. J. Therm. Sci. 61(2012) 106-117.
[16] A. Darvishi, R. Davand, F. Khorasheh, M. Fattahi, Modeling-based optimization of fixed-bed industrial reactors for oxidative dehydrogenation of propane (ODHP), Chin. J. Chem. Eng. 24(2016) 612-622.
[17] P.B. Kowalczuk, J. Drzymala, Physical meaning of the Sauter mean diameter of spherical particulate matter, Part. Sci. Technol. 34(2016) 645-647.
[18] G. Brenn, Drop size spectra in sprays from pressure-swirl atomizers, Int. J. Multiphase Flow 36(2010) 349-363.
[19] J.O. Hinze, Fundamentals of the hydrodynamic mechanism of splitting in dispersion processes, AIChE J 1(2010) 289-295.
[20] A.H. Lefebvre, Atomization and Sprays, Hemisphere Publishing Corporation, New York, US, 19891-75.
[21] Y. Duan, Y. Nie, R. Gong, S. Yu, D. Deng, M. Lu, P. Chen, J. Ji, Measurements and correlations of density, viscosity, and vapor pressure for methyl ricinoleate, J. Chem. Eng. Data 61(2016) 766-771.
[22] J.M.R. Patino, M.R.R. Niño, Interfacial characteristics of food emulsifiers (proteins and lipids) at the air-water interface, Colloid Surf. B-Biointerfaces 15(1999) 235-252.
[23] T. Richter, H.W. Glaser, Auslegung von Hohlkegel-Druckdüsen, Chem. Ing. Tech. 59(1987) 332-334.
[24] W.A. Sowa, Interpreting mean drop diameters using distribution moments, Atomization Sprays 2(1992) 1-15.

Predictive models for characterizing the atomization process in pyrolysis of methyl ricinoleate

Predictive models for characterizing the atomization process in pyrolysis of methyl ricinoleate

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