3D printed millireactors for process intensification

doi:10.1016/j.cjche.2018.12.013

Abstract

Abstract: The scope of the present research aims at demonstrating the 3D printing use in the manufacturing of microchannels for chemical process applications. A comparison among digital model processing applications for 3D print (slicers) and a print layer thickness analysis were performed. The 3D print fidelity was verified in several devices, including the microchannels' printing with and without micromixer zones. In order to highlight the 3D print potential in Chemical Engineering, the biodiesel synthesis was also carried out in a millireactor manufactured by 3D printing. The millireactor operated under laminar flow regime with a total flow rate of 75.25 ml·min^-1 (increment of about 130 times over traditional microdevices used for biodiesel production). The printed millireactor provided a maximum yield of Ethyl Esters of 73.51% at 40℃, ethanol:oil molar ratio of 7 and catalyst concentration of 1.25 wt% and residence time about 10 s. As a result of flow rate increment attained in the millireactor, the number of required units for scaling-up the chemical processes is reduced. Using the approach described in the present research, anyone could produce their own millireactor for chemical process in a simple way with the aid of a 3D printer.

Key words: Process intensification, 3D printer, Millireactors, Micromixers, Microdevices, Biodiesel

摘要： The scope of the present research aims at demonstrating the 3D printing use in the manufacturing of microchannels for chemical process applications. A comparison among digital model processing applications for 3D print (slicers) and a print layer thickness analysis were performed. The 3D print fidelity was verified in several devices, including the microchannels' printing with and without micromixer zones. In order to highlight the 3D print potential in Chemical Engineering, the biodiesel synthesis was also carried out in a millireactor manufactured by 3D printing. The millireactor operated under laminar flow regime with a total flow rate of 75.25 ml·min^-1 (increment of about 130 times over traditional microdevices used for biodiesel production). The printed millireactor provided a maximum yield of Ethyl Esters of 73.51% at 40℃, ethanol:oil molar ratio of 7 and catalyst concentration of 1.25 wt% and residence time about 10 s. As a result of flow rate increment attained in the millireactor, the number of required units for scaling-up the chemical processes is reduced. Using the approach described in the present research, anyone could produce their own millireactor for chemical process in a simple way with the aid of a 3D printer.

关键词: Process intensification, 3D printer, Millireactors, Micromixers, Microdevices, Biodiesel

Harrson S. Santana, Alan C. Rodrigues, Mariana G. M. Lopes, Felipe N. Russo, Jo?o L. Silva Jr, Osvaldir P. Taranto. 3D printed millireactors for process intensification[J]. Chinese Journal of Chemical Engineering, 2020, 28(1): 180-190.

Harrson S. Santana, Alan C. Rodrigues, Mariana G. M. Lopes, Felipe N. Russo, Jo?o L. Silva Jr, Osvaldir P. Taranto. 3D printed millireactors for process intensification[J]. 中国化学工程学报, 2020, 28(1): 180-190.

References

[1] C. Ramshaw, The incentive for process intensification, Proceedings, 1st Intl. Conf. Proc. Intensif. For Chem. Ind., 18, BHR Group, London 1995, p. 1.
[2] A.I. Stankiewicz, J.A. Moulijn, Process intensification:transforming chemical engineering, Chem. Eng. Prog. (2000) 22-34.
[3] R.C. Lo, Application of microfluidics in chemical engineering, Chem. Eng. Process Technol. 1(2013) 1002.
[4] H.S. Fogler, Elements of Chemical Reaction Engineering, fouth ed. Prentice Hall PTR, Upper Saddle River, NJ, 2006.
[5] G.M. Whitesides, The origins and the future of microfluidics, Nature 442(2006) 368-373.
[6] A. Skardal, S.V. Murphy, M. Devarasetty, I. Mead, H.-W. Kang, Y.-J. Seol, Y.S. Zhang, S.-R. Shin, L. Zhao, J. Aleman, A.R. Hall, T.D. Shupe, A. Kleensang, M.R. Dokmeci, S.J. Lee, J.D. Jackson, J.J. Yoo, T. Hartung, A. Khademhosseini, S. Soker, C.E. Bishop, A. Atala, Multi-tissue interactions in an integrated three-tissue organ-on-a-chip platform, Sci. Rep. 7(2017) 8837.
[7] S. Cardoso, D.C. Leitao, T.M. Dias, et al., Challenges and trends in magnetic sensor integration with microfluidics for biomedical applications, J. Phys. D. Appl. Phys. 50(2017).
[8] H.S. Santana, G.B. Sanchez, O.P. Taranto, Evaporation of excess alcohol in biodiesel in a microchannel heat exchanger with Peltier module, Chem. Eng. Res. Des. 124(2017) 20-28.
[9] H.S. Santana, D.S. Tortola, E.M. Reis, J.L. Silva Jr., O.P. Taranto, Transesterification reaction of sunflower oil and ethanol for biodiesel synthesis in microchannel reactor:experimental and simulation studies, Chem. Eng. J. 302(2016) 752-762.
[10] J.L. Silva Jr., H.S. Santana, G.B. Sanchez, O.P. Taranto, Numerical simulation of excess ethanol evaporation from biodiesel in a micro heat-exchanger, Chem. Eng. Trans. 57(2017) 1123-1128.
[11] J. Singh, N. Kockmann, Novel three-dimensional microfluidic device for process intensification, Chem. Eng. Process. Process Intensif. 86(2014) 78-89.
[12] A. Pohar, I. Plazl, Process intensification through microreactor application, Chem. Biochem. Eng. Q. 23(2009) 537-544.
[13] M.P.C. Marques, P. Fernandes, Microfluidic devices:useful tools for bioprocess intensification, Molecules 16(2011) 8368-8401.
[14] J. Zhang, K. Wang, A.R. Teixeira, K.F. Jensen, G. Luo, Design and scaling up of microchemical systems:a review, Annu. Rev. Chem. Biomol. Eng. 8(2017) 285-305.
[15] J. Melo, Usinas de biodiesel em Pernambuco, https://www.biodieselbr.com/noticias/colunistas/convidado/usinas-biodiesel-pernambuco-300410.htm,Accessed date:16 November 2017.
[16] K.S. Elvira, X.C. Solvas, R.C.R. Wootton, A.J. Mello, The past, present and potential for microfluidic reactor technology in chemical synthesis, Nat. Chem. 5(2013) 905-915.
[17] H.S. Santana, J.L. Silva Jr., O.P. Taranto, Numerical simulation of biodiesel synthesis in microchannels with circular obstructions, Chem. Eng. Process. Process Intensif. 98(2015) 137-146.
[18] H.S. Santana, J.L. Silva Jr., O.P. Taranto, Optimization of micromixer with triangular baffles for chemical process in millidevices, Sensors Actuators B Chem. 281(2019) 191-203.
[19] T. Xie, L. Zhang, N. Zu, Biodiesel synthesis in microreactors, Green Process. Synth. 1(2012) 61-70.
[20] Y. Zhang, S.C. Born, K.F. Jensen, Scale-up investigation of the continuous phasetransfer-catalyzed hypochlorite oxidation of alcohols and aldehydes, Org. Process. Res. Dev. 18(2014) 1476-1481.
[21] T. Han, L. Zhang, H. Xu, J. Xuan, Factory-on-chip:modularised microfluidic reactors for continuous mass production of functional materials, Chem. Eng. J. 326(2017) 765-773.
[22] R.E. Billo, C.R. Oliver, R. Charoenwat, B.H. Dennis, P.A. Wilson, J.W. Priest, H. Beardsley, A cellular manufacturing process for a full-scale biodiesel microreactor, J. Manuf. Syst. 37(2015) 409-416.
[23] K. Wang, Y. Lu, G. Luo, Strategy for scaling-up of a microsieve dispersion reactor, Chem. Eng. Technol. 37(2014) 2116-2122.
[24] M.W. Bedore, N. Zaborenko, K.F. Jensen, T.F. Jamison, Aminolysis of epoxides in a microreactor system:a continuous flow approach to β-amino alcohols, Org. Process. Res. Dev. 14(2010) 432-440.
[25] W.K.T. Coltro, E. Piccin, E. Carrilho, D.P. de Jesus, A.F. da Silva, H.D.T. da Silva, C.L. Lago, Microssistemas de análises químicas. Introdução, tecnologias de fabricação, instrumentação e aplicações, Quím. Nova 30(2007) 1986-2000.
[26] J.M. Lee, M. Zhang, W.Y. Yeong, Characterization and evaluation of 3D printed microfluidic chip for cell processing, Microfluid. Nanofluid. 20(2016) 5.
[27] K.V. Wong, A. Hernandez, A review of additive manufacturing, ISRN Mech. Eng. 2012(2012), 208760. https://doi.org/10.5402/2012/208760(10 pages).
[28] P.J. Kitson, S. Glatzel, W. Chen, C.G. Lin, Y.F. Song, L. Cronin, 3D printing of versatile reactionware for chemical synthesis, Nat. Protoc. 11(2016) 920-936.
[29] C. Chen, B.T. Mehl, A.S. Munshi, A.D. Townsend, D.M. Spence, R.S. Martin, 3D-printed microfluidic devices:fabrication, advantages and limitations-a mini review, Anal. Methods 8(2016) 6005-6012.
[30] W. Gao, Y. Zhang, D. Ramanujan, K. Ramani, Y. Chen, C.B. Williams, C.C.L. Wang, Y.C. Shin, S. Zhang, P.D. Zavattieri, The satus, challenges, and future of additive manufacturing in engineering, Comput. Aided Des. 69(2015) 65-89.
[31] A.J. Capel, S. Edmonson, S.D.R. Christie, R.D. Goodrridge, R.J. Bibb, M. Thurstans, Design and additive manufacture for flow chemistry, Lab Chip 13(2013) 4583.
[32] G. Gaal, M. Mendes, T.P. de Almeida, M.H. Piazzetta, Â.L. Gobbi, A. Riul, V. Rodrigues, Simplified fabrication of integrated microfluidic devices using fused deposition modeling 3D printing, Sensors Actuators B Chem. 242(2017) 35-40.
[33] N.H. Moreira, A.L.D.J. de Almeida, M.H. de Oliveira Piazzeta, D.P. de Jesus, A. Deblire, A.L. Gobbi, J.A. da Silva, Fabrication of a multichannel PDMS/glass analytical microsystem with integrated electrodes for amperometric detection, Lab Chip 9(2009) 115-121.
[34] J. Norman, R.D. Madurawe, C.M.V. Moore, M.A. Khan, A. Khairuzzaman, A new chapter in pharmaceutical manufacturing:3D-printed drug products, Adv. Drug Deliv. Rev. 108(2017) 39-50.
[35] J. Goole, K. Amighi, 3D printing in pharmaceutics:a new tool for designing customized drug delivery systems, Int. J. Pharm. 499(2016) 376-394.
[36] S. Glatzel, M. Hezwani, P.J. Kitson, P.S. Gromski, S. Schürer, L. Cronin, A portable 3D printer system for the diagnosis and treatment of multidrug-resistant Bacteria, Chem 1(2016) 494-504.
[37] Y. Zhang, S. Ge, J. Yu, Chemical and biochemical analysis on lab-on-a-chip devices fabricated using three-dimensional printing, Trends Anal. Chem. 85(2016) 166-180.
[38] A.K. Au, W. Huynh, L.F. Horowitz, A. Folch, 3D-printed microfluidics, Angew. Chem. Int. Ed. 55(2016) 3862-3881.
[39] N. Battacharjee, A. Urrios, S. Kang, A. Folch, The upcoming 3D-printig revolution in microfluidics, Lab Chip 16(2016) 1720-1742.
[40] Y. He, F. Yang, H. Zhao, Q. Gao, B. Xia, J. Fu, Research on the printability of hydrogels in 3D bioprinting, Sci. Rep. 6(2016), 29977. https://doi.org/10.1038/srep29977.
[41] A.A. Yazdi, A. Popma, W. Wong, T. Nguyen, Y. Pan, J. Xu, 3D printing:an emerging tool for novel microfludics and lab-on-a-chip application, Microfluid. Nanofluid. (2016) 20-50.
[42] U.M. Dilberoglu, B. Gharehpapagh, U. Yaman, M. Dolen, The role of additive manufacturing in the era of industry 4.0, Procedia Manuf. 11(2017) 545-554.
[43] Y. Hwang, O.H. Paydar, R.N. Candler, 3D printed molds for non-planar PDMS microfluidics channels, Sensors Actuators A 226(2015) 137-142.
[44] B. Aghel, M. Rahimi, A. Sepahvand, M. Alitabar, H.R. Ghasempour, Using a wire coil insert for biodiesel production enhancement in a microreactor, Energy Convers. Manag. 84(2014) 541-549.
[45] A.V. Veličković, O.S. Stamenković, Z.B. Todorović, V.B. Veljković, Application of the full factorial design to optimization of base-catalyzed sunflower oil ethanolysis, Fuel 104(2013) 433-442.
[46] G. Anastopoulos, Y. Zannikou, S. Stournas, S. Kalligeros, Transesterification of vegetable oils with ethanol and characterization of the key fuel properties of ethyl esters, Energies 2(2009) 362-376.
[47] H.S. Santana, D.S. Tortola, E.M. Reis, J.L. Silva Jr., O.P. Taranto, Biodiesel synthesis in micromixer with static elements, Energy Convers. Manag. 141(2017) 28-39.